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Antimicrobial resistant E. coli and enterococci in pangasius fillets and prawns inDanish retail imported from Asia
Ellis-Iversen, Johanne; Seyfarth, Anne Mette; Korsgaard, Helle Bisgaard; Bortolaia, Valeria; Munck,Nanna Sophia Mucha; Dalsgaard, Anders
Published in:Food Control
Link to article, DOI:10.1016/j.foodcont.2019.106958
Publication date:2020
Document VersionPeer reviewed version
Link back to DTU Orbit
Citation (APA):Ellis-Iversen, J., Seyfarth, A. M., Korsgaard, H. B., Bortolaia, V., Munck, N. S. M., & Dalsgaard, A. (2020).Antimicrobial resistant E. coli and enterococci in pangasius fillets and prawns in Danish retail imported fromAsia. Food Control, 114, [106958]. https://doi.org/10.1016/j.foodcont.2019.106958
Journal Pre-proof
Antimicrobial resistant E. coli and enterococci in pangasius fillets and prawns inDanish retail imported from Asia.
Johanne Ellis-Iversen, Anne Mette Seyfarth, Helle Korsgaard, Valeria Bortolaia,Nanna Munck, Anders Dalsgaard
PII: S0956-7135(19)30547-X
DOI: https://doi.org/10.1016/j.foodcont.2019.106958
Reference: JFCO 106958
To appear in: Food Control
Received Date: 21 August 2019
Revised Date: 14 October 2019
Accepted Date: 15 October 2019
Please cite this article as: Ellis-Iversen J., Seyfarth A.M., Korsgaard H., Bortolaia V., Munck N. &Dalsgaard A., Antimicrobial resistant E. coli and enterococci in pangasius fillets and prawns in Danishretail imported from Asia., Food Control (2019), doi: https://doi.org/10.1016/j.foodcont.2019.106958.
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© 2019 Published by Elsevier Ltd.
Antimicrobial resistant E. coli and enterococci in pangasius fillets and 1
prawns in Danish retail imported from Asia. 2
Johanne Ellis-Iversen*1, Anne Mette Seyfarth
2,3, Helle Korsgaard
1, Valeria Bortolaia
3, Nanna Munck
1, Anders 3
Dalsgaard4,5
4
5
Affiliations: 6
1) EpiRisk, Risk Assessment and Nutrition, National Food Institute, Technical University of Denmark, 7
Kemitorvet, Building 201, 2800 Kgs. Lyngby 8
2) Danish Veterinary and Food Administration, Laboratories Division, 4100 Ringsted, Denmark. 9
3) Genetic Epidemiology, National Food Institute, Technical University of Denmark, Kemitorvet, Building 204, 10
2800 Kgs. Lyngby 11
4) Food Safety and Zoonoses, Department for Veterinary and Animal Sciences, Copenhagen University 12
Stigbøjlen 4, 1870 Frederiksberg C 13
14
5) School of Chemical and Biomedical Engineering, Nanyang Technological University, Singapore 15
16
17
18
19
20
*corresponding author: 21
Johanne Ellis-Iversen, National Food Institute, Technical University of Denmark, Kemitorvet, Building 22
201, Room 3, 2800 Kgs. Lyngby, Email: [email protected] 23
24
2
Abstract 25
Antimicrobial resistance (AMR) genes, resistant bacteria and antimicrobial residues may be 26
transferred to humans through consumption of fish and prawns raised in aquaculture. This 27
study investigated AMR in E. coli and enterococci introduced to Denmark via prawns and 28
pangasius products imported from Asia. In total, 300 samples of frozen pangasius fillets and 29
prawns were collected from retail shops around Denmark. Samples were collected every two 30
months between September 2017 and May 2018 yielding 96 raw prawns, 107 pre-cooked 31
prawns and 97 pangasius fillets. The majority of samples (97%) were from Vietnam. Of the 300 32
samples, Enterococcus faecalis was detected in 87.0% (CI95% 83;93), E. faecium in 21.7% (CI95% 33
17;27) and E. coli in 22.3% (CI95% 18;27). Both E. faecalis and E. facium were detected in 57 34
samples and E.coli was only detected in combination with enteroccci. Of the isolates, 65.7% 35
(CI95% 57;73) E. faecalis, 1.5% (CI95% 0.9;10) E. faecium and 40.3% (CI95% 29;52) of E .coli were 36
fully sensitive to all antimicrobials in the panel tested. In 62 of the 300 samples (20.1% (CI95% 37
16;26)), resistance to at least one of the critically important and highest priority antimicrobials 38
as classified by WHO was detected. No resistance to carbapenem, vancomycin or linezolid was 39
detected, but one E. coli isolate carried resistance genes to multiple antibiotics including 40
cephalosporins, colistin, flouroquinolones and macrolides. 41
42
43
44
Keywords: imported seafood, antimicrobial resistance, microbiological contamination, prawns, 45
pangasius 46
3
1. Introduction 47
The emergence and increase of antimicrobial resistance (AMR) is an internationally recognized 48
problem and “The FAO action plan on Antimicrobial Resistance 2016-2020” supports the 49
agricultural and food industries in tackling AMR worldwide (FAO, 2016). The Food and 50
Agriculture Organization of the United Nations (FAO) recognizes that the risk of increasing AMR 51
appears to be higher in countries with weaker legislation and regulatory systems for use of 52
antimicrobial drugs than countries with implemented action plans and surveillance on the use 53
of antimicrobials (Hendriksen et al., 2019; Thornber et al., 2019). Global food trade is likely to 54
play a role in spreading AMR between countries and well-regulated countries may be at risk of 55
introducing novel resistant pathogens, resistance genes and increasing the national burden of 56
AMR via imported foods. 57
In 2016, global aquaculture production was 110.2 million tonnes with a first-sale value 58
estimated at USD 243.5 billion. Asian countries, in particular China are the main producers 59
accounting for nearly 90% of the global production (FAO, 2018). Prawns and fish, including 60
pangasius (Pangasianodon hypophthalmus), are main commodities produced and exported. 61
Intensification of aquaculture in Asian countries has often been accompanied by a higher 62
frequency of outbreaks of infectious bacterial diseases that require preventive and control 63
measures, e.g. antimicrobial treatments. Whilst the use of antimicrobials may have benefited 64
aquaculture production, it has also attracted some criticism due to negative environmental 65
impacts and development of AMR among the bacterial populations in ponds and cultured 66
aquatic species. Concerns that AMR genes, resistant bacteria and antimicrobial residues may be 67
4
transferred to humans through consumption of fish and prawns raised in aquaculture have 68
been expressed (Watts et al., 2017). 69
Vietnam is the main global pangasius producer, but has experienced a fall in exports to the 70
European Union (EU) during recent years (Globefish, 2018). The effects of weak consumer 71
demand, damaging media coverage and strong competition from whitefish alternatives have 72
now been compounded by the high price level on other import markets (Globefish, 2018). EU 73
member countries continue to import large volumes of prawns, mainly vannamei prawns 74
(Litopenaeus vannamei) from Asia, particularly from Vietnam (Globefish, 2018). However, the 75
public perception of tropical farmed prawns and pangasius tends to be increasingly negative, 76
perpetuated by negative mainstream and internet based media stories, blogs and information 77
outlets (Little et al., 2012; Murk, Rietjens, & Bush, 2018). A recent assessment of the 78
toxicological risks of consuming imported Asian prawns in the EU suggested a reduced 79
consumption risk. This was mainly based on fewer RASFF (Rapid Alert System on Food and 80
Feed) alerts than expected, when taken the increased supply over the lifetime of the alerts 81
system into account (Newton, Zhang, Leaver, Murray, & Little, 2019). In contrast to the 82
monitoring of antimicrobial residues, AMR in pangasius and prawns is not routinely monitored 83
by the EU member countries. Such a monitoring is challenged by the lack of good indicators of 84
AMR in seafood as the traditional bacterial indicators of antimicrobial resistance used in 85
livestock meat types, i.e. Escherichia coli (E. coli) and Enterococci faecium (E. faecium) and 86
Enterococci faecalis (E. faecalis), are not part of the normal microbiota in seafood. 87
E. coli and enterococci have, however, been used to study the antimicrobial resistance from 88
raw fish and seafood imported into Switzerland (Boss, Overesch, & Baumgartner, 2016). The 89
5
same authors furthermore proposed E. coli and E. faecalis in pangasius and shrimps as potential 90
candidates for programs monitoring antimicrobial resistance. Dib et al., 2018, also found 91
antimicrobial resistance in E. coli isolated from seafood in Constantine, Northeast Algeria. 92
The aim of this study was to investigate levels of AMR in E. coli and enterococci introduced to 93
Denmark via prawns and pangasius products imported from Asia. 94
2. Materials and methods 95
2.1. Sample collection 96
In total, 300 samples of frozen pangasius (Pangasianodon hypophthalmus) fillets and prawns 97
(Penaeidae family) imported from Asia were collected from retail shops around Denmark. 98
Samples were collected every two months between September 2017 and May 2018 by the 99
regional food officers from the Danish Veterinary and Food Administration (DVFA). 100
The number of shops, establishments and samples selected by each regional DVFA control unit 101
was proportional to the number of establishments in the region relative to the total number of 102
establishments in the country. Samples were equally distributed between pangasius, raw 103
prawns and ready-to-eat prawns. Samples remained frozen until analysis and were analyzed 104
before the expiry date of the product. 105
2.2. Laboratory methods 106
2.2.1. Detection of E. coli and enterococci 107
A total of 25 g thawed sample was added to 225 ml Buffered Peptone Water (BPW) in a sterile 108
stomacher bag and homogenized for 30 sec. For detection of enterococci, 100 µl of the 109
6
suspension was streaked onto Slanetz and Bartley agar (Bio-rad, Denmark) and incubated at 110
41.5°C for 48 h. For detection of E. coli, 100 µl of the suspension was streaked onto Violet Red 111
Bile (RVG) agar (Difco, Denmark) and incubated at 30°C for 4-6 hours followed by incubation at 112
44°C over night. The remaining suspension was incubated at 37°C for 18-22 h (hereafter 113
referred to as overnight culture). 114
115
In case growth of enterococci or E. coli was not observed on the agar plates, 10 µl of the 116
overnight culture was plated onto Slanetz Bartley and RVG agar again and incubated as 117
described above without the incubation step at 30°C for E. coli. 118
119
Furthermore, to screen for the critically important cephalosporin- or carbapenem resistant E. 120
coli the overnight culture was streaked on each of the following agar plates: 10 µl on 121
MacConkey (MCA) agar containing 1 µg/ml of cefotaxime (Tritium, Netherlands) and 20 µl on 122
ChromID CARBA and ChromID OXA-48 (Biomerioux, France). The MCA and ChromID agar plates 123
were incubated at 44°C for 18-22 h and 35-37°C for 18-24 h, respectively. 124
125
From each agar plate, up to three colonies resembling E. coli, two colonies resembling E. 126
faecalis and another two resembling E. faecium were selected for species verification. One 127
isolate of presumptive cephalosporin- and carbapenem resistant E. coli was selected per 128
sample. 129
130
131
7
2.2.2. Species verification 132
Presumptive E. coli colonies were verified on Tryptone Bile Glucuronic (TBX) agar (Oxoid, 133
Denmark) incubated at 44°C overnight. Presumptive enterococci colonies were sub-cultivated 134
on blood agar and identified by a real-time PCR assay (Dutka-Malen, Evers, & Courvalin, 1995). 135
All verified isolates were stored at –80°C until further analysis. 136
137
2.2.3. AMR identification 138
Antimicrobial susceptibility testing (AST) was performed by Minimum Inhibitory Concentration 139
(MIC) determination using broth microdilution (Sensititre, Trek Diagnostic Systems Ltd.). The 140
antimicrobial panels and interpretive criteria used were in accordance with the Decision 141
2013/652/EU on the EU harmonized monitoring of AMR in foodborne bacteria. All procedures 142
were performed according to ISO 20776-1:2006 standard. AST was performed for one isolate 143
per sample for each bacterial species. 144
WGS and bioinformatics tools were used to characterize carbapenem and cephalosporin-145
resistant E. coli as confirmed by AST. Genomic DNA (Easy-DNA, Invitrogen, Carlsbad, CA, USA) 146
was prepared for paired-end sequencing, 2x251 cycles, on the Illumina MiSeq platform 147
(Illumina, Inc., San Diego, CA). Library preparation was performed with the present version of 148
the NexteraXT® protocol (Guide 15031942, Illumina, Inc., San Diego, CA). Raw sequence data 149
were de novo assembled using SPAdes (Bankevich et al., 2012), and assembled sequences were 150
analyzed using the Centre for Genomic Epidemiology (www.genomicepidemiology.org) tools 151
including MLST Finder 2.0 (Larsen et al., 2012) for multi locus sequence typing (MLST) and 152
8
ResFinder 3.1 for detection of genes and chromosomal mutations mediating AMR (E. Zankari et 153
al., 2012; Ea Zankari et al., 2017). 154
2.2.4. Data cleaning and analysis 155
Data was extracted from the DVFA laboratory information management system (LIMS) and 156
validated in Microsoft Excel 2016. Further data cleaning, formatting and analysis were 157
performed in STATA 14 (Statacorp, Texas, USA). 158
Data was tabulated, examined for outliers and described using Wilson Score Interval confidence 159
intervals. Univariate comparisons by ꭓ2 tests and logistic regression analyses adjusted for 160
confounding, when appropriate. 161
3. Results 162
In total, 97 frozen, raw pangasius fillets were sampled and analyzed for E. coli and enterococci 163
(Table 1). All pangasius fillets originated from Vietnam and three were repacked after arrival in 164
Denmark. The majority of pangasius were raised in aquaculture with only two products of wild-165
caught pangasius. 166
Of the 203 frozen prawn samples, 107 were cooked and 96 were raw products. The majority of 167
the cooked prawns were pre-peeled (65%) or partially peeled with only the tail-shell remaining 168
(13%), whereas most of the raw prawns products were shell-on (81%). Of the pre-peeled or 169
partially peeled prawns, only five samples had visible remains of the intestinal tract. The 170
majority of the prawn products were from Vietnam (n=194), followed by Bangladesh and India 171
(four from each) and one sample’s origin was described as from “Indonesia, Vietnam or 172
9
Ecuador”. The majority of the products were packed in their country of origin. However, 13 173
products were re-packed in Denmark, three in France and one in the Netherlands. Almost all 174
prawns were farmed (97%). 175
Only 31 of the 300 pangasius and prawn samples were negative for both E. coli and enterococci. 176
Enterococcus faecalis was detected in 87.0% (CI95% 83;93) of the samples, E. faecium in 21.7% 177
(CI95% 17;27) and E. coli in 22.3% (CI95% 18;27) of samples. Both E. faecalis and E. facium were 178
detected in 57 samples and E.coli was only detected in combination with enterococci. 179
3.1. Enterococci spp. 180
The majority of samples (89.7%, CI95% 86;93) were contaminated by at least one of the two 181
Enterococcus spp. and at least one Enterococcus spp. was isolated from all pangasius fillets and 182
84% of the prawns. Raw prawns were significantly more likely to be contaminated by 183
enterococci than cooked prawns (93.8% vs. 76.6%, pꭓ2> 0.001). Shell-on prawns were also more 184
likely to contain enterococci, but this association was confounded by the fact that most cooked 185
prawns were pre-peeled and the risk associated with shell-on prawns disappeared once 186
adjusted for whether or not they were cooked. 187
Both E. faecalis and E. facium were detected in 57 samples (five pangasius and 52 prawn 188
samples), whereas E. faecalis was detected alone in 204 samples and E. faecium in eight 189
samples. Both species were detected in 18.7% of the cooked prawns and in 33.3% of the raw 190
prawn products. Detection of enterococci species was independent of the visibility/presence of 191
the intestinal tract. 192
10
A total of 140 E. faecalis and 65 E. faecium isolates were selected for MIC testing (Fig. 1). The 193
majority of E. faecalis (65.7%, CI95% 57;73) were sensitive to all antimicrobials tested, 27.9% 194
(CI95% 21;36) were resistant to one antimicrobial, 3.6% (CI95% 1.5;8.1) to two antimicrobials and 195
four strains (2.9%, CI95% 1.1;7.1) were resistant to three or more of the antimicrobials in the 196
panel (MDR). All multi-resistant strains were resistant to chloramphenicol, erythromycin, and 197
tetracycline and one strain was further resistant to gentamicin. E. faecalis is intrinsically (i.e. 198
naturally) resistant to streptogramin A and B (quinupristin-dalfopristin), and interpretation of 199
the MIC testing for this drug was therefore not evaluated. 200
Only 1.5% (CI95% 0.9;10) of E. faecium isolates were susceptible to all antimicrobials and 20% 201
(CI95% 12;31) of the isolates were resistant to three or more antimicrobials in the panel (MDR). 202
All the MDR isolates were resistant to erythromycin, quinopristin-dalfopristin and tetracycline 203
and two strains were additionally resistant to either ciprofloxacin or chloramphenicol. 204
No resistance to the last-line critically important drugs: linezolid or vancomycin was detected in 205
any of the enterococci isolates by the methods applied, suggesting that resistance to these 206
drugs would be present in less than 1% of imported seafood from Asia. 207
3.2. E.coli 208
E.coli was detected in 67 samples on agar plates without antimicrobial agents and was 209
significantly more often detected in pangasius fillets (74.6%) than in prawns (25.4%) (pꭓ2> 210
0.001). The majority of contaminated prawn samples were raw, but E. coli was also detected in 211
two cooked samples originating from Bangladesh and Vietnam, respectively. Every E. coli 212
contaminated sample was also contaminated with enterococci. 213
11
Standard panel antimicrobial testing was performed for all 67 isolates. A total of 40.3% (CI95% 214
29;52) were sensitive to all antimicrobials tested. The levels of resistance to different antibiotics 215
based on MIC are shown in Fig. 2. Only one strain isolated on non-selective media was resistant 216
to cephalosporins (cefepime, ceftazidime and cefotaxime). 217
Ten isolates were resistant to three or more antimicrobial groups. The MDR isolates displayed 218
various profiles (Table 2) with co-resistance to ampicillin, ciprofloxacin, tetracycline and 219
trimethoprim being observed in the majority (60%) of the MDR isolates in combination with 220
resistance to additional compounds. No resistance to nalidixic acid was detected in the MDR 221
isolates, despite nearly all of them exhibiting ciprofloxacin resistance. 222
3.3. Screening for cephalosporin- and carbapenem resistant E. coli 223
Four E. coli were isolated on cefotaxime-containing agar plates whereas no E. coli were isolated 224
on agar plates selective for carbapenemase-producers. These E. coli were isolated from prawn 225
samples only, three samples from Vietnam and one from Bangladesh. WGS data showed that 226
these isolates displayed different STs and harboured two different Extended Spectrum Beta-227
Lactamase (ESBL)-encoding genes, namely blaCTX-M-15 or blaCTX-M-55 (Table 3). Furthermore, all 228
isolates harboured genes conferring resistance to additional antimicrobials including the 229
plasmid-mediated quinolone resistance (PMQR) gene qnrS1 and, notably, the colistin resistance 230
gene mcr-1 occurring in one Vietnamese, shell-on, raw prawn. 231
3.4. Overall resistance imported via the products 232
In 62 of the 300 samples (20.7% (CI95% 17;26), we detected resistance to at least one of the 233
critically important and highest priority antimicrobials as classified by WHO (WHO, 2017). 234
12
4. Discussion 235
The majority of samples originated from Vietnam (97.0%), which probably reflects the origin of 236
Asian prawns and pangasius in the Danish retail stores. We found enterococci and/or E. coli in a 237
large proportion (89.7%) of the seafood samples. This was surprising, especially in the pre-238
cooked prawns, where 71.7% of the samples were contaminated with either enterococci or E. 239
coli. This suggests that the contamination occurred late in the processing after cooking. Very 240
often Northern Europeans consider cooked prawns ready-to-eat and consumer advice may be 241
considered appropriate. The fact that so many samples contained detectable levels of 242
enterococci and E. coli even after freezing also suggested that the initial contamination levels 243
were very high. This means that pathogens may survive too and the products may pose a risk to 244
consumers. 245
A considerable proportion (45.6%) of enterococci displayed resistance to at least one 246
antimicrobial. However, occurrence of AMR differed considerably between the two enterococci 247
species analyzed, and results were in line with the notion that acquired AMR occurs more 248
frequently in E. faecium than in E. faecalis (Hollenbeck & Rice, 2012) . 249
We found very high occurrence of tetracycline and quinupristin-dalfopristin resistance in E. 250
faecium and tetracycline resistance in E. faecalis, which is similar to other food matrices in 251
other EU countries (Danmap, 2017). Tetracycline and similar antimicrobial products were used 252
daily in Vietnam until the national action plan was implemented in 2016, which may explain the 253
high resistance levels to tetracycline (Long and Lua, 2017). 254
13
Of the E. coli isolates obtained on agar plates without antimicrobial agents, 40.2% were 255
resistant to at least one antimicrobial. Very high occurrence of ciprofloxacin resistance was 256
detected, despite a ban on using flouroquinolones in Vietnamese aquaculture was instated in 257
2016 (Long and Lua, 2017). The phenotypic resistance was often detected in the presence of 258
nalidixic acid susceptibility, which is a phenotype generally mediated by PMQR genes. This 259
suggests that PMQR genes were circulating widely in E. coli in Asian and Vietnamese seafood 260
imported to Denmark at the time of sampling. Although the public health significance of PMQR 261
genes has not yet been fully elucidated, it is known that occurrence of such genes facilitates the 262
selection of high level of resistance to quinolones (Poirel, Cattoir, & Nordmann, 2012), which 263
are among the highest priority critically important antimicrobials for human medicine. This 264
phenotype is not common in Danish food and imports may be a source of PMQR genes for 265
humans (Danmap, 2018). 266
On a positive note, only very low occurrence of resistance to other highest priority critically 267
important antimicrobials such as third-generation cephalosporins and colistin was detected. No 268
resistance to carbapenems or macrolides was observed. Carbepenem resistance was detected 269
in seafood imported from Southeast Asia to Canada suggesting food as a potential source of 270
exposure to consumers (Janecko et al., 2016). When analyzing the same samples by a selective 271
culture procedure, only a low proportion (1.3%) yielded third-generation cephalosporin-272
resistant E. coli indicating that overall this phenotype occurred sporadically in E. coli in Asian 273
seafood imported to Denmark at the time of sampling. The third-generation cephalosporin 274
resistance was mediated by ESBL-encoding genes such as blaCTX-M-15 and blaCTX-M-55 that have 275
been commonly described in bacteria from human and animal sources in Vietnam and other 276
14
Asian countries (Bui et al., 2015; Hoang et al., 2017; Nguyen et al., 2016; Zurfluh et al., 2015). 277
These ESBLs have also been described sporadically in isolates from Danish production animals 278
and retail meat of Danish origin whereas they are among the most commonly detected ESBLs in 279
human clinical isolated in Denmark (Danmap, 2018). 280
One E. coli isolate harboured a blaCTX-M-55–gene and was resistant to antimicrobials from nine 281
classes, including four classified as highest priority critically important antimicrobials for human 282
medicine (Table 3, isolate 4). Most of the AMR genes detected in this isolate have been 283
previously described on mobile genetic elements, and although we did not verify if these genes 284
were transferrable to other bacteria, it is of high concern that an E. coli resistant to virtually all 285
antimicrobials available for therapy occurs in food. 286
5. Conclusions 287
In this study, only one MDR isolate from a raw prawn sample from Vietnam harboured the 288
many very rare resistance genes. Nonetheless, in combination with the high proportion of 289
contaminated pre-cooked samples, high number of mobile resistance genes present and the 290
Danish habit of eating cold pre-cooked prawns, even 1 in 300 imported seafood samples could 291
expose consumers in Denmark to AMR genes that are very rare in domestic food sources, such 292
as plasmid-mediated flouro-quinolones or carbapenem. 293
Acknowledgement 294
The survey was funded by the Danish Veterinary and Food Administration, who also sampled 295
and carried out the laboratory analysis. 296
15
Conflict of interest 297
Declarations of interest: none 298
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Legends 399
Tables: 400
Table 1. Description of 300 retail samples of pangasius (Pangasianodon hypophthalmus) fillets 401
and prawns (Penaeidae family) from Asia collected in Danish supermarkets. 402
Table 2. Resistance profiles for 10 MDR E. coli isolates. 403
Table 3. Phenotypic and genotypic traits of four ESBL-producing E. coli isolates from Asian 404
prawns recovered from the overnight culture. 405
Figures: 406
Figure 1. Resistance to different antimicrobial agents in 140 E. faecalis and 65 E. faecium 407
originating from pangasius and prawns from Asia. E. faecalis is intrinsic resistant to 408
quinupristin/dalfopristin and therefore not shown. 409
Figure 2. Proportion of antimicrobial resistance in the 67 E. coli strains isolated from pangasius 410
and prawn samples. 411
412
Table 1.
Total E.coli
detected*
Enterococcus
detected
Neither
detected
Pangasius 97 50 97 0
Prawns 203 17 172 31
Country of origin Vietnam 291 65 260 31
India 4 0 4 0
Bangladesh 4 2 4 0
Other** 1 0 1 0
Prawns (n=203) Shell 102 13 97 5
Pre-peeled 87 4 65 22
Tail only 14 0 10 4
Intestinal tract visible 107 13 102 5
No intestinal tract 96 4 70 26
Cooked prawns 107 2 82 25
Uncooked prawns 96 15 90 6
Farmed prawns 197 17 166 31
Wild-caught prawns 6 0 6 0
*E. coli obtained on agar plates without antimicrobial agents
**Origin of sample “Indonesia, Vietnam or Ecuador”
Table 2.
MDR pattern Number of strains
SMX;TET;TMP 1
CIP;TET;TMP 3
AMP; CIP; SMX; TET; TMP 2
AMP; CHL; CIP; SMX; TET; TMP; 3
AMP; CIP; CHL; FEP; FOT; TET; TMP; TAZ 1
Total MDR 10
Note: AMP=Ampicillin; CIP=Ciprofloxacin; CHL=Chloramphenicol; FEP=Cefepime; FOT=Cefotaxime;
SMX=Sulphamethoxazole; TAZ=Ceftazidime; TET=Tetracycline; TMP=Trimethoprim; MDR=Multi drug resistance
Table 3. 1
Isolate
number
ST Phenotypic resistance
profile
ESBL genes Additional AMR genes
(WGS and Resfinder 3.1)
1 ST3052 AMP CIP FEP FOT TAZ blaCTX-M-15 qnrS1
2 ST226 AMP CIP FEP FOT TAZ blaCTX-M-15 qnrS1
3 Unknown AMP CHL CIP FEP FOT
TAZ TET TMP
blaCTX-M-55
aadA5, blaTEM-1B, dfrA17,
floR, qnrS1, tet(A)
4 Unknown AMP AZI CHL CIP COL
FEP FOT FOX GEN NAL
SMX TAZ TET TMP
bla CTX-M-55
aac(3)-Iid, aadA22, aadA5,
aph(3')-Ia, aph(6)-Id,
dfrA17, mcr-1, mph(A),
Inu(F), FloR, GyrA S83L*,
qnrS1, Sul2, sul3, tet(A),
Note: AMP=Ampicillin; AZI=Azithromycin; CIP=Ciprofloxacin; CHL=Chloramphenicol; COL=Colistin; 2
FEP=Cefepime; FOT=Cefotaxime; FOX=Cefoxitin; GEN=Gentamicin; NAL=Nalidixan; 3
SMX=Sulphamethoxazole; TAZ=Ceftazidime; TET=Tetracycline; TMP=Trimethoprim; MDR=Multi drug 4
resistance. Isolates discovered by selective enrichment methods. *Mutational resistance. 5
6
HighlightsHighlightsHighlightsHighlights
• Samples of frozen pangasius fillets and prawns imported from Asia to Denmark were
analysed.
• The majority of samples were contaminated by at least one of the two Enterococcus
spp.
• Resistance to critically important and highest priority antimicrobials were detected.
Declarations of interest: none