1
Faculteit Bio-ingenieurswetenschappen
Academiejaar 2011 – 2012
De relatie tussen abiotische bodemcondities, de bodemfauna en de
vegetatiesamenstelling van heischrale graslanden en graslanden onder
natuurherstel
Elyn Remy
Promotors: Prof. dr. ir. Kris Verheyen en dr. ir. An De Schrijver
Co-promotor: Dr. Eduardo de la Peña
Masterproef voorgedragen tot het behalen van de graad van
Master in de bio-ingenieurswetenschappen: Bos- en Natuurbeheer
2
Faculty Bioscience Engineering
Academic year 2011 – 2012
The relationship between abiotic soil characteristics, soil fauna
and vegetation composition of acidic, nutrient-poor grasslands
and grasslands under nature restoration
Elyn Remy
Promoters: Prof. dr. ir. Verheyen Kris and dr. ir. An De Schrijver
Co-promoter: Dr. Eduardo de la Peña
Master thesis proposed to obtain the degree of Master of Bioscience Engineering: Forest and
Nature management
3
“This master thesis is an examination document not corrected for possible stated mistakes. In
publications, referring to actual master thesis is allowed with the written permission of the
promoters.”
The promoters: The student:
Prof dr. ir. Kris Verheyen Elyn Remy
Dr. ir. An de Schrijver
4
Acknowledgements
First of all, I’d like to thank An De Schrijver. She accompanied me on all my field trips, aided with plant
identifications and created a spontaneous working atmosphere. She answered all my questions, both related
to the experiments and to the statistical analysis, and made time to guide me through the process of writing
a master thesis. She was truly a great mentor!
My co-promoter, Eduardo de la Peña, the “insect-specialist”, helped me with the analysis of the soil fauna.
The Berlese-Tullgren extraction was performed using his advice. He also taught me how to examine the
bacterial community through the use of Ecoplates. He made sure I could use the needed equipment.
I wish to thank my second promoter, Kris Verheyen, for giving me supporting advice and critics. Furthermore,
for answering all my questions regarding the statistical program RStudio, I’d like to thank Lander Baeten. A
word of gratitude to everybody at the Department of Forest and Water Management, Ghent University, for
the friendly and helpful atmosphere, especially to Luc and Greet for performing the chemical analysis of my
soil samples. Thanks to Predrag Miljkovic, the student who did his internship at the Laboratory of Forestry,
when I executed the vegetation surveys. Whenever he had time, he came along and helped with plant
identifications and taking soil samples.
Last but not least, I want to thank my family and friends, for listening to my constant talking about the
fascinating fauna and flora of acidic, nutrient-poor grasslands. Special thanks go to my brother, who reread
the whole document.
Elyn Remy
June 4th 2012
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Summary
Acidic, nutrient-poor grasslands used to cover a significant area of Europe and in addition Flanders, but land
use changes and eutrophication led to a drastic decline in their presence. Most nature restoration and nature
development takes place on formerly cultivated land, where it is necessary to lower the nutrient status in
order to obtain a species-rich target community. This research focused on the restoration of acidic, nutrient-
poor grasslands on sandy soils and took place in three Belgian nature areas (Liereman, Turnhouts
Vennengebied and Gulke Putten). We investigated the relationship between abiotic soil characteristics, soil
fauna and the vegetation composition. All necessary variables were obtained by means of vegetation surveys
and soil samples. Macrofauna was removed by hand, mesofauna was gathered by the Berlese-Tullgren
extraction and the microbial community was analyzed through the use of Biolog Ecoplates.
Deficiency in an essential nutrient (N, P, K) is crucial to limit plant growth and establish a diverse plant
community. High nutrient availability will lead to competition for light and favor the dominance of fast-
growing, high productive grasses. Recently, researchers provided evidence that P- rather than N (or K)-
enrichment induced species loss in a range of ecosystems. Indeed, P-limited soils (< 15 mg Olsen P kg-1)
contained overall more species. Furthermore, endangered (Red List) species and species typical for Nardo-
Galion grasslands (Calluna vulgaris, Pedicularis sylvatica) were more abundant on nutrient-poor sites. Soil
acidity is an important soil characteristic. At high pH values, grasses (Lolium perenne, Holcus lanatus) occur
with high relative cover, while species of the target community occur on sites with low pH values
(pH-KCl < 4.5).
Restoring a diverse plant community doesn’t solely depend on abiotic soil conditions, but also on the soil
food web, since soil fauna can steer the succession and diversity of the vegetation. The importance of
macro-, meso- and microfauna was assessed and our results suggest that microfauna has a larger influence
on the vegetation composition than the sampled macro- and mesofauna. However, these findings need to be
regarded with caution, and new experiments will be conducted to explore the soil fauna in more depth. Of
course soil biota are also affected by abiotic soil characteristics, especially by Ca.
Thus when a Nardo-Galion grassland needs to be reestablished, suitable abiotic soil conditions (low P
availability, low pH) are of primer importance, followed by a well-developed microbial community.
6
Samenvatting
Historisch gezien kwamen heischrale graslanden abundant voor in Vlaanderen en Europa, maar door
veranderingen in landgebruik en vermesting zijn deze soortenrijke graslanden zeldzaam geworden. Herstel
van dit type grasland gaat veelal door op voormalige landbouwgronden waarbij het steeds van belang is de
hoeveelheid voedingsstoffen in de bodem te verlagen, aangezien een hoge soortenrijkdom bereikt wordt op
gronden met een lage nutriëntenhoeveelheid. Dit onderzoek focust op het herstel van heischrale graslanden
op arme zandbodems en ging door in drie natuurgebieden in Vlaanderen (de Liereman, het Turnhouts
Vennengebied en de Gulke Putten). Hier onderzochten we de relatie tussen de abiotische
bodemkarakteristieken, de bodemfauna en de vegetatiesamenstelling. Al de nodige variabelen werden
bekomen door het uitvoeren van vegetatieopnames en het nemen van bodemstalen. Macrofauna werd met
de hand verwijderd, voor het verzamelen van de mesofauna werd de Berlese-Tullgren extractie gebruikt, en
de microbiële gemeenschap werd geanalyseerd via het gebruik van Biolog Ecoplates.
Limitatie van plantengroei door een tekort aan een essentieel voedingselement is cruciaal voor het bekomen
van soortenrijke natuur. Bij een te hoge nutriëntenbeschikbaarheid wordt de competitie tussen planten
immers gestuurd door de beschikbaarheid aan licht, wat resulteert in de dominantie van snel groeiende en
hoog productieve grassen. Wetenschappers bewezen onlangs dat vooral het fosforgehalte (P) in de bodem
een belangrijke rol speelt, meer nog dan het gehalte aan stikstof (N) en kalium (K). Uit dit onderzoek bleek
inderdaad dat bodems, arm aan biobeschikbaar P (< 15 mg Olsen P kg-1), een hogere soortenrijkdom
vertoonden. Bovendien kwamen bedreigde (Rode Lijst) soorten en typische soorten van heischrale
graslanden (Gewone struikhei, Heidekartelblad) meer voor op deze arme bodems. De zuurtegraad is een
belangrijke bodemeigenschap. Bij hoge pH waarden kwamen grassen (Engels raaigras, Gestreepte witbol)
met een hogere relatieve bedekking voor, terwijl soorten van de doelgemeenschap voorkwamen op sites met
lage pH waarden (pH-KCl < 4.5).
Voor het herstel van deze soortenrijke graslanden moeten naast abiotische randvoorwaarden ook de
ondergrondse biotische kenmerken optimaal zijn, aangezien bodemfauna de successie en diversiteit van de
vegetatie kan bepalen. Het belang van macro-, meso- en microfauna werd nagegaan en uit onze resultaten
bleek dat microfauna een grotere invloed heeft op de vegetatiesamenstelling dan macro- en mesofauna.
Deze resultaten moeten met voorzichtigheid benaderd worden, en nieuwe experimenten zullen uitgevoerd
worden om de bodemfauna beter te bestuderen. Natuurlijk wordt de bodemfauna ook beïnvloed door
abiotische bodemparameters, met name door het element Ca.
In de eerste plaats moeten de abiotische bodemparameters geschikt zijn voor het herstel van heischrale
graslanden (lage hoeveelheid biobeschikbaar P en lage pH), terwijl een goed uitgebouwde microbiële
gemeenschap ook voordelig is.
7
Table of content
1. Introduction .......................................................................................................................................... 10
2. Literature review ................................................................................................................................... 11
2.1. Acidic, nutrient-poor grasslands.......................................................................................................... 11
2.2. Plant diversity and abiotic soil properties............................................................................................ 12
2.2.1. Introduction ................................................................................................................................. 12
2.2.2. Nitrogen ...................................................................................................................................... 12
2.2.3. Soil pH ......................................................................................................................................... 14
2.2.4. Phosphorus .................................................................................................................................. 16
2.3. Plant diversity and productivity .......................................................................................................... 18
2.4. Soil fauna............................................................................................................................................ 18
2.4.1. Introduction ................................................................................................................................. 18
2.4.2. Microfauna .................................................................................................................................. 19
2.4.3. Mesofauna................................................................................................................................... 20
2.4.4. Macrofauna ................................................................................................................................. 21
2.5. Vegetation and soil fauna ................................................................................................................... 22
2.6. Ex-agricultural land ............................................................................................................................. 24
2.6.1. Secondary succession and soil fauna ............................................................................................ 24
2.6.2. Nature restoration ....................................................................................................................... 26
2.7. Plant species diversity and the composition of the soil food web ........................................................ 28
3. Materials and methods ............................................................................................................................. 29
3.1. Study area .......................................................................................................................................... 29
3.2. Vegetation surveys ............................................................................................................................. 30
3.3. Abiotic soil properties ......................................................................................................................... 30
3.4. Soil fauna............................................................................................................................................ 30
3.4.1. Invertebrate community .............................................................................................................. 30
3.4.2. Microbial community ................................................................................................................... 31
3.5. Data analysis....................................................................................................................................... 32
3.5.1. Diversity indices ........................................................................................................................... 32
3.5.2. Weighted mean Ellenberg scores ................................................................................................. 33
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3.5.3. Ordination ................................................................................................................................... 33
3.5.4. Classification ................................................................................................................................ 34
3.5.5. Statistical analysis (Mixed models and Mantel test) ..................................................................... 34
4. Results...................................................................................................................................................... 35
4.1. Vegetation .......................................................................................................................................... 35
4.1.1. Weighted mean Ellenberg scores ................................................................................................. 35
4.1.2. Species diversity and composition ................................................................................................ 36
4.1.3. Classification ................................................................................................................................ 37
4.2. Abiotic soil conditions ......................................................................................................................... 38
4.3. Soil fauna............................................................................................................................................ 39
4.3.1. Macro- and mesofauna ................................................................................................................ 39
4.3.2. Microfauna .................................................................................................................................. 41
4.4 Relationship between biotic and abiotic features................................................................................. 42
4.4.1. Relationship between vegetation composition and abiotic soil characteristics ............................. 42
4.4.2. Relationship between soil fauna and abiotic soil characteristics ................................................... 44
4.4.3. Relationship between vegetation composition and soil fauna ...................................................... 47
5. Discussion ............................................................................................................................................. 50
5.1. Relationship between vegetation composition and soil abiotic characteristics .................................... 50
5.2. Relationship between soil fauna and abiotic soil characteristics .......................................................... 53
5.3. Relationship between vegetation composition and soil fauna ............................................................. 55
6. Conclusion and future research ............................................................................................................. 58
7. List of abbreviations and symbols .......................................................................................................... 59
8. References ............................................................................................................................................ 60
9. Appendices ............................................................................................................................................ 72
Appendix I: VIF factors ............................................................................................................................... 72
Appendix II: Overview of plant species, Shannon-Wiener diversity index and eveness ............................... 73
Appendix III: Overview Stress value ........................................................................................................... 75
Appendix IV: NMDS ordination diagrams based on the vegetation surveys ................................................ 76
Appendix V: TWINSPAN ............................................................................................................................. 81
Appendix VI: The relationship between pH-KCl and exchangeable Al ......................................................... 87
Appendix VII: NMDS ordination diagrams based on macro- and mesofauna .............................................. 88
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Appendix VIII: Biolog Ecoplates .................................................................................................................. 94
Appendix VIIII: NMDS ordination diagrams based on the ACWD values of 31 carbon sources .................... 96
Appendix X: Mixed models ...................................................................................................................... 102
Appendix XI: NMDS correlations .............................................................................................................. 108
Appendix XII: CCA .................................................................................................................................... 110
Appendix XIII: Mantel test ....................................................................................................................... 111
Appendix XIIII: The relationship between Olsen P concentration and the number of Red List species ...... 112
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1. Introduction Acidic, nutrient-poor grasslands used to cover a significant area of Europe and in addition Flanders. In upland
sites they still occur in large areas, but in lowland area, such as the Netherlands and Belgium they are rare
and constrained in size (www.natuurkennis.nl). In Great Britain, these grasslands still cover an extensive area
(UK Biodiversity Group, 1998).Through land use changes, mainly intensive agriculture, soils became more
alkaline and nutrient-rich, inducing a strong decline in the appearance of these grasslands. Also
abandonment of the management led to a considerable decline in the presence of acidic, nutrient-poor
grasslands (Ellenberg, 1996), especially in Central Europe, where they almost exclusively occur in nature
reserves (Duprè et al., 2010).
Nitrogen (N) and phosphorus (P) are the two most important limiting nutrients in nutrient-poor semi-natural
grasslands (Van Landuyt et al., 2008). Not only direct application of fertilizers but also atmospheric deposition
enriched soils, causing a significant species loss (Wassen et al., 2005; Maskell et al., 2010). High N availability
will favor the dominance of fast-growing, high productive grasses such as Agrostis capillaris in dry conditions
and Molinia caerulea in wet conditions (www.natuurkennis.nl). Fertilization leads also to high P availability.
Moreover, sulphur (S) and N deposition will acidify soil via precipitated acids, oxidation of dry-deposited
compounds, loss of basic cations and nitrification1 (Stevens et al., 2009). Over the last three decades,
deposition of S compounds has decreased drastically in North America and Europe, but N deposition rates
have barely changed (NEGTAP, 2001). Wet acidic, nutrient-poor grasslands are faced with a third threat,
namely dessication (www.natuurkennis.nl).
Most nature restoration and nature development takes place on formerly cultivated land, where it is
necessary to lower the nutrient status in order to obtain a species-rich target community (Marrs and Gough,
1989). This is especially the case for P, a relative insoluble element with a long persistence in soil (Wild,
1988). Restoring a diverse plant community doesn’t solely depend on abiotic soil conditions, but also on the
soil food web. Bacteria and fungi insure the breakdown of organic matter to inorganic compounds,
determining the availability of nutrients to plants (Bardgett, 2005). They can also enhance nutrient
acquisition of plants through symbiotic relationships. Other soil animals influence the nutrient cycling by
feeding on microbes and changing the amount and form of organic matter in soil. Soil fauna can also affect
plants directly as pathogens or root feeders (Bardgett, 2005).
Many studies have focused on the role of N and P in the restoration of species-rich grassland (Janssens et al.,
1998; Critchley et al., 2002; Gilbert et al., 2009; Maskell et al., 2010), while other researchers investigated soil
fauna and their impact on plant community (Spehn et al., 2000; De Deyn et al., 2003: Sugiyama et al., 2008;
Eisenhauer et al., 2011; Sabais et al., 2011). The goal of this study is to link both views and to retrieve the
relationship between abiotic soil conditions, the soil fauna and the vegetation structure and composition of
acidic, nutrient-poor grasslands. In this study we focus on the abundance of earthworms, beetles, mites,
1 Nitrification is the oxidation of ammonium (NH4+) to nitrate (NO3
-). During this process two protons (H+) are released,
accelerating soil acidification.
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springtails, nematodes, potworms and bacteria and their relationship with vegetation diversity and
composition, as well with soil conditions, being P availability (Olsen-P and total P), pH and exchangeable
concentrations of aluminium (Al) and calcium (Ca).
In the next section (§2) a summary is given of the results of previous and related research. Afterwards the
materials and methods (§3) of this study are mentioned, followed by an overview of the results (§4). These
are critically reviewed in the discussion (§5), from which a conclusion (§6) is drawn.
2. Literature review
2.1. Acidic, nutrient-poor grasslands Nardo-Galion grasslands are dominated by grasses (Poaceae), sedges (Cyperaceae), rushes (Juncaceae), forbs
and dwarf shrubs. Frequently occurring plant species are matt-grass (Nardus stricta), heath grass (Danthonia
decumbens), common tormentil (Potentilla erecta), heather (Calluna vulgaris), bog heather (Erica tetralix)
and purple moor grass (Molinia caerulea). Mosses found in this type of grassland are neat feather-moss
(Scleropodium purum), hypnum moss (Hypnum cupressiforme) and common haircap moss (Polytrichum
commune). Not much animals are bound to this habitat, since mostly the area of this type of grassland is too
small as is the case for Flanders (e.g. for breeding birds, foxes,…) and due to a low food supply (low numbers
of mice are quite typical). Overall, Nardo-Galion grasslands contain a rich fungal diversity, butterflies, e.g. the
alcon blue (Maculinea alcon), spiders and ground beetles (www.natuurkennis.nl). Some rare reptile species
occurring are the viviparous lizard (Lacerta vivipara) and the smooth snake (Coronella austriaca).
The soil is strong to moderately acid, with a pH range of 4 to 6. The soil texture is often sandy to sandy loam.
In Flanders, the most important differential factor is moisture content, defining wet and dry acidic, nutrient-
poor grasslands. Wet representatives are characterized by a groundwater level at a surface level during
wintertime and a groundwater level deeper than 1.5 m during summertime.
Nardo-Galion grasslands resulted from extensively cultivated grass- and hayfields in large parts of Central and
Western Europe (Ceulemans et al., 2009). On the other hand they can also originate from disturbing
(mowing, burning, sod-cutting, treading) heath land communities. They differ from the latter in that they are
more diverse and not dominated by low-remaining shrubs. Intensive forest management can also lead to this
biotope. Degradation was initiated by the application of manure, leading to forest or intensively managed
grassland. When management is abandoned, this grassland evolves to heathland on the most poor and
undisturbed fields. However, due to high atmospheric deposition succession will take place in different
stages: first grasses will dominate, followed by brushwood and finally forest will develop
(http://www.inbo.be/docupload/1521.pdf).
Management consists of not interfering, mowing once a year (e.g. in the beginning of August for Gulke
Putten), extensive grazing (by sheep, goat, ponies, donkeys or Galloway cows) or burning (detrimental to
fauna and not an option in densely populated areas). More nutrient-rich grasslands can be mown twice a
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year (end of June and beginning of September) to lower the nutrient status
(http://www.inbo.be/docupload/1521.pdf).
2.2. Plant diversity and abiotic soil properties
2.2.1. Introduction
Grasslands of the highest botanical value are generally found on nutrient-poor soils. Species richness
diminishes with increasing nutrient availability, which favors competitive species capable of rapid growth and
biomass accumulation, such as perennial grasses (Bakker and Berendse, 1999). Thus, nutrient limitation is
one of the most important factors influencing plant community structure (Critchley et al., 2002).
Unfortunately, most soils are disturbed by human activities, which lead to eutrophication, acidification,
desiccation, … (Bakker and Berendse, 1999). Since the 1950s, most farmers have been applying fertilizers to
increase the yield of their land. This residual soil fertility may form a major obstacle in the restoration of
degraded semi-natural grasslands. Restoration of ecological diversity in grassland communities requires,
besides suitable abiotic conditions, an appropriate management and colonization of the target species
(Critchley et al., 2002). These measures can only be effective if the atmospheric deposition of nutrients
doesn’t exceed critical levels. The critical N load for Nardo-Galion grassland lies between 10 and 20 kg N ha-1
yr-1 (Decleer, 2007). In the past, this limit was exceeded in densely populated and industrialized regions such
as Flanders, but nowadays the average yearly deposition equals 20,4 kg N ha-1, whereas this amounted to
32,7 kg N ha-1 in 1990 (MIRA Achtergronddocument 2011 Vermesting).
2.2.2. Nitrogen
World-wide deposition of NOx and NHx more than tripled between 1860 and the early 1990s (Galloway et al.,
2004). Since the 1990s acidifying deposition (of Sox, NHx and NOx) has declined in Flanders and Western
Europe, although this is less pronounced for NHx and NOx (http://www.milieurapport.be). Most of the N input
(84%) either accumulates in the soil or leaves the system by nitrate leaching, denitrification or ammonia
volatilization (Van Der Meer, 1982). This N deposition has direct effects, e.g. a higher N supply to the
vegetation (Bakker and Berendse, 1999), but also indirect effects, resulting from the increasing rate of
accumulation of soil organic matter. This has in turn led to an accelerated increase in N mineralization during
succession (Berendse, 1990). Other indirect effects are soil acidification (see § 2.2.3.), base cation depletion
(Ca2+, Mg2+ and K+) and higher Al3+ concentrations (which are both linked to soil acidification) (Bowman et al.,
2008). In most communities, fast growing perennial grasses benefit from the increase in N supply, since they
outcompete a great variety of low-statured or slow-growing species adapted to nutrient-poor soils (Bakker
and Berendse, 1999).
The effect of N deposition on different vegetation types (forest understoreys, grasslands, heathlands,
freshwater wetlands, salt marshes and bogs) has been studied by a meta-analysis conducted by De Schrijver
et al. (2011), based on data from North America, Europe and Australia. The impact of cumulative N input on
these vegetation types and the present growth forms (forbs, graminoids, shrubs, bryophytes and lichens) was
analyzed. The response of both vegetation types and growth forms was very variable, in that grasslands and
salt marshes showed an increase in biomass as a result of N addition, while heathlands, bogs and freshwater
wetlands had a neutral response and forest understoreys a negative response. Forb and shrub biomass didn’t
13
change following N addition, whereas bryophyte biomass decreased and graminoid biomass increased. Grass
species are able to react fast on increased N availability, producing more biomass, and consequently more
litter as a result of N input. This limits place and light availability for other low-statured species, such as forbs
(e.g. Bobbink, 1991; Wedin and Tilman, 1996). Also bryophytes are not able to cope with increasing plant
cover (Virtanen et al., 2000). Arróniz-Crespo et al. (2008) investigated the impact of N deposition on two
bryophyte species within acidic grassland. Their abundance strongly declined but differed between the
species, indicating that some species are more tolerant. This was also reflected in the shoot K concentration,
which decreased for one species due to the exchange of NH4+ and K+ or due to a direct toxic effect of N,
causing leakage of K+ ions (Pearce et al., 2003). Ericaceous shrubs are not favoured by high N input, since they
own an N-conserving strategy, which is necessary to survive in low-nutrient environments (Chapman et al.,
2006). Several authors (Krupa, 2003; Kleijn et al., 2008) proved that shrubs and forbs are sensitive to high
NH4+ concentrations, whereas graminoids are not (van den Berg et al., 2005). Concerning species richness, all
vegetation types combined showed a significant decline, but when considered separately only heathland and
grassland had a negative correlation with N addition. Furthermore, species richness decline in grasslands and
heathlands was significantly correlated to the cumulative N input, with a fast species loss at low levels of
cumulative N input or at the beginning of the addition, followed by an increasingly slower species loss at
higher cumulative N inputs.
Maskell et al. (2010) stated that N deposition affected species richness and vegetation composition in
different habitats (heathland, acid, calcareous and mesotrophic grassland), having a positive influence on
grasses but a negative one on the presence of forbs, the latter being different to what De Schrijver et al.
(2011) found (neutral response). They showed that in acid grassland and heathland acidification rather than
increased fertility was responsible for species loss, in contrast with calcareous grasslands where the decline in
species was allocated to eutrophication. Thus, the relationship between plant traits and N deposition differed
in different habitat types.
Duprè et al. (2010) focused on the effect of N deposition on species richness and composition in European,
acidic grasslands (situated in Great Britain, Germany and the Netherlands). Mean Ellenberg values (see §
3.5.2.) for light (mL), moisture (mF), soil pH (mR) and fertility (mN) were calculated and cumulative N
deposition was estimated. Mean R and N values lay between 2 and 4, but some plots had values lower than
2, demonstrating the acid and nutrient-poor soil conditions. Most variation in species composition was
explained by mean R and mean N values. Models were established to explain the variation in species richness
and based on several variables. Area was strongly positively related to species richness. Geographical
variables (longitude and altitude) had weak effects, but latitude was correlated with species richness
(increasing with increasing latitude in Great Britain, but decreasing in Germany). The greatest impact was
noticed for mean R, positively related to dicots and negatively to grasses. The second most important
variable was N deposition, influencing the number of all grasses (positively), dicots and bryophytes
(negatively) in all three countries. In time a clear increase in the proportion of grasses and ruderals could be
seen in Germany and the Netherlands (based on data since 1940s, lacking for Great Britain). In contrast,
dwarf shrubs and many herbaceous dicots (forbs) became less frequent, except species bound to more fertile
grasslands e.g. Rumex acetosa. Abandoning management of grasslands (grazing, mowing) can contribute to
14
the reduction of species diversity and favor growth of grasses. Sulphur (S) deposition was not retained in the
experiment, due to the strong correlation with N deposition. Furthermore, since soils are characterized by a
low pH, the acidifying effect of S deposition was negligible.
Also Stevens et al. (2010) investigated to what extent N deposition forms a threat to species richness of acid
grasslands. All grasslands were situated in the Atlantic biogeographic zone of Europe. They too observed a
negative exponential relationship between species diversity and N deposition, indicating higher species loss
at low cumulative N addition. This can be clarified by the extinction of N-sensitive species at lower cumulative
levels, resulting in a plant community of less sensitive species and thus reducing species loss when N keeps
accumulating. Via multiple regression they identified other drivers, responsible for species loss. At high
deposition rates soil pH and nitrate concentrations are the next most important variables, at low deposition
rates this seemed to be the extent of extractable aluminium (Al). These results implicate that protection of
sensitive grasslands (low buffer capacity, due to low concentration of base cations, Skiba et al., 1989) can
only be obtained when atmospheric deposition remains very low (Emmet, 2007). Nowadays, deposition has
to be below a critical load of 10 to 20 kg N ha-1 (Bobbink et al., 2003), but these experiments show that such a
deposition might already result in a significant species loss. In accordance to other studies (Bakker and
Berendse, 1999; Duprè et al., 2010; Maskell et al., 2010) the greatest decline was accounted for by forbs. In
2009, Stevens et al. defined indicators to deduce the impact of N deposition on acid grasslands. They
concluded that presence or absence of species, nor plant cover are suitable indicators (due to other drivers
such as management and land use history), but species richness, forb richness and the grass:forb ratio are
more appropriate.
2.2.3. Soil pH
The atmospheric deposition of nitrogenous and sulphuric compounds has caused a significant increase in the
rate of soil acidification. Luckily, deposition of sulphuric compounds has declined, but this doesn’t apply for N
deposition (Bakker and Berendse, 1999). Acidification can result from the dissolution of carbon dioxide (CO2)
to carbonic acid (H2CO3), from nitrification, from atmospheric pollution and natural sources (volcanic
eruptions) and from the breakdown of organic matter rich in phenolic and carboxyl groups (Bardgett, 2005).
Plant species richness in grassland communities has been found to be strongly correlated with soil pH (Grime
J.P., 1979). This is confirmed by Critchley et al. (2002), who stated that soil pH showed the strongest
relationship with the vegetation of lowland grasslands in Great Britain, followed by total N and organic
matter. The same was retrieved by an experiment of Duprè et al. (2010) where soil pH was the main driver of
species richness on acidic grasslands, resulting in a positive influence on total number of vascular plants and
the portion of dicots. Only grasses experienced a negative influence of increasing pH. Most European plant
species show an ecological optimum around higher pH values (i.e. higher than pH values of acidic grasslands)
(Schuster and Diekmann, 2003), meaning that a decrease in soil pH will lead to a decline in species that do
not tolerate acid soils. Indeed many species are sensitive to high H+ or Al3+ concentrations (Kleijn et al., 2008).
Few species are able to tolerate a lowering of soil pH and the few that can, such as Molinia caerulea, are able
to dominate (Maskell et al., 2010). Bryophytes seem to be sensitive to Al3+, which becomes available in high
concentrations at soil pH lower than 4.5 (Virtanen et al., 2000). Soil pH also affects the bioavailability and
15
mobility of other metals (Tyler and Olsson, 2001), such as lead (Pb) and iron (Fe) which show the same
behavior towards soil acidity, becoming more available at pH values below 5 (Stevens et al., 2009).
Thus soil pH clearly influences vegetation, but also the rate of nutrient availability (cations, P) and soil biota
(Bardgett, 2005). In acidic soils (pH below 4.5), unstable clay minerals release soluble Al (Kennedy, 1992),
which can be toxic to plants and microbes. Ions such as calcium (Ca), potassium (K) and magnesium (Mg)
leach out and are replaced by protons (H+) and Al (Jönsson et al., 2003). Increasing the concentration of base
cations (Ca, K and Mg) in the soil solution can mitigate Al toxicity (Alva et al., 1986). Under acid conditions,
most P is found in the form of Fe and Al phosphates, compounds that are not fit for plant uptake. Phosphates
will generate soluble P by dissolving, a reaction triggered by the rise of the pH, with a highest P availability
between pH values of 6 and 7 (see § 2.2.4.). All soil organisms are tolerant for certain pH ranges. For instance,
earthworms do not tolerate acid soils well (except epigeic species) (Edwards, 2009), but enchytraeid worms
(also known as potworms) do, making them the functionally dominant soil organisms in these circumstances
(Bardgett, 2005).
The soil acidity of formerly cultivated land is influenced by reforestation in several ways: by atmospheric
depositions, by the quality of the litter, by symbiotic relationships when planting trees living in symbiosis with
N-fixing bacteria and by nutrient uptake (De Schrijver et al., 2011). De Schrijver et al. (2011) investigated soils
in West Flanders that were for at least 50 years under cultivation and the impact of different tree species on
soil acidification. According to de Vries and Breeuwsma (1986), leaf litter with poor quality produces more
organic acids. N2-fixing bacteria raise the amount of reactive N in the soil (Compton et al., 2003). Tree roots
excrete H+ to solve the disequilibrium between anions and cations, caused by a higher uptake of cations
(Nilsson et al., 1982). Acid soils contain higher Al3+ and lower exchangeable base cation concentrations
(Bowman et al., 2008). This was demonstrated for increasing forest age, which was accompanied by a
decrease in soil pH and exchangeable Ca2+ and an increase in exchangeable Al3+ (De Schrijver et al., 2011).
This doesn’t only impact trees (lower uptake, damaged root structure and function) (Weber-Blaschke et al.,
2002), but also soil fauna e.g. burrowing earthworm species (sum of endogeic and anecic species) (Muys and
Granval, 1997). These earthworm species play an important role in litter decomposition (Edwards, 2009).
Poor leaf litter quality (high C and lignin concentration, low Ca2+ concentration) induces absence of burrowing
species, enhancing litter accumulation. The influence of acidifying processes diminished with soil depth (for
all tree species Al3+ concentrations declined with depth, for two species soil pH and Ca2+ increased and the
other three species showed no response for the latter two variables, possibly due to bioturbation by
earthworm burrying). Thus, burrowing earthworms mitigate soil acidification by mixing the topsoil with litter,
by mixing upper layers with deeper soil layers (richer in base cations) and by egesting casts2 (De Schrijver et
al., 2011).
2 Mineral soil and organic matter are mixed in the gut of earthworms and enriched with organic secretions. This slurry is
colonized by microbes, responsible for the breakdown of soil organic matter. When the casts are egested (in soil or on
the surface), microbes remain active, enhancing soil fertility.
16
2.2.4. Phosphorus
Not only N and pH should be regarded, also P and K should be taken into account since grasslands of high
botanical value are generally associated with lower levels of these nutrients (Critchley et al., 2002). Soil
consists of inorganic (minerals or salts) and organic P (humus). P occurs in nature mainly in the form of
phosphates, chemical bounds of P and oxygen (Schoumans et al., 2008). P is mainly utilized by plants as
inorganic phosphates.
Soil P can be divided into three major pools that are in dynamic equilibrium (Stevenson and Cole, 1999;
Richter et al., 2006): labile, slowly cycling, and occluded P pools. Labile P is available for immediate biological
uptake (by flora and fauna) (Tiessen and Moir, 2008) and consists of phosphate in soil solution or phosphates
that desorbs or mineralizes from (in)organic soil compounds (Vandecar, 2009). Slowly cycling P is phosphate
adsorbed onto soil particles, inorganic and organic phosphate that has reacted with elements (such as Ca, Al
or Fe), and more stable organic P. This type of P can easily be converted to the labile P pool (Richter et al.,
2006). Phosphates can also be occluded, meaning that they remain in the soil for years without being
available to plants. Consequently they have little impact on soil fertility (Stevenson and Cole, 1999). The
occluded P pool consists of insoluble inorganic compounds and organic compounds that are resistant to
mineralisation by microorganisms. Highest concentrations of Al and Fe compounds are measured in acid soils
(pH < 5), enhancing the process of fixation (i.e. the adsorption of phosphates). In soils with a pH value over 5,
phosphates can combine with Ca, which reaches a maximum concentration at pH 7.5. Most soil P occurs in
organic form e.g. as orthophosphate monesters or inositol phosphates (Bardgett, 2005).
Rooney et al. (2009) found that phosphate addition to acidic upland grassland soil significantly increased root
biomass, shoot biomass (especially of Lolium perenne, followed by Festuca ovina), soil pH, and microbial
activity. The increase in microbial activity as a result of phosphate addition reflects P limitations in natural
acidic grasslands. Both microbes and plants require P for their growth. In which form P occurs in soil (mineral
or organic) is dependent on several factors e.g. soil type, pH, vegetation type or fertilizer application (Curtin
and Smillie, 1984; Daly et al., 2001). Plants preferably use labile, inorganic phosphates (Curtin and Smillie,
1984), but this fraction is generally low in unimproved Nardo-Galion grassland. Thus, plants depend on the
microbial community for making phosphates bioavailable, through breakdown of organic matter and
solubilization of insoluble phosphates (Troeh and Thompson, 1993). Since the importance of P is known,
farmers have added soluble phosphates, available for uptake by plants and microbes to their land to increase
productivity (Withers et al., 2001). Rooney et al. (2009) also followed the change, resulting from phosphate
addition, in the fungal and bacterial community, which are responsible for P cycling (Bardgett, 2005). Results
showed that both communities decreased in biomass after phosphate addition and that the effect is
dependent on the aboveground plant species. The decrease of fungal biomass is probably due to a negative
response of mycorrhizal fungi (Rooney et al, 2009). Mycorrhizal fungi play an import role in nutrient limited
soils, where they aid plants in the acquisition of nutrients (especially N and P) (Bardgett, 2005), but become
rather redundant when P is added to soil. Arróniz-Crespo et al. (2008) tested the influence of simultaneous
addition on N and P on bryophytes, showing that some species were benefited by this treatment, while slow-
growing species were not. Wassen et al. (2005) provided evidence that P- rather than N-enrichment induced
species loss in a range of ecosystems (from terrestrial freshwater wetland to moist grassland) throughout
17
temperate Eurasia. This transect coincides with a decline in atmospheric N deposition. They confirmed that
highest diversity was obtained at intermediate productivity (between 200 and 600 g m-2) and at intermediate
tissue N:P ratios. Endangered species were most abundant on P-limited sites and their proportion increased
with increasing P-limitation. Fertilization has strongly enhanced P-availability (Gough and Marrs, 1990) and
the conservation of endangered species necessitates the restoration of P-limited ecosystems. These findings
were confirmed by Ceulemans et al. (2011), who selected nutrient-poor semi-natural grasslands in Western
Europe (United Kingdom, France and Belgium) based on a soil fertility gradient. More grassland species were
negatively influenced by elevated P availability (30 %) compared to elevated N availability (8 %). Furthermore,
they linked P susceptibility to plant traits, indicating that species characterized by stress tolerance, low
maximum canopy height and symbiosis with arbuscular mycorrhizae3 are more sensitive to high P levels.
There are several methods to extract P, but Olsen's method of P extraction is recommended for analyzing
soils of areas identified for habitat creation; values of less than 10 mg kg-1 will give the greatest potential for
the restoration of species-rich mesotrophic grassland (Gilbert et al., 2009). This is confirmed by Hommel et al.
(2006), who found a reference value of 5 to 9 mg P kg-1 for both dry and wet nutrient-poor, acidic grasslands.
Herr et al. (2011) found similar results and consider 15 mg Olsen P kg-1 as a threshold value to recreate a
diverse target community (Nardo-Galion grassland and heathland). Janssens et al. (1998) investigated the
relationship between soil chemical factors and plant diversity in old permanent grasslands of West and
Central Europe. They found the highest diversity at sites where the P concentration was below the optimum
for plant nutrition (50 to 80 mg P kg-1). Based on their findings, P concentration (extracted by acetate and
EDTA) and species richness are correlated by a humped-back curve reaching an optimum amount of species
around 40 mg P kg-1. The same relationship accounts for the Shannon-Wiener diversity index and the rarity
index (based on a relative rarity coefficient for each plant per region). This humped-back curve doesn’t apply
to other soil factors such as pH and organic matter content, indicating a more complex interplay between
these factors and species number. Ceulemans et al. (2009) stated that an optimal reestablishment of Nardo-
Galion grassland can be obtained at P availability lower than 3 mg kg-1. However, this low value results from
the applied technique to measure plant available P. In this experiment P values were measured by means of
ion exchange membranes, a technique which extracts less P to soil than the Olsen or NH4Ac-EDTA extraction
method. Applying P to a P-limited soil favors the abundance of legumes (Bobbink, 1991; Elisseou et al., 1995),
since this element is necessary for nodulation (Dunlop and Hart, 1987). This would in turn lead to a higher soil
N content via symbiotic fixation, which has been proven for Trifolium repens (Caradus and Snaydon, 1988).
3 Mycorrhizae are symbiotic relationships between fungi and vascular plants, insuring a more elaborate nutrient and
water uptake and a higher resistance (against heat, salt, heavy metals) for plants, while fungi obtain photosynthetic
compounds necessary for their growth (http://www.arboris.be). There are three types of mycorrhizae: endomycorrhizae
(fungal hyphae penetrate plant cells), ectomycorrhizae (fungal hyphae remain extracellular) and ericoid mycorrhizae
(symbiosis with plants of the family Ericaceae). Endomycorrhizae form vesicles (storage organs) and arbuscules (transfer
structures) inside the plant (http://dnn.cropower.com).
18
2.3. Plant diversity and productivity Tilman et al. (1996) stated that plant diversity influences grassland productivity and sustainability. Plant
species in a diverse community complement each other in the use of resources, utilizing limiting nutrients
more effectively. This is known as the diversity-productivity hypothesis. Both soil extractable NH4+ and NO3
-
decreased with increasing species richness, and undisturbed, native grasslands showed the same results. By
using resources more efficiently, nutrient leaching, diminishes, leading to a more sustainable (or closed)
nutrient cycle, which is known as the diversity-sustainability hypothesis. Bezemer and van der Putten (2007)
conducted an experiment to confirm the statement of Tilman et al. (1996). Different levels of species richness
were established (no sowing, 4 and 15 species sowed) and related to temporal stability. Non-sown plots,
where succession occurred naturally, showed the highest species richness, Shannon diversity and lowest
biomass production. A low biomass production could be explained by the restricted presence of legumes,
which were strongly related to biomass production. Extinction and colonization rates were lowest for the
plots with highest amount of sown species, resulting in a higher temporal stability. These results seem
contradictory to what Tilman et al. stated, but can be reconciled, since the plant species in the non-sown
plots were early-successional species (rapid growth, low competiveness), contributing to a low temporal
stability. Thus species composition and species richness are important drivers of ecosystem functioning
(Tilman et al., 2007).
2.4. Soil fauna
2.4.1. Introduction
The soil foodweb consists of microbes (bacteria and fungi), microfauna (body width < 0.1 mm; e.g. protozoa
and nematodes), mesofauna (body width 0.1 – 2.0 mm; e.g. microarthropods and potworms), macrofauna
(body width > 2.0 mm; e.g. earthworms and millipedes) and megafauna (e.g. some earthworms, Mollusca
and Coleoptera) (Bardgett, 2005; see Figure 1). Soil organisms can also be classified based on their body
length, resulting in three categories: micro-, meso- and macrofauna. Soil animals are assigned to the same
categories as based on their body width, except for the nematodes, who are now allocated to the mesofauna
(Coleman et al., 2004).
19
Figure 1: Classification of soil biota based on their body width (adapted from Swift et al. 1979).
In this research the megafauna and fungi are not considered. The soil fauna can also be subdivided based on
their feeding habit, allocating them to functional groups. Some organisms predate on microbes (microbial-
feeders) or other animals (carnivores), while others feed on litter (detritivores) or plant biomass (herbivores).
Some are not constricted to one feeding source and are called omnivores.
2.4.2. Microfauna
Microbes (bacteria, fungi, actinomycetes and algae) constitute the most abundant part of the soil food web.
They are the primary consumers, responsible for the decomposition of organic substances to inorganic
compounds (i.e. the process of mineralization). On the other hand, secondary consumers feed on microbes,
on each other and on organic matter (Bardgett, 2005).
2.4.2.1. Bacteria
The prokaryotic4 and unicellular bacteria move actively through soil by means of flagella; in absence of these
structures they are passively transported (via roots, fauna or water) (Bardgett, 2005). They occur in all
4 Prokaryotic cells lack a cell nucleus, mitochondria or any other membrane-bound organelles. Organisms with
prokaryotic cells belong to two taxonomic domains: the Bacteria and the Archaea (http://biology.about.com).
20
habitat types, surviving the most extreme conditions. Extracellular enzymes are produced to break down
organic matter. Other abilities can be attributed to certain bacterial genera, such as nitrification (by nitrifying
genera Nitrosomonas and Nitrobacter) and N fixation (by the symbiotic genus Rhizobium and the free living
genera Azotobacter and Clostridium) (Bardgett, 2005). Pasture soil can contain up to 1.8 107 cells per cubic
cm, while arable soil counts up to 2.1 1010 cells cm-3 (Torsvik et al., 2002).
2.4.2.2. Fungi
Fungi are eukaryotic5, filamentous organisms, consisting of hyphae (Bardgett, 2005). These hyphae form a
mycelium, which can weigh as much as 250 kg ha-1 in the upper 5 cm of grassland soil (Bardgett et al, 1993a).
The mycelium has several functions: degrading organic matter with extracellular enzymes, exploiting new
nutrient-rich regions and translocating nutrients through the mycelial network (Boddy, 1999). Fungi play
other important roles, as plant pathogens and food source of microbial-feeding soil fauna. They optimize and
stabilize soil structure by bounding particles together. Some fungi establish mutualistic associations with
plant roots (mycorrhizae), supplying the plant with nutrients, and receiving photosynthetic compounds in
return (Bardgett, 2005).
2.4.3. Mesofauna
2.4.3.1. Nematodes (Nematoda)
Nematodes (or roundworms) need a water film in the soil pores to be able to move, feed and reproduce.
They can be subdivided in functional groups according to the morphology of their mouthparts, since they can
be bacterial-feeders, herbivores, fungal-feeders, omnivores and carnivores (Bardgett, 2005). Because
nematodes are bound to certain states of ecosystems (old versus young, annual crops versus perennial
crops,…) they can be used as indicators for the ecosystem condition (Yeates, 1999;Ferris et al., 2001).
Nematodes seek actively spots in soil with high concentrated organic matter, such as the rhizosphere (the
region of the soil influenced by roots, root metabolites and associated micro-organisms) (Griffiths and Caul,
1993).
2.4.3.2. Springtails (Collembola)
Springtails are wingless insects of a few millimeters, with six abdominal segments occurring in all biomes
(Coleman et al., 2004). They are named after a springing apparatus ventrally on the abdomen, absent in
groups living in deeper soil layers. These groups also lack eyes and pigmentation according to Petersen
(2002). In the rhizosphere they are very numerous, reaching up to 100 000 organisms per square meter. Their
feeding source consists mainly of fungi.
2.4.3.3. Mites (Acari)
Mites posses rounded body forms and have in temperate grassland an equal biomass as springtails. Four
suborders occur frequently in soils: the Oribatei, the Prostigmata, the Mesostigmata and the Astigmata.
5 Eukaryotic cells have a cell nucleus and membrane-bound organelles, increasing the complexity and size of the cells.
Cells of animals, plants, fungi and protists (i.e the four kingdoms of the domain Eukarya) are eukaryotic
(http://www.cod.edu).
21
Species of these suborders differ in their feeding habit. Oribatid mites are fungivorous and/or detritivorous.
They are characterized by juvenile polymorphism (immature stadia do not resemble the adult stadium), slow
reproduction and high abundance in soil (negatively affected by cultivation, descending the number of
oribatid mites to 25 000/m²). They have a sclerotized (often calcerous) exoskeleton, lacking in the other
suborders (Coleman et al., 2004). They influence litter decomposition and nutrient cycling indirectly by
feeding (Petersen and Luxton, 1982). Mesostigmatic mites are mainly predators (the smaller ones predate on
nematodes, the larger ones on other microarthropods and their eggs), a few are fungivorous. Walter and
Ikonen (1989) proved in grasslands in the west of the United States that nematodes were mostly predated by
mesostigmatic mites. Prostigmatic mites are very diverse and can be predators (mostly of nematodes or
other microarhtropods and their eggs, just like mesostigmatic mites), microbial feeders, plant feeders or
parasites (Kethley, 1990). The biomass of prostigmatic mites is generally small, compared to the other
suborders, although their numbers are higher in temperate than in (sub)tropical habitats (Luxton, 1981b).
Astigmatic mites are most abundant in moist, organic soils (Coleman et al., 2004). Most of them are microbial
feeders, although some can live on fungi, algae or plant material (Philips, 1990).
2.4.3.4. Potworms (Enchytraeidae)
These are an important family of the oligochaeta, just like earthworms (discussed in § 2.4.4.1.). They are
much smaller than earthworms (up to 20 mm) and unpigmented (Coleman et al., 2004). They can be
distinguished from nematodes by their round body shape. 19 of the 28 genera are terrestrial, the other
genera occur in marine or freshwater habitats. Enchytraeid densities of grasslands lay between 2000 and
more than 20 000 individuals per square meter, lowering when land is being cultivated and highest in acid,
undisturbed ecosystems (van Vliet, 2000). Potworms ingest mineral and organic matter, such as plant
material, fungi and bacteria. They influence the microbial community by predation, diminishing the microbial
population, but enhancing the microbial activity. Soil structure is also affected by potworms, through the
excretion of fecal pellets and the creation of pores (Coleman et al., 2004).
2.4.4. Macrofauna
2.4.4.1. Earthworms (Lumbricidae)
Earthworms are physiologically adapted to all habitats characterized by enough soil water and a favorable
temperature for at least some part of the year. Inopportune periods are overcome by entering a temporary
dormant state (the aestivation or diapause) or by making a resistant cocoon that hatches when proper
conditions are met (Edwards and Bohlen, 1996). Their densities range from 10 to more than 2000 organisms
per square meter. Temperate grasslands can count 50 to 200 individuals per square meter, with the lower
value being typical for acid soils (Coleman et al., 2004). Land management is detrimental to earthworm
populations. In contrast, soils under nature restoration show a rise in earthworm densities (Edwards and
Bohlen, 1996). They can be assigned to one of the three ecological groups, following Bouché (1977): epigeics
(worms living in and feeding on leaf litter); anecics (worms forming vertical burrows in the soil) and endogeics
(worms inhabiting the mineral soil horizon and making horizontal burrows). Epigeic earthworms can be 15 cm
large and are pigmented bright red or red-brown. They utilize organically enriched substrates, such as plant
litter and the carbon-rich upper layers of the soil. Endogeic earthworms are often unpigmented and become
up to 20 cm. They live and feed in the soil up to 80 cm deep. Anecic earthworms live in burrows in the soil,
22
but feed on leaf litter. They are darkly colored at the head end (red or brown) and have paler tails
(http://www.earthwormsoc.org.uk). Earthworms form an important part of the soil fauna, as they are
ecosystem engineers. They influence the soil structure by forming burrows, hereby creating pores, which
facilitate aeration and infiltration. Leaf litter is pulled into the burrows and digested, resulting in the
production of casts. After some time (when all organic matter is decomposed) casts may harden into soil
aggregates (Coleman et al., 2004).
2.4.4.2. Other macrofauna
Isopoda
These saprovoreous crustaceans occur in a variety of habitats, but are susceptible to desiccation (Coleman et
al., 2004).
Diplopoda
Millipedes or Diplopoda are important saprophages of forests, where they are major consumers of organic
matter (Coleman et al., 2004).
Chilopoda
Centipedes or Chilopoda are predators in soil and litter, occurring in many biomes. Just like millipedes and
Isopoda, they are sensitive to desiccation (Coleman et al., 2004).
Hymenoptera
This order consists of ants and ground-dwelling wasps (Coleman et al., 2004). Ants are important soil
predators, due to their impact on soil structure as “ecosystem engineers” (Hölldobler and Wilson, 1990).
They change nutrient levels in soil by building nests and gathering food and predate on a wide variety of
animals, thus influencing the local food web indirectly and directly (http://www.sciencedaily.com).
Larvae
Juvenile stadia of Coleoptera (beetles) and Diptera (flies and mosquitoes) inhabit soil. The order of the
beetles consists of soil species that are predators, phytophages or saprovores. Many species of the Diptera
pupate in soil, thus being part of the soil food web. Fly larvae are saprovores or predators (Coleman et al.,
2004).
2.5. Vegetation and soil fauna Several experiments have tried to define the relationship between the aboveground biomass (vegetation)
and the soil fauna. In a study of an experimental grassland site in Germany, Gastine et al. (2003) found no
effects of plant diversity or functional group identity on several soil properties (including soil N availability,
microbial activity, and abundance and diversity of fauna). According to Sugiyama et al. (2008) eukaryote and
prokaryote abundance is driven by different parameters, whereby prokaryote (or bacterial) richness depends
on soil characteristics, while eukaryote diversity (protista, nematodes, microarthropods and mainly fungi)
depends on the vegetation structure. The higher the floral diversity, the higher the litter heterogeneity and
by consequence the soil decomposer group will be more diverse (Sugiyama et al., 2008).
23
Salamon et al. (2004) found in grassland field trials that plant species richness had no effect on the total
diversity of Collembola. This study was part of the BIODEPTH (Biodiversity and ecological processes in
terrestrial herbaceous ecosystems) project and conducted in Switzerland on calcareous, loamy soils. The
previously arable land was ploughed, left bare over the winter and harrowed. However, the number of
Collembola increased in the presence of a plant functional group, namely the legumes6, benefiting from
higher litter quality and the higher microbial biomass in the rhizosphere of these plants. But Sabais et al.
(2011) demonstrated that Collembola density and diversity increased with plant species and plant functional
group richness. This study was conducted as part of the Jena experiment, a large biodiversity experiment
located in the floodplain of the Saale river in Germany. The site was formerly used as an arable field and
ploughed and harrowed several times before the experiment was established. The Collembola benefited
from higher food resources, namely from a higher quantity and quality of litter and a higher root and
microbial biomass. Changes in the Collembolan community will impact plant productivity and composition,
because the primary producers rely on microbial and animal decomposers in terms of nutrient availability
(Bardgett, 2005). The Collembola also steer the microbial community, directly by feeding on them and
indirectly by changing the nutrient availability (Griffiths and Bardgett, 1997). By feeding of meso- and
macrofauna on microbes, the microbial activity will increase and thus the plant nutrient availability (Spehn et
al., 2000).
Spehn et al. (2000) examined the effect of plant diversity on soil heterotrophic activity in grassland
ecosystems, located on formerly cropped calcareous, loamy soils in Switzerland. They found that the
reduction in plant biomass (due to a lower number of plant species) had more pronounced effects on voles
and earthworms than on microbes. This means that higher trophic levels are more strongly affected than
lower trophic levels, but all trophic levels will be influenced. Microbial biomass will decrease, because less
organic carbon sources enter the soil, thus limiting soil microbial activity (Smith and Paul, 1990; Van de Geijn
and van Veen, 1993). Consequently, mesofauna, depending on bacteria and macrofauna as a food supply,
may suffer from plant diversity loss. Thus, reducing the plant biomass affects the whole decomposer
community. Koricheva et al. (2000) also investigated the response of different trophic groups of invertebrates
to manipulations of plant diversity in grasslands. They found that the populations of the most sedentary and
host specific herbivores were stronger influenced by plant species and functional group diversity than the less
specialized or more mobile species. The activity and total number of predators was negatively correlated with
plant species and functional group richness, meaning that monocultures counted more predators. The
presence of legumes induced a higher number of invertebrates. The proportion of the other two functional
groups, grasses and non-legume forbs, had no significant impact on the different trophic groups of
invertebrates.
6 Legumes are able to fixate atmospheric nitrogen (N2), through a symbiotic relationship with bacteria (rhizobia).
Rhizobia are attracted to the roots by plant organic molecules, flavonoides. Bacterial infection is followed by local rapid
growth of the plant tissue, creating nodules. Plants provide rhizobia with water and nutrients, while the bacteria
produce plant available N from N2 (http://www.public.iastate.edu/~teloynac/354n2fix.pdf).
24
Eisenhauer et al. (2011) studied the effect of plant species richness in experimental grassland on nematodes.
He found that herbivorous nematodes dominated soils with low vegetation diversity, while species-rich plots
were dominated by microbivorous nematodes. Thus higher plant species richness evokes a shift in the
abundance of two functional groups of nematodes, hereby positively affecting the plant performance by
stimulating nutrient cycling. De Deyn et al. (2004) showed in experimental grassland trials that the soil
nematode community structure and diversity is driven by both species diversity and species identity (i.e.
plant species), but the effect of certain plant species was stronger than diversity treatments. Plant species
identity affected primary and secondary decomposers more than carnivorous and omnivorous nematodes
(i.e. the higher trophic levels), confirming that feeding groups closely interacting with plants are more fiercely
influenced. Root zones of Holcus lanatus, Agrostis capillaris and Centaurea jacea showed highest abundance
of plant-feeding nematodes. Moreover, the feeding type of the nematodes varied between the plant species,
where grass species (H. lanatus and A. capillaris) favored the dominance of ecto- and semi-endoparasites,
while forb species (C. jacea) favored sedentary endo- and ectoparasites. The positive impact of plant species
diversity can be allocated to the complementarity in resource quality, rather than the increase in total
resource quantity.
The relationship works in both directions, since soil fauna influences the grassland succession and diversity
and plant community diversity and structure steers soil fauna. The soil invertebrates enhance secondary
succession by preferably feeding on the mid-succession dominant plant species, hereby suppressing them
and insuring a high diversity (De Deyn et al., 2003). Eisenhauer et al. (2010) showed that soil arthropods are
beneficially to plant performance in grasslands ecosystems of different diversity. They investigated the effect
of the application of a contact insecticide on soil fauna and two plant functional groups, grasses and forbs.
The insecticide reduced soil herbivore abundance, which would lead to a higher plant biomass in the treated
plots. However, this was not the case, indicating the importance of soil decomposer animals. Especially
Collembola densities were affected negatively by the insecticide (except some families). Changes in this
trophic group led to a decline in nutrient mineralization (and thus plant nutrient availability) and alteration of
the soil microbial community, suppressing plant growth. Numbers of soil predators diminished too. The
impact of soil arthropods was not dependent of plant functional group (both grasses and forbs showed the
same results), nor of the resident plant community.
2.6. Ex-agricultural land
2.6.1. Secondary succession and soil fauna
Soil fauna influences vegetation directly as parasites, root feeders, pathogens or via a symbiotic relationship
(van der Putten et al., 1993) and indirectly by decomposing litter, soil organic matter and root exudates
(Wardle, 2002). Kardol et al. (2007) investigated the microbe-mediated plant-soil feedback7 on ex-arable land
in the Netherlands (loamy soil with a neutral pH and rich in N and P). To retrieve the influence of the
microbial community on plant community, they used microcosms (soil cores of the same width and depth)
7 The plant-soil feedback is defined as the interaction between (a)biotic soil conditions and vegetation (Bever et al.,
1997).
25
planted with monocultures and mixtures of early-successional and mid-successional species (both containing
grasses and forbs). In a second phase the plant-soil feedback was determined by planting seedlings (with the
same establishment as the first set-up) in the soil obtained from the first stage of the experiment. The
process of plant-soil feedback consists of two phases. In the first phase, plants alter the structure of the soil
community (Chanway et al., 1991, Kowalchuk et al., 2002) what results in a negative (reduced growth) or a
positive feedback (increased growth) on plant performance (Bever et al., 1997, Thrall et al., 1997). The
responses differed for the monocultures (showing both negative and neutral responses), but in mixed plots
the plant-soil feedback response of the early-successional species was negative. This response is attributed to
plant pathogens and root feeders, and not to nutrient depletion, since there was no difference in shoot
biomass between the first and the second stage of the experiment. Furthermore, they showed that the
composition of mid-successional species is determined by the history of the soil, i.e. the presence and
identity of early-successional species. Mid-successional grasses are for instance favored on soils previously
established by early-successional forbs. This corresponds with the findings of Bezemer et al. (2006) who
investigated the effects of plant species and plant functional group on abiotic and microbial soil properties
and their impact on plant-soil feedback. The experiments were conducted on fields under nature restoration
since 1996, consisting of two soil types, sandy and chalk soils. Determination of the microbial community was
assessed by means of the phospholipid fatty acids (PLFA). They retrieved a significant relationship between
plant species and soil chemical properties on sandy soils, while monoculture identity (i.e. the species
constituting the monoculture) affected the PLFA composition on chalk soils. Furthermore, chalk soils
demonstrated a significant soil-species interaction, indicating that plant performance depended on the fact
of soils were formerly planted with the same species. Plant performance on sandy soils on the other hand
depended on the plant functional group (grass or forb) previously grown on the soil, performing better on
‘forb soil’. Thus soil type influences plant-soil feedback, where the response on sandy soils is steered by
abiotic features and by soil biota on chalk soils. This evidence should also be taken into account in restoration
management.
Another experiment was conducted by Kardol et al. (2006) to find the temporal variation in the plant-soil
feedback. Several sandy and sandy loam abandoned fields in the Netherlands were defined as early-
successional, mid-successional and late-successional fields. Microcosms were planted with species (two
grasses and two forbs), typical for each succession stage. After the first harvest, soils were replanted with the
same species to account for plant community feedback. Early-successional species showed a negative
feedback (producing less biomass in the second set-up) and mid-successional species were indifferent to the
manipulations (neutral feedback). Shoot biomass of late-successional species was higher in the second
growth period and higher when grown in late-successional soil, indicating a positive plant-soil feedback. This
didn’t result out of relaxed competition, nor of decreased nutrient availability (in accordance with the results
of the previous section), but was due to a change in the soil fauna composition. Bacterial biomass didn’t
change during the experiment, but fungal and mycorrhizal biomass reached a maximum in late-successional
soil. Thus on short time scales (less than decades), plant succession may mainly be dependent on the
presence of harmful and beneficial organisms in the rhizosphere (Van der Putten et al., 1993; Bever, 2003)
instead of changing abiotic soil properties. A second conclusion is that negative plant–soil feedback enhances
26
succession in early stages and positive plant–soil feedback retards succession in later stages (while
aboveground herbivory has the reverse effect) (Kardol et al., 2006).
In another study, Kardol et al. (2009) focused on the effect of secondary succession on oribatid mites and
nematodes on well-drained, sandy soils. They determined diversity on three levels: the α-diversity (diversity
of the sampled plot), β-diversity (diversity between plots) and γ-diversity (diversity of a whole region)
(Whittaker, 1960). Their goal was to prove that each biodiversity scale increased with time (being the time of
cessation of agricultural practices). Formerly arable land was selected in the Netherlands and classified as an
early, a mid or a late stage of succession. A semi-natural heathland was taken as reference ecosystem.
Abundance of oribatid mites increased toward the reference system, while nematode density showed no
difference in the four succession stages (γ-diversity). The other diversity scales showed different evolutions,
since α-diversity was highest in mid-successional and reference sites for mites and in mid- and late-
successional sites for nematodes. In contrast, β-diversity diminished towards the late-successional sites for
mites and was lowest in early-successional sites for nematodes. Thus nematode communities became more
heterogeneous during succession and were dependent on the historical legacy of land cultivation, whereas
the β-diversity of mites depended on the colonization process and became more homogeneous (Gormsen et
al., 2006; Zaitsev et al., 2006). Low α-diversity of mites could be explained by limited colonization of the local
species pool, while α-diversity of nematodes is steered by the dominant vegetation (dominant plant species
favour certain nematode taxa), which also explains a nearly constant γ-diversity. It can be concluded that
changes in diversity, as a result of abandonment of agricultural practices, depend on the observed scale and
species.
Since nematodes are fast-reproductive organisms, they react rather fast on land use changes (Hànel, 2003),
making them ideal indicators for changes in the soil food web. Kardol et al. (2005) hypothesized that plant
and nematode community show the same development towards a semi-natural reference condition on sandy
and sandy loam ex-arable soils in the Netherlands. Results demonstrated that total densities of nematodes
in the ex-arable fields did not differ from those in semi-natural fields. But the proportion of the functional
groups changed, as was reflected by the Channel Index (CI), the weighted ratio of opportunistic bacterial and
fungal feeding nematodes (Ferris and Matute, 2003). The CI and the field age were positively related,
indicating a change in dominance of bacterial feeding to fungal feeding nematodes. Plant community did
change toward the reference site, in case of a matt-grass sward, but not for the heath land communities,
while nematode communities showed an opposite evolution, suggesting that nematode and plant similarities
correlated with different reference sites. The similarity of the plant community to the semi-natural sites was
highest in the two fields that were less recently abandoned, whereas the similarity for the nematodes was
highest in sites, characterized by intermediate lengths of abandonment. The relative nematode community
similarity to the semi-natural sites was higher than relative plant community similarity (except for the two
oldest fields).
2.6.2. Nature restoration
In an experiment, again conducted by Kardol et al. (2009), a formerly cultivated sandy field in the
Netherlands (from which 50 cm of the topsoil was removed) was covered by hay and/or soil and alternatively
transplanted with turfs. These two approaches were used to find out if simultaneous input of seeds and soil
27
organisms facilitate the development towards the target community. None of the performed actions had an
impact on nematode abundance, nor on taxonomic composition. Pywell et al. (2007) conducted studies on
turf transplantation and evaluated the impact on plant species composition and abiotic soil conditions,
without regarding the effect of soil organisms. They attributed the poor reestablishment of plant species to
different physical, chemical or hydrological soil properties between both donor and receptor sites. Kardol et
al. (2009) noticed a sole difference in soils where the topsoil wasn’t removed (bacterial feeders dominated
these soils). Abiotic soil conditions were similar throughout the different treatments (hay, soil, hay + soil, turf
and control). Soils, from which the topsoil was removed, had lower N mineralization, lower P bioavailability,
total N, total P and organic matter concentrations and lower moisture content. However, the plant
community seemed affected by spreading of hay and hay and soil, but not by turfs or the application of soil
alone. Transplanting turfs is not an effective way to obtain nature restoration, because species did not leave
the turfs (P. Kardol 2006, Netherlands Institute of Ecology [NIOO-KNAW], personal observation), due to
unfavorable abiotic or biotic conditions. Plant communities of soils from which the topsoil isn’t removed,
differ significantly from soils that are digged off, being dominated by ruderal, nitrophilous species and having
a lower species richness. Introduction of hay (containing mainly grass seeds, Smith et al., 1996) resulted in
the establishment of more common species and after five years the plant community still differed
significantly from the target community. Over time, all treatments at the digged of receptor site converged to
a low productive, species-rich grassland, although convergence with the target community was not obtained,
whereas species richness didn’t increase in the no topsoil removal treatment (Kardol et al., 2009).
Since grasslands of high floristic diversity are bound to sites characterized by low soil extractable P
concentration, P concentrations should be lowered on formerly cultivated land (Janssens et al., 1998).
However, this is not easily achieved, due to the stability of P in soil. P can be linked to clays, limestone and
minerals (e.g. Ca, Fe and Al), explaining its high retention even long after agricultural practices have ceased.
N, on the other hand, leaches quickly but can be replenished in several ways, such as by atmospheric
deposition, fixation by legumes and mineralization (Janssens et al., 1998). Rapid reduction of P availability
can be achieved by chemical amelioration. Addition of Al sulphate insured the binding of P, making it
unavailable to plant uptake. However, plant diversity didn’t increase (even decreased initially), probably due
to a decline of soil pH, caused by Al phosphate, favoring grasses such as Holcus lanatus (Gilbert et al., 2003).
Furthermore, chemical materials could be potentially toxic and are preferably not used in nature restoration
(Walker et al., 2004). The same accounts for deturfing (removing the topsoil), which can damage underlying
archaeological features, the seed bank and the soil fauna community (Swash and Belding, 1999). The desired
species could directly be introduced through sowing, where highest seeding rates gave the best results
(Stevenson et al., 1995). These findings were true for calcareous soils, but not for acid soils, where high soil
pH (> 4) and competitive interactions from ruderal species limited the establishment of the target community
(Owen and Marrs, 2000a). Addition of the hemi-parasite Rhinanthus minor has proven to negatively influence
the dominance of grasses, insuring suitable gaps for the establishment of herbs (Davies et al., 1997).
Reducing the nutrient status can also be done by traditional ways, such as sod-cutting, digging off the top soil
and mowing. The disadvantages of the first two methods are the removal of soil fauna and part of the seed
bank. Furthermore, the dept till which soil will be removed, has to be measured based on phosphate
concentrations. Mowing on the other hand will lose effectiveness after several years, since shortage in N and
28
K will cause a decline in production (Oomes et al., 1990). New techniques have been developed, e.g. mining.
Productivity is kept at a high level, through appropriate application of manure, hereby insuring that the
vegetation will withdraw most of the soil phosphates. Using this technique will require a long time before the
desired phosphate concentration is obtained (Chardon W.J., 2008).
2.7. Plant species diversity and the composition of the soil food web Several scientists have investigated the link between plant diversity, the bacterial community and ecosystem
processes. Higher plant production, and not higher plant diversity per se, induces higher microbial biomass
and higher microbial activity (Brodie et al., 2002; Zak et al., 2003), except for N mineralization and the rate of
C cycling, since these features depended on plant diversity. Elevated plant species richness alters the ratio of
N mineralization and immobilization, leading to a net supply of plant available N, which will in time lead to a
higher plant production (Zak et al., 2003). Stephan et al. (2000) wanted to retrieve the link between plant
diversity and culturable soil bacteria on former arable land. The site used for this experiment was part of the
BIODEPTH project and contained calcareous nutrient-rich soil. Screening of the bacterial activity and
functional diversity was conducted by Biolog Ecoplates (see § 3.4.2.). Plant species richness increased
catabolic activity and microbial diversity (use of different carbon-oxidation pathways, Staddon et al., 1998).
Plant functional group effects differed, whereby forbs didn’t influence the microbial community, whereas
legumes increased both activity and diversity. Similarly, testing the effect of plant species identity, showed
only a significant response for the legume Trifolium repens (Stephan et al., 2000).
Plant species adapted to particular habitat conditions are provided with specific ecophysiological traits
(Grime, 1979), and these traits can also determine soil biological properties, such as the rate of
decomposition of litter (Grime et al. 1996; Cornelissen and Thompson, 1997; Wardle et al., 1998; Cornelissen
et al., 1999). Fast-growing plant species, proliferating in fertile soils, allocate most of their C to rapid growth,
insuring a high photosynthetic capacity, and producing easily decomposable litter that is rich in nutrients. On
the other hand, slow-growing species, bound to conditions of low nutrient availability tend to be small,
producing nutrient-poor foliage and litter that is rich in resistant compounds, e.g. lignin and phenolics. Soil
food web structure and nutrient turnover are affected by these plant traits, in that fast-growing plants lead
to bacterial-dominated food webs and fast nutrient turnover. In contrast slow-growers favor a fungal-
dominated food web (fungi and their consumers, such as fungal-feeding collembolans and mites) and slow
nutrient cycling (Coleman et al., 1983; Moore and Hunt, 1988). High quality litter (low C:N ratio) of fast-
growing plants stimulates the growth and activity of bacteria and their consumers (e.g. bacterial feeding
protozoa and nematodes) leading to enhanced decomposition and nutrient turnover, further benefitting the
rapid growth of plant species adapted for fertile sites (Bardgett, 2005)
29
3. Materials and methods
3.1. Study area Three nature areas were examined; two of them are situated in the province of Antwerp (Turnhouts
Vennengebied and Liereman) and one of them lies in West Flanders (Gulke Putten).
The first nature reserve, Turnhouts Vennengebied (51°22'0.70"N, 4°56'19.08"O), lies in the municipalities of
Turnhout and Merksplas. Turnhouts Vennengebied consists of heath, forests, meadows and fens. It is
considered as one of the most important areas for the conservation of heath land communities in Belgium
(http://nl.wikipedia.org). Because of the diversification of the landscape a lot of birds find a suitable habitat,
such as meadow birds like the blacktailed godwit (Limosa limosa), the lapwing (Vanellus vanellus) and the
curlew (Numenius arquata) (http://www.vogelsvanbelgie.be). The whole area of 541 ha is part of Natura
2000 and in 2006 a Life project (‘Life Turnhouts Vennengebied’) started with the intension of restoring heath,
fens and poor, acidic grasslands on former agricultural land. LIFE is the EU’s financial instrument supporting
environmental and nature conservation projects throughout the EU, as well as in some candidate, acceding
and neighbouring countries (http://ec.europa.eu/environment/life). Despite the sensitive species and
habitats, agriculture and recreation are still possible. At present over 400 ha are managed by the non-profit
association Natuurpunt. Two other organizations, the Agency for the Environment and Forest (ANB) and the
Flemish Land Agency (VLM), are responsible for the nature development in this reserve. Nature development
is the area-specific restoration, development and protection of valuable nature by arranging an area as
suitably as possible and allowing a suitable environment to form (http://www.stropersbos.be/nieuws.pdf).
This project is coupled to the ambitious Life project, coordinated by Natuurpunt. In the past few years the
most sensitive parcels were obtained by land consolidation, so that farmers could continue their activities in
less sensitive areas. Parts of the topsoil, which consists of sand and loam, will be removed to create nutrient
poor conditions, suited for the rare fauna and flora, typical for heathland with moist and wet fens. Other
ongoing actions are sodcutting, creating a mosaic landscape with the original microrelief, dredge the existing
fens, grazing by Fjord horses and donkeys and removing coniferous forest (http://www.life-
turnhoutsvennengebied.be).
The second nature area lies in the vicinity of the first, namely in the municipality of Oud-Turnhout,
approximately six kilometers from the city of Turnhout. Other surrounding municipalities are Ravels and
Arendonk. Landscape the Liereman (51°20'12.39"N, 5° 0'53.25"O) is one of the oldest protected nature
reserves in Belgium and comprises an area of 435 ha. The environment alternates between meadows,
forests, wet and dry heath, peatland, dunes and sweet gale (Myrica gale) scrubs. It is managed by
Natuurpunt (http://www.natuurpunt.be). In 2004, a Life project (‘Life Landschap de Liereman’) was started to
restore the natural habitats consistent with the European Council Directive 92/43/EEC on the restoration and
protection of natural habitats and wild fauna and flora, known as the Habitats Directive. The main aim of the
Habitats Directive is to promote the maintenance of biodiversity by requiring member states to take
measures to maintain or restore natural habitats and wild species listed on the Annexes to the Directive at a
favourable conservation status (http://jncc.defra.gov.uk/page-1374). This project ended in September 2010
(http://www.natuurpunt.be).
30
Gulke Putten (51° 4'44.16"N, 3°20'8.52"O) lies in Wingene, bordering the community of Ruiselede and
comprises an area of 99 ha. In 1969 it became officially a nature reserve with a surface area of only 1.25 ha.
In 2001, its surface area was significantly enlarged, as the area no longer served as a radio broadcasting
station, but became military domain. The broadcasting facilities are still protected as industrial patrimony. As
the area is owned by the military forces, it is not accessible for recreation. This nature reserve is also
managed by Natuurpunt. Through an appropriate management of sodcutting, mowing, cutting, grazing by
Galloway cows and not interfering, rare relict species and habitats can be restored and preserved. Gulke
Putten is part of the Flemish Ecological Network (VEN) and the Natura 2000 network. The management and
development are supported by the European Union through a Life-project, called 'Life Vlaams Veldgebied'
(http://www.natuurpunt.be). The landscape consists of heath, lanes, coppice, former agricultural fields and
meadows, scrubs, poor grasslands, open spots and deciduous and coniferous forests
(http://www.studiokontrast.com).
3.2. Vegetation surveys In total we examined 51 parcels: 11 plots in Liereman (L), 17 in Turnhouts Vennengebied (TV) and 23 in Gulke
Putten (GP). In most of the parcels five subplots of 2 m x 2 m were laid out, except for the very small parcels
(2 or 3 subplots) and the homogenous rich agricultural grasslands (3 subplots). In these subplots, we
determined the different species and estimated their relative cover (in %, with a least estimated cover of 1
%). The cover and the number of different mosses were also taken into account.
3.3. Abiotic soil properties In each subplot, we took five soil samples of 10 cm deep by means of a soil auger. The five samples were
bulked to one sample per subplot. Soil samples were dried for 48 h at 40 °C before sieving over a 2 mm mesh.
pH-KCl is measured using a glass electrode (Orion, model 920A) after extracting 14 ml soil in a 70 ml KCl (1M)
solution. Total soil P concentration was determined according to the colorimetric malachite green procedure
(Lajtha et al. 1999) after acid wet digestion of 0.2 g soil with HClO4/HNO3/H2SO4 in Teflon pots at 150°C during
4 hours. As a measure of soil inorganic P availability, Olson P values were determined by shaking 2 g dry soil
for 30 min with 0.5 M NaHCO3 at pH 8.5 and subsequent colorimetric analysis of the extracts using the
malachite green procedure (Lajtha et al. 1999). Exchangeable Al and Ca concentrations were determined by
atomic absorption spectrometry after extracting 5 g of dry soil in 100 ml BaCl2 (0.1M).
3.4. Soil fauna In three of the five subplots (subplot one, three and five) of each parcel, five soil samples of 10 cm deep were
taken and again bulked. They were stored in the fridge (max. 5°C) and searched for macrofauna. Found
animals (earthworms, spiders, ants, Coleoptera larvae and Diptera larvae) were removed manually and put in
ethanol (70 % diluted in H2O). Part of the soil was put in a Falcon tube and stored in the freezer. These
samples were used to determine the microbial abundance and diversity.
3.4.1. Invertebrate community
Micro- and mesofauna were collected by means of the Berlese-Tullgren extraction (Finnamore et al. 1998). A
portion of fresh soil was placed in the funnel over a metallic sieve (with a mesh size of approximately 1 mm).
Above the funnels electric lamps (150 Watt, infrared) were installed, which served as a heat source. As a
31
consequence of the desiccation of the soil, the fauna will descend through the sieve and fall in a receptacle
filled with ethanol (70 % diluted). Antonio Berlese described this method of dynamic sampling in 1905 with a
hot water jacket as heat source. In 1918 Albert Tullgren described a modification, where the heating came
from above by an electric bulb (http://en.wikipedia.org/wiki/Antonio_Berlese).
Test phase
For adequate sampling, we first tested this method: we searched for the optimal temperature and the
optimal soil moisture content. We placed the lamps (5) at two different heights in order to determine the
optimal temperature. Four soil samples of 100 g were placed in the funnels and an equal amount of the same
samples was used under the second set-up (with lower lamps) to obtain comparable results. The mean
temperature on the left was 26,5 °C and on the right 33,5°C (measured with a digital thermometer), but the
temperature distribution over the board was too irregular. To obtain a homogenous temperature 9 lamps
instead of 5 were hanged over the wooden boards and the lamps were steadily lowered, to insure a certain
temperature gradient. But these soil samples dried out quickly, so in the next trial we moistened the soil
before placing it under the lamps, to avoid a rapid desiccation.
Final set-up
We decided to subject the soil samples in the funnels (of 150 g) to a temperature of 22,5°C (with a deviation
of maximum 0,7°C, measured with a digital thermometer and no gradient). The samples that were too dry,
were moistened. Only eight lamps were used, otherwise the temperature became too high in the middle of
the board. The final set-up is presented on Figure 2.
Figure 2 : Final set-up of the Berlese-Tullgren extraction.
3.4.2. Microbial community
The composition and abundance of the microbial community is obtained by using Biolog Ecoplates, which are
plastic microtiter plates with 96 wells. These plates are filled with carbon sources and each carbon source is
repeated three times. Three wells are filled with 150 µl of de-ionized water and act as control wells
32
(http://www.biolog.com). 100 µg of each soil sample is weighted and diluted with 50 ml of de-ionized water.
The remaining wells are filled with 75 µl of this soil solution and 75 µl of de-ionized water to establish a total
dilution of 1 g soil in 1 l of water. The carbon sources consist of carbohydrates, amino acids, carboxylic acids,
amines, amides and polymers (Stefanowicz, 2006). Nine of the 31 substrates are known as components of
exudates of plants roots (Campbell et al., 1997). Bacteria will oxidize the carbon sources, which is
accompanied by a color development. This color development is due to the metabolism of the bacteria, what
reduces the tetrazolium dye to the insoluble purple formazan. Different communities of organisms will give a
characteristic reaction pattern called a metabolic fingerprint or a community-level physiological profile
(CLPP). Tetrazolium dye is not metabolized by fungi, so fungi do not contribute to the CLPP on these plates
(Stefanowicz, 2006). The Ecoplates are put in the spectrophotometer to measure the absorbance or optical
density (OD) at 590 nm and 720 nm every 24 hours during one week. Before statistical analyses are done, the
absorbance value of a control well (no substrate) is subtracted from the absorbance value of each well
containing a substrate. In that way one receives the so-called net absorbance value (Kelly et al., 1998). The
average of the net absorbance value of each soil sample (31 wells) equals the average color well
development (ACWD). ACWD values at the end of the measurement (t = 7) are used to perform statistical
analysis. Each plot is assigned to a type of land use (agricultural field versus reference site), to ascertain if
clustering occurs.
3.5. Data analysis
3.5.1. Diversity indices
Shannon-Wiener index H
This index reflects the species richness of a sampled plot and is calculated as follows
(1)
with s the number of plant species and pi the cover of a species i, expressed as a fraction of the total cover.
For each subplot the Shannon-Wiener index (H) was calculated, once without the moss cover and once with
the moss cover. For further analysis only the results without the moss cover were used. The Shannon-Wiener
index was also calculated based on the findings of macro- and mesofauna, to indicate soil fauna diversity.
Eveness J
This index indicates how even the species composition is distributed, indicating a strong dominance of certain
species with a low value. The higher the value, the more evenly distributed the subplot. The eveness is
calculated via
(2)
with s the number of plant species and pi the cover of a species i, expressed as a fraction of the total cover.
33
3.5.2. Weighted mean Ellenberg scores
Ellenberg’s indicator values are used to order plants with the same ecological traits in classes. These classes
consist of a nine point scale for soil acidity (R), productivity/nutrients (N), soil humidity (F), continentality (K),
soil salt content (S) and light (L). For each subplot the weighted mean Ellenberg value for acidity (mR), light
(mL), humidity (mF) and productivity (mN) was calculated via the following formula
(3)
with mN1 the weighted mean value of N for subplot 1, N1 the value of N for species 1 and x11 the cover of
species 1 in subplot 1 (in %). The same calculation was executed for mL, mR and mF.
3.5.3. Ordination
Ordination techniques are used to represent the relationship between species composition and the
underlying environmental gradients in a low-dimensional space. Via ordination, similarities between species
and samples will be detected and projected onto two dimensions in such a way that species and samples
most similar to one another will be close together, while dissimilar species and samples will appear farther
apart. The closer the species is to a subplot, the higher its abundance in that subplot (Verheyen, 2011). These
results can be related to environmental gradients, in order to determine which factors influence the
community structure. This is the principle of indirect (or unconstrained) ordination techniques, e.g.
Detrended Correspondence Analysis (DCA), Principal Components Analysis (PCA) and Non-Metric
Multidimensional Scaling (NMDS). Direct (or constrained) ordination techniques, such as Canonical
Correspondence Analysis (CCA) and Redundancy Analysis (RDA), instantly use environmental gradients to
order species and samples onto the ordination scheme. The length of gradient (a measure for species
turnover) determines if the response is linear (< 3) or unimodal (> 4) and consequently which technique
should be used, since PCA is applicable in case of a linear response and DCA when the response is unimodal.
Based on the value of the length of gradient DCA was performed, but due to inappropriate ordination
diagrams, NMDS was used, where an arch effect rarely occurs. This method analyses the matrix of
dissimilarities between n samples and finds a configuration of these objects in a k-dimensional ordination
space (k = 2), so that those distances in ordination space correspond to dissimilarities. The term ‘Stress’
measures the lack of fit between distances in ordination space and dissimilarities.
(4)
where is the distance between sample points in the ordination diagram, is the dissimilarity in the
original matrix of distances and f() is a non-metric monotonous transformation (Leps and Smilauer, 2003).
NMDS sometimes can’t represent all relationships accurately, which is reflected by a high Stress value.
Contrary to eigenvector methods such as PCA, NMDS calculations do not maximize the variability associated
with individual axes of the ordination, meaning that NMDS axes are arbitrary, so the final plots can be
rotated, centered, and inverted (http://www.ohio.edu). Environmental factors are added to the ordination
diagram as arrows. The direction of the arrow shows the direction of the strongest gradient or change in the
variable. The length of the arrow is proportional to the correlation between ordination and environmental
34
variable and this is often called the strength of the gradient. The goodness of fit of the environmental factor
is the squared correlation coefficient (r²). This is defined as
(5)
where ss_w and ss_t are within-group and total sums of squares.
For each variable group a separate CCA was done (abiotic variables, macro- and mesofauna, and microfauna).
The forward selection option was used to exclude non-significant variables. Next, the unique fraction of
variance explained by one set of variables and not shared with other sets was obtained by partial CCA, in
which the significant member variables of the concerning group are used as constraining variables, while the
significant variables of all other sets are treated as covariables (Borcard et al., 1992). ANOVA was executed to
ascertain the significance of the used and retained models.
3.5.4. Classification
Classification aims the same as ordination, in that both are multivariate techniques who wish to visualize the
community structure in an accurate way. Clustering of samples can be obtained by several methods:
hierarchical (usually displayed by a dendrogram) versus non-hierarchical, divisive (from the top) versus
agglomerative (from the bottom) and monothetic (division based on a single attribute) versus polythetic
(division based on multiple attributes). Two-way indicator species analysis (TWINSPAN) is an example of a
hierarchical, divisive and polythetic classification method (Leps and Smilauer, 2003). The TWINSPAN method
was performed with the program PCORD, with 0, 2, 5, 10 and 20 as cutlevels and a minimum group size of
five species for division. The Mann-Whitney-Wilcoxon test is used to decide whether the population
distributions are identical, without assuming them to follow the normal distribution (www.r-tutor.com).
3.5.5. Statistical analysis (Mixed models and Mantel test)
Normality was tested with SPSS 19.0 through a Shapiro-Wilk normality test. To ascertain there was no
multicollinearity between the predictor variables, variance inflation factors (VIF) were calculated as follows:
(6)
Low VIF values (i.e smaller than three) indicate low collinearity and allow the variables to be used in the same
model. So-called mixed-effect models (or just mixed models) are often appropriate for representing
clustered, and therefore dependent data, for instance, when data are collected hierarchically, as is in our
case (subplots in plots, plots in areas). Mixed models were performed in RStudio. First, a null model was
constructed, to which the predictor variables were added. Calculation of the intra-class correlation (ICC)
shows the proportion of total variance due to the hierarchy in the data, meaning that the remaining variance
can be described by predictor variables, where is the variance of the intercept and
is the variance of
the residuals:
(7)
35
The amount of variation explained by adding the predictor variables can be estimated through the ratio of
the difference in residuals between the null model ( and the final model (
over the residuals of
the null model:
(8)
When plotting the fitted values (according to the model) against the residuals results in a random
configuration, it is acceptable to use non-normally distributed variables. ANOVA was executed to ascertain
the significance of the selected final models. Finally, a Mantel test was performed to measure the correlation
between two matrices (containing measures of distance) and consequently the degree of spatial
autocorrelation. Data exploration, ordinations (DCA, NMDS and CCA) and the Mantel test were executed in
RStudio.
4. Results
4.1. Vegetation
4.1.1. Weighted mean Ellenberg scores
From Table 1 we can see that mL and mF show little variation (in and among the three nature areas), while
mR and mN have a larger range. The nature area Liereman (L) is slightly more acidic, whereas soils are more
N-rich in Turnhouts Vennengebied (TV). The factor mF was the only floral characteristic distributed normally,
the other values didn’t obtain a normal distribution even after numerous transformations. mR and mN are
highly correlated (VIF > 3), as can be seen in Table AI.1.
Table 1: Minimum, maximum and average weighted mean Ellenberg scores (mL,mF,mR and mN) for the three nature
areas.
Weighted mean Ellenberg sores
mL mF mR mN
Liereman
min 6.67 4.95 1.00 1.70
max 8.42 8.25 7.21 6.43
average 7.57 6.56 4.63 4.04
Turnhouts Vennengebied
min 6.27 4.40 1.63 2.06
max 8.21 7.62 7.07 6.88
average 7.46 6.19 5.17 4.39
Gulke Putten
min 6.47 5.24 1.03 1.44
max 8.42 7.78 7.28 6.41
average 7.70 6.45 5.10 4.23
36
4.1.2. Species diversity and composition
Several target species occur in the three nature areas, such as matt-grass (Nardus stricta), heath grass
(Danthonia decumbens), common tormentil (Potentilla erecta), heather (Calluna vulgaris) and bog heather
(Erica tetralix). An overview of all the plant species present in the three nature areas can be found in Table
AII.1). The stress values of NMDS based on the vegetation can be found in Table AIII.1. The minimum,
maximum and average Shannon-Wiener diversity index and eveness of the vegetation in the three nature
areas can be found in Table AII.2.
The nature area Liereman consist mainly of H. lanatus, A. canina, L. perenne, R. acris, M. caerulea, L.
autumnalis, T. repens and P. erecta, being the eight plant species with the highest total abundance. In total L
counts 52 plant species. R. acris and A. canina are the two most frequently found species, respectively in 27
and 26 of the 45 subplots. The highest diversity is reached on a site with 15 plant species and 1 moss species
and a Shannon Wiener diversity index (H) of 2.17.
An overview of the numbers in the ordination diagrams and the corresponding subplots can be found in
Appendix IV (Table AIV.1, Table AIV.2 and Table AIV.3). NMDS of the vegetation matrix of L results in a lowest
stress value of 0.12. When species are located near a subplot, they have a high relative cover in this subplot.
Based on the NMDS diagram of L, C. pratensis is located closest to subplot 5-2, indicating a high occurrence in
this subplot. The same accounts for A. canina, which is close to subplot 7-2 (see Figure AIV.1).
In TV, H. lanatus, A. canina, L. perenne, R. acris, M. caerulea, T. repens, R. acetosa and L. hispidus were the
plant species with the highest total abundance. In total, TV counts 69 plant species. The most frequently
found species is H. lanatus, followed by R. acris, respectively found in 31 and 27 of the 66 subplots. The
highest plant diversity equals 19 plant species and 2 moss species. The lowest stress value obtained via NMDS
for the vegetation matrix of TV is 0.17. Subplot 2-1 is quite isolated, due to the presence of G.
pneumonanthe. Species L. corniculatus is most abundant in subplot 4-5, while H. lanatus has a high cover in
subplot 14-1 (see Figure AIV.2).
In Gulke Putten (GP) H. lanatus, A. canina, L. perenne, R. acris, T. repens, M. caerulea, T. officinalis and J.
effusus were the plant species with the highest total abundance. In total, GP counts 63 plant species. R. acris
is the most frequently present species (found in 91 of the 108 subplots), followed by H. lanatus (in 85
subplots) and T. repens (in 77 subplots). The highest H-value (2.27) is found on a site with 17 plant species
and 1 moss species. The lowest stress value is 0.12 for the NMDS based on the vegetation matrix of GP. On
the NMDS diagram subplot 2-3 is isolated, due to the low amount of plant species (3) and the presence of
Betula. The species E. tetralix is closest to subplot 1-3, explaining its high occurrence in this subplot. P.erecta
has a high cover in subplot 1-1 (see Figure AIV.3).
Subplots of the three areas are randomly distributed on the overall NMDS diagram, allowing a further
analysis of the combined results (see Figure 3).
37
Figure 3: NMDS ordination diagram based on the vegetation surveys in Liereman, Turnhouts Vennengebied and Gulke
Putten (black = Liereman, red = Turnhouts Vennengebied, green = Gulke Putten).
4.1.3. Classification
TWINSPAN led to three division levels (see Figure 4). Group 0 and 1 significantly differ based on all abiotic soil
characteristics and all weighted mean Ellenberg scores. Group 00 and 01 differ in all variables, except for mL.
Values for exchangeable Ca and mL do not differ significantly for group 11 and 10, whereas values of all other
variables do. Divergence of groups 010 and 011 is based on differences in exchangeable Ca, mL and mN. mN
is determinant in separating groups 110 and 111. Group 00 isn’t divided, since subdivisions contain an
insufficient number of subplots, while group 10 can’t be divided since variables do not differ significantly (p <
0.05). Correlations between TWINSPAN groups and abiotic soil characteristics and between TWINSPAN
groups and mean weighted Ellenberg scores, can be found in Table AV.1, along with the two-way ordered
tables (Figure AV.1).
38
Figure 4: Result of the TWINSPAN classification. Species in italic are indicator species, species between brackets are
preferential species.
4.2. Abiotic soil conditions None of the measured soil parameters (total P concentration, Olsen P concentration, pH, exchangeable Ca
and exchangeable Al) is distributed normally. Total P concentration and Olsen P concentration are highly
correlated (VIF > 3; see Table AI.1), as can be deduced from Figure 5, and are not used in the same model.
Figure 5: Olsen P concentration (mg kg-1) in function of total P concentration (mg kg-1) for the three nature areas
(Liereman, Turnhouts Vennengebied and Gulke Putten).
0
50
100
150
200
0 200 400 600 800
Ols
en P
(m
g kg
-1)
Total P (mg kg-1)
Liereman
0
50
100
150
0 500 1000
Ols
en P
(m
g kg
-1)
Total P (mg kg-1)
Turnhouts Vennengebied
0
50
100
150
200
0 500 1000 1500 2000
Ols
en P
(m
g kg
-1)
Total P (mg kg-1)
Gulke Putten
39
Total soil P and Olsen P concentration show a large gradient, as can be seen from Table 2. Low P
concentrations coincide with reference sites, while high values are characteristic for ex-agricultural land. pH
ranges don’t differ much between the three nature areas. On the other hand exchangeable Ca and Al
concentrations do differ significantly.
Table 2: Minimum, maximum and average of the abiotic soil characteristics for the three nature areas.
Total P
(mg kg-1) Olsen P
(mg kg-1) pH-KCl
Exchangeable
Ca (mg kg-1)
Exchangeable
Al (mg kg-1)
Liereman
min 22.19 2.13 3.48 4.90 8.00
max 744.71 152.55 4.96 1062.70 607.00
average 335.55 45.55 4.23 421.93 122.67
Turnhouts Vennengebied
min 50.16 4.49 3.52 96.20 8.00
max 986.67 120.25 5.22 1431.90 541.00
average 407.97 50.19 4.47 597.42 119.50
Gulke Putten
min 37.66 0.11 3.48 22.10 -4.00
max 1692.30 169.55 5.33 2030.90 385.00
average 580.02 74.27 4.36 563.81 119.47
On Figure AVI.1, it can be seen that pH-KCl declines with increasing concentration of exchangeable Al.
4.3. Soil fauna
4.3.1. Macro- and mesofauna
Results on the number of taxa, the amount of organisms and the Shannon-Wiener diversity index of macro-
and mesofauna of the three nature areas are shown in Table 3. In total 15 taxa were found (16 when ants are
considered as a separate group).
40
Table 3: Minimum, maximum and average number of taxa, number of organisms and Shannon-Wiener diversity index
(H) for the three nature areas.
Number of taxa
Number of organisms
Shannon-Wiener
Liereman
min 0 0 0.00
max 6 37 1.33
average 3 8 0.74
Turnhouts Vennengebied
min 0 0 0.00
max 7 129 1.56
average 3 14 0.74
Gulke Putten
min 0 0 0.00
max 8 138 1.56
average 4 27 0.84
Ten different taxa are found in the soil samples of L (no Chilopoda, Diplopoda, Orthoptera, Isopoda,
Hymenoptera and Heteroptera were present). The most abundant taxa are nematodes (in 19 of the 33
subplots), mites (18) and springtails (17). The highest number of individuals belonging to one taxum is 18
(mites and ants). The soil of subplot 6-1 contained none of the target species.
An overview of the stress values based on NMDS for macro- and mesofauna can be found in Table AIII.1. The
lowest stress value of the NMDS based on the presence of macro- and mesofauna in L is 0.14. An overview of
the numbers in the ordination diagrams and the corresponding subplots can be found in Appendix VII (Table
AVII.1., Table AVII.2 and Table AVII.3). Spiders (Arachnida) are most abundant in subplot 8-3, which makes
this subplot different from all others. Nematodes are abundant in subplot 7-3, springtails in subplot 2-1 and
Thysanoptera in subplot 10-3 (see Figure AVII.1).
Soil samples of TV contain no Chilopoda and Diplopoda. In total 14 taxa are present in the topsoil of TV. The
highest number of individuals belonging to one taxum is 94 (springtails). Nematodes occur in 32 of the 51
subplots and are the most frequently found taxum, followed by springtails (29) and mites and potworms
(both found in 20 subplots). One subplot (17-3) contained none of the desired species.
NMDS of the data for macro- and mesofauna in TV gives rise to a stress value of 0.18. Diptera are close to
subplot 10-1, while Coleoptera are close to subplot 13-5, occurring in these subplots with the highest
abundance. Plot 9-1 differs from all other plots, containing only one group of organisms, namely ants. High
numbers of nematodes appear for instance in subplots 3-1 and 12-3 (see Figure AVII.2).
The soil samples of GP contain no ants, Orthoptera and Heteroptera. In total 14 taxa occur in the topsoil of
GP. Nematodes are the most abundant group (with up to 109 individuals in one sample, namely subplot 9-5),
followed by potworms and mites, with a maximum amount of respectively 39 and 36 organisms. Four
41
subplots contain none of the target species (2-1, 12-5, 17-3 and 22-1). Nematodes are most frequently
present (in 54 of the 66 subplots), followed by springtails, mites and potworms, respectively present in 44, 40
and 39 of the 66 subplots.
NMDS didn’t give a readable ordination diagram (overlap of all but one subplot, namely 17-2), so rare taxa
(Chilopoda, Diplopoda, Hymenoptera, Heteroptera, Orthoptera, Isopoda, Thysanoptera and ants) were
omitted from the matrix and a new NMDS was performed. This resulted in a stress value of 0.22, indicating a
high degree of lack of fit. On the NMDS diagram (see Figure AVII.3) nematodes are located next to subplot 5-
3, explaining their higher abundance in this subplot.
NMDS performed on the data of the macro- and mesofauna of all areas leads to a stress value of 0.22.
Subplot 9-1 of TV is isolated from the other subplots, since it contains only ants and subplot 8-3 of L contains
only spiders (see Figure AVII.4). For further analysis both outliers (L 8-3 and TV 9-1) are removed from the
data matrix, and Figure AVII.5 represents the new ordination diagram.
4.3.2. Microfauna
All 31 carbon sources and their position in the Biolog Ecoplates can be found in Table AVIII.1. An overview of
the stress values based on NMDS for microfauna can be found in Table AIII.1. An overview of the numbers in
the ordination diagrams and the corresponding subplots can be found in Appendix VIIII (Table AVIIII.1., Table
AVIIII.2 and Table AVIIII.3).
For L, NMDS of the ACWD values (indicative for the degree of bacterial use) of the 31 C-sources shows a
lowest stress value of 0.10. Glycogen is mostly used in subplot 6-3, while L-phenylalanine is highly oxidized in
subplot 6-5 (see Figure AVIIII.1). Ex-agricultural fields cluster on the right of Figure AVIIII.2, while reference
sites lie left in the figure.
NMDS of the ACWD values of the 31 C-sources of TV gives rise to an inappropriate figure, caused by an
outlier (subplot 5-1). Better results are obtained by rejecting this subplot from the data matrix (stress value of
0.14). Putrescine is most frequently used in subplot 17-1. Subplot 7-7 is relatively isolated from the other
subplots (see Figure AVIIII.3). Neither ex-agricultural fields nor reference sites cluster on the NMDS diagram
(see Figure AVIIII.4).
NMDS of the ACWD values of the 31 C-sources of GP has a stress value of 0.17. D,L-α-glycerol is preferentially
used in subplot 18-3 (see Figure AVIIII.5). Ex-agricultural fields cluster on the right of Figure AVIIII.6, while
reference sites appear lower and more on the left.
Originally, the data of all areas result in an inappropriate figure (overlap of all but one subplot). After
removing the outlier (TV 5-1) from our dataset, a new NMDS was performed on the ACWD values of the 31 C-
sources of the three nature areas and a stress value of 0.17 was obtained. Subplot 6-3 from L is quite isolated
from the other subplots, due to low ACWD values (see Figure AVIIII.7). Ex-agricultural fields cluster on the
right, while reference sites lie on the left, as shown on Figure 6.
42
Figure 6: NMDS ordination diagram based on ACWD values of the three nature areas. Ellipses indicate clustering of
reference sites = ref (black) and ex-agricultural fields = field (blue).
Subplots of the three areas are randomly distributed, so we decided to conduct all further analyses on the
combined data of L, TV and GP (see Figure AVIIII.9).
4.4 Relationship between biotic and abiotic features
4.4.1. Relationship between vegetation composition and abiotic soil characteristics
Results of mixed models
An overview of the results of the mixed models can be found in Table AX.1. 60% of the variation in mF is due
to the hierarchical structure of the sampled data. Adding pH, exchangeable Ca and exchangeable Al to the
model with mF as response variable decreases the AIC value significantly, when added separately. pH and
exchangeable Ca are both negatively correlated with mF, while exchangeable Al has a positive correlation.
pH, exchangeable Ca and exchangeable Al explain respectively 49%, 22% and 39% of the residual variation in
mF. Most of the residual variation (52%) is explained by the combination of pH and exchangeable Ca, after all
possible combinations of the five soil characteristics are executed.
All soil characteristics improve the null model with mR as response variable. Four variables show a positive
correlation with mR (total P concentration, Olsen P concentration, pH and exchangeable Ca), while
exchangeable Al has a negative correlation. Residual variation in mR is mostly explained by pH (58%),
followed by total P content (33%). Combination of these two predictor variables accounts for 75% of the
residual variation in mR.
43
27% of the residual variation in mN is explained by pH and 19% by exchangeable Al, whereas exchangeable
Ca has a minor impact and total P and Olsen P don’t improve the model. pH shows a positive correlation with
mN, while exchangeable Al has a negative correlation. Combination of pH and exchangeable Al clarifies 35%
of the residual variation in mN. Results of ANOVA performed on the final models can be found in Table AX.2.
The null model of both the Shannon-Wiener diversity index H and the eveness J are not affected by any of the
predictor variables, although hierarchy of the data accounts for 50% and 44% of the explained variation,
respectively for H and J. The variation in the amount of red list species is influenced by all predictor variables,
but the plot of the fitted values against the residuals is not randomly distributed, so no conclusions can be
drawn. The number of plant species is negatively affected by total P concentrations and Olsen P
concentrations, but again fitted values and residuals don’t follow a random distribution. Based on the ICC
values, 79% of the variation in the amount of red list species and 75% of the variation in the number of plant
species is explained by the hierarchy of the data.
NMDS NMDS based on the cover of all plant species in the three nature areas results in a lowest stress of 0.18. All
abiotic soil characteristics are significantly bound to the axes (p < 0.001), with the highest squared correlation
coefficient for pH, followed by exchangeable Al. Figure 7 shows that exchangeable Al is negatively correlated
with axis 1, and the four other abiotic soil characteristics (total P concentration, Olsen P concentration, pH-
KCl and exchangeable Ca) are positively correlated with axis 1 (see Table AXI.1).
Figure 7: NMDS diagram based on the vegetation surveys, executed in the three nature areas. Blue dots represent
subplots belonging to TWINSPAN group 1, red dots represent subplots belonging to TWINSPAN group 0. Arrows
indicate the gradient in the abiotic soil characteristics.
high low Olsen P concentration, total P concentration, pH-KCl, exchangeable Ca
low high Exchangeable Al
44
CCA
Abiotic soil characteristics explain 15% of the variation in the vegetation community. ANOVA was executed to
ascertain the significance of this model (p < 0.01; see Table AXII.1). Forward selection retains pH and total P
concentration as most important factors influencing the vegetation composition (see Table AXII.2).
Mantel test
According to the Mantel test there is 43% resemblance between the dissimilarity matrix of the vegetation
and the dissimilarity matrix of abiotic soil characteristics (p < 0.001; see Table AXIII.1).
4.4.2. Relationship between soil fauna and abiotic soil characteristics
The influence of abiotic soil characteristics on macro- and mesofauna
Results of mixed models
According to the ICC values, 11% of the variation in the number of taxa and the Shannon-Wiener diversity
index is clarified by the hierarchy of the data, and 14% of the variation in the number of organisms. All the
predictor variables, except exchangeable Al, influence the number of taxa, but none of the plots, showing
fitted values against residuals are randomly distributed. Transformations to obtain a normal distribution
weren’t successful. Only total P concentration and Olsen P concentration seem to positively affect the
number of organisms, but again no appropriate plots were obtained. The five abiotic soil characteristics don’t
significantly reduce the AIC value of the null model with H as response variable (see Table AX.3).
NMDS
The lowest stress value of the NMDS based on the macro- and mesofauna of all areas is 0.22. NMDS is
performed without rare taxa (Chilopoda, Diplopoda, Hymenoptera, Heteroptera, Orthoptera, Isopoda,
Thysanoptera and ants). Environmental fit of abiotic soil characteristics leads to a highest correlation of
exchangeable Ca (p < 0,05) with the composition of the community of macro-and mesofauna, followed by pH
(p < 0.1). Both variables are positively correlated with axis 2. Only exchangeable Al has a negative link with
axis 2 (see Table AXI.2). When two outliers are omitted (L 8-5 and TV 9-1) none of the abiotic soil
characteristics are significantly bound to the NMDS axes (see Table AXI.3). On Figure 8, mites (Acari) are
located closely to the exchangeable Al arrow, while Diptera and spiders (Arachnida) are close to the pH
arrow.
45
Figure 8: NMDS ordination diagram based on the macro- and mesofauna of the three nature areas. Numbers represent subplots, taxa are indicated in red and blue arrows represent abiotic soil characteristics.
CCA 6% of the variation in macro- and mesofauna can be explained by the abiotic soil characteristics (p < 0.1; see
Table AXII.1). Forward selection retains Olsen P concentration as most important abiotic soil characteristic
(p < 0.01; see Table AXII.2).
Mantel test The Mantel test for these two matrices results in a negative correlation, which is not significant (see Table AXIII.1).
The influence of abiotic soil characteristics on microfauna
Results of mixed models C-sources are partitioned in 8 groups (carbohydrates, carboxylic acids, amino acids, esters, polymers,
aromatic compounds, phosphorylated chemicals and amines). Carbohydrates, carboxylic acids, amino acids,
aromatic compounds and amines are normally distributed, whereas the other groups are not.
Almost none of variation in the use of carbohydrates can be explained by the hierarchy of the data (1%). The
residual variation is almost completely clarified by total P or Olsen P concentration (99%). Total P and Olsen P
concentration positively influence bacteria that use carbohydrates. None of the abiotic soil characteristics
significantly reduce the AIC value of the null model, belonging to the use of amino acids. The same accounts
for the model based on carboxylic acids, esters, amines, phosphorylated chemicals and aromatic compounds.
13% of the variation in the use of polymers can be clarified by the hierarchy of the data, based on the ICC
46
value. 46% of the residual variation is explained by exchangeable Ca. The exchangeable Ca concentration is
positively correlated with the use of polymers (see Table AX.4 and Table AX.5).
NMDS Based on the environmental fit of the abiotic soil characteristics, soil pH and exchangeable Ca show the
highest correlation (p < 0.001) with the variation in the composition of the bacterial community. Total P
concentration explains less variation with a significance level of p < 0.01, while Olsen P and exchangeable Al
explain least of the variation (p < 0.05) (see Table AXI.4). On Figure 9 sites with high exchangeable Al
concentration appear up in the figure, and nutrient-rich sites with high total P, Olsen P, exchangeable Ca
concentration and pH are in the bottom.
Figure 9: NMDS ordination diagram based on ACWD values of the three nature areas. Numbers represent subplots,
C-sources are indicated in red and abiotic soil characteristics are represented by blue arrows.
CCA
12% of the variation in the bacterial community, and consequently the use of C-sources, can be explained by
abiotic soil characteristics (p < 0.05). Forward selection retains exchangeable Ca as most important abiotic
soil characteristic (p < 0.01).
Mantel test
The correlation between the dissimilarity matrices of the abiotic soil characteristics and the ACWD values of
the microfauna is 0.27 (p < 0.001; see Table AXIII.1).
47
4.4.3. Relationship between vegetation composition and soil fauna
The influence of macro- and mesofauna on the vegetation composition
Results of mixed models
None of the characteristics of macro- and mesofauna (number of taxa, number of organisms and Shannon-
Wiener diversity index) significantly reduce the AIC value of the null model, belonging to mF, mN, Shannon-
Wiener diversity index of the vegetation, eveness J and number of plant species. 64% of the variation in mR
can be explained by the hierarchy of the data. 7% of the residual variation is clarified by the number of taxa,
which shows a positive correlation with mR. The AIC value is significantly reduced by the number of taxa in
the case of the number of red list species, but the plot of the fitted values and the residuals didn’t have a
random configuration, so this result can’t be used. Transformations to obtain normality didn’t offer a solution
(see Table AX.6 and Table AX.7).
NMDS
The lowest stress value, based on the vegetation matrix, where only subplots are included for which there
are also data on soil fauna, is 0.17. When taxa are fitted upon the NMDS, only springtails (Collembola) appear
to have a significant correlation with the NMDS axes (p < 0.1; see Table AXI.5). Figure 10 represents the
result of the ordination based on all taxa, while Figure 11 shows the influence of the soil fauna characteristics
(number of taxa, number of organisms and H-value).
Figure 10: NMDS ordination diagram based on the subplots for which data of soil fauna are available. Numbers
represent subplots, plant species are indicated in red and taxa are represented by blue arrows.
48
The number of taxa and the Shannon-Wiener diversity index H are significantly bound to the NMDS axes
(p < 0.01). The number of organisms has no influence on the vegetation composition (see Table AXI.6).
Figure 11: NMDS ordination diagram based on the subplots for which data of soil fauna are available. Numbers
represent subplots, plant species are indicated in red and the characteristics of the macro- and mesofauna (number of
taxa, number of organisms and Shannon-Wiener diversity index H) are represented by blue arrows.
CCA
Only 3.7% of the variation in vegetation composition can be explained by the presence of macro- and
mesofauna (see Table AXII.1). When forward selection was executed, none of the variables of macro- and
mesofauna were retained (see Table AXII.2).
Mantel test
The correlation between the dissimilarity matrices of the vegetation composition and the abundance of the
macro- and mesofauna is 0.14 (p < 0.05; see Table AXIII.1).
The influence of microfauna on the vegetation composition
Results of mixed models
70% of the variation in mF can be explained by the hierarchical structure of the data. The use of polymers
explains 21% of the residual variation, which has a negative correlation with mF. The use of polymers also
explains 17% of the residual variation in mR (where 71% of the variation is due to the hierarchy of the data).
None of the used C-sources explains the variation in mN, the Shannon-Wiener diversity index for the
vegetation, the eveness J, the number of red list species and the number of plant species (see Table AX.8 and
Table AX.9).
Taxa
H
49
NMDS
First, C-sources were grouped into carbohydrates, carboxylic acids, amino acids, esters, polymers, aromatic
compounds, phosphorylated chemicals and amines. NMDS based on these eight groups led to a stress value
of 0.16 and only aromatic compounds and amines explain some of the variation in the vegetation
composition (p < 0.1; see Table AXI.7). The eight groups are represented on the ordination diagram of Figure
12, while the C-sources are considered separately on Figure 13. When C-sources are used separately, two
sources (D-galactronic acid γ-lactone and glycyl-L-glutamic acid) influence vegetation structure with a
significance of p < 0.05 and two sources (itaconic acid and phenylethylamine) are less correlated (p < 0.1; see
Table AXI.8). Two sources, namely D-galactronic acid γ-lactone and itaconic acid coincide with sources
selected by forward selection in CCA (see Table AXII.2).
Figure 12: NMDS ordination diagram based on subplots for which data of microfauna is available. Numbers represent
subplots, plant species are indicated in red and the groups of C-sources (carbohydrates, carboxylic acids, amino acids,
esters, polymers, aromatic compounds, phosphorylated chemicals and amines) are represented by blue arrows.
50
Figure 13: NMDS ordination diagram based on subplots for which data of microfauna is available. Numbers represent
subplots, plant species are indicated in red and the gradient of the C-sources is represented by arrows. For clarity,
only C-sources with a significant correlation are shown. See Table AVIII.2 for the full names of the C-sources and
Figure AVIIII.8 for the NMDS ordination diagram with all C-sources.
CCA
56% of the variation in vegetation composition can be explained by bacteria, based on the ACWD values of 31 C-sources. When the C-sources are grouped, this value reduces to 13% (see Table AXII.1). None of the grouped C-sources are retained when using forward selection, but 6 C-sources are selected when introduced separately (D-galactronic acid γ-lactone, Tween 40, N-acetyl-D-glucosamine, 4-hydroxy benzoic acid, D-Cellobiose, α-D-Lactose and Itaconic acid; see Table AXII.2).
Mantel test
The correlation between the dissimilarity matrices of the vegetation composition and the ACWD values of the
microfauna is 20% for the 31 C-sources (p < 0.001) and 6% when C-sources are grouped, but this last result is
not significant (see Table AXIII.1).
5. Discussion
5.1. Relationship between vegetation composition and abiotic soil characteristics In this section the findings of the vegetation composition and the abiotic soil characteristics are compared to
the available literature, and in a second phase their relationship is discussed, based on our results and
comparisons with other authors.
high low Galactlact, GlycylLGlutAcid, Phenyletam
low
high
ItaconicA
51
The value mL was not considered in the analysis, since it was consistently high (ranging between six and
eight), reflecting that all plant species need a lot of light to be able to grow. Species with a light value of less
than six are considered forest species, that is species of the understory (1–3) or canopy gaps of moderate size
(4–5) (Ellenberg, 1988). The high light values of our experiment indicate that plants need an open habitat.
The present species are found in dry to moist environments, since mF ranges between 5.0 and 8.2 in the
three study areas. mR and mN show a stronger variation, whereby mR lies between 1 and 7 for the three
areas, characterizing the soils as strongly acidic to weakly acidic and even weakly basic. mN varies between 1
and 6 for L and GP, meaning that soils have a low N concentration at low mN values and have an
intermediate N concentration at a value of 6. TV has a slightly higher minimum, indicating that soils are richer
in N, compared to the other nature areas. The large variation in mR and mN converges with the succession
gradient of nutrient-rich ex-agricultural land to nutrient-poor, acidic reference sites. The highest amount of
plant species occurs in TV, but target species are sown in this nature area.
Based on the classification technique, the vegetation can be divided in two groups. These two groups differ
on all variables (weighted mean Ellenberg scores and abiotic soil characteristics), but the strongest
significance accounts for mN. Species of the first group are typical for nutrient-rich soils (H. lanatus and R.
acris), while species of the second group are characteristic for nutrient-poor sites (C. vulgaris, P. erecta and
M. caerulea, all frequently present in Nardo-Galion grasslands). The first group is further divided in two
subgroups, with L. perenne as indicator species for the first subdivision. Preferential species for the second
subdivision are L. hispidus and L. autumnalis. These species grow on moderately rich soils, whereas plants of
the first subdivision have a high fertility requirement (http://plants.usda.gov), thus nutrient availability steers
this division. The second subdivision can be split in a group of plants occurring on calcareous, N-rich soils
(such as R. acris and T. repens), while R. acetosella and J. vulgaris are indicative for the second group. These
plant species grow on acid, N-rich soils (http://www.soortenbank.nl), so exchangeable Ca concentration
drives this separation. The second group of the first subdivision (characterized by species of nutrient-poor
sites) can be divided in two groups, based on the Olsen P concentration and mR. One group is represented by
P. erecta, and the second group is represented by C. vulgaris, which needs more acid soils. The latter can be
split in two, where one group is characterized by E. tetralix, a heathland species, and the second group by N.
stricta. Other plant species in this group are D. decumbens and C. panicea, both occur on rather nutrient-
poor, acid soils.
There are two methods for measuring soil pH: pH-KCl (used in this master thesis) and pH-H2O, where pH-KCl
has consistently lower values than pH-H2O. pH-KCl values can be converted to pH-H2O values via the formula
(9)
(Azedevoa et al., submitted) resulting in a range of 4.5 to 6.2 pH-H2O, which is consistent with the pH range,
typical for Nardo-Galion grassland, according to Zwaenepoel and Stieperaere (2002) and Herr et al. (2011).
Protons bound to clay particles and humus are released when KCl is added to soil, but not when H2O is added
(only free protons are measured) (http://www.agriton.nl), explaining the higher values of pH-H2O. On Figure
AVI.1 the concentration of exchangeable Al starts to rise when pH-KCl reaches a value of 4. This is consistent
with Kennedy (1992) who stated that in acidic soils (pH-H2O below 4.5) unstable clay minerals release soluble
52
Al, which becomes bioavailable. Within the pH range of 4.5 to 6.0, soil acidity is buffered by cation exchange
processes (Ulrich, 1983). The pH will drop when base saturation of the exchange complex is depleted, and
this results in an increased leaching of base cations, increased Al mobilization and enhanced Al:Ca ratios (Van
Breemen et al., 1982). Al is an abundant metal in the earth’s crust, where it is part of most clay particles.
When the soil pH is above 5.5, the Al in soils remains in a solid combination with other elements and is not
harmful to plants. As the pH drops below 5.5, Al containing materials begin to dissolve
(http://www.soiltesting.okstate.edu). Below a pH-H2O value of about 4.2, Al is released and can become toxic
for plants and soil fauna (Falkengren-Grerup and Tyler, 1993), thus below this threshold only species tolerant
of Al toxicity are found (Grime et al., 2007). However, it is difficult to make a generalization of this threshold,
since it appears to be different for each plant species and soil type (Boxman et al., 1991).
The range of Olsen P and total P concentration indicates that sites where cessation of agriculture happened
recently as well as reference sites were sampled. Reference values for total P and Olsen P concentration of
Nardo-Galion grasslands are 145 to 450 mg total P kg-1 and 5 to 9 mg Olsen P kg-1 (Hommel, 2006) or 11 mg
Olsen P kg-1, according to Zwaenepoel and Stieperaere (2002). Indeed, our reference sites have an Olsen P
concentration between < 0.1 and 20 mg P kg-1 and a total P concentration between 22 and 319 mg P kg-1. Ex-
agricultural land shows a large variation in total P and Olsen P concentration (from 75 to 1692 mg total P kg -1
and from 10 to 170 mg Olsen P kg-1). Rooney et al. (2009) found that phosphate addition to acidic upland
grassland soil significantly increases soil pH, confirming the results of mixed models, where higher total P
concentration and Olsen P concentration result in an increasing mR (measure for pH). However, this was not
clearly reflected by the measured pH values, where high values (> 4.5) occur on soils with high total P
concentration, but not in the case of Olsen P concentration. P bioavailability is profoundly influenced by
changes in soil pH. In agricultural soils, the pH-H2O is generally maintained between 6 and 7, since this pH
range corresponds to the range with the highest fraction of bioavailable P (Stevenson and Cole, 1999). In soils
with lower pH, Fe and Al phosphates can be formed, whereas Ca phosphates occur in soils with higher pH
(Bardgett, 2005). On the other hand, mR is lower on more acid soils, where higher exchangeable Al
concentrations occur.
A rise in pH should increase the number of dicots and negatively influence grasses, according to Duprè et al.
(2010), but this wasn’t true for our results, since grasses have a higher cover on sites with a high mR value
(> 5). Duprè et al. investigated unfertilized acidic grasslands (indicated by the range of mR from 1 to 5), while
we included ex-agricultural land in our experiment, and this can explain the different findings. M. caerulea, a
species that tolerates acid soils well, has indeed the highest relative cover on sites with pH-KCl below 4,
supporting the findings of Maskell et al. (2010).
According to Wassen et al. (2005) endangered species are most abundant on P-limited sites and their
proportion increases with increasing P-limitation. This was confirmed by this master thesis, since the number
of Red List species strongly decreased with increasing Olsen P concentration. More than two Red List species
occur on sites with Olsen P concentration below 30 mg kg-1, while more than four species occur on sites with
less than 15 mg P kg-1 (see Figure AXIIII.1).
53
Values of less than 10 mg Olsen P kg-1 will give the greatest potential for the restoration of species-rich
mesotrophic grassland (Gilbert et al., 2009), while Hommel et al. (2006) state 5 to 9 mg P kg -1 as reference
value. Herr et al. (2011) consider 15 mg Olsen P kg-1 as a threshold value to recreate a diverse target
community. Our results support the findings of Herr et al. (2011), as highest species richness (more than 16
species) is obtained on sites with less than 15 mg Olsen P kg-1. Furthermore, species typical for Nardo-Galion
grassland (C. vulgaris, P. sylvatica) occur on sites with less than 20 mg Olsen P kg-1 and less than
300 mg P kg-1.
Nutrient-rich sites are clearly separated from nutrient-poor sites on Figure 7. This is confirmed by the plant
species (such as L. perenne, P. annua, P. pratensis and S. media on nutrient-rich sites and P. erecta and C.
palustris on nutrient-poor soils) and the direction of the arrows, indicating a larger gradient in pH, total P
concentration, Olsen P concentration and exchangeable Ca, on nutrient-rich sites. Nutrient-poor sites are
characterized by high exchangeable Al concentrations. According to NMDS, pH and exchangeable Al play the
most important role in vegetation composition. Our results confirm the findings of Critchley et al. (2002),
since pH shows the highest impact on the vegetation composition. Since Al has a high impact on the
vegetation, it is probably already released. Thus, our threshold for Al toxicity possibly lies higher than
indicated by Falkengren-Grerup and Tyler (1993). Forward selection retains pH and total P concentration as
driving factors of the structure of the vegetation community. When soluble phosphates are added to soil,
productivity of the land increases (Withers et al., 2001), but Wassen et al. (2005) provided evidence that
highest diversity was obtained at sites with intermediate productivity (between 200 and 600 g plant biomass
m-2). Thus P plays an important role in determining plant species diversity, and consequently the vegetation
composition.
It can be concluded that abiotic soil characteristics highly influence the vegetation composition, as is
confirmed by the Mantel test and CCA.
5.2. Relationship between soil fauna and abiotic soil characteristics
Influence of storage time on the efficiency of soil fauna extraction
The low number of organisms, found in L, is probably due to a longer storage time, compared to the soil
samples of TV and GP. Soil samples of TV and GP were almost immediately used for the Berlese-Tullgren
extraction, while soil samples of L stayed in the refrigerator for 4 weeks, since the extraction technique had
to be optimized. Eisenhauer et al. (2011) conducted an experiment on soil nematode communities, where
soil samples were stored at 5° C for less than a week. Lakly and Crossley (2000) investigated the impact of
storage on the efficiency of the Berlese-Tullgren extraction for mites. One set of soil samples was
immediately set up for extraction, while the other sets were stored in a 6° C refrigerator for 48, 96, 144 and
192 h. The number of mites they recovered decreased linearly with longer storage time, thus storage time
should be kept as short as possible. However, the Shannon Wiener diversity index shows only little difference
between the three nature areas, indicating that despite mortality a representative image of the soil fauna is
still obtained. Indeed, the same taxa occur in the soil samples of the three nature areas. To ascertain this
statement, new soil samples should be taken and the extractions should be repeated.
54
Influence of abiotic soil characteristics on macro- and mesofauna
According to Kardol et al. (2009) the abundance of oribatid mites increases towards the reference system,
while nematode density shows no difference in γ-diversity. Our results show that more mites occur on sites
with less than 100 mg Olsen P kg-1 and less than 800 mg P kg-1, indicating that agriculture has been stopped
for a while or that P has been added less intensely on these sites. Indeed, nematodes are more abundant on
sites with 60 to 170 mg Olsen P kg-1 and 400 to 1400 mg P kg-1 than on sites with lower P concentration,
indicating a constant γ-diversity. However, extraction might not have been optimal, due to the storage time
and the technique. Several other techniques exist to extract nematodes, such as the Baermann extraction,
centrifugation or flotation methods (Ruess, 1995) or decantation (De Deyn et al., 2003). Potworms thrive well
in acid, nutrient-poor soils (Bardgett, 2005), as is confirmed by our results, since a higher number of
potworms was found on soils with less than 100 mg Olsen P kg-1 and pH-KCl values beneath 4.
More mites occur on sites with a higher Al content, according to their position in Figure 8. When comparing
this with the findings of Kardol et al. (2009) we see that mite α-diversity is indeed highest in reference sites.
Our results differ slightly from Kardol’s results for the nematodes, since they occur with the highest numbers
in early- and mid-successional stages (indicated by their position in the middle of the figure), whereas Kardol
et al. (2009) found that nematodes were more abundant in mid- and late-succession sites. In another
experiment, Kardol et al. (2005) demonstrated that the proportion of the nematode functional groups
changed from ex-arable fields to semi-natural fields. In semi-natural fields more bacterial feeding nematodes
occurred, while the number of fungal feeding nematodes declined. However, allocating nematodes to
functional groups wasn’t in the scope of this master thesis, due to the limited time frame.
Since earthworms do not tolerate acid soils well, according to Edwards (2009), but enchytraeid worms do,
they should be the functionally dominant soil organisms in acid, nutrient-poor grasslands (Bardgett, 2005).
Earthworms appear slightly higher than potworms on Figure 8, indicating their preference for soils with
higher total P concentration, pH and exchangeable Ca. Our collection of earthworms wasn’t thoroughly
enough to conclude if they were dominated by potworms on reference sites. There are different methods to
sample earthworms, such as combining litter sorting (in forest ecosystems), extraction with mustard solution,
hand sorting (applied in this experiment, but on a small soil sample, while dimensions of 0.3 x 0.3 with 20 cm
depth are recommended) (De Schrijver et al., 2011) and electrical extraction (Bohlen et al., 1995).
According to the used techniques (CCA and Mantel test) there’s only a low impact of abiotic soil
characteristics on macro- and mesofauna. This is reflected by the different results, since NMDS indicates pH
and exchangeable Ca as most important factors influencing the soil fauna community, while forward
selection retains Olsen P concentration as most important variable. In temperate regions, such as Flanders,
lime and fertilizers are commonly added to agricultural soil, inducing a raise in pH and soil fertility. The main
nutrients of applied fertilizers are N, P and K (Haynes and Naidu, 1998). Ca is an important soil element, since
it neutralizes soil acidity and creates a healthy environment for soil biota (www.emep.int). Moreover, the
Ca2+ ion serves as a universal messenger, transmitting signals from the eukaryotic cell surface to the interior
of the cell (Dominguez, 2004). Changes in the concentration of Ca2+ have been associated with the regulation
55
of a variety of cellular processes, such as cell differentiation, transport, motility, gene expression, stress
signals, metabolism, cell cycle and pathogenesis (Sanders et al., 1999; Whitaker and Larman, 2001).
Influence of abiotic soil characteristics on microfauna
In Figure AVIII.1 is shown that L has the lowest ACWD value for all groups of C-sources, except for
phosphorylated chemicals, meaning that bacteria are less active in L.
High quality litter (low C:N ratio) of fast-growing plants stimulates the growth and activity of bacteria and
their consumers (e.g. bacterial feeding protozoa and nematodes) leading to enhanced decomposition and
nutrient turnover, further benefitting the rapid growth of plant species adapted for fertile sites (Bardgett,
2005). However, we found no evidence for this statement, in that fertile soils (high total P and Olsen P
concentration) didn’t have higher ACWD values for the eight groups of C-sources.
According to NMDS, pH, exchangeable Ca and total P concentration influence the microbial community most.
The role of exchangeable Ca and total P concentrations is confirmed by mixed models. Furthermore,
exchangeable Ca is the only abiotic soil characteristic retained by forward selection, stressing its importance
for soil microbes. The role of Ca can be explained by the findings of Smith (1995), who found evidence that
calcium is involved in a number of bacterial processes such as maintenance of cell structure, motility, cell
division, gene expression and cell differentiation processes.
The results of mixed models and NMDS seem to contradict each other for nutrient-poor soils. Higher total P
concentrations and consequently higher Olsen P concentrations, along with higher Ca concentrations favor
bacteria oxidizing carbohydrates, since the AIC value of the null model reduces significantly when these
variables are introduced separately. Furthermore, higher Ca concentrations lead to a higher use of polymers.
On Figure 6 reference sites are separated from ex-agricultural sites. But according to Figure 9, bacteria on
acid, nutrient-poor sites oxidize more L-phenylalanine, N-acetyl-D-glucosamine and D-glucosaminic acid,
which are respectively an amino acid, a carbohydrate and a carboxylic acid. On the other hand bacteria in rich
soils utilize mainly α-D-lactose (carbohydrate), D-xylose (carbohydrate), α-cyclodextrin (polymer) and glycyl-
L-glutamic acid (amino acid). So for rich soils results are mainly compatible, since more carbohydrates and
polymers are used in soils with higher total P concentration and exchangeable Ca. Rooney et al. (2009) found
that phosphate addition increased microbial activity, but we can’t offer any study that confirms a higher
oxidation of carbohydrates in nutrient-rich soils.
We can conclude that the microbial community is more influenced by abiotic soil characteristics than macro-
and mesofauna.
5.3. Relationship between vegetation composition and soil fauna
Influence of macro- and mesofauna on vegetation composition
Sabais et al. (2011) demonstrated that Collembola density and diversity increased with plant species and
plant functional group richness, but Salamon et al. (2004) found no effect of species richness on the total
56
diversity of Collembola. In our case, the number of Collembola is highest on sites with an intermediate
number of plant species (eight to ten). The same accounts for Acari, Nematoda and Enchytraeidae, where the
highest number of organisms occurs on sites with seven to ten plant species. Higher plant diversity insures an
elevated quantity and quality of plant residues, which serve as food resource (Sabais et al., 2011). However,
invertebrate soil fauna enhances secondary succession and local plant species diversity. The soil fauna
steered the plant community towards the dominance of plant species from the late succession (target)
community (De Deyn et al., 2003). Indeed, most reference sites (containing species typical for Nardo-Galion
grasslands) count higher numbers of nematodes, springtails and potworms. Based on Figure 11 rich soils
(characterized by species such as L. perenne) should contain more taxa, slightly more organisms and have a
higher diversity. The highest number of taxa (> 6) and organisms (> 100) occurred on soils with more than 50
mg bioavailable P kg-1, while the highest Shannon-Wiener diversity index (>1.4) occurred on nutrient-poor
and nutrient-rich soils. I expect that on these soils (with a large amount of organisms, but an inappropriate
Olsen P concentration for the establishment of Nardo-Galion species) succession towards the target
community will continue once the desired P availability is reached. Extraction of soil fauna will be repeated
and based on these results we will see if this explanation still holds.
A higher number of taxa induces a rise in mR, since soil fauna decomposes litter, soil organic matter and root
exudates (Wardle, 2002) insuring a high plant nutrient availability and a rise of soil pH, as can be deduced
from the findings of Rooney et al. (2009).
Figure 10 confirms our previous finding, namely that nematodes occur especially on early- and mid-
successional sites. The arrow representing the nematodes coincides with the sites characterized by species
typically found on nutrient-rich soils, such as L. perenne and R. acris. Mites should be more present in acid
soils, consequently I expected that the arrow, which represents mites would point to the left, but this isn’t
the case. In fact, none of the arrows, representing taxa point to the left, indicating that vegetation
composition on acid, nutrient-poor soils isn’t primarily driven by the investigated groups of macro- and
mesofauna. For instance we didn’t allocate macro- and mesofauna to different functional groups, whereas
Eisenhauer et al (2011) demonstrated that simple plant communities and species-rich plant communities
differ in their functional structure of the soil food web. Our results confirm the findings of Bezemer et al.
(2006) who found that plant-soil feedback responses in sandy soils are based on abiotic soil properties, while
soil biota (microbes) altered the plant-soil feedback in chalk soils. The soil of the three nature areas,
investigated in this master thesis is mainly composed of sand.
Overall, we conclude that macro- and mesofauna are of minor importance for the vegetation composition of
acidic, nutrient-poor grasslands.
Influence of microfauna on vegetation composition
According to Staddon et al. (1998), plant species richness increases catabolic activity and microbial diversity
(use of the different carbon-oxidation pathways). In their experiment they also used Biolog microtiter plates.
However, we didn’t find higher ACWD values (or oxidation rates) with higher plant species richness. Of course
the number of C-sources used in the microtiter plates is limited and this can create a bias. Stephan et al.
57
(2000) showed that forbs didn’t influence the microbial community, whereas legumes increased both activity
and diversity. Testing the effect of plant species identity, showed only a significant response for the legume
Trifolium repens. In our case the presence of T. repens didn’t evoke higher ACWD-values of none of the
groups of C-sources (higher relative cover of this plant species didn’t increase ACWD-values). Zak et al. (2003)
found that changes in microbial community biomass, activity and composition resulted from higher levels of
plant production, rather than plant diversity. We didn’t measure plant biomass, but the most productive
sites, were the ones where agriculture recently ceased and with low species richness (mainly L. perenne, H.
lanatus and R. acris). Furthermore, Brodie et al. (2002) investigated the bacterial community across a floristic
gradient (from a Nardo-Galion grassland to an improved pasture) by means of Biolog microtiter plates and
found an increase of bacterial numbers and microbial activity with decreasing plant diversity. These findings
support our results. Moreover, they investigated which C-sources contributed most to the differences in the
microbial communities of the Nardo-Galion grassland and the pasture. Differences in soil microbial
community carbon utilization could be attributed to D-serine (a C-source we didn’t use) and α-cyclodextrin.
Comparing our ACWD values of reference sites and ex-agricultural land confirms the difference in the use of
α-cyclodextrin. The ACWD values of the carbohydrates α-D-lactose and D-xylose also showed large
differences for reference sites and ex-agricultural land. Indeed the use of polymers, such as α-cyclodextrin,
influences vegetation composition, since higher oxidation of polymers reduces mF and increases mR
according to the technique of mixed models. The results of NMDS are contradictory, saying that the use of
amines and aromatic compounds influences vegetation composition more than bacterial use of other C-
sources.
There’s a larger gradient in C-sources on nutrient-rich soils (characterized by e.g. L. perenne and T. officinalis)
according to Figure 13, explaining the higher use (ACWD values) on ex-agricultural land. N-acetyl-D-
glucosamine and Tween 40 are more used on reference sites compared to ex-agricultural land, indicated by
their higher ACWD values.
According to CCA and the Mantel test a significant part of the variation in vegetation composition can be
clarified by the bacterial use of several C-sources. This can be explained by the findings of Van der Putten et
al. (1993) and Bever (2003), who stated that on short time scales, plant succession may mainly be dependent
on the presence of harmful (pathogens) and beneficial organisms (who decompose litter, soil organic matter
and root exudates or establish a symbiotic relationship) in the rhizosphere, instead of abiotic soil properties.
Soil bacteria are important for the nutrient cycling in ecosystems, degrading organic compounds that can be
taken up by plants. They can favor some species by providing N through symbiosis (genus Rhizobium) or as
free-living bacteria (genera Azotobacter and Clostridium) (Bardgett, 2005). When C-sources are grouped,
averages are used (omitting part of the data), and this could explain their low correlation with the vegetation
matrix (Mantel test) and their low contribution to the variation in the vegetation composition (CCA).
58
6. Conclusion and future research
Most nature restoration takes place on formerly cultivated land, which makes it necessary to reduce the
nutrient level to obtain the target plant community. Especially P should receive attention, due to its long
retention time in soil. Species richness appears to be low on ex-agricultural land, whereas target species can
be found on reference sites with low P availability. Particularly endangered species are susceptible to high P
levels. Soil acidity (and consequently exchangeable Al) are also important factors, influencing the vegetation
composition by suppressing sensitive species, while others get the opportunity to dominate (such as M.
caerulea). Clearly, there’s a relationship between abiotic soil characteristics and the vegetation composition
of acidic, nutrient-poor grasslands.
Abiotic soil characteristics have more impact on the bacterial community than on macro- and mesofauna.
The interplay of Olsen P concentration, soil pH and exchangeable Ca influences the macro- and mesofauna,
while exchangeable Ca is retained as most important soil property when microfauna is considered. Soil biota
attach more importance to calcium, which has a role in cell regulation, signal transduction and neutralizes
soil acidity.
Based on our results, the bacterial community has a larger influence on the vegetation composition of Nardo-
Galion grasslands than macro- and mesofauna. Bacteria were more active on high-productive ex-agricultural
land, especially the use of polymers differentiates reference sites from ex-agricultural land.
In order to reestablish a Nardo-Galion grassland, abiotic soil conditions certainly need to be considered and
probably the microbial community as well. Biolog ecoplates have several constraints: they only contain
culturable bacteria, the used substrates are not necessarily the substrates present in soil and fungi do not
metabolize tetrazolium dye (Stefanowicz, 2006). So analysis of the microbial community can be repeated
with other techniques, such as DNA extraction or phospholipid fatty acids (PLFA) analysis, where total
microbial biomass is quantified and the microbial community is assessed. Furthermore, the role of fungi
should be investigated, to find out if they interfere with our recent results. Analysis of the macro- and
mesofauna could be conducted based on their feeding habit (functional groups). In the future, vegetation
surveys and soil analysis can be repeated to ascertain if succession towards the target community continues
on ex-agricultural land.
59
7. List of abbreviations and symbols
Abbreviation/Symbol Meaning
L Liereman
TV Turnhouts Vennengebied
GP Gulke Putten
H Shannon-Wiener diversity index
J Eveness
PCA Principal Components Analysis
DCA Detrended Correspondence Analysis
NMDS Non-Metric Multidimensional Scaling
CCA Canonical Correspondence Analysis
TWINSPAN Two-way indicator species analysis
VIF Variance inflation factors
ICC Intra-class correlation
N Nitrogen
P Phosphorus
K Potassium
Ca Calcium
Mg Magnesium
Al Aluminium
Pb Lead
mL Weighted mean Ellenberg score for light
mF Weighted mean Ellenberg score for soil humidity
mR Weighted mean Ellenberg score for soil acidity
mN Weighted mean Ellenberg score for productivity
ACWD Average color well development
60
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Withers P.J.A., Edwards A.C. and Foy R.H. (2001). Phosphorus cycling in UK agriculture and implications for phosphorus loss from soil. Soil Use and Management 17, 139-149. Zaitsev A.S.,Wolters V.,Waldhardt R. and Dauber, J. (2006). Long-term succession of oribatid mites after conversion of croplands to grasslands. Applied Soil Ecology 34, 230–239. Zak D.R., Holmes W.E., White D.C., Peacock A.D. and Tilman D. (2003). Plant diversity, soil microbial communities, and ecosystem function: are there any links ? Ecology 84, 2042-2050. Zwaenepoel A. and Stieperaere H. (2002). Systematiek van natuurtypen voor Vlaanderen: 6.5 Graslanden, heischrale graslanden, hoofdstuk 16: heischraal grasland (Nardo-Galion). Instituut voor Natuur- en Bosonderzoek, Brussel. Zwart K.B. and Darbyshire J.F. (1991). Growth and nitrogenous excretion of a common soil flagellate, Spumella sp. European Journal of Soil Science 43, 145-157.
72
9. Appendices
Appendix I: VIF factors Table AI.1: VIF factors (red cases indicate high correlation, VIF > 3).
Predictor variable 1
Predictor variable 2 R² VIF Variable 1 Variable 2 R² VIF
total P Olsen P 0.72 3.51 mF mR 0.48 1.90
pH-KCl 0.37 1.59 mN 0.56 2.27
Exchangeable
Ca 0.51 2.03 Shannon-
Wiener 0.00 1.00
Exchangeable
Al 0.25 1.33 Eveness 0.02 1.02
Olsen P pH-KCl 0.23 1.29 mR mN 0.76 4.12
Exchangeable
Ca 0.22 1.29 Shannon-
Wiener 0.00 1.00
Exchangeable
Al 0.25 1.32 Eveness 0.06 1.06
pH-KCl Exchangeable
Ca 0.58 2.35 mN Shannon-
Wiener 0.02 1.02
Exchangeable
Al 0.56 2.28 Eveness 0.05 1.06
Ca Exchangeable
Al 0.26 1.35 Shannon-Wiener Eveness 0.30 1.43
Number of taxa
Number of organisms 0.38 1.61
Number of Red List species
mF 0.17 1.21
Shannon-Wiener 0.57 2.34 mR 0.42 1.71
Number of organisms
Shannon-Wiener 0.03 1.03 mN 0.47 1.90
Shannon-Wiener 0.02 1.02
Eveness 0.06 1.06
Number of plant
species
mF 0.02 1.02
mR 0.02 1.02
mN 0.05 1.05
Shannon-Wiener 0.55 2.23
Eveness 0.00 1.00
Number of Red List species 0.13 1.14
73
Appendix II: Overview of plant species, Shannon-Wiener diversity index and
eveness Table AII.1: Overview of the 95 plant species present in the three nature areas. For analysis, genus name is restricted
to the first letter (e.g. Pedicularis sylvatica = P. sylvatica).
Plant species
Pedicularis sylvatica Festuca pratensis Drosera rotundifolia
Molinia caerulea Bidens tripartita Achillea millefolium
Potentilla erecta Galium palustre Stellaria media
Calluna vulgaris Lotus corniculatus var. corniculatus Stellaria graminea
Erica tetralix Rumex acetosella Centaurium
Polygala serpyllifolia Rumex acetosa Polypodium vulgare
Nardus stricta Taraxacum officinalis Anthriscus sylvestris
Poa annua Jasione montana Leucanthemum vulgare
Poa pratensis Lysimachia vulgaris Prunella vulgaris
Lolium perenne Plantago major subsp. major Salvia officinalis
Hydrocotyle vulgaris Plantago lanceolata Cytisus scoparius
Arrhenatherum elatius Fragaria vesca Centaurea jacea
Carex panicea Cirsium palustre Equisetum
Holcus mollis Cirsium arvense Conyza canadensis
Holcus lanatus Potentilla anserina Senecio viscosus
Danthonia decumbens Artemisia vulgaris Senecio erucifolius
Hieracium pilosella Ornithopus perpusillus Veronica arvensis
Rubus idaeus Caltha palustris subsp. palustris Chamerion angustifolium
Juncus effusus Ranunculus acris Viola arvensis
Juncus squarrosus Ranunculus flammula Matricaria recutita
Lycopus europaeus Alopecurus pratensis Trifolium arvense
Lycopodiella inundata Rhinanthus minor Rumex obtusifolius
Polygonum persicaria Persicaria mitis Gnaphalium uliginosum
Agrostis canina Trifolium dubium Gentiana pneumonanthe
Luzula campestris Cerastium arvense Geranium molle
Trifolium repens Hypericum perforatum Pinus sylvestris
Trifolium pratense Hieracium sabaudum Betula
Leontodon autumnalis Urtica dioica Rhamnus frangula
Leontodon hispidus Vicia sepium Salix
Persicaria lapathifolia subp. pallida Jacobaea vulgaris subsp. vulgaris Alnus
Phragmites australis Tanacetum vulgare Quercus
Cardamine pratensis Veronica serpyllifolia
74
Table AII.2: Minimum, maximum and average Shannon-Wiener diversity index (H) and Eveness (J) of the three nature
areas (Liereman, Turnhouts Vennengebied and Gulke Putten).
Shannon-
Wiener Eveness
Liereman
min 0.34 0.21
max 2.17 0.96
average 1.31 0.70
Turnhouts Vennengebied
min 0.82 0.53
max 2.56 0.90
average 1.61 0.71
Gulke Putten
min 0.13 0.41
max 2.27 0.95
average 1.71 0.80
75
Appendix III: Overview Stress value Table AIII.1: Overview of the lowest stress value (S) for the different ordinations (based on the vegetation, the macro-
and mesofauna, and the microfauna).
response variable Area S
vegetation
Liereman 0.12
Turnhouts Vennengebied 0.17
Gulke Putten 0.12
All areas 0.18
macro- and mesofauna
Liereman 0.14
Turnhouts Vennengebied 0.18
Gulke Putten 0.22
All areas 0.22
microfauna
Liereman 0.10
Turnhouts Vennengebied 0.14
Gulke Putten 0.17
All areas 0.17
76
Appendix IV: NMDS ordination diagrams based on the vegetation surveys Table AIV.1: Subplots corresponding with the numbers on the ordination diagram for Liereman.
Liereman
Plot Subplot Number Plot Subplot Number
1 1 1 7 1 25
2 2
2 26
3 3
3 27
4 4
4 28
5 5
5 29
2 1 6 8 1 30
2 7
2 31
3 8
3 32
3 1 9
4 33
2 10
5 34
3 11 9 1 35
4 12
2 36
5 13
3 37
4 1 14 10 1 38
2 15
2 39
3 16
3 40
5 1 17
4 41
2 18
5 42
3 19 11 1 43
6 1 20
2 44
2 21
3 45
3 22
4 23
5 24
77
Table AIV.2: Subplots corresponding with the numbers on the ordination diagram for Turnhouts Vennengebied.
Turnhouts Vennengebied
Plot Subplot Number Plot Subplot Number Plot Subplot Number
1 1 1 8 1 29 14 1 55
2 2 2 30 2 56
3 3 3 31 3 57
2 1 4 4 32 15 1 58
2 5 5 33 2 59
3 6 9 1 34 3 60
3 1 7 2 35 16 1 61
2 8 3 36 2 62
3 9 4 37 3 63
4 1 10 5 38 17 1 64
2 11 10 1 39 2 65
3 12 2 40 3 66
4 13 3 41
5 14 4 42
5 1 15 5 43
2 16 11 1 44
3 17 2 45
6 1 18 3 46
2 19 4 47
3 20 5 48
7 1 21 12 1 49
2 22 2 50
3 23 3 51
4 24 13 1 52
5 25 2 53
6 26 3 54
7 27
8 28
78
Table AIV.3: Subplots corresponding with the numbers on the ordination diagram for Gulke Putten.
Gulke Putten
Plot Subplot Number Plot Subplot Number Plot Subplot Number Plot Subplot Number
1 1 112 7 1 142 13 1 172 19 1 198
2 113 2 143 2 173 2 199
3 114 3 144 3 174 3 200
4 115 4 145 4 175 4 201
5 116 5 146 5 176 5 202
2 1 117 8 1 147 14 1 177 20 1 203
2 118 2 148 2 178 2 204
3 119 3 149 3 179 3 205
4 120 4 150 15 1 180 4 206
5 121 5 151 2 181 5 207
3 1 122 9 1 152 3 182 21 1 208
2 123 2 153 4 183 2 209
3 124 3 154 5 184 3 210
4 125 4 155 16 1 185 4 211
5 126 5 156 2 186 5 212
4 1 127 10 1 157 3 187 22 1 213
2 128 2 158 4 188 2 214
3 129 3 159 5 189 23 1 215
4 130 4 160 17 1 190 2 216
5 131 5 161 2 191 3 217
5 1 132 11 1 162 3 192 4 218
2 133 2 163 18 1 193 5 219
3 134 3 164 2 194
4 135 4 165 3 195
5 136 5 166 4 196
6 1 137 12 1 167 5 197
2 138 2 168
3 139 3 169
4 140 4 170
5 141 5 171
79
Figure AIV.1: NMDS ordination diagram based on the cover of plant species present in Liereman. Numbers represent
subplots (see Table AIV.1), species are indicated in red.
Figure AIV.2: NMDS ordination diagram based on the cover of plant species present in Turnhouts Vennengebied.
Numbers represent subplots (see Table AIV.2), species are indicated in red.
80
Figure AIV.3: NMDS ordination diagram based on the cover of plant species present in Gulke Putten. Numbers
represent subplots (see Table AIV.3), species are indicated in red.
81
Appendix V: TWINSPAN Table AV.1: Correlations between TWINSPAN groups and abiotic soil characteristics and between TWINSPAN groups
and weighted mean Ellenberg scores (with *= significant, p < 0.05).
0 vs. 1 00 vs. 01 11 vs. 10 010 vs. 011 110 vs. 111
Total P (mg kg-1) 3.75E-14* 6.60E-12* 0.001* 0.341 0.279
Olsen P (mg kg-1) 5.73E-14* 6.80E-06* 2.70E-04* 0.053 0.721
pH-KCl 2.19E-14* 4.75E-11* 0.005* 0.349 0.959
Exchangeable Ca (mg kg-1) 3.07E-11* 3.05E-10* 0.020* 0.037* 0.234
Exchangeable Al (mg kg-1) 7.94E-12* 5.09E-07* 0.616 0.146 0.195
mL 1.21E-07* 4.65E-01 0.303 1.18E-04* 0.833
mF 2.21E-07* 7.41E-08* 0.047* 0.856 0.057
mR 4.27E-13* < 2.2e-16* 4.83E-04* 0.068 0.051
mN < 2.2e-16* < 2.2e-16* 0.003* 0.017* 0.045*
87
Appendix VI: The relationship between pH-KCl and exchangeable Al
Figure AVI.1: pH-KCl in function of exchangeable Al concentration (mg kg-1) for the three nature areas.
0 1 2 3 4 5 6
0 200 400 600 800
pH
-KC
l
Exchangeable Al (mg kg-1)
Liereman
0 1 2 3 4 5 6
0 200 400 600
pH
-KC
l
Exchangeable Al (mg kg-1)
Turnhouts Vennengebied
0
2
4
6
0 100 200 300 400
pH
-KC
l
Exchangeable Al (mg kg-1)
Gulke Putten
88
Appendix VII: NMDS ordination diagrams based on macro- and mesofauna Table AVII.1: Subplots corresponding with the numbers on the ordination diagram for Liereman.
Liereman
Plot Subplot Number
1 1 1
3 2
5 3
2 1 4
3 5
5 6
3 1 7
3 8
5 9
4 1 10
3 11
5 12
5 1 13
3 14
5 15
3 16
5 17
7 1 18
3 19
5 20
8 1 21
3 22
5 23
9 1 24
3 25
5 26
10 1 27
3 28
5 29
11 1 30
3 31
5 32
89
Table AVII.2: Subplots corresponding with the numbers on the ordination diagram for Turnhouts Vennengebied.
Turnhouts Vennengebied
Plot Subplot Number Plot Subplot Number
1 1 1 11 1 32
3 2 3 33
5 3 5 34
2 1 4 12 1 35
3 5 3 36
5 6 5 37
3 1 7 13 1 38
3 8 3 39
5 9 5 40
4 1 10 14 1 41
3 11 3 42
5 12 5 43
5 1 13 15 1 44
3 14 3 45
5 15 5 46
6 1 16 16 1 47
3 17 3 48
5 18 5 49
7 1 19 17 1 50
3 20 5 51
5 21
7 22
8 1 23
3 24
5 25
9 1 26
3 27
5 28
10 1 29
3 30
5 31
90
Table AVII.3: Subplots corresponding with the numbers on the ordination diagram for Gulke Putten.
Gulke Putten
Plot Subplot Number Plot Subplot Number
1 1 1 12 1 34
3 2 3 35
5 3 13 1 36
2 3 4 3 37
5 5 5 38
3 1 6 14 1 39
3 7 3 40
5 8 15 1 41
4 1 9 3 42
3 10 5 43
5 11 16 1 44
5 1 12 3 45
3 13 5 46
5 14 17 1 47
6 1 15 2 48
3 16 18 1 49
5 17 3 50
7 1 18 4 51
3 19 5 52
5 20 19 1 53
8 1 21 3 54
2 22 5 55
3 23 20 1 56
5 24 3 57
9 1 25 5 58
3 26 21 1 59
5 27 3 60
10 1 28 5 61
3 29 22 2 62
5 30 23 1 63
11 1 31 3 64
3 32 5 65
5 33
91
Figure AVII.1: NMDS ordination diagram based on the macro- and mesofauna of Liereman. Numbers represent
subplots (see Table AVII.1), species are indicated in red.
Figure AVII.2: NMDS ordination diagram based on the macro- and mesofauna of Turnhouts Vennengebied. Numbers
represent subplots (see Table AVII.2), species are indicated in red.
92
Figure AVII.3: NMDS ordination diagram based on the macro- and mesofauna of Gulke Putten (without Chilopoda,
Diplopoda, Hymenoptera, Heteroptera, Orthoptera, Isopoda, Thysanoptera and ants). Numbers represent subplots
(see Table AVII.3), species are indicated in red.
Figure AVII.4: NMDS ordination diagram, based on the macro- and mesofauna of the three nature areas. Blue circles
indicate outliers (22 = L 8-3 and 58 = TV 9-1).
93
Figure AVII.5: NMDS ordination diagram, based on the macro- and mesofauna of the three nature areas, without
outliers (L 8-3 and TV 9-1).
94
Appendix VIII: Biolog Ecoplates Table AVIII.1: Carbon sources in Biolog Ecoplates belonging to different functional groups.
a The four columns are
repeated three times on one Ecoplate.
A1: Water A2: β-methyl-D-glucoside1 A3: D-galactonic acid γ-lactone2 A4: L-Arginine3
B1: Pyruvic acid methyl esther4 B2: D-xylose1 B3: D-galacturonic acid2 B4: L-Asparagine3
C1: Tween 405 C2: i-Erythritol1 C3: 2-hydroxy benzoic acid6 C4: L-Phenylalanine3
D1: Tween 805 D2: D-Mannitol1 D3: 4-hydroxy benzoic acid6 D4: L-Serine3
E1: α-cyclodextrin5 E2: N-acetyl-D-glucosamine1 E3: γ-hydroxybutyric acid2 E4: L-Threonine3
F1: Glycogen5 F2: D-glucosaminic acid2 F3: Itaconic acid2 F4: Glycyl-L-Glutamic acid3
G1: D-Cellobiose1 G2: Glucose-1-Phosphate7 G3: α-Ketobutyric acid2 G4: Phenylethylamine8
H1: α-D-Lactose1 H2: D,L-α-Glycerol phosphate7 H3: D-Malic acid2 H4: Putrescine8
a Functional groups:
1 Carbohydrates,
2 Carboxylic acids,
3 Amino acids,
4 Esters,
5 Polymers,
6 Aromatic compounds,
7
Phosphorylated chemicals, 8 Amines.
Figure AVIII.1: Use of the grouped carbon sources in the three nature areas (Liereman, Turnhouts Vennengebied and
Gulke Putten).
0.00
0.20
0.40
0.60
0.80
1.00
1.20
1.40
1.60
Liereman Turnhouts Vennengebied Gulke Putten
95
Table AVIII.2: Abbreviations of the carbon sources used for analysis and their full names.
methylgluc β-methyl-D-glucoside hydrbutacid γ-hydroxybutyric acid
galactlact D-galactonic acid γ-lactone Lthreo L-threonine
arg L-arginine glycogen glycogen
Pyracidmet Pyruvic acid methyl esther Dglucoacid D-glucosaminic acid
Dxyl D-xylose ItaconicA Itaconic acid
Dgalactacid D-galacturonic acid GlycylLGlutAcid Glycyl-L-Glutamic acid
Lasp L-asparagine DCello D-Cellobiose
Tween40 Tween 40 Gluc1Phos Glucose-1-Phosphate
iErythritol i-Erythritol KetobutAcid α-Ketobutyric acid
2hydrbenzacid 2-hydroxy benzoic acid Phenyletam Phenylethylamine
Lphenylal L-phenylalanine Lact α-D-Lactose
Tween80 Tween 80 DLGlycerol D,L-α-Glycerol phosphate
Dmann D-mannitol DMalicA D-Malic acid
4hydrbenzacid 4-hydroxy benzoic acid Putrescine Putrescine
Lser L-serine Nacetylgluc N-acetyl-D-glucosamine
cyclodex α-cyclodextrin
96
Appendix VIIII: NMDS ordination diagrams based on the ACWD values of 31
carbon sources Table AVIIII.1: Subplots corresponding with the numbers on the ordination diagram for Liereman (A), for Turnhouts
Vennengebied (B) and for Gulke Putten (C).
A) Liereman
Plot Number
1-5 1
2-1 2
3-1 3
4-1 4
5-3 5
6-3 6
7-5 7
8-3 8
9-3 9
10-3 10
11-3 11
7-3 12
3-5 13
6-5 14
B) Turnhouts Vennengebied
Plot Number
1-1 1
2-3 2
3-3 3
4-1 4
6-3 5
7-7 6
8-3 7
9-5 8
10-1 9
11-3 10
12-3 11
13-1 12
14-3 13
15-3 14
16-1 15
17-1 16
17-3 17
12-1 18
7-1 19
C) Gulke Putten
Plot Number
1-3 1
2-3 2
3-5 3
4-5 4
5-5 5
6-3 6
7-3 7
8-5 8
9-5 9
10-1 10
11-5 11
12-1 12
13-5 13
14-3 14
15-5 15
16-3 16
17-1 17
18-3 18
19-3 19
20-1 20
21-3 21
22-1 22
23-5 23
21-1 24
20-3 25
16-5 26
97
Figure AVIIII.1: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Liereman. Numbers
represent subplots (see Table AVIIII.1A), C-sources are indicated in red.
Figure AVIIII.2: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Liereman, where subplots
are identified as reference sites (=ref) or ex-agricultural land (=field). Black dots = reference sites, blue dots = ex-
agricultural land.
98
Figure AVIIII.3: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Turnhouts Vennengebied.
Numbers represent subplots (see Table AVIIII.1B), C-sources are indicated in red.
Figure AVIIII.4: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Turnhouts Vennengebied,
where subplots are identified as reference sites (=ref) or ex-agricultural land (=field). Black dots = reference sites,
blue dots = ex-agricultural land.
99
Figure AVIIII.5: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Gulke Putten. Numbers
represent subplots (see Table AVIIII.1C), C-sources are indicated in red.
Figure AVIIII.6: NMDS ordination diagram, based on the ACWD values of 31 C-sources of Gulke Putten, where
subplots are identified as reference sites (=ref) or ex-agricultural land (=field). Black dots = reference sites, blue dots
= ex-agricultural land.
100
Figure AVIIII.7: NMDS ordination diagram, based on the ACWD values of 31 C-sources of the three nature areas
(Liereman, Turnhouts Vennengebied and Gulke Putten).
Figure AVIIII.8: NMDS ordination diagram based on the vegetation surveys of the three nature areas (Liereman,
Turnhouts Vennengebied and Gulke Putten). Numbers represent subplots, plant species are indicated in red and the
C-sources are represented by blue arrows.
101
Figure AVIIII.9: NMDS ordination diagram based on the ACWD values of the three nature areas (blue = Liereman,
black = Turnhouts Vennengebied and green = Gulke Putten).
102
Appendix X: Mixed models Table AX.1: Results of mixed models performed on the characteristics of the vegetation and abiotic soil
characteristics. Green cases represent final selected models, na (= not applicable) indicates insufficient lowering of
the AIC value of the null model or inappropriate plots of fitted and residual values.
response variables
mF mR mN
Shannon-Wiener Eveness
Number of Red
List species
Number of plant
species
Null model
AIC 394.63 651.96 442.83 132.06 -407.00 562.90 1043.49
ICC 60.11% 76.38% 87.89% 49.06% 43.88% 78.86% 75.25%
Model
pre
dicto
r variable
s
Total P
AIC 395.63 637.71 443.44 132.52 -407.66 557.43 1040.91
t na 4.48 na na na na na
explained variance na 33.55% na na na na na
Olsen P
AIC 394.74 638.85 444.30 133.09 -408.93 560.28 1042.20
t na 4.19 na na na na na
explained variance na 28.18% na na na na na
pH-KCl
AIC 379.01 620.21 436.83 134.00 -407.50 554.95 1045.46
t -5.08 7.25 3.27 na na na na
explained variance 48.78% 57.61% 27.47% na na na na
Exchangeable Ca
AIC 391.53 644.49 441.99 134.06 -407.65 561.84 1044.43
t -2.50 3.47 na na na na na
explained variance 22.11% 28.35% na na na na na
Exchangeable Al
AIC 379.85 635.57 438.06 133.37 -408.90 547.70 1043.30
t 4.60 -4.71 -2.80 na na na na
explained variance 38.61% 33.35% 19.01% na na na na
pH-KCl* Exhcangeable
Ca
AIC 378.11 na na na na na na
explained variance 52.15% na na na na na na
Total P*pH-KCl
AIC na 603.90 na na na na na
explained variance na 75.21% na na na na na
pH-KCl* Exchangeable
Al
AIC na na 437.25 na na na na
explained variance na na 35.22% na na na na
103
Table AX.2: Results of ANOVA performed on the selected final models as indicated in Table AX.1 (significance code
*** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1).
response variables
mF mR mN
Final model
Df 165 165 165
F 4.88 14.63 0.65
t 2.21 -3.83 0.81
P 0.0285** 0.0002*** 0.4199
Table AX.3: Results of mixed models performed on the characteristics of macro- and mesofauna and abiotic soil
characteristics (na = not applicable, indicates insufficient lowering of the AIC value of the null model or
inappropriate plots of fitted and residual values). No final models were selected.
response variables
Number of taxa
Number of organisms
Shannon-Wiener
Null model
AIC 558.49 1389.65 168.66
ICC 10.61% 13.56% 10.65%
Model
pre
dicto
r variables
total P
AIC 542.85 1374.70 165.14
t 4.64 4.48 na
explained variance 90.39% 50.64% na
OlsenP
AIC 546.90 1371.06 167.95
t 3.93 4.94 na
explained variance 60.76% 64.68% na
pH-KCl
AIC 553.53 1388.95 166.40
t 2.71 na na
explained variance 51.33% na na
Exchangeable Ca
AIC 552.73 1389.57 168.74
t 2.85 na na
explained variance 48.87% na na
Exchangeable Al
AIC 556.27 1389.39 168.58
t na na na
explained variance na na na
104
Table AX.4: Results of mixed models performed on the microfauna and abiotic soil characteristics. Green cases represent final selected models, na (= not
applicable) indicates insufficient lowering of the AIC value of the null model or inappropriate plots of fitted and residual values.
response variables
carbohydrates
carboxylic acids
amino acids esters polymers
aromatic compounds
phosphorylated chemicals amines
Null model
AIC 87.55 -3.94 52.84 87.85 67.41 60.23 24.58 79.91
ICC 1.50% 0.00% 0.00% 0.00% 13.10% 16.62% 0.00% 0.25%
Model
pre
dicto
r variable
s
Total P
AIC 81.73 -6.62 51.56 89.75 59.51 55.69 25.86 79.45
t 2.84 na na na na na na na
explained variance 99.99% na na na na na na na
Olsen P
AIC 81.25 -6.89 51.31 88.25 62.74 54.49 25.09 79.46
t 2.93 na na na na na na na
explained variance 99.99% na na na na na na na
pH-KCl
AIC 87.87 -3.78 54.20 89.83 65.12 58.63 21.85 79.41
explained variance na na na na na na na na
Exchangeable Ca
AIC 81.86 -4.52 51.66 89.41 51.22 58.04 18.94 77.44
explained variance na na na na 46.09% na na na
Exchangeable Al
AIC 88.15 -3.57 54.24 89.79 67.20 60.36 23.66 80.03
explained variance na na na na na na na na
105
Table AX.5: Results of ANOVA performed on the selected final models as indicated in Table AX.4 (significance
code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1).
response variables
carbohydrates polymers
Final model
Df 8 8
F 8.61 20.62
t 2.93 4.54
P 0.0189* 0.0019**
Table AX.6: Results of mixed models performed on the characteristics of macro- and mesofauna and the
vegetation composition. Green cases represent final selected models, na (= not applicable) indicates insufficient
lowering of the AIC value of the null model or inappropriate plots of fitted and residual values.
response variables
mF mR mN
Shannon-Wiener Eveness
Number of Red
List species
Number of plant species
Null model
AIC 299.63 498.35 385.39 76.15 -270.86 455.48 728.19
ICC 51.06% 92.90% 56.60% 22.89% 7.58% 80.98% 74.57%
Model
pred
ictor variab
les
Number of taxa
AIC 300.90 494.26 384.50 77.86 -269.14 451.75 730.04
explained variance na 7.39% na na na 8.44% na
Number of
organisms
AIC 300.89 498.06 386.71 77.10 -268.91 455.75 726.75
explained variance na na na na na na na
Shannon-Wiener
AIC 301.29 499.86 386.35 78.13 -269.04 454.04 730.10
explained variance na na na na na na na
Table AX.7: Results of ANOVA performed on the selected final model as indicated in Table AX.6 (significance
code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1).
response variable
mR
Final model
Df 96
F 6.16
t 2.48
P 0.0148*
106
Table AX.8: Results of mixed models performed on microfauna and the vegetation composition. Green cases
represent final selected models, na (= not applicable) indicates insufficient lowering of the AIC value of the null
model or inappropriate plots of fitted and residual values.
response variables
mF mR mN
Shannon-Wiener Eveness
Number of Red
List species
Number of plant species
Null model
AIC 135.45 219.34 179.14 59.45 -94.97 187.43 328.69
ICC 69.89% 71.28% 92.89% 72.23% 62.89% 0.00% 74.52%
Model
pre
dicto
r variable
s
carbohydrates AIC 137.16 217.91 180.99 61.28 -94.47 189.27 329.45
explained variance na na na na na na na
carboxylic acids
AIC 135.11 214.23 181.10 55.02 -93.69 186.96 327.61
explained variance na na na na na na na
amino acids
AIC 136.00 215.31 181.09 59.61 -93.01 188.22 328.76
explained variance na na na na na na na
esters
AIC 136.64 221.26 180.28 61.45 -93.08 187.27 330.33
explained variance na na na na na na na
polymers
AIC 130.28 208.09 180.40 60.30 -93.07 184.86 330.18
explained variance 21.33% 16.58% na na na na na
aromatic compounds
AIC 133.99 215.23 180.78 60.44 -93.01 185.46 330.51
explained variance na na na na na na na
phosphorylated chemicals
AIC 134.12 218.58 180.80 61.04 -93.18 189.40 330.20
explained variance na na na na na na na
amines
AIC 134.93 212.15 180.39 60.20 -93.03 188.34 330.10
explained variance na na na na na na na
107
Table AX.9: Results of ANOVA performed on the selected final models as indicated in Table AX.8 (significance
code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1).
response variables
mF mR
Final model
Df 8 8
F 7.56 14.39
t -2.75 3.79
P 0.0251* 0.0053**
108
Appendix XI: NMDS correlations Table AXI.1: Environmental fit of the abiotic soil characteristics on the vegetation composition (significance code
*** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) totP 0.97525 0.22111 0.3640 0.001 *** OP 0.98291 -0.18410 0.3316 0.001 *** pH 0.94190 0.33589 0.5618 0.001 *** Ca 0.80337 0.59548 0.3641 0.001 *** Al -0.97619 -0.21692 0.4888 0.001 ***
Table AXI.2: Environmental fit of the abiotic soil characteristics on the macro- and mesofauna community
(significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) totP 0.72418 0.68961 0.0131 0.353 OP 0.73968 0.67296 0.0130 0.406 pH 0.31289 0.94979 0.0330 0.081 . Ca 0.45393 0.89104 0.0459 0.035 * Al -0.18805 -0.98216 0.0238 0.146
Table AXI.3: Environmental fit of the abiotic soil characteristics on the macro- and mesofauna community
(significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations). Outliers (L
8-5 and TV 9-1) and rare taxa (Chilopoda, Diplopoda, Hymenoptera, Heteroptera, Orthoptera, Isopoda,
Thysanoptera and ants) are omitted.
NMDS1 NMDS2 r2 Pr(>r) totP 0.400922 0.916112 0.0058 0.677 OP -0.333597 0.942716 0.0010 0.930 pH -0.353701 0.935358 0.0172 0.313 Ca -0.758052 0.652194 0.0107 0.488 Al 0.030204 -0.999544 0.0245 0.164
Table AXI.4: Environmental fit of the abiotic soil characteristics on the microfauna community (significance code
*** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) totP 0.89187 -0.45229 0.1811 0.005 ** OP 0.94754 -0.31963 0.1379 0.015 * pH 0.47216 -0.88151 0.3177 0.001 *** Ca 0.83344 -0.55261 0.2630 0.001 *** Al -0.44680 0.89463 0.1331 0.024 *
Table AXI.5: Environmental fit of the macro- and mesofauna on the vegetation composition (significance code
*** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) Acari 0.1400436 0.9901453 0.0068 0.580 Collembola 0.0922625 -0.9957347 0.0398 0.073 . Arachnida -0.3753793 0.9268713 0.0140 0.330 Nematoda 0.9814088 0.1919288 0.0245 0.157 Enchytraeidae 0.6655353 0.7463664 0.0281 0.107 Lumbricidae 0.5011610 0.8653541 0.0133 0.365 ants -0.1377014 -0.9904738 0.0303 0.090 . Coleoptera 0.6670966 -0.7449712 0.0102 0.477 Diptera 0.7250749 0.6886700 0.0138 0.351 Thysanoptera 0.0030492 -0.9999954 0.0016 0.876
109
Table AXI.6: Environmental fit of the characteristics of macro- and mesofauna (number of taxa, number of
organisms and Shannon-Wiener diversity index H) on the vegetation composition (significance code *** P <
0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) Taxa 0.997633 -0.068767 0.0717 0.004 ** Aantal 0.968989 -0.247103 0.0261 0.153 H 0.985228 -0.171247 0.0698 0.007 **
Table AXI.7: Environmental fit of the ACWD- values of the microfauna on the vegetation composition. Carbon
sources are grouped into carbohydrates, carboxylic acids, amino acids, esters, polymers, aromatic compounds,
phosphorylated chemicals and amines. (significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values
based on 999 permutations).
NMDS1 NMDS2 r2 Pr(>r) carbohydrates 0.56737 -0.82346 0.0410 0.318 carboxylicacid 0.87904 -0.47675 0.0695 0.108 aminoacids 0.69879 -0.71532 0.0330 0.393 esters -0.23759 -0.97137 0.0191 0.585 polymer 0.97826 0.20737 0.0311 0.419 aromatic 0.90644 -0.42234 0.0892 0.073 . phosphorylatedchemicals 0.46870 -0.88336 0.0426 0.279 amines 0.95622 -0.29266 0.0844 0.098 . Table AXI.8: Environmental fit of the ACWD- values of the microfauna on the vegetation composition, when the
31 carbon sources are used separately (significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, P values
based on 999 permutations). For full names of the C-sources see Table AVIII.2.
NMDS1 NMDS2 r2 Pr(>r) methylgluc 0.223012 -0.974816 0.0180 0.609 galactlact 0.838518 0.544874 0.1157 0.036 * arg 0.813248 -0.581918 0.0410 0.313 Pyracidmet -0.373868 -0.927482 0.0107 0.720 Dxyl 0.808429 0.588594 0.0640 0.155 Dgalactacid 0.588130 -0.808766 0.0413 0.327 Lasp 0.443951 -0.896051 0.0360 0.371 Tween40 -0.945726 -0.324966 0.0096 0.764 iErythritol 0.806623 -0.591066 0.0343 0.380 X2hydrbenzacid 0.999573 0.029235 0.0302 0.408 Lphenylal -0.240169 -0.970731 0.0030 0.924 Tween80 0.903560 -0.428461 0.0281 0.451 Dmann -0.615641 -0.788026 0.0071 0.835 X4hydrbenzacid 0.782574 -0.622558 0.0776 0.101 Lser -0.285534 0.958369 0.0111 0.721 cyclodex 0.980918 0.194424 0.0359 0.332 Nacetylgluc -0.797816 0.602901 0.0687 0.144 hydrbutacid 0.997274 -0.073790 0.0284 0.444 Lthreo 0.193133 -0.981173 0.0774 0.113 glycogen 0.926758 0.375659 0.0427 0.287 Dglucoacid -0.744791 -0.667298 0.0088 0.802 ItaconicA 0.415487 -0.909599 0.0857 0.075 . GlycylLGlutAcid 0.992009 0.126169 0.1188 0.026 * DCello 0.598363 -0.801225 0.0396 0.304 Gluc1Phos 0.654329 -0.756210 0.0399 0.336 KetobutAcid 0.974618 0.223874 0.0317 0.392 Phenyletam 0.999949 0.010084 0.0879 0.058 . Lact 0.997464 0.071173 0.0642 0.127 DLGlycerol 0.125232 0.992127 0.0175 0.603 DMalicA 0.566847 0.823823 0.0171 0.634 Putrescine 0.975171 0.221455 0.0138 0.669
110
Appendix XII: CCA Table AXII.1: Results of CCA (significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1).
response variable
constraining variable
proportion explained Df F P
vegetation abiotic soil
characteristics 15.12% 5 1.89 0.005*
macro- and mesofauna 3.74% 3 0.71 0.87
microfauna
(all C-sources) 55.55% 31 1.09 0.02 *
microfauna (grouped C-
sources) 12.63% 8 0.90 0.44
macro- and mesofauna
abiotic soil characteristics 6.06% 5 1.89 0.08 .
microfauna abiotic soil
characteristics 12.40% 5 1.50 0.02 *
Table AXII.2: Results of the forward selection method (significance code *** P < 0.001, **P < 0.01, *P < 0.05,
. P < 0.1, na = not applicable; no variables retained). For full names of the C-sources see Table AVIII.2.
response variable
constraining variable
variables retained by forward selection P
vegetation abiotic soil
characteristics pH-KCl, Total P 0.005**
macro- and mesofauna na na
microfauna
(all C-sources)
galactlact, Tween40, Nacetylgluc, X4hydrbenzacid,
Dcello, Lact, ItaconicA 0.005**
microfauna (grouped C-
sources) na na
macro- and mesofauna
abiotic soil characteristics Olsen P 0.005**
microfauna abiotic soil
characteristics Exchangeable Ca 0.005**
111
Appendix XIII: Mantel test Table AXIII.1: Results of the Mantel test (significance code *** P < 0.001, **P < 0.01, *P < 0.05, . P < 0.1, Mantel
statistic based on Spearman rank correlation, correlation based on 999 permutations).
Dissimilarity matrix 1
Dissimilarity matrix 2 Mantel statistic P
vegetation abiotic soil
characteristics 0.436 0.001**
macro- and mesofauna 0.142 0.012*
microfauna
(all C-sources) 0.202 0.001**
microfauna (grouped C-
sources) 0.065 0.115
macro- and mesofauna
abiotic soil characteristics -0.005 0.525
microfauna abiotic soil
characteristics 0.272 0.001**
112
Appendix XIIII: The relationship between Olsen P concentration and the
number of Red List species
Figure AXIIII.1: Relationship between the Olsen P concentration (mg kg-1) and the number of Red List species,
based on vegetation surveys in three nature areas (Liereman, Turnhouts Vennengebied and Gulke Putten).
0
1
2
3
4
5
6
7
0 50 100 150 200
Nu
mb
er
of
Re
d L
ist
spe
cie
s
Olsen P (mg kg-1)