Bibliography

1. Abbott, I and C. A. Parker. 1981. Interactions between earthworms and their soil

environment. Soil Biology and Biochemistry 13: 191-197.

2. Abdul J. K., Othmam and S. F Loo. 1999. Isolation of cellulolytic fungi from the barrio

highlands, Sarawak. ASEAN Review of Biodiversity and Environmental Conservation.

3. Abdul Rida A.M and M. B. Bouché.1997. Earthworm toxicology: from acute to chronic

tests. Soil Biology and Biochemistry 29: 699–703.

4. Abdul, J. K and O. Othman. 1998. Isolation of cellulolytic fungi from sayab-kinabalu

park sahib. ASEAN Review of biodiversity and environmental conservation. Article II.

5. Acosta-Martinez, V and M. A. Tabatabai. Enzyme activities in a limed agricultural

soil. Biology and Fertility of Soils 31:85-91. 2000.

6. Ahmad, F., I. Ahmad and M. S. Khan. 2005. Indole acetic acid production by the

indigenous isolates of Azotobacter and fluorescent Pseudomonas in the presence and

absence of tryptophan Turkish Journal of Biology 29:29-34.

7. Aina P.Q.1984. Contribution of earthworms to porosity and water infiltration in a tropical

soil under forest and long-term cultivation. Pedobiologia 26: 131–136.

8. Akbari G. A, S. M. Arab, H.A. Alikhani, I. Allahabadi and M.H. Arzanesh 2007.

Isolation and selection of indigenous Azospirillum spp. and the IAA of superior strains

effects on wheat roots. World Journal of Agricultural Sciences 3 (4): 523-529.

9. Alexander, M. 1971. Microbial ecology. John Wiley & Sons Inc, New York.

10. Anderson, J. M., P. Ineson, and S. A. Huish. 1983. The effects of animal feeding

activities on element release from deciduous forest litter and soil organic matter. Pages

87-100, in: P. Lebrun, H. M. André, A. de Medts, C. Grégoire-Wibo and G. Wauthy

(editors) New trends in soil biology. Dieu-Brichart, Louvain-la-Neuve.

11. Anderson, J.P.E. and K.H. Domsch. 1978. A physiological method for the quantitative

measurement of microbial biomass in soil. Soil Biology and Biochemistry 10: 215-221.

12. Anderson, O. R and P. J. Bohlen. 1998. Abundance and diversity of gymnamoebae

associated with earthworms (L. terristris) middens in the north eastern U.S. forest. Soil

Biology and Biochemistry 30:1213-1216.

13. Antoun, H., C. J. Beauchamp, N. Goussard, R. Chabot and R. Lalande. 1998. Potential of

Rhizobium and Bradyrhizobium species as plant growth promoting rhizobacteria on

nonlegumes: effect on radishes (Raphanus sativus L.). Plant Soil 204:57-67.

14. Ariffin, H., N. Abdullah, M. S. Umi Kalsom, Y. Shirai. 2006. Hassan 2006. Production

and characterization of cellulase by Bacillus pumilus Eb3. International Journal of

Engineering and Technology 3(1): 47-53.

15. Arun, K. R., B. Abhinanda, G. Keka and K.S. Sukanta. 2007. Optimization of

fermentation conditions for cellulase production by Bacillus subtilis cy5 and Bacillus

circulans tp3 isolated from fish gut. Acta ichthyologica et piscatorial 37 (1): 47–53.

16. Asawalam, D. O and S. Johnson. 2007. Physical and chemical characteristics of soils

modified by earthworms and termites. Communications in Soil Science and Plant

Analysis 38 (3): 513-521.

17. Asghar M., M. J. Asad and M. Arshad. 2000. Alpha-amylase from Aspergillus niger in

waste bread medium. Proc. 2nd International Symposium, New Technology for

Environmental Monitoring and Agro-Application, Tekirdag, Turkey.

18. Ashrafuzzaman, M., F. A. Hossen, M. R. Ismail, M. A. Hoque, M. Z. Islam, S.M.

Shahidullah and S. Meon. 2009. Efficiency of plant growth promoting Rhizobacteria

(PGPR) for the enhancement of rice growth. African Journal of Biotechnology 8 (7):

1247- 1252.

19. Atlas, R. M. 1984. Diversity of microbial communities. Advances in Microbial Ecology

7:1-47.

20. Axel D., B. Steinberg, I. Schöning, K. Pritsch., M. Joschko., G. Gleixner and E. D.

Schulze. 2008. Organic carbon sequestration in earthworm burrows. Soil Biology and

Biochemistry 40 (7):1803-1812.

21. Bano, K and R. D. Kale. 1988. Earthworm fauna of South Karnataka. in: G. K. Veeresh,

D. Rajagopal and C. A. Viraktamath (Editors) Management and conservation of soil

fauna. 10th International Soil Zoology Symposium, Bangalore, India. Oxford

22. Barley, K. P and A. C. Jennings. 1959. Earthworms and soil fertility-the influence of

earthworms on the availability of nitrogen. Australian Journal of Agricultural Research

10: 364-370.

23. Barne,A.J. 2006.The location of organic matter in soil matrix affects growth rates of

Aporrectodea rosea.(poster)

24. Barnett, H.L and B. H Barry. 1972. The Illustrated Genera of Imperfect Fungi, 4th

edition,

APS Press Saint Paul, Minnesota, USA.

25. Barois, I and P. Lavelle. 1986. Changes in respiration rate and some physicochemical

properties of a tropical soil during transit through Pontoscolex corethrurus

(Glossoscolecidæ, Oligochæta). Soil Biology and Biochemistry 18 (5): 539-541.

26. Barois, I. 1992. Mucous production and microbial activity in the gut of two species of

Amynthas from cold and warm tropical climates. Soil Biology and Biochemistry 24:

1507-1510.

27. Barois, I., B. Verdier, P. Kaiser, A. Mariotti, P. Rangel and P. Lavelle. 1987. Influence of

the tropical earthworm Pontoscolex corethrurus (Glossoscolecidae) on the fixation and

mineralization of nitrogen. Pages 151-158, in: A. M. Bonvicini Pagliai and P. Omodeo

(editors) On Earthworms. Mucchi, Modena.

28. Barois, I., P. Lavelle, M. Brossard, J. Tondoh, M. Angeles Martinez, J. P. Rossi, B. K.

Senapati, A. Angeles, C. Fragoso, J. J. Jimenez, T. Decaëns, C. Lattaud, J. Kanyonyo, E.

Blanchart, L. Chapuis, G. Brown and A. Moreno. 1999. Ecology of earthworm species

with large environmental tolerance and/or extended distribution. Pages 57–84, in: P.

Lavelle, L. Brussaard and P. Hendrix (editors). Earthworm’s management in tropical

agroecosystems. London: CAB International.

29. Bashan, Y., H. Gina and Luz E. de-Bashan. 2004. Azospirillum-plant relationships:

physiological, molecular, agricultural, and environmental advances (1997-2003).

Canadian Journal of Microbiology 50: 521-577.

30. Basker A., A. N. Macgregor and J. H. Kirkman. 1992. Influence of soil ingestion by

earthworms on the availability of potassium in soil: An incubation experiment. Biology

and Fertility of Soils 14:4 300-303.

31. Baudone, Benizrie and A. Guckert. 2001. Metabolic fingerprint of microbial communities

from distinct maize rhizosphere compartments. European Journal of Soil Biology 37: 85.

32. Beare, M.H., D.C.Coleman, D.A. Crossley, P.F. Hendrix and E Odum. 1995. A

hierarchical approach to evaluating the significance of soil biodiversity to

biogeochemical cycling. Plant and Soil 170: 5-22.

33. Beauchamp, C. J. 1993. Mode of action of plant growth-promoting rhizobacteria and

their potential use as biological control agents. Phytoprotection 71:19-27.

34. Benner, R., S. Y. Newell, A. E. Maccubbin and R. E. Hodson. 1984. Relative

contributions of bacteria and fungi to rates of degradation of lignocellulosic detritus in

salt-marsh sediments. Applied and Environmental Microbiology 48:36–40.

35. Berg, B., G. Ekbohm and C. McClaugherty. 1984. Lignin and holocellulose relations

during long-term decomposition of some forest litters. Long-term decomposition in a

Scots pine forest. IV. Canadian Journal of Botany 62, 2540–2550.

36. Bernardes, F. F., C. M. Ribeiro and S. I. Klein. 1997. On the interaction of Pontoscolex

corethrurus and the microbiology of tropical soils. Scientific registration n° : 2277

Symposium n° : 41 Presentation : poster.

37. Bernardes, F.F and J.C. Kiehl. 1994. Behavior of earthworm under different conditions of

temperature and soil moisture. Pages 245-246, in: Proceedings of Brazilian Meeting on

Soil Fertility and Plant Nutrition, 21. Petrolina, SCBS.

38. Bertrand H, R. Nalin, R. Bally and J.C. Cleyet-Marel. 2001. Isolation and identification

of the most efficient plant growth-promoting bacteria associated with canola (Brassica

napus). Biology and Fertility of Soils 33, 152-156.

39. Bhatnagar, T. 1975. Earthworms and humifcation : A new aspect of microbial nitrogen

incorporation induced by earthworms. Pages 169-182 in: G. Kilbertus, O. Reisinger, A.

Mourey, J.A. Cancela da Fonseca, (Editors), Biodegradation and Humification. Pierron,

Sarreguemines.

40. Bhattacharjee, G and P. S. Chaudhuri. 2002. Cocoon production, morphology, hatching

pattern and fecundity in seven tropical earthworm species – a laboratory-based

investigation. Journal of Biosciences 27:283–294Blackmore, R.J. 2000. Ecological

considerations of the earthworms used in vermiculture- a review of the species.

Presentations at the Vermillenium conference at Kalamazoo, Michigan, Sept 16-22.

42. Bochner, B. 1989. Breathprints at the microbial level. ASM News 55:536-539.

43. Boddey, R.M., O.C. De Oliveira, S. Urquiaga, V.M. Reis, F.L. Olovares, V.L.D. Baldani

and J. Dobereiner. 1995. Biological nitrogen fixation associated with sugar cane and rice:

contribution and prospects for improvements. Plant Soil 174: 195–209.

44. Bohlen, P. J., R. W. Parmelee, D. A McCartney and C. A. Edwards.1997. Earthworm

effects on carbon and nitrogen dynamics of surface litter in corn agroecosystems.

Ecological Applications 7:1341-1349.

45. Bok, J. D., D. A. Yernool and D. E. Eveleigh. 1998. Purification, characterization, and

molecular analysis of thermostable cellulases CelA and CelB from Thermotoga

neopolitana. Applied Environmental Microbiology 64: 4774–4781.

46. Borneman, J and E. W. Triplett. 1997. Molecular microbial diversity in soils from

Eastern Amazonia: Evidence for unusual microorganisms and microbial population shifts

associated with deforestation. Applied and Environmental Microbiology 63:2647–2653.

47. Bose, R. G. 1963. A modified cellulosic medium for the isolation of cellulolytic fungi

from infected materials and soils. Nature 198:505-506.

48. Bossio, D.A and K.M. Skow. 1995. Impact of carbon and flooding on the metabolic

diversity of microbial communities in soils. Applied Environmental Microbiology 61:

4043-4050.

49. Bostrom, U. 1986. The effects of soil compaction on earthworms (Lumbricidae) in a

heavy clay soil. Swedish Journal of Agricultural Research 16:137-141.

50. Bouche, M. B and F. Al- Addan. 1997. Earthworms, water infiltration and soil stability:

Some new assessments. Soil Biology and Biochemistry 29:441-452.

51. Bouché, M. B. 1975. Faunal action on the states of the organic matter in ecosystems.

Pages 157–168, in: G Kilbertus, O. Reisinger, A. Mourey and J. A Cancela da Fonseca

(editors) Humification and biodegradation. Sarruguemines, Pierron.

52. Bouche, M. B. 1983. The establishment of earthworm communities. Pages 431 -448, in:

J.E. Satchell (editor) Earthworm ecology: From Darwin to vermiculture. Chapman and

Hall, London.

53. Bouché, M. B. and A. Kretzschmar. 1974. Functions of earthworms II. Methodological

research for qualitative analysis of plant organic matter ingested (People's Study of the

station RCP-165/PBI). Review of Ecology and Biology of Soil 11:127-139.

54. Bouche, M. B., G. Ferrire and P Soto. 1987. The role of earthworms in the decomposition

and nitrogen nutrition of plants in grassland. Pages 113-129, in: A.M. Bonvicini and P.

Omodeo (editors) On earthworms. Selected Symposia and Monographs U. Z. I., Modena.

55. Bouche, M.B. 1977. Earthworm Strategies. Pages 122-132, in: U. Lohm and T. Persson

(editors) Soil Organisms as Components of Ecosystems. Biology Bulletin (Stockholm).

56. Brajeshori, K., C. Nilesh, Sharma and S. Gupta. 2000. Production and characterization of

fungal cellulases from lignocellulosic wastes. Asian Journal of Microbiological

Biotechnology and Environment Sciences, 4 (3-4): 113-120.

57. Brown, G. G. 1995. How do earthworms affect microfloral and faunal community

diversity? Plant and Soil 170: 209-231.

58. Brown, G. G., I. Barois and P. Lavelle. 2000 Regulation of soil organic matter dynamics

and microbial activity in the drilosphere and the role of interactions with other edaphic

functional domains. European Journal of Soil Biology 36, 177–198.

59. Brown, J.A. S.A. Collin and T.M Wood. 1987. Development of a medium for high

cellulase, xylanase and β-glucosidase production by a mutant strain (NTG1116) of

cellulolytic fungus Penicillium pinophilium. Enzyme and Microbial Technology 5: 425 –

429.

60. Brown, M. E. 1972. Plant growth substances produced by microorganisms of soil and

rhizosphere. Journal of Applied Bacteriology 35:443.

61. Buckley, D and T. Schmidt. 2002. Exploring the biodiversity of soil - A microbial rain

forest.Pages 183–208, in: Biodiversity of Microbial Life, J. Staley and A. Reysenbach

(editors) Wiley, New York.

62. Burns, R.G. 1983. Extracellular enzyme substrate interactions in soil, Pages 249–298, in:

J.H. Slates, R. Whittenbury and J.W.T Wimpenny (Editors), Microbes in their natural

environment, Cambridge University Press, Cambridge, MA.

63. Campbell, C., S. Grayston and D. Hirst. 1997. Use of rhizosphere carbon sources in sole

carbon source tests to discriminate soil microbial communities. Journal of

Microbiological Methods 30: 33-41.

64. Carneiro, R. M. D. G. 1992. Principles and trends of biological control of nematodes with

nematphagus fungi. Pesquisa Agropecuária Brasileira 27: 113-121.

65. Caron M, C.L. Patten and S. Ghosh. 1995. Effects of plant growth promoting

rhizobacteria Pseudomonas putida GR-122 on the physiology of canolla roots. Plant

Growth Reg Soci Am, 22nd proceeding, Ed. Green DW.

66. Carter, A., J. Heinonen and J. de Vries.1982. Earthworms and water movement.

Pedobiologia 23: 395–397.

67. Chabot R., H. Antoun and P.Cecas. 1993. Stimulating the growth of corn and romaine

lettuce by microorganisms dissolving the inorganic phosphorus. Canadian Journal of

Microbiology 39: 941-947.

68. Charest, M.H., C.J. Beauchamp and H. Antoun. 2005. Effects of the humic substances of

de- inking paper sludge on the antagonism between two compost bacteria and Pythium

ultimum. FEMS Microbiology Ecology, 52: 219–227.

69. Charpentier, F. 1996. Effect of inoculation of earthworm Pontoscolex corethrurus on the

dynamics of organic matter in a continuous culture in the Peruvian Amazon soil PhD

Thesis, University of Paris.

70. Chen, Y.P., P. D. Rekha, A.B. Arun, F.T. Shen, W.A. Lai and C.C. Young. 2006.

Phosphate solubilizing bacteria from subtropical soil and their tricalcium phosphate

solubilizing abilities. Applied Soil Ecology 34: 33-41.

71. Choi, K.H and F.C. Dobbs. 1999. Comparison of two kinds of Biolog microplates (GN

and ECO) in their ability to distinguish among aquatic microbial communities. Journal of

Microbiological Methods 36: 03-213.

72. Christensen M, W.F. Whittingham and R.O. Novak. 1962. The soil micro fungi of wet

mesic forest in southern Wisconsin. Mycologia, 54: 374-388.

73. Christensen, M and W.F. Whittingham. 1965. The soil micro fungi of open bogs and

conifer swamps in Wisconsin. Mycologia, 57: 882-896.

74. Christensen, M. 1969. The soil micro fungi of dry to mesic conifer hard wood forests in

northern. Wisconsin Ecology 50: 9-27.

75. Chrost, R. J. 1994. Microbial enzymatic degradation and utilization of organic matter.

Pages 118–174 in: J. Overbeck and R.J. Chrost (editors) Microbial ecology of Lake

Plubsee. Springer-Verlag, New York.

76. Clegg, C.D., J.M. Anderson, H.M. Lappin-Scott, J.D. Van Elsas and J.M. Jolly. 1995.

Interaction of a genetically modified Pseudomonas fluorescens with the soil-feeding

earthworm Octolasion cyaneum (Lumbricidae). Soil Biology and Biochemistry 27:1423–

1429.

77. Contreras, E. 1980. Studies on the intestinal actinomycete flora of Eisenia lucens

(Annelida, Oligochaeta). Pedobiologia 20: 411-416.

78. Cooke, A and M. Luxton. 1980. Effects of microbes on food selection by Lumbricus

terrestris L. Review of Ecology and Biology of Soil 17: 365-370.

79. Daniel, O and J.M Anderson. 1992. Microbial biomass and activity in contrasting soil

materials after passage through the gut of the earthworm Lumbricus Rubellus

Hoffmeister. Soil Biology and Biochemistry 24: 465-470.

80. Darwin, C. 1881. In ‘The formation of Vegetable Mould through the action of Worms

with observations on their habits. D. Apleton and Co., New York.

81. Dawson, R. C. 1948. Earthworm microbiology and the formation of water stable soil

aggregates. Proceedings of Soil Science Society of America 12:512–516.

82. De Freitas, J. R., M. R. Banerjee and J. J. Germida. 1997. Phosphate-solubilizing

rhizobacteria enhance the growth and yield but not phosphorus uptake of canola

(Brassica napus L.). Biology and Fertility of Soils 24:358-364.

83. Dell’ Agnola, G and S. Nardi. 1987. Hormone-like effect and enhanced nitrate uptake

induced by depolycondensaded humic fractions obtained from Allolobofora and A.

caliginosa faeces. Biology and Fertility of Soils 4: 115–118

84. Derouard L, J. Tondoh, L. Vilcosqui and P. Lavelle. 1997. Effects of earthworm

introduction on soil processes and plant growth. Soil Biology and Biochemistry 29: 541-

545

85. De-Souza, M. J., S. Nair and D. Chandramohan, 2000. Phosphate solubilizing bacteria

around Indian peninsula. Indian Journal of Marine Sciences 29: 48-51.

86. Devliegher, W and W. Verstraete. 1995. Lumbricus terrestris in a soil core experiment:

Nutrient-enrichment processes (NEP) and gut-associated processes (GAP) and their

effect on microbial biomass and microbial activity. Soil Biology and Biochemistry

27:1573–1580.

87. Devliegher, W and W. Verstraete. 1997. Microorganisms and soil physico-chemical

conditions in the drilosphere of Lumbricus terrestris. Soil Biology and Biochemistry 29:

1721-1729.

88. Di Giovanni, G.D., L.S. Watrud, R.J. Seidler and F. Widmer. 1999. Comparison of

parental and transgenic alfalfa rhizosphere bacterial communities using Biolog GN

metabolic fingerprinting and enterobacterial repetitive intergenic consensus sequence-

PCR (ERIC-PCR). Microbial Ecology 37: 139-139.

89. Dobereiner, J. 1992. History and new perspectives of diazotrophs in association with

non-leguminous plants. Symbiosis 13: 1-13.

90. Doi, R. H. and Kosugi. 2004 .Cellulosomes, plant cell wall degrading enzyme complexes.

National review of Microbiology 2: 541-551.

91. Doran, J.W., M. Sarrantonio and M.A. Liebig. 1996. Soil health and sustainability.

Advanced Agronomy 56:2–54.

92. Dubey, R.C. and D.K. Maheshwari. 1999. A text book of Microbiology, Chand and

Company Ltd., New Delhi.

93. Edwards, C.A and Bohlen, P.J. 1996. The Biology and Ecology of Earthworms.3rd

ed.

London; Chapman and Hall.

94. Edwards, C.A and J.R. Lofty. 1982. The effects of direct drilling and minimal cultivation

on earthworm populations. Journal of Applied Ecology 19: 723-734.

95. Edwards, C.A and K. E. Fletcher. 1988. Interactions between earthworms and

microorganisms in organic-matter breakdown. Pages 235-247, in: C.A. Edwards (Editor)

Biological Interactions in Soil. Elsevier, New York.

96. Edwards, C.A and P.J. Bohlen. 1996. Biology and Ecology of Earthworms. 3rd

Edition.

Chapman and Hall, London.

97. Edwards, C.A and R Lofty. 1980. The effects of earthworm inoculation upon the root

growth of direct drilled cereals. Journal of Applied Ecology 17: 533-543.

98. Emtiazi, G., M. Pooyan and M. Shamalnasab. 2007. Cellulase Activities in Nitrogen

Fixing Paenibacillus isolated from Soil in N-free Media. World Journal of Agricultural

Sciences 3 (5): 602-608.

99. Eriksson, K. K and S.C. Johnsrud. 1983. Mutants of white – rot fungus Sporotrichum

pulverulentum with increased cellulase and β-glucosidase production. Enzyme and

Microbial Technology 38: 425 – 429.

100. Fergus, G and Priest. 1997. Extracellular enzyme synthesis in the genus Bacillus,

Bacteriological reviews 41: 711-153.

101. Fonte, S.J., A.Y.Y. Kong., C. van Kessel., P.F. Hendrix and J. Six. 2007. Influence of

earthworm activity on aggregate-associated carbon and nitrogen dynamics differs with

agroecosystem management. Soil Biology and Biochemistry 39:1014-1022.

102. Frankenberger, W.T and M.L. Poth. 1989. Tryptophan transaminase of a bacterium

isolated from the rhizosphere of Festuca octoflora (Graminae). Soil Biology and

Biochemistry 20: 299-304.

103. Gamo, M and T. Shoji. 1999. A method of profiling microbial communities based on a

most-probable-number assay that uses BIOLOG plates and multiple sole carbon sources.

Applied Environmental Ecology 65: 4419-4424.

104. Gange, A.C. 1993. Translocation of mycorrhizal fungi by earthworms during early

succession. Soil Biology and Biochemistry 25: 1021-1026.

105. Garcia-Martinez, D.V., A. Shinmyo, A. Madia and A.L. Deman, 1980. Studies on

cellulase production by Clostridium thermocellum. European Journal Applied

Microbiology and Biotechnology 9: 189–197.

106. Gargova, S., Z. Roshkova and G. Vancheva. 1997. Screening of fungi for phytase

production. Biotechnology Techniques 11:221–224.

107. Garland J.L and A. L. Mills. 1991. Classification and characterization of heterotrophic

microbial communities on the basis of patterns of community-level-sole-carbon-source

utilization. Applied and Environmental Microbiology 57: 2351-2359.

108. Garland, J.L. 1996. Analytical approaches to the characterization of samples of

microbial communities using patterns of potential C utilization. Soil Biology and

Biochemistry 28:213–221.

109. Gates, G.E. 1972. Burmese earthworms- an introduction to the systematics and biology

of megadrile oligochaetes with special reference to Southeast Asia. Transactions of the

American Philosophical Society, New series 62:1-326.

110. Gilbert, W. 1789. The Natural History and Antiquities of Selborne. London: Cassell &

Company, Pages 38–39.

111. Gilot- Villenave, C., P. Lavelle and F. Granary. 1996. Effect of a tropical geophagus

earthworm, Millsonis anomala, on some soil characteristics, on maize- residue

decomposition and on maize production in Ivory Coast. Applied Soil Ecology 4:201-211.

112. Glick, B.R.1995. The enhancement of plant growth by free living bacteria. Canadian

Journal of Microbiology 41: 109-114.

113. Goechenaur, S.E and W. F. Whittingham. 1967. Mycoecology of willow and

cottonwood low land communities in southern Wisconsin I. Soil microfungi in the willow

cottonwood forests. Mycopathology and Mycological Applications 33: 125- 139.

114. Gokhan, C., G. Burhan, A. N. Naldi and G. V. Hatice. 2002. Some Properties of Crude

Carboxymethyl Cellulase of Aspergillus niger Z10 Wild-Type Strain. Turkish Journal of

Biology 26: 209-213.

115. Gomes, I., J. Gomes, W. Steiner and R. H. Esterbaue. 1992. Production of cellulase and

xylanase by a wild strain of Trichoderma viride, Applied Microbiology and

Biotechnology 36 (5): 701-707.

116. Gomeze, J. Garland and Contim. 2004. Reproducibility in the response of soil bacterial

community-level physiological profiles from a land use intensification gradient. Applied

Soil Ecology 26:21.

117. González, G and X. M. Zou. 1999. Earthworm influence on N availability and the

growth of Cecropia schreberiana in tropical pasture and forest soils. Pedobiologia 43:

824-829.

118. González, G., C.Y. Huang, X.M. Zou and C. Rodríguez. 2006. Earthworm invasions in

the tropics. Biological Invasions. 8:1247-1256.

119. Goodfellow, M and T. Cross. 1983. The Biology of Actinomycetes. Academic Press.

120. Gordon, S.A and R.P. Weber. 1951. Colorimetric estimation of indole-acetic acid. Plant

Physiology. 26: 192-195.

121. Görres, J.H., M. C. Savin and J. A. Amador. 1997. Dynamics of carbon and nitrogen

mineralization, microbial biomass, and nematode abundance within and outside the

burrow walls of anecic earthworms (Lumbricus terrestris). Soil Science 162: 666-671.

122. Graff, O and F. Makeschin. 1980. Crop yield of rye- grass influenced by the excretions

of three earthworm species. Pedobiologia 20:176-180.

123. Graff, O. 1967. Shift of nutrient elements in the underground by earthworm activity.

Landwirsch Researchers 20: 117-127.

124. Graff, O. 1971. Does earthworm affect plant nutrition? Preceedings of Agricultural

research Voelkenrode 21: 103-108.

125. Greiner, R., U. Konietzny and K.D. Jany. 1993. Purification and characterization of two

phytases from Escherichia coli. Archives of Biochemistry and Biophysics 303: 107–113.

126. Grishkan, I and E. Nevo. 2008. Soil microfungal communities of 'Evolution Canyons'

in Israel-extreme differences on a regional scale. Biological Journal of the Linnean

Society 93:157-163.

127. Guerra, R. T and N. Asakawa. 1981. Effect of the presence and number of Pontoscolex

corethrurus (Glossoscolecidae, Oligochaeta) on the total population of soil

microorganisms Acta Amazonica 11(2): 319-324.

128. Haack, S. K., Garchowh, M. J. Klug and J. Forneyl. 1995. Analysis of factors affecting

the accuracy, reproducibility, and interpretation of microbial community carbon source

utilization patterns. Applied Environmental Microbiology 61:1458.

129. Habib, O., R. Z. Mohammad, M. Mostafa, Z. Nosratollah. 2005. Identification of over

producer strain of endo-1, 4- glucanase in Aspergillus species: Characterization of crude

carboxymethyl cellulase. African Journal of Biotechnology 4 (1):26-30.

130. Hamilton, W.E and D.L Dindal. 1983. The Vermisphere Concept- Earthworm Activity

and Sewage Sludge. Biocycle, 54.

131. Hamilton, W.E and D.Y. Sillman. 1989. Influence of earthworm middens on the

distribution of soil microarthropods. Biology and Fertility of Soils 7: 1‐6.

132. Hand, P., W.A. Hayes, J.C. Frankland and J.E. Satchell. 1988. The Vermicomposting

of cow slurry. Pedobiologia 31:199-209.

133. Hankin, L and Anagnostakis, S. L. 1977. Solid media containing carboxymethyl

cellulose to detect Cx cellulase activity of microorganisms. Journal of General

Microbiology 98: 109-115.

134. Harayama, S. 1998. Artificial evolution of DNA shuffling, Trends in Biotechnology 16:

76–82.

135. Harrison, N.G., J.D. Allan, R.K. Colwell, D.J. Futuyma and J. Howell. 1968. The

relationship between species diversity and stability: an experimental approach with

protozoa and bacteria. Ecology 1091– 101.

136. Hass, D and G. Defago. 2005. Biological control of soil borne pathogens by fluorescent

Pseudomonads. Nature Reviews Microbiology 3: 307-319.

137. Hawksworth, D and A. Rossman. 1997. Where are all the undescribed fungi?

Phytopathology 87:888-891.

138. Haynes, R.J and P.M. Fraser. 1998. Acomparison of aggregate stability and biological

activity in earthworm casts and uningested soil as affected by amendment with wheat or

lucerne straw. European Journal of Soil Science 49:629–636.

139. Hedrick, D.B., A. Peacock, J.R. Stephen, S. J. Macnaughton, J. Bruggemann and D.C.

White. 2000. Measuring soil microbial community diversity using polar lipid fatty acid

and denaturing gradient gel electrophoresis data. Journal of Microbiological Methods

41:235–248.

140. Hendricks, C.W., J. D. Doyle and B. Hugley. 1995. A new solid medium for

enumerating cellulose-utilizing bacteria in soil. Applied Environmental Microbiology

61:2016–2019.

141. Hendriksen, N. B. 1991. Gut load and food retention time in earthworms Lumbricus

festivus and L. castenius: a field study. Biology and Fertility of Soils. 11: 170-173.

142. Hendrix, P.F. 1995. Earthworm Ecology and Biogeography in North America. Boca

Raton(FL); Lewis publishers

143. Hensyl, R. W. 1994. Bergey’s Manual of Determinative Bacteriology. 9th

edition,

Williams and Wilkins.

144. Hilda, R and R. Fraga. 1999. Phosphate solubilizing bacteria and their role in plant

growth promotion. Biotechnological Advances. 17:319–359.

145. Hoffman, R.M and T.M Wood. 1985. Isolation and partial characterization of a mutant

Penicillium for the saccharification of straw. Biotechnology and Bioengineering 27:81-

85.

146. Idowu A.B., M.O. Edema and A.O. Adeyi. 2006. Distribution of Bacteria and fungi in

the earthworm Libyodrillus violaceous, a native earthworm from Nigeria. International

Journal of Tropical Biology 54 (1): 49-58.

147. Immanuel, G. R., P. Dhanusha, Prema and A. Palavesam. 2006. Effect of different

growth parameters on endoglucanase enzyme activity by bacteria isolated from coir

retting effluents of estuarine environment. International Journal of Environmental

Science and Technology 3(1): 25-34.

148. Insam, H. 1997. Substrate utilization tests in microbial ecology. A preface to the special

issue. Journal of Microbiological Methods 30:1- 2.

149. Ismail and A. Sultan. 1995. Earthworms in soil fertility management. Pages 77-100, in:

P.K. Thampan, (editor) “Organic Agriculture”. Peekay Tree Crops Development

Foundation, Cochin.

150. Ismail, S.A. 1997. Vermicology: The biology of Earthworms. In Orient Longman

Limited, Chennai, page 92.

151. Ismail, S.A., C. Ramakrishnan and M.M. Anzar. 1990. Density and diversity in relation

to the distribution of earthworms in Madras. Proceedings of Indian Academic Sciences

(Animal Science) 99:73-78.

152. Jacobsen, C. S. 1997. Plant protection and rhizosphere colonization of barley by seed

inoculated herbicide degrading Burkholderia (Pseudomonas) cepacia DBO1 (pRO101) in

2, 4-D contaminated soil.Plant Soil 189:139–144.

153. Jacoud,C., D. P. Job, Wadoux and R. Bally. 1999. Initiation of root growth stimulation

by Azospirillum lipoferum CRT1 during maize seed germination. Canadian Journal of

Microbiology 45:339-342.

154. Jeanson, C. 1971. Structure of a earthworm gallery by the microprobe technique. Pages

513-525, in: d’Aguilar J (editor) Soil organisms and primary production INRA, Paris.

155. Jeon, J.S., S. Lee, H.Y. Kim, T.S. Ahn and H. Song. 2003. Plant growth promotion in

soil by some inoculated microorganisms. Journal of Microbiological Society of Korea

41:271-276.

156. Joergensen, R.G., H, KuÈntzel and S. Scheu, D Seitz. 1998. Movement of faecal

indicator organisms in earthworm channels under a loamy arable and grassland soil.

Applied Soil Ecology 8: 1-10.

157. Joffe, J.S. 1936. Pedology. Rutgers University Press, University Park, PA, USA.

158. Jose, A. 2006. Effect of earthworm interaction over self demographic parameters,

microbial functional groups, nutrient status and bioturbation. (Poster).

159. Joseph, B., R.R. Patra and R. Lawrence. 2007. Characterization of plant growth

promoting Rhizobacteria associated with chickpea (Cicer arietinum L). International

Journal of Plant Production 1 (2): 141-152.

160. Joseph, S and M.S. Jisha. 2008. Buffering reduces phosphate solubilizing ability of

selected strains of bacteria. American-Eurasian Journal of Agricultural and

Environmental Science 4:110-112.

161. Joshi, F.R., D.K. Desai, G. Archana and A.J. Desai. 2009. Enhanced survival and

nodule occupancy of Pigeon pea nodulating Rhizobium sp. ST1 expressing fegA gene of

Bradyrhizobium japonicum 61A152. On Line Journal of Biological Sciences 9 (2): 40-51.

162. Julka, J. M. 1988. The fauna of India and the adjacent countries. Megadrile:

Oligochaeta (Earthworms). Haplotaxida: Lumbricana: Megascolecoidea: Octochaetidae.

Zoological Survey of India, Calcutta.

163. Julka, J. M., R. Paliwal and P. Kathireswari. 2009. Biodiversity of Indian earthworms-

an overview. Pages 36–56 in: C. A. Edwards, R. Jayaraaj and I. A. Jayraaj, (Editors)

Proceedings of Indo-US Workshop on Vermitechnology in Human Welfare, Coimbatore,

India.

164. Julka, J.M and R Paliwal. 2005. Distrbution of earthworms in different agro-climatic

region of India. Pages 3-13, in: P.S. Ramakrishnan, K.G. Saxena, M. J. Swift, Raoks and

R.K. Maikhuri (editors). Soil biodiversity, ecological processes and landscape. Oxford

and ABH Publications Co. Pvt. Ltd., New Delhi,

165. Julka, J.M. 1988. The fauna of India and Adjacent countries- Megadrile Oligochaeta.

Zoological Survey of India, Kolkata.

166. Julka, J.M. 2001 Distribution of earthworms in different agroclimatic regions of India.

Workshop on tropical Soil Biology and Fertility programme. School of Environmental

Sciences. J N U, New Delhi.

167. Ka Kayondo, J. K. 1984. Ecology of detritivore Earthworm Millsonia Lamiani

(Acantho Drilidae-Oligochaeta) in the savannah (Côte d'Ivoire). PhD Thesis, University

of Paris.

168. Kale R.D., K. Bano, M.N. Sreenivasa and D.J. Bagyaraj. 1987. Influence of worm cast

on the growth and mycorrhizal colonization of two ornamental plants. South Indian

Horticulture, 35: 433-437.

169. Kale, R. D and K. Bano. 1986. Field trials with vermicompost - an organic fertilizer; In

Proc. of National Seminar on ‘Organic Waste Utilization by Vermicomposting’; GKVK

Agricultural University, Bangalore, India.

170. Kale, R. D and N. Karmegam. 2010. The Role of Earthworms in Tropics with

Emphasis on Indian Ecosystems. Applied Environmental Soil Science 16 pages.

171. Kale, R.D and Krishnamoorthy. 1978. Distribution and abundance of earthworms in

Bangalore. Proceedings of Indian Academy (Animal Sciences), 87B (3): 23-25.

172. Kale, R.D and Krishnamoorthy. 1981. What affects the abundance and diversity of

earthworms in soils? Proceedings of the Indian Academy of Science 51: 117-121.

173. Kale, R.D. 1997. Earthworm and Soil. Proceedings of National Academy of Science,

India 67 (B):13-24.

174. Kapulnik, Y. 1996. Plant growth promoting rhizosphere bacteria. Pages 769-781 in: Y.

Waisel, A. Eshel and U. Kafkafi (editors). Plant Roots The Hidden Half, Marcel Dekker,

NewYork.

175. Karmegam, N and T. Daniel. 2000. Selected physico-chemical characteristics and

microbial populations of the casts of the earthworm, Pontoscolex corethrurus (Muller)

and surrounding soil in an undisturbed forest floor in Sirumalai Hills, South India. A

Journal of Microbiology, Biotechnology and Environmental Science, 2:231–234.

176. Karsten, G. R and H. L. Drake. 1995. Comparative assessment of the aerobic and

anaerobic microfloras of earthworm guts and forest soils. Applied Environment

Microbiology 61:1039-1044.

177. Kasing, A., C. J. Bor and S. Azib. 2000. Screening and isolation of cellulolytic and

amylolytic Bacillus from pith waste. Journal of General and Applied Microbiology 46:

263-267.

178. Kazuhisa, M. 1997. Renewable biological system for alternative sustainable energy

production (FAO-Agricultural Services Bulletin, 128), Osaka University, Osaka, Japan.

179. Kelly, J.J and R. L. Tate. 1998. Use of Biolog for the analysis of microbial

communities from zinc-contaminated soils. Journal of Environmental Quality 27: (3),

600.

180. Khalid, A., M. Arshad and Z.A. Zahir. 2004. Screening plant growth-promoting

rhizobacteria for improving growth and yield of wheat. Journal of Applied Microbiology,

96 (3): 473-480.

181. Khambata S. R and J. V. Bhat. 1957. A contribution to the study of the intestinal

microflora of Indian earthworms Archives of Microbiology 28(1): 69-80.

182. Kirk, T. K and R. L. Farrell. 1987. Enzymatic combustion: the microbial degradation of

lignin. Annual Review of Microbiology 41:465–505.

183. Kloepper, J. W and M. N. Schroth. 1978. Plant growth-promoting rhizobacteria on

radishes. Pages 879-882 in: Proceedings of the 4th International Conference on Plant

Pathogenic Bacteria. Vol. 2, Station of Plant Pathology and phytobacteriology, INRA,

Angers, France.

184. Kloepper, J. W. 1993. Plant-growth-promoting rhizobacteria as biological control

agents. Pages 255-273 in: F.B. Jr., Metting (editor). Soil Microbial Ecology, Marcel

Dekker inc., NewYork.

185. Kloepper, J. W., R. Lifshitz and R. M. Zablotowicz. 1989. Free-living bacterial inocula

for enhancing crop productivity. Trends Biotechnology 7:39-44.

186. Kokalis-Burelle, N., C. S. Vavrina, E. N. Rosskopf and R. A. Shelby. 2002. Field

evaluation of plant growth-promoting Rhizobacteria amended transplant mixes and soil

solarization for tomato and pepper production in Florida. Plant Soil 238:257-266.

187. Koleff, P., K.J. Gaston and J.J. Lennon. 2003. Measuring beta diversity for presence-

absence data. Journal of Animal Ecology 72:367-382.

188. Kozlovskaya, L.S and E.N. Zhdannikova. 1961. The combined activity of earthworms

and the microflora in forest soils. Dokl. Acad. Nauk SSSR 139:574-576.

189. Kretzschmar, A and P. Monestiez. 1992. Physical control of soil biological activity due

to endogenic earthworm behaviour. Soil Biology and Biochemistry 24: 1609–1614.

190. Kristufek, V., K. Ravasz and V. Pizl. 1992. Changes in densities of bacteria and

microfungi during gut transit in Lumbricus rubellus and Aporrectodea calignosa. Soil

Biology and Biochemistry 24: 1499-1500.

191. Kuehn, K. A., M. O. Gessner, R. G. Wetzel and K. Suberkropp. 1999. Decomposition

and CO2 evolution from standing litter of the emergent macrophyte Erianteus giganteus.

Microbial Ecology 38:50–57.

192. Lal, L. 2002. Phosphatic biofertilizers. Page224, in: Agrotechnology, Publising

Academy, Udaipur, India.

193. Lal, R. 1988. Effects of macrofauna on soil properties in tropical ecosystems.

Agricultural. Ecosvstems and Environment 24: 101-1 16.

194. Lattaud, C., B. G. Zhang, S. Locati, C. Rouland and P. Lavelle. 1997. Activities of the

digestive enzymes in the gut and in tissue culture of a tropical geophagous earthworm,

Polypheretima elongata (Megascolecidae). Soil Biology and Biochemistry 29: 335–339.

195. Lattaud, C., P. Mora, M. Garvin, S. Locati and C. Rouland. 1999. Enzymatic digestive

capabilities in geophagus earthworms- origin and activities of cellulolytic enzymes.

Pedobiologia 43: 842-850.

196. Lau, G. W., D. J. Hassett, H. Ran and F. Kong. 2004. The role of pyocyanin in

Pseudomonas aeruginosa infection. Trends in Molecular Medicine 10:599- 606.

197. Lavelle P, M. Dangerfield, C. Fragoso, Eschen-brnner, L. Fernandez, B. Pashanasi and

L. Brussard. 1994. The relationship between soil macro fauna and tropical soil fertility.

Pages 117-169, in: P.L. Woomer and M. J. Smith. (Editors) The Biological Management

of Tropical Soil Fertility, Pergamon.Lavelle P. 1983. The structure of earthworm

communities. pp. 449-466, in: J. E. Satchell (editor) Earthworm ecology. Chapman and

Hall, London.

199. Lavelle, P and A. Martin. 1992. Small-scale and Large-scale effects of endogeic

earthworms on dynamics of organic matter of moist savanna soil. Soil Biology and

Biochemistry 24:1491-1498.

200. Lavelle, P and A.V. Spain. 2001. Soil Ecology. Kluwer Academic Publishers, London.

201. Lavelle, P. 1981. 1981. Strategies of reproduction in worms. Acta OEcologica 2:117-

133.

202. Lavelle, P. 1983. The structure of earthworm communities. Pages 449-466, in: J. E.

Satchell (editors) Earthworm ecology. Chapman and Hall, London.

203. Lavelle, P. 1987. The importance of biological processes in productivity of soils in the

humid tropics. Pages 175-214, in: R. E. Dickinson and J. Lovelock (editors)

Geophysiology of Amazoni. Wiley & Sons, New York.

204. Lavelle, P. 1988. Earthworm activities and the soil systems. Biology and Fertility of

Soils 6:237-251.

205. Lavelle, P. 1997. Faunal activities and soil processes: Adaptive strategies that

determine ecosystem function. Advanced Ecological Research 24: 93-132.

206. Lavelle, P. and B. Pashanasi. 1989. Soil macrofauna and land management in Peruvian

Amazonia (Yurimaguas, Loreto). Pedobiologia 33:283-291.

207. Lavelle, P. and C. Gilot. 1994. Priming e€ect of macroorganisms on microflora: a key

process of soil function? Pages 173-180, in: K.J. Ritz, J. Dighton and K.E. Giller

(Editors) Beyond the Biomass: Compositional and Functional Analysis of Soil Microbial

Communities. Wiley, Chichester.

208. Lavelle, P., C. Lattaud, D. Trigo and I. Barois, 1995. Mutualism and biodiversity in

soils. Plant and Soil 170: 23-33.

209. Lavelle, P., D. Bignell, M. Lepage, V. Wolters, P. Roger, P. Ineson, O. W Heal and S.

Dhillon. 1997. Soil function in a changing world: the role of invertebrate ecosystem

engineers. European Journal of Soil Biology 33: 159-193.

210. Lavelle, P., I. Barois, E. Blanchart, G. Brown, L. Brussaard, T. Decaëns, C. Fragoso, J.

J. Jimenez, K. K. Kajondo, M. D. L. Ángeles, A. Moreno, B. Pashanasi, B. K. Senapati

and C. Villenave. 1998. Earthworms as a resource in tropical agroecosystems; Nature

Resources 34: 26–41.

211. Lavelle, P., Lattaud, C., Trigo, D and I. Barois. 1995. Mutualism and biodiversity in

soils. Plant and Soil 170: 23-33.

212. Lavelle, P., Z. Zaidi and R. Schaefer. 1983. Interactions between earthworms, soil

organic matter and microflora in an African savanna soil. Pages 253-259, in: P. Lebrun,

A. De Medts, C. Gregoire-Wibo and G. Wauthy (editors) New trends in soil biology,

Dieu-Brichard, Louvain-la-Neuve.

213. Lawlor, K., B.P. Knight, V.L. Barbosa-Je!erson, P.W. Lane, A.K. Lilley, G.I. Paton,

S.P. McGrath, S.M. O’Faherty and P.R. Hirsch. 2000. Comparison of methods to

investigate microbial populations in soils under different agricultural management. FEMS

Microbiology and Ecology 33:129-137.

214. Lazarovits, G and J. Nowak. 1997. Rhizobacteria for improvement of plant growth and

establishment. Horticultural Science 32:188-192.

215. Lee, K. E. 1985. Earthworms: their ecology and relationships with soils and land use.

Sydney, Australia. Academic Press: 411.

216. Liesack, W., P.H. Janssen, F.A Rainey, N.L Ward-Rainey and E. Stackebrandt. 1997.

Microbial diversity in soil: the need for a combined approach using molecular and

cultivation techniques. Modern Soil Microbiology, Marcel Dekker, New York.

217. Liu, Z. G and X. M. Zou. 2002. Exotic earthworms accelerate plant litter decomposition

in a Puerto Rican pasture and a wet forest. Ecological Applications 12: 1406-1417.

218. Logsdon, G. 1994. Worldwide progress in vermicomposting. Biocycle 35 (10): 63-65.

219. Lopez-Hernandez, D., J. C Fardea and P Lavelle. 1993. Phosphorus transformations in

two P-sorption contrasting tropical soils during transit through Pontoscolex corethrurus

(Glossoscolecidae, Oligochaeta). Soil Biology and Biochemistry 25: 789-792.

220. Loquet, M., T. Bhatnagar, M. B. Bouché and J. Rouelle. 1977. Test for estimating the

ecological influence of earthworms on microorganisms. Pedobiologia 17: 400–417.

221. Lucas-García, J., J. Domenech, C. Santamaría, M. Camacho, A. Daza and F. Gutiérrez-

Mañero. 2004. Growth of forest plants (pine and holm-oak) inoculated with

rhizobacteria: relationship with microbial community structure and biological activity of

its rhizosphere. Environmental and Experimental Botany 52: 239-251.

222. Lundquist, K., R. Simonsson, and K. Tingsvik. 1980. Studies on lignin–carbohydrate

linkages in milled wood lignin preparations. Swedish paper journal 83: 452–454.

223. Lynd, L. R., P. J. Weimer, W. H. Van Zyl and I. S. Pretorius. 2002. Microbial cellulose

utilization; Fundamentals and Biotechnology. Molecular Biology Review 66: 506-577.

224. Mackay, A.D., J.K. Syers, J.K. Springett and P. E. H. Gregg. 1983. Origin of the effect

of earth worm in the availability of phosphorous in phosphatase rock. Soil Biology and

Biochemistry 14: 281-287.

225. Mackay, R.J and K.E. Kersey. 1985. A preliminary study of aquatic insect

communities and leaf decomposition in acid streams near Dorset, Ontario.

Hydrobiologia 122:3-11

226. Madan, M., S. Sharma, R. Bisaria and R. Bhamidimarri. 1988. Recycling of organic

wastes through vermicomposting and mushroom cultivation. Alternative waste treatment

systems 132-141.

227. Magurran, A.E. 1988. Ecological diversity and its measurement. Princeton University

Press, Princeton, N.J

228. Maliha, R., K. A. Samina, Najma, A. Sadia and L. Farooq. 2004. Organic acids

production and phosphate solubilization by phosphate solubilizing microorganisms under

in vitro conditions. Pakistan Journal of Biological Science 7:178-196.

229. Mandal, S.M., K.C. Mondal, S. Dey and B.R. Pati. 2007. Optimization of Cultural and

Nutritional conditions for Indol-3-Acetic acid (IAA) production by a Rhizobium sp.

isolated from rot nodules of Vigna mungo (L) hepper. Research Journal of Microbiology

2 (3): 239-246.

230. Mandels, M. 1974. Production and Applications of Cellulase" Laboratory Procedures

Handbook, U.S. Army Materials Laboratories.

231. Mandels, M., L. Hontz and J. Nystron. 1974. Enzymatic hydrolysis of waste cellulose.

Biotechnology and Bioengineering 16:147-149.

232. Mansell, G. P., Syres, J. K. and P. E. H. Gregg. 1981. Plant availability of P in dead

herbage ingested by surface casting earthworms. Soil Biology and Biochemistry 13:163-

167.

233. Maraun, M., J. Alphei, M. Bonkowski, R. Buryn, S. Migge, M. Peter, M. Schaefer and

S. Scheu. 1999. Middens of the earthworm Lumbricus terrestris (Lumbricidae):

microhabitats for micro- and mesofauna in forest soil. Pedobiologia 43: 276–287.

234. Mariaglieti, K. 1979. On the community structure of the gut microbiota of Eisenia

lucens (Annelida, Oligochaeta). Pedobiologia 19: 243-252.

235. Marianne H and W. J. Page. 1988. Zn2+

Increases Siderophore Production in

Azotobacter vinelandii. Applied and Environmental Microbiology 2625-2631.

236. Marques, S., H. Pala, L. Alves, M.T. Amaral-Collac¸ O. F.M. Gama, F.M. Gırio. 2003.

Characterisation and application of glycanases secreted by Aspergillus terreus CCMI 498

and Trichoderma viride CCMI 84 for enzymatic deinking of mixed office wastepaper.

Journal of Biotechnology 100: 209-219.

237. Martin, A., A. Mariotti, J. Balesdent and P. Lavelle. 1991. Estimates of soil organic

matter assimilation by a geophagous tropical earthworm based on I3C natural abundance.

Ecology, 73: 118-128.

238. Mattijs, S., K. A. Tehrani, G. Laus, W. Jackson, R. M. Cooper and P. Cornelis. 2007.

Thioquinolobactin, a Pseudomonas siderophore with antifungal and anti- pytium activity.

Environmental Microbiology 9:425-434.

239. McLean, M.A., S. Migge-Kleian and D. Parkinson. 2006. Earthworm invasions of

ecosystems devoid of earthworms: effects on soil microbes. Biological Invasions 8:

1257–1273.

240. Meunchang, S., P. Thongraar, S. Sanoh and S. Kaewsuralikhit. 2006. Development of

Rhizobacteria as a biofertilizer for rice production. International workshop on sustained

management of the soil Rhizosphere system for efficient crop production and fertilizer

used. Land Development Department Bangkok.

241. Meunchang, S., S. Panichsakpatana and R. W. Weaver. 2005. Co-composting of filter

cake and bagasse; by-products from a sugar mill. Bioresource Technology 96: 437-442.

242. Meyer, J.M and M.A. Abdallah. 1978. The fluorescent pigment of Pseudomonas

fluorescens: Biosynthesis, purification and physicochemical properties. Journal of

General Microbiology 107:319- 328.

243. Meyer, J.M., V.A. Geoffroy, N. Baida, L.Gardan, D. Izard and P. Lemanceau. 2002.

Siderophore typing, a powerful tool for the identification of fluorescent and non-

fluorescent pseudomonads. Applied and Environmental Microbiology 68: 2745 – 2753.

244. Miele W.H and A.E Linkins. 1978. Cellular activity during the growth of Achly

bisexualis on glucose, cellulose and selected polysaccharides. Canadian Journal of

Botany 56: 1974–1981.

245. Mikanova and Kubat. 1994. Phosphorus solubilization from hardly soluble phosphates

by soil microflora. Rostlinná výroba 40:833-844.

246. Mishra, A and C. S. Nautiyal. 2009. Functional diversity of the microbial community in

the rhizosphere of chickpea grown in diesel fuel-spiked soil amended with Trichoderma

ressei using sole-carbon-source utilization profiles. World journal of Microbiology and

Biotechnology 25: 1175- 1180.

247. Morales, V.M., E. Martinez Molina and D.H Hubbell. 1984. Cellulase production by

Rhizobium. Plant and Soil 80: 407–415.

248. Muhammad, S., A. Aqeel, S. Saleem and A. K. Shakeel. 2005. A survey of amylolytic

bacteria and fungi from Native environmental samples. Pakistan Journal of Botany 37(1):

155-161.

249. Murao, S., K. Ohyama and M. Arai. 1979. β-amylase from Bacillus polymyxa.

Agricultural Biology and Chemistry 43(4): 719-726.

250. Murugappan, R.M., S Rekha and R. Thirumurugan. 2006. Characterization and

quantification of siderophores produced by Aeromonas hydrophila isolated from

Cyprinus carpio. Pakistan Journal of Biological Science 9:437–440.

251. Nakamura, K. and Kppamura, K. 1982. Isolation and identification of crystalline

cellulose hydrolyzing bacterium and its enzymatic properties. Journal of Fermentation

Technology 60 (4): 343 - 348.

252. Nannipieri, P., J. Ascher, M. Ceccherini, L. Landi, G. Pietramellara and G. Renella.

2003. Microbial diversity and soil functions. European Journal of Soil Science 54:655-

670.

253. Needham, A.E. 1957. Components of nitrogenous excreta in the earthworms Lumbricus

terrestris, L. and Eisenia foetida (savigny). Experimental Biology 34: 425-446.

254. Nielson, R. 1965. Presence of plant growth substances in earthworms demonstrated by

paper chromatography and the Wet Pea Test. Nature. 208 (5015):1113-1114.

255. Nowak, E. 1975. Population density of earthworms and some elements of their

production in several grassland environments. Ekologia Polska 23: 459-491.

256. O’Connel, S. P and J. L. Garland. 2002. Dissimilar response of microbial communities

in Biolog GN and GN2 plates. Soil Biology and Biochemistry 34:413.

257. Odum E. P. 1982. Fundamentals of Ecology PWRiL, Warsaw, pages 667.

258. Ogram, A. 2000. Soil molecular microbial ecology at age 20: methodological

challenges for the future. Soil Biology and Biochemistry 32: 1499–1504.

259. Onsori, H., Zamani, M.R., Motallebi, M. and Zarghami, N. 2005. Identification of over

producer strain of endo-B-1-4- glucanase in Aspergillus species: Characterization of

crude carboxy methyl cellulase. African Journal of Biotechnology 4 (1):26-30.

260. Orazova, M .K., A. S. Tatyana and A. V Tinov. 2003. The microfungal community of

Lumbricus terrestris middens in a linden (Tilia cordata) forest. Pedobiologia 47: 27-32.

261. Ozaki, K and S. Ito. 1991. Purification and properties of an acid endo-B-1-4-glucanase

from Bacillus sp. KSM-330. Journal of General Microbiology 137:41-48.

262. Pandey A, P. Nigam, C. R. Soccol, V.T. Soccol, D. Singh and R. Mohan. 2000.

Advances in microbial amylases. Biotechnological Application of Biochemistry 31: 135–

152.

263. Parkin, T.B and E.C. Berry. 1994. Nitrogen transformations associated with earthworm

casts. Soil Biology and Biochemistry 26: 1233-1238.

264. Parle, J.N. 1963. A microbiological study of earthworm casts. Journal of General

Microbiology 31:13-22

265. Parle, J.N. 1963. Micro-organisms in the intestines of earthworms. Journal of General

Microbiology 31:1–11.

266. Pashanasi, B., G. Melendez, L. Szott and P. Lavelle. 1992. Effect of inoculation with

the endogeic earthworm Pontoscolex corethrurus (Glossoscolecidae) on N availability,

soil microbial biomass, and the growth of three tropical fruit tree seedlings in a pot

experiment. Soil Biology and Biochemistry 24:1655-1659.

267. Patten, C.L and B.R. Glick. 2002. Role of Pseudomonas putida indoleacetic acid in

development of the host plant root system. Applied Environmental Microbiology 68:

3795–3801.

268. Pedersen, J.C and N.B. Hendriksen. 1993. Effect of passage through the intestinal tract

of detritivore earthworms (Lumbricus spp.) on the number of selected Gram-negative and

total bacteria. Biology and Fertility of Soils 16:227–232.

269. Pielou, E. C. 1984. The interpretation of ecological data. John Wiley & Sons, Inc., New

York.16

270. Pielou, F.D. 1975. Ecological Diversity. Wiley Interscience, New York.

271. Polyanskaya, L. M and A.V. Tiunov. 1996. Microflora of the walls of galleries formed

by the earthworm Lumbricus terrestris. Microbiology 65: 88-90.

272. Ponmurugan, P and C. Gopi. 2006. Distribution pattern and screening of Phosphate

solubilizing bacteria isolated from different food and forage crops. Journal of Agronomy

5(4): 600-604.

273. Prakash, M., M. Jayakumar and N. Karmegam. 2008. Physico-chemical characteristics

and fungal flora in the casts of the earthworm, Perionyx ceylenensis Mich. reared in

Polyalthia longifolia leaf litter. Journal of Applied Science Research 4 (1): 53-57.

274. Prasetsan, P and H.W. Doelle. 1987. Nutrient optimization for cellulase biosynthesis by

a newly isolated Cellulomonas sp. Mircen Journal 3: 33–44.

275. Preston-Mafham J., Boddyl and F. Randerson. 2002. Analysis of microbial community

functional diversity using sole-carbon-source utilization profiles -a critique. FEMS

Microbiology and Ecology 42, 1.

276. Probanza, A., J. L. Mateos, J. A. Lucas García, B. Ramos, M. R. Felipe and F. J.

Gutierrez Mañero. 2001. Effects of inoculation with PGPR Bacillus and Pisolithus

tinctorius on Pinus pinea L. growth, bacterial rhizosphere colonization, and mycorrhizal

infection. Microbial Ecology 41: 140-148.

277. Pulleman, M.M., J. Six, A. Uyl, J.C.Y. Marinissen and A.G. Jongmans. 2005.

Earthworms and management affect organic matter incorporation and microaggregate

formation in agricultural soils. Applied Soil Ecology 29: 1-15.

278. Ramalingam. 1997. Studies on the life cycle growth and population of Lampito mauritii

(Kinberg) and Eudrilus eugeniae cultured in different organic wastes and analysis of

nutrients and microbes of vermicompost. Ph.D Thesis, Anamalai University, India.

279. Richardson, A.E. and P.A. Hadobas. 1997. Soil isolates of Pseudomonas spp. that

utilize inositol phophates. Canadian Journal of Microbiology 43:509–516.

280. Righi, G. 1984. Pontoscolex (Migochaeta, Glossoscolecidae), a new evaluation. Studies

on Neotropical Fauna and Environment 19:159-177.

281. Robb, F., B. R. Davies, R. Cross, C. Kenyon, and C. Howard- Williams. 1979.

Cellulolytic bacteria as primary colonizers of Potamogeton pectinatus L. (sago pond

weed) from a brackish south-temperate coastal lake. Microbial Ecology 5:167–177.

282. Robert, M and C. Chenu. 1992. Interactions between soil minerals and microorganisms.

Pages 307-404, in: G. Stotzky and J.M. Bollag (editors) Soil Biochemistry Vol 7, Marcel

Dekker, New York.

283. Rodriguez, H and R. Fraga. 1999. Phosphate solubilizing bacteria and their role in plant

growth promotion. Biotechnological Advances 17: 319-339.

284. Rose A.H. 1980. Microbial Enzymes and Bioconversions. Academic Press, London,

England.

285. Ross D.J. and T.W. Speir. 1979. Studies on a climosequence of soils in tussock

grasslands. 23. Cellulase and hemicellulase activities of topsoils and tussock plant

materials. New Zealand Journal of Science 22:25–33.

286. Ross, J and A. Cairns. 1982. Effect of earthworms and rye grass on respiratory and

enzyme activities of soil. Soil Biology and Biochemistry 14:583-587.

287. Ruttimann, C., M. D. Vicuna, M. D. Mozuch and T.K. Kirk. 1991. Limited bacterial

mineralization of fungal degradation intermediates from synthetic lignin. Applied and

Environmental Microbiology 57 (12): 3652-3655.

288. Ryu, R and C.L. Patten. 2008a. Aromatic amino acid-dependent expression of indole-3-

pyruvate decarboxylase is regulated by 4 TyrR in Enterobacter cloacae UW5. American

Society for Microbiology 190 (21): 1-35.

289. Sala, M. M., and H. Gu¨de. 2004. Ectoenzymatic activities and heterotrophic bacteria

decomposing detritus. Archive of Hydrobiology 160:289–303.

290. Satchel, J.E and K. Martin. 1984. Vermicomposting influences phosphorous

microbiology leading to phosphorous enrichment in end product. Soil Biology and

Biochemistry 16: 191-194.

291. Satchell, J.E. 1967. Lumbricidae, Pages 259-322, in: A. Burges and F. Raw (editors)

Soil Biology. Academic Press, London.

292. Savin, M. C, J. H. Gorres and J. A. Amador. 2004. Microbial and Microfaunal

Community Dynamics in Artificial and Lumbricus terrestris (L.) Burrows. Soil Science

Society of America Journal 68:116–124.

293. Sawada, H., L. D. Kuykendall and J. M. Young. 2003. Changing concepts in the

systematics of nitrogen-fixing legume symbionts. Journal of General Applied

Microbiology 49:155-179.

294. Scheu, S and D. Parkinson. 1994. Effects of earthworms on nutrient dynamics, carbon

turnover, and microorganisms in soil from cool temperate forests of the Canadian Rocky

Mountains – laboratory studies. Applied Soil Ecology 1:113–125.

295. Scheu, S and V. Wolters. 1991. Influence of fragmentation and bioturbation on the

decomposition of (14) C-labelled beech leaf litter. Soil Biology and Biochemistry 23:

1029- 1034.

296. Scheu, S. 1987. Microbial activity and nutrient dynamics in earthworm casts

(Lumbricidae). Biology and Fertility of Soils 5:230-234.

297. Scheu, S. 1990. Changes in microbial nutrient status during secondary succession and

its modification by earthworms. Oecologia 84:351-358.

298. Sharpley A. N and J. K. Syers. 1976. Potential role of earthworm casts for the

phosphorus enrichment of run-off waters. Soil Biology & Biochemistry 8: 341-346.

299. Shaw, C and S. Pawluk. 1986. Faecal microbiology of Octolasion tyrtaeum

Aporrectodea turgida and Lumbricus terrestris and its relation to the carbon budgets of

three artificial soils. Pedobiologia 29:377–389.

300. Shaw, T.V and H. Quejesky. 1979. Characterization of the growth and cellulolytic

activities of Trichoderma viride. Developments in Industrial Microbiology 12: 212 – 224.

301. Shuster, W. D., S. Subler and E. L. McCoy. 2001. Deep-burrowing earthworm

additions changed the distribution of soil organic carbon in a chisel-tilled soil. Soil

Biology and Biochemistry 33 (7-8): 983-996

302. Shutter, M and R. Dick. 2001. Shifts in substrate utilization potential and structure of

soil microbial communities in response to carbon substrates Soil Biology and

Biochemistry 33: 1481–1449.

303. Sinsabaugh, R. L., M. M. Carreiro, and S. Alvarez. 2002. Enzyme and microbial

dynamics during litter decomposition. Pages 249–266, in: R. Burns and R. P. Dick

(editors). Enzymes in the Environment. Marcel Dekker, New York, New York, USA.

304. Slater, J. H and D. Lovatt. 1984. Biodegradation and the significance of microbial

communities. Pages 439–485 in: D. T. Gibson, (editor) Microbial degradation of organic

compounds. Marcel Dekker, New York, New York USA.

305. Smalla K, U. Wachtendorf, W.T. Liu and L. Forney. 1998. Analysis of BIOLOG GN

substrate utilization patterns by microbial communities. Applied Environmental

Microbiology 64:1220–25.

306. Soderber, K.H., P.A. Olsson, and E. Baath. 2002. Structure and activity of the bacterial

community in the rhizosphere of different plant species and the effect of arbuscular

mycorrhizal colonization. FEMS Microbiology and Ecology 40: 223-231.

307. Spain, A. V., P. Lavelle and A. Mariotti. 1992. Stimulation of Plant growth by tropical

earthworms. Soil Biology and Biochemistry 24: 1629-633.

308. Spain, J. C and D. T. Gibson. 1991. Pathway for biodegradation of para-nitrophenol in

a Moraxella sp. Applied Environmental Microbiology. 57:812-819.

309. Spalding B.P. 1980. Enzyme activities in coniferous leaf litter, Soil Science Society of

America Journal 44:760–764.

310. Spiers, G. A., D. Gagnon, G. E. Nason, E. C Packee and J. D Louiser. 1986. Effects and

importance of indigenous earthworms on decomposition and nutrient cycling in coastal

forest ecosystems. Canadian Journal for Research 16: 983-989.

311. Springett, J.A and J.K. Seyers. 1979. The effect of earthworm casts on ryegrass

seedlings. Pages 44-47, in: T.K. Crosby and R.P. Pottinger (editors). "Proceedings of the

2nd Australasian Conference on Grassland Invertebrate Ecology." Government Printer,

Wellington, New Zealand.

312. Sridevi, M and K.V. Mallaiah. 2007. Bioproduction of indole acetic acid by Rhizobium

strains isolated from root nodules of green manure crop, Sesbania sesban (L) Merr.

Iranian Journal of Biotechnology 5 (3): 178-182.

313. Staddon, W.J., L.C. Duchesne and J.T. Trevors. 1998. Impact of clear-cutting and

prescribed burning on microbial diversity and community structure in a jack pine (Pinus

banksiana Lamb.) clear-cut using Biolog Gram-negative microplates. World Journal of

Microbiology and Biotechnology 14:119-123.

314. Steenhoudt, O and J. Vanderleyden. 2000. Azospirillum, a free-living nitrogen-fixing

bacterium closely associated with grasses: genetic, biochemical and ecological aspects.

FEMS Microbiology Reviews 24 (4): 487–506.

315. Stefanowicz, A. 2006.The Biolog Plates Technique as a Tool in Ecological Studies of

Microbial Communities. Polish Journal of Environmental Studies 15, (5): 669-676.

316. Stehouwer, R. C., W. A Dick and S. J Traina. 1993. Characteristics of earthworm

burrow lining affecting atrazine sorption. Journal of Environmental Quality 22: 181-185.

317. Steinberg, D.A., R.V. Pouyat, R.W. Parmelee and P.M. Groffman. 1997. Earthworm

abundance and nitrogen mineralization rates along an urban-rural land use gradient. Soil

Biology and Biochemistry 29:427–430.

318. Stephens, P. M., C. W. Davoren, B. M. Doube and M. H. Rder. 1994. Ability of the

earthworms Aporrectodea rosea and A. trapezoids to increase plant growth and the foliar

concentration of elements in Wheat (Triticum aestivum cv. Spear) in a sandy loam soil.

Biology and Fertility of Soils 18: 150-154.

319. Stephenson, J. 1923. Fauna of British India- The Oligochaeta. Pages 222-259. Oxford

University, Clarendon Press, UK.

320. Sturz, A.V and J. Nowak. 2000. Endophytic communities of rhizobacteria and the

strategies required to create yield enhancing associations with crops. Applied Soil

Ecology 15:183-190.

321. Stutzenberger F.G. 1972. Cellulolytic activity of Thermonospora curbata: Optimal

assay conditions, partial purification and product of the cellulase. Applied Microbiology

24: 83–90.

322. Subba Rao, N.S. and Gaur D.Y. 2000. Microbial diversity-Management and

exploitation for sustainable agriculture, Pages 48-58, in: J.S.P. Yadav et al., (editors)

Extended summaries: International Conference on Managing Natural Resources for

Sustainable Agricultural Production in the 21 st century New Delhi, India .

323. Subler, S and A.S. Kirsch. 1998. Spring dynamics of soil carbon, nitrogen, and

microbial activity in earthworm middens in a no-till cornfield. Biology and Fertility of

Soils 26:243–249.

324. Suhane, R.K. Sinha and P.K. Singh. 2008. Vermicompost, cattle-dung compost and

chemical fertilizers: Impacts on yield of wheat crops. Communication of Rajendra

Agriculture University, Pusa, Bihar, India.

325. Sumner, J. B. 1921. Dinitrosalicylic Acid: A Reagent for the Estimation of Sugar in

Normal and Diabetic Urine. Journal of Biology and Chemistry. 47: 5.

326. Suto, M and F. Tomita. 2001. Induction and catabolite repression mechanisms of

cellulase in fungi. Journal Bioscience and Bioengineering 92: 305-311.

327. Szlavecz, K. 1985. The effect of microhabitats on the leaf litter decomposition and on

the distribution of soil animals. Holarctic Ecology 8: 33–38.

328. Takasaki Y. 1976. Production and Utilizations of β-amylase and pullunase from

Bacillus cereus var. mycoides. Agricultural Biology and Chemistry 40(8): 1515-1522.

329. Tanaka, Y. 1993. Aerobic cellulolytic bacterial flora associated with decomposing

Phragmites leaf litter in a seawater lake. Hydrobiologia 263:145–154.

330. Tapia-Coral, S.C. 2004. Macroinvertebrates, soil carbon stocks and nutrients in different

types of upland vegetation in the Peruvian Amazon. Doctoral Thesis. INPA/UFAM.

331. Tate, R.L. 2000. Soil microbiology. 2nd edition. New York: John Wiley & Sons.

332. Teather, R. M and P. J. Wood. 1982. Use of the Congo-red polysaccharide interaction

and characterization of cellulolytic bacteria from the bovine rumen. Applied

Environmental Microbiology 43: 777-780.

333. Tian, F., Y. Ding, H. Zhu, L. Yao and B. Du. 2009. Genetic diversity of siderophore-

producing bacteria of tobacco rhizosphere. Brazilian Journal of Microbiology 40 (2):

276-284.

334. Timmusk, S., B. Nicander, U. Granhall and E. Tillberg. 1999. Cytokinin production by

Paenibacillus polymyxa. Soil Biology and Biochemistry. 31:1847-1852.

335. Tisdall J. J. 1978. Ecology of earthworms in irrigated orchards. Pages 297-303, in: W.

W. Emerson, R. D. Bond and A. K Dexter, (Editors) Modification of Soil Structure,

Wiley, Chichester.

336. Tiunov, A.V and G. Dobrovolskaya, 2002. Fungal and bacterial communities in

Lumbricus terrestris burrow walls: a laboratory experiment. Pedobiologia 46:595 – 605.

337. Tiunov, A.V and N. A Kuznetsova. 2000. Environmental activity of anecic earthworms

(Lumbricus terrestris L.) and spatial organization of soil communities. Izvestiya

Akademii Nauk Seriya Biologicheskaya 5: 607–616.

338. Tiunov, A.V and S. Scheu. 1999. Microbial respiration, biomass, biovolume and

nutrient status in burrow walls of Lumbricus terrestris L. (Lumbricidae). Soil Biology

and Biochemistry 31:2039–2048.

339. Tiunov, A.V and S. Scheu. 2000. Microbial biomass, biovolume and respiration in

Lumbricus terrestris L. cast material of different age. Soil Biology and Biochemistry 32:

265- 275.

340. Tiunov, A.V., M Bonkowski, J. Alphei and S. Scheu. 2001a. Microflora, Protozoa and

Nematoda in Lumbricus terrestris burrow walls: a laboratory experiment. Pedobiologia

45:46–60.

341. Tiunov, A.V., T.G. Dobrovolskaya and L.M. Polyanskaya. 1997. Microbial

communities of Lumbricus terrestris burrow walls. Microbiology 66: 349-353.

342. Tiwari, S.C. and R. R. Mishra. 1993. Fungal abundance and diversity in earthworm

casts and in uningested soil. Biology and Fertility of Soils 16: 131-134.

343. Tiwari, S.C., Tiwari, B.K., R.R. Mishra. 1989. Microbial populations, enzyme activities

and nitrogen-phosphorus potassium enrichment in earthworm casts and in the

surrounding soil of a pineapple plantation. Biology and Fertility of Soils 8:178–182.

344. Tomati, U., A. Grappelli, and E. Galli, 1988. The hormone-like effect of earthworm

casts on plant growth. Biology and Fertility of Soils 5: 288-294.

345. Torsvik, V and L. Ovreas. 2002. Microbial diversity and function in soil: from genes to

ecosystems. Current Opinion in Microbiology 5: 240–45.

346. Torsvik, V., J. Goksoyr and F. Daae. 1990. High diversity in DNA of soil bacteria.

Applied and Environmental Microbiology 56:782-787.

347. Trigo, D and P. Lavelle. 1993. Changes in respiration rate and some physiochemical

properties of soil during gut transit through Allolobophora molleri (Lumbricidae,

Oligochaeta). Biology and Fertility of Soils 15: 185-188.

348. Trousseilier, M. and P. Legendre. 1981. A functional evenness index. Microbial

Ecology 7:283-296.

349. Truu, J., E. Talpsep, E. Heinaru, U. Stottmeister, H. Wand and A. Heinaru. 1999.

Comparison of API 20NE and Biolog GN identification systems assessed by techniques

of multivariate analyses. Journal of Microbiological Methods 36: 193-201.

350. Tsavkelova, E.A., T.A. Cherdyntseva, S.Y. Klimova, A.I. Shestakov, S.G. Botina and

A.I. Netrusov. 2007. Orchid-associated bacteria produce indole-3-acetic acid, promote

seed germination, and increase their microbial yield in response to exogenous auxin.

Archives of Microbiology 188 (6): 655-664.

351. Turco, R. F., A. C. Kennedy and M. D. Jawson. 1994. Microbial indicators of soil

quality. Pages. 73-90 in: J. W. Doran, D. C. Coleman, D. F. Bezdicek, and B. A. Steward

(editors) Defining soil quality for a sustainable environment. Soil Science Society of

America Journal Special Publication 35, Madison, WI.

352. Tzean, S. S., J. L. Chen, G.Y. Liou, C. C. Chen and W. H. Hsu. 1990. Aspergillus and

related telomorphs from Taiwan. Culture collection and Research Center, R. O. C.

353. Van Elsas J.D and J.T. Trevors. 1997. Modern Soil Microbiology. New York: Marcel

Dekker 124.

354. Van Elsas, J.D., P. Garbeva and J.F. Salles. 2002. Effect of agronomical measures on

the microbial diversity of soil as related to the suppression of soil-borne plant pathogens.

Biodegradation 13:29–40.

355. Van Rhee, A. 1965. Earthworm activity and plant growth in artificial cultures. Plant

and Soil 22: 45-48.

356. Vance, C. P., P. H. Graham and D. L. Allan. 2000. Biological nitrogen fixation:

phosphorous a critical future need? Pages 502-518, in: F.O. Pederosa, M. Hungria, M. G.

Yates and W. E. Newton (Editors) Nitrogen fixation from molecules to crop productivity,

Kluwer Academic Publishers, Dordrecht, the Netherlands.

357. Vessey, J.K. 2003. Plant growth promoting rhizobacteria as biofertilizers. Plant Soil

255, 571-586.

358. Vijila, K. 2000. Estimation of IAA production in Nitrogen fixing microorganisms.

Pages 38-39 in: Practical manual- microbial interaction in soil. Tamilnadu Agricultural

University, Coimbatore.

359. Vinotha, S.P., K. Parhtasarathi and L.S. Ranganathan. 2000. Enhanced phosphatase

activity in earthworm casts is more of microbial origin. Current Science 79 (9): 1158-

1159.

360. Visser, S. 1985. Role of the soil invertebrates in determining the composition of soil

microbial communities, Pages 297-317. in: Fitter A., Read D. and M.B. Usher (eds)

Ecological Interactions in Soil: Plants, Microbes and Animals. Blackwell Scientific

Publications, Oxford, UK.

361. Wan J. H. C and M. H. Wong. 2004. Effects of earthworm activity and P-solubilizing

bacteria on P availability in soil. Journal of Plant Nutrition and Soil Science 167 (2):

209–213.

362. Weihua, D and X. Yin. 2007. ‘Transformation of carbon and nitrogen by earthworms

in the decomposition processes of broad-leaved litters’ Earth and Environmental Science.

Chinese Geographical Science 17 (2): 166-172.

363. Wen-Jing, L., W. Hong-Tao, Y. Shi-Jian, W. Zhi-Chao and N. Yong-Feng. 2005.

Isolation and characterization of mesophilic cellulose-degrading bacteria from flower

stalks-vegetable waste co-composting system. Journal of General and Applied

Microbiology 51: 353–360.

364. Whitelaw, M.A. 2000. Growth promotion of plants inoculated with phosphate

solubilizing fungi. Advanced Agronomy 69:99-151.

365. Widmer, F., A. FlieMbach, E. Laczko, J. Schulze-Aurich and J. Zeyer. 2001. Assessing

soil biological characteristics: a comparison of bulk soil community DNA-, PFLA-, and

Biolog- analyses. Soil Biology and Biochemistry 33, 1029-1036.

366. Williams, J.B., A.I. Gusev and D.M. Hercules. 1995. Characterization of polyesters by

transesterification using matrix-assisted laser desorption ionization mass spectrometry.

Proceedings of the 43rd ASMS Conference on Mass Spectrometry and Allied Topics,

Atlanta, GA. 949.

367. Winding, A. 1994. Fingerprinting bacterial soil communities using biolog micro titer

plates. Pages 85- 94 in: K. Ritz, J. Dighton and K.E. Giller (editors) Beyond the biomass:

compositional and functional analysis of soil microbial communities. Wiley, Chichester.

368. Wood, T.M and K. M. Bhat. 1988. Methods for measuring cellulase activities. Methods

in Enzymology 160:87–117.

369. Wunsche, L., L. Bruggemann and W. Babel. 1995. Determination of substrate

utilization patterns of soil microbial communities: An approach to assess population

changes after hydrocarbon pollution. FEMS Microbiology and Ecology 17:295-306.

370. Yahya and Al- Azawi. 1989. Occurrence of phosphate solubilisizing bacteria in some

Iraqi soils. Plant and Soil 177:135-141.

371. Yamane, K., H. Suzuki, M. Hirotani, H. Ozawa, and K. Nisizawa. 1970. Effect of

nature and supply of carbon sources on cellulase formation in Pseudomonas fluorescens.

Journal of Biochemistry (Tokyo) 67:9-18.

372. Yoon, S.J., Y.J. Choi and H.K. Min. 1996. Isolation and identification of phytase-

producing bacterium, Enterobacter sp. and enzymatic properties of phytase enzyme.

Enzyme and Microbial Technology 18: 449–454.

373. Zak, J.C., M. R. Willing, D. L. Moorhead and H. G Wildman. 1994. Functional

diversity of microbial communities: a quantitative approach. Soil Biology and

Biochemistry 26:1101-1108.

374. Zhang, H and S. Schrader. 1993. Earthworm effects on selected physical and chemical

properties of soil aggregates. Biology and Fertility of Soils 15: 229–234.

375. Zvreafis, L and V. Torsvik. 1998. Microbial diversity and community structure in two

different agricultural soil communities. Microbial Ecology 36: 303-315.