Научная статья на тему 'Molecular characterization of STEC isolated from Ducks and its relation to ESBL production'

Molecular characterization of STEC isolated from Ducks and its relation to ESBL production Текст научной статьи по специальности «Биологические науки»

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E.coli / STEC / ESBL / Duck

Аннотация научной статьи по биологическим наукам, автор научной работы — Aparna Banerjee, Surajit Acharyya

The ESBL producing genes are responsible for bacterial resistance to number of antibiotics whereas Shiga toxin producing genes are responsible for bacterial virulence. The association between ESBL producing genes and Shiga toxin producing E. coli (STEC) may pose bigger threat in the battle of antibiotic resistance. This study was conducted to determine the prevalence of Shiga-toxin-producing Escherichia coli (STEC) in ducks reared in organized and unorganized sectors from different agro climatic zones of West Bengal, India and to study their relationship with extended spectrum beta-lactamase (ESBL) production. Total 202 cloacal swab samples were collected from both indigenous ducks reared in backyards sector (110 samples) and Khaki Campbell Ducks reared in organized farm (92 samples). Initially the samples were screened for detection of E. coli on the basis of their cultural, morphological and biochemical properties followed by PCR confirmation for E. coli 16S rRNA. E. coli isolates were subjected to multiplex PCR to detect the presence of shiga toxin producing genes such as stx1, stx2, eaeA and ehxA. STEC isolates were screened phenotypically for production of ESBL and ACBL by double disk diffusion method and subsequently PCR detection for blaCTX-M, blaTEM, blaSHV and blaAmpC genes were performed. Serotyping of all the STEC was also done. Out of 202 samples total 109 were confirmed to be E. coli positive. Out of them total 27 (24.77 %) E. coli isolates were detected to be positive for STEC. Higher prevalence of STEC was observed in unorganized sector compared to the organized sector. Positive association (P < 0.05) was observed between STEC and ESBL production. This study indicates that the duck may play an important role in transmission of Siga-toxin-producing E. coli (STEC) as well as antibiotic resistance genes to human beings, other birds, animals and the environment.

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Текст научной работы на тему «Molecular characterization of STEC isolated from Ducks and its relation to ESBL production»

Ukrainian Journal of

Veterinary and Agricultural Sciences!

http://ujvas.com.ua

Stepan Gzhytskyi National University of Veterinary Medicine and Biotechnologies Lviv

Volume 3 Number 2

original article | UDC 636.09 doi: 10.32718/ujvas3-2.04

Molecular characterization of STEC isolated from Ducks and its relation to ESBL production

Apama Banerjee, Surajit Acharyya

Institute of Animal Health and Veterinary Biologicals (Research & Training), Kolkata, West Bengal, India

Article info Received 26.03.2020 Received in revised form

29.04.2020 Accepted 30.04.2020

Correspondence author

Aparna Banerjee

Tel.: +91-9932043314

E-mail: aparnavet2009@gmail. com

2020 Banerjee A. et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Contents

1. Introduction................. .. 24

2. Materials and methods .... .. 25

3. Results and discussion .... .. 26

4. Conclusions................ .. 28

.. 28

Abstract

The ESBL producing genes are responsible for bacterial resistance to number of antibiotics whereas Shiga toxin producing genes are responsible for bacterial virulence. The association between ESBL producing genes and Shiga toxin producing E. coli (STEC) may pose bigger threat in the battle of antibiotic resistance. This study was conducted to determine the prevalence of Shiga-toxin-producing Escherichia coli (STEC) in ducks reared in organized and unorganized sectors from different agro climatic zones of West Bengal, India and to study their relationship with extended spectrum beta-lactamase (ESBL) production. Total 202 cloacal swab samples were collected from both indigenous ducks reared in backyards sector (110 samples) and Khaki Campbell Ducks reared in organized farm (92 samples). Initially the samples were screened for detection of E. coli on the basis of their cultural, morphological and biochemical properties followed by PCR confirmation for E. coli 16S rRNA. E. coli isolates were subjected to multiplex PCR to detect the presence of shiga toxin producing genes such as stxl, stx2, eaeA and ehxA. STEC isolates were screened phenotypically for production of ESBL and ACBL by double disk diffusion method and subsequently PCR detection for blacTx-M, blaTEM, blaSHv and blaAmpc genes were performed. Serotyping of all the STEC was also done. Out of 202 samples total 109 were confirmed to be E. coli positive. Out of them total 27 (24.77 %) E. coli isolates were detected to be positive for STEC. Higher prevalence of STEC was observed in unorganized sector compared to the organized sector. Positive association (P < 0.05) was observed between STEC and ESBL production. This study indicates that the duck may play an important role in transmission of Siga-toxin-producing E. coli (STEC) as well as antibiotic resistance genes to human beings, other birds, animals and the environment.

Key words: E.coli, STEC, ESBL, Duck.

Citation:

Banerjee, A., & Acharyya, S. (2020). Molecular characterization of STEC isolated from Ducks and its relation to ESBL production. Ukrainian Journal of Veterinary and Agricultural Sciences, 3(2), 24-29.

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1. Introduction

Shiga toxin producing E. coli (STEC) also known as Vero toxin producing E. coli are food borne pathogens associated with different types of human infection ranging from bloody diarrhea to life threatening infection such as hemolytic uremic syndrome (HUS), thrombotic thrombocytopenic purpurea (TTP), haemorrhagic colitis (HC) etc. (Paton & Paton, 1998a; Jamshidi et al., 2016). The ability of STEC to cause human infection is due to production of Shiga toxins which inhibit protein synthesis of the host cell leading to cell death (Karmali et al., 2010). These toxins are subdivided into two major groups: Shiga toxin 1 (stx1) and Shiga toxin 2 (stx2). Lysogenic bacteriophages are responsible for production of E. coli Shiga toxin encoded by stxl and stx2 gene (O'Brien et al., 1984). The eaeA gene is responsible for the production of "intimin" protein, helps in intimate adhesion of bacteria to the enterocytes and production of attaching and effacing (AE) lesion (Paton & Paton, 1998a). Some of the STEC strain also exhibit haemolysis in washed sheep

blood agar due to production of enterohaemolysin encoded by ehxA gene (Beutin et al., 1993). There are several reports of prevalence and characterization of STEC in domestic and wild ruminants (Wani et al., 2004; Mahanty et al., 2013; Mahanty et al., 2014) and from poultry avian species including pigeon (Farooq et al., 2009). A few reports of antibiotic resistance in STEC are available (Shroeder et al., 2002). Extended spectrum beta-lactamase (ESBL) producing E. coli shows resistance against higher generation of cepha-losporin and monobactum. Now a day ESBL producing organisms are becoming a major threat for human beings and animals as well. There are three major classes of ESBL viz. TEM, SHV and CTX-M encoded by blaTEM, blaSHv and blacTx-M genes respectively (Geser et al., 2012). Production of ACBL mediated by blaAmpc gene is also another major threat. It becomes difficult when there is association between STEC and ESBL production. Treatment for STEC infection with antibiotics also increases the chances of in vivo production of Shiga toxin (Paton & Paton, 1998a). E coli O:157, H:7 serotype is well known for its numerous

outbreaks in human (Karch et al., 2005) and animals (Osek et al., 2002; Keen et al., 2006). Several other serogroups of STEC (O26, O91, 0103, 0104, O111, O113, O121, O123 and O145) have also been isolated from several outbreaks of human disease in different countries (Hussein, 2007; Espié et al., 2008; King et al., 2009). However, to the author's best knowledge, there is no such data available from India regarding isolation of STEC from duck (organized and unorganized sector), their comparison and relation to ESBL production. India has 2nd largest duck population next to China. According to the 19th Livestock Census India has 32.76 million duck population out of which about 1/3 rd of total duck population belongs to West Bengal. So a need of systemic study on sector wise, zone wise prevalence of STEC, their serotype and relation to ESBL production from duck of West Bengal, India was felt.

2. Materials and methods

Samples

In this study, total 202 (n = 202, single sample/duck) cloacal samples were collected from both Indigenous ducks reared in backyard (110 samples) and Khaki Campbell ducks reared in organized farms (92 samples). These samples were collected on random basis from different districts of West Bengal, India.

The collection area included farms of North 24 Parganas district, Belgachia of Kolkata district, Nabadwip and Kal-yani block of Nadia district (New Alluvial zone); Jangipara block of Hooghly district, Raina - I block of Purba Burdwan district and Jagatballavpur block of Howrah district (Old Alluvial zone) and Bankura - I block of Bankura district (Red Laterite zone). Among them samples of Khaki Campbell ducks were collected from organized duck farms of North 24 Parganas district and Kalyani block, Nadia district; whereas samples of Indigenous (Desi) ducks were collected from rest of the places.

The cloacal samples were collected aseptically with sterile cotton swabs (HiMedia, India). After collection, the swabs were kept in a sterile sample collecting vial containing peptone water as a media for transport. All the collected samples with proper label were placed on ice in a thermo flask and were brought to the laboratory for further processing.

Reference Strains

Extended spectrum p-lactamase producing Escherichia coli and STEC strains used in this research work as positive control were supplied by the Department of Veterinary Microbiology, West Bengal University of Animal and Fishery Sciences, Kolkata.

Isolation & Identification of Escherichia coli from collected cloacal samples

The collected samples were incubated in peptone water at 37 °C for overnight. After that it was streaked on Mac-Conkey's agar plates (HiMedia, India) and incubated at 37 °C for overnight for isolation of E coli. After incubation, rose pink colonies were selected and sub cultured on EMB agar (HiMedia, India) and incubated overnight at 37°C. Next day colonies with metallic sheen were identified and single colony was preserved on nutrient agar (HiMedia, India) slant for further morphological and biochemical confirmation.

All the isolates preserved on nutrient agar slants were stained by Gram's staining procedure and examined microscopically. The characters considered for morphological identification were Gram positive/ Gram negative, shape, size and arrangement of the organisms. Biochemical identification of the isolates was performed as per methods described by (Quinn et al., 1994) with modifications as per media/ reagent manufacturer's recommendations.

PCR based confirmation of Escherichia coli.

For PCR based confirmation of E. coli, DNA was extracted from all the morphological and biochemically confirmed isolates. The isolates were subjected to PCR for molecular confirmation as described by Wang et al. (1996) and Jamshidi et al. (2016) with some modifications and the amplified product was visualized by gel documentation system (UVP, UK) after electrophoresis in 2 % (w/v) agarose (SRL, India) gel containing ethidium bromide (0.5^g/ml) (SRL, India).

PCR based detection for STEC

All the E. coli isolates were subjected to multiplex PCR for detection of stxl, stx2, eaeA, ehxA genes as described by Paton & Paton, (1998b) with some modification. 5^l DNA templetes, 0.5 ^M each primers, 200 mM deoxynuceoside triphosphate, 1U of Taq DNA polymerase (Promega, USA), 2 mM MgC12 was added in a 25 ^l reaction mixture and subjected to two regime of PCR amplification . First regime consisted of 15 cycles. Each cycle consisted of 95 °C for 1min, 65 °C for 2 min and 72 °C for 1 min 30 sec. Second regime consisted of 20 cycles of 95 °C for 2 min, 60 °C for 2min, 72 °C for 2 mins. This was followed by final extension of 5 min at 72 °C. The amplified product was visualized by gel documentation system (UVP, UK) after electro-phoresis in 1.5 % (w/v) agarose (SRL, India) gel containing ethidium bromide (0.5 ^g/ml) (SRL, India). The primers and the annealing temperature and predicted length of PCR amplification product are listed in Table 1.

Serogrouping of STEC isolates

STEC producing E. coli were sent for Serogrouping to National Salmonella and Escherichia Centre, HP, India.

Double disc diffusion test

All the STEC producing E. coli isolates were subjected to screening for extended spectrum beta lactamase production by antibiotic sensitivity test containing cefotaxime (30 ^g, HiMedia, India) and ceftazidime (30 ^g, HiMedia, India) antibiotic discs with or without clavulanate (10 ^g, HiMedia, India) (CLSI, 2014). A difference of >5 mm between the zone diameters of either of the cephalosporin discs and their respective Cephalosporin/clavulanate discs was considered to be phenotypically positive for ESBL production. Further, cefoxitin-cloxacillin double disc synergy (CC-DDS) was performed for phenotypic confirmation of ACBL production (Tan et al., 2009).

Molecular detection of ESBL and ACBL genes

All the Physically detected ESBL producing STEC isolates were subjected to PCR for detection of blaTEM genes (Weill et al., 2004), blaSHv genes (Cao et al., 2002), blaCTx-M genes (Weill et al., 2004) .

The PCR for detection of ACBL producing gene (й/ûAmpc gene) was performed as per the procedure described by Féria et al. (2002).

The PCR products were electrophoresed in 1.5 % (w/v) agarose (SRL, India) gel containing ethidium bromide (0.5

Table 1

List of primers

^g/ml) (SRL, India) and the gel was visualized in gel documentation system (UVP, UK) and photographed. The primers, corresponding annealing temperature and predicted length of PCR amplification products are listed in Table 1.

Sl. Target gene Primer sequence Annealing Product Reference

No. amplified (5'^3') temp. size (bp)

01

E. coli 16S rRNA

02 Ыйтям

03 Ыйзш

04 Ыйстх-м

05 ЫйЛтрС

06 stxl

07 stx2 0S eaeA 09 ehxA

F: GACCTCGGTTTAGTTCACAGA R: CACACGCTGACGCTGACCA R: TCATCGCACCGTCAAAGGAACC R: TTCACTCTGAAGTTTTCTTGTGTTC F: ATAAAATTCTTGAAGACGAAA R: GACAGTTACCAATGCTTAATC F: TTA TCT CCC TGT TAG CCA CC R: GAT TTG CTG ATT TCG CTC GG F: CAATGTGCAGCACCAAGTAA R: CGCGATATATCGTTGGTGGTTGGTG F: CCCCGCTTATAGAGCAACAA R: TCAATGGTCGACTTCACACC F: ATAAATCGCCATTCGTTGACTAC R: AGAACGCCCACTGAGATCATC F: GGCACTGTCTGAAACTGCTCC R: TCGCCAGTTATCTGACATTCTG F: GACCCGGCACAAGCATAAGC R: CCACCTGCAGCAACAAGAGG F: GCATCATCAAGCGTACGTTCC R: AATGAGCCAAGCTGGTTAAGCT

5S °C

53 °C

52 °C

53 °C 60 °C

65 °C in first regime and 60 °C in second regime

5S5

10S0 792 540 634 1S0 255 3S4 534

Wang et al. (1996)

Weill et al. (2004) Cao et al. (2002) Weill et al. (2004) Féria et al. (2002)

Paton & Paton (199S)

3. Results and discussion

Results

From 202 duck cloacal swab samples total 109 E. coli isolates were identified, 61 were isolated from unorganized sector farm samples and 48 were obtained from organized sector farm samples (Table 2). Out of 109 E. coli isolates, 27 (24.77 %) isolates were found to be positive for STEC bearing gene. Among them 02 (7.4 %) samples were found to be positive for all stxl, stx2 and eaeA; 02 (7.4 %) samples were found to be positive for both stxl & stx2; 17 (62.96 %) samples were detected positive for stxl only; 04 (14.81 %) samples were found to be positive for stx2 only and 02 (7.4 %) samples were found to be positive for eaeA only. However no sample was found to be positive for ehxA (Figure 1).

In zone wise as well as sector wise analysis 13 (27.08%) isolates were detected from New Alluvial zone of West Bengal, India and organized sector. In case of unorganized sector and Old Alluvial zone of West Bengal, India 14 (22.95%) isolates were found to be positive for STEC. So, slightly higher prevalence of STEC was observed in organized sector compared to the unorganized sector (Table 2).

Out of 27 STEC isolates 25 (92.59%) were found to be positive for ESBL /ACBL production (Table 3). So, positive association between ESBL/ACBL producing genes and Shiga toxin producing genes was observed. Total 15 (60%)

STEC isolates were found to be positive for either one or more than one of the blacrx-u, blamu, blasnv and blaAmpc genes. Total 25 STEC isolates were detected to be positive for ACBL production.

STEC

25

stxl stx2 eaeA ehx.4

■ STEC

Fig. 1. Distribution of Shiga toxin genes in STEC positive isolates

The serotyping report of these STEC isolates reveled 11 different serogroup (O119, O83, O84, O5, O2, O8, O 88, O 157, O 35, O 128, O 119) and 11 isolates were untypeable (Table 3).

Table 2

Virulence genes of Escherichia coli (Zone and Sector wise)

Source Zone wise Sector wise PCR ASSAY FOR STEC

Sample no. stxl stx2 eaeA ehxA

GD 1 E + - - -

GD 2E + - - -

North 24 New Organized GD 4E + - - -

parganas Alluvial (Khaki GD 5 E + - - -

zone Campbell) GD 8E + - - -

GD 9E + + + -

GD 12 E + - - -

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GD 16E + - - -

GD 25 E + - - -

GD 31E + - - -

Nadia (Kalyani) KE35/4 + - - -

KE35/9 + - -

KE35/10 + - - -

Total 13 13 12 02 01 00

Hooghly

Burdwan

Old Alluvial zone

Unorganized (Desi)

HE2

HE3

HE6

HE7

HE8

HE9

HE10

HE12

BE1

BE2

BE5

BE18

+ + + + + +

+ + +

Howrah HWE 22 HWE 29 - - + + -

Total 14 14 09 06 03 00

Grand Total 27 21 08 04 00

Table 3

Serogroup of the STEC isolates along with corresponding ESBL/ACBL genes

STEC Isolate No. Serogroup Genotype for STEC associated genes Genotype for ESBL/ACBL associated genes

GD1E O119 stxl blaAmpC

GD2E O83 stxl blaAmpC

GD4E O84 stxl blacTX-M & blaAmpC

GD5E UT stxl blacTX-M & blaAmpC

GD8E O5 stxl blaTEM & blaAmpC

GD9E O2 stxl, stx2 & eaeA blaAmpC

GD12E O83 stxl blaAmpC

GD16E O2 stxl blaAmpC

GD 25E O2 stxl blaCTX-M & blaAmpC

GD 31E O83 stxl blaAmpC

KE 35/4 O8 stxl --

KE 35/9 UT stx2 blaTEM

KE 35/10 UT stxl --

HE2 UT stxl blaTEM & blaAmpC

HE 3 UT stxl blaTEM,, blaCTX-M, blasHV & blaAmpC

HE6 O88 stxl blaTEM,, blaCTX-M & blaAmpC

HE7 UT stxl blaTEM,, blaCTX-M, blasHV & blaAmpC

HE8 O35 stxl blaTEM,, blaCTX-M, blasHV & blaAmpC

HE9 O 157 stxl & stx2 blaTEM & blaAmpC

HE 10 O128 stxl & stx2 blaTEM,, blaCTX-M, blasHV & blaAmpC

HE 12 UT stx2 blaTEM,, blaCTX-M, blasHV & blaAmpC

BE1 O119 stx2 blaTEM,, blaCTX-M & blaAmpC

BE2 O 83 stx2 blaAmpC

BE 5 UT stxl blaAmpC

BE 18 UT stxl, stx2 & eaeA blaAmpC

HWE22 UT eaeA blaAmpC

HWE29 O83 eaeA blaTEM & blaAmpC

Discussion

Ducks have free access to land and water bodies, screening duck samples can give an idea about the distribution pattern of STEC in both land & water and the antibiotic resistance genes carried by those organisms; very little of which was known so far.

In the present study a total of 202 duck cloacal swab samples were collected from different agro-climatic zones of West Bengal to minimize sampling error, out of which 110 samples were collected from backyard ducks kept by small and marginal farmers while 92 samples were collected from organized farms and each of the samples were screened individually. Successful isolation of E. coli from about 54 % (109 out of 202) of total duck samples containing about 55 % (61 out of 110) from backyard unorganized sectors and about 52 % (48 out of 92) from organized sector farms; invariably represent the ubiquitous prevalence of this organisms in their respective habitat.

STEC were identified on the basis of presence of four set of genes viz. stxl, stx2, eaeA and ehxA considered to be specific for production of four major Shiga toxin components stx1, stx2, eaeA and ehxA. Out of 109 E. coli isolates 27 isolates could be identified through PCR for carriage of one or more of the above mentioned genes. The result showed that about 25 % (27 out of 109) of the isolates were positive for one or more components of Shiga toxin producing gene. A similar study from Srinagar, India by Farooq et al. (2009) reported only 4.24 % STEC isolates. However, the present study revealed a much higher percentage i.e. about 25 % of STEC isolated which may be attributed to wide geographical distance between the places from where samples were collected. It was quite fascinating to see that organized farms contained slightly less STEC carriers compared to unorganized farms (13 and 14 STEC positive respectively) which may be due to common sharing of water bodied by the unorganized sector ducks with other animals and human beings.

So far the carriage of different genes responsible for production of Shiga toxin components by STEC isolates were concerned; 7.4 % (2 out of 109) isolates were found to be positive for three major genes viz. stxl, stx2 and eaeA; 7.4 % (2 out of 109) isolates were found to be positive for both stxl & stx2; 62.96 % (17 out of 27) isolates were detected positive for stxl only; 14.81 % (04 out of 27) isolates were found to be positive for stx2 only and 7.4 % (2 out of 109) isolates were found to be positive for eaeA only. No isolate was positive for presence of ehxA. The result also varied with great extent to a similar study previously made by Wani et al. (2004) from Srinagar, India; carried on assorted samples from chicken and pigeon where they did not report any stxl or stx2 positive isolate. Again the previously mentioned study of Farooq et al. (2009) on assorted samples collected from pigeon, duck and chicken indicated the presence of stxl, stx2 and eaeA genes among STEC isolates. The difference of present results compared to their findings may be attributed to the considerable differences in size and geographical origin as well as heterogeneous nature of the samples incorporated in their experiment.

Out of 27 STEC isolates 25 (92.59 %) were found to be positive for ESBL /ACBL production. Significantly higher association (P < 0.05) was observed by statistical analysis (chi-square test) between ESBL/ACBL producing genes and Shiga toxin producing genes. Total 15 (60 %) STEC isolates were found to be positive for either one or more than one of

the blacTx-M, blaTEM, blaSnv and blaAmpc genes. Total 25 STEC isolates were detected to be positive for ACBL production. Present findings could not be compared as no data of similar nature was apparently available from India from available literatures during the period of this study.

The serotyping report of these STEC isolates reveled 11 different serogroup (0119, 083, 084, 05, 02, 08, O 88, O 157, 0 35, 0 128, 0 119) and 11 isolates were untypeable as mentioned previously. The results also varied with the findings of Wani et al. (2004) from Srinagar, India possibly due to dissimilarities in origin of samples in terms of both the species of origin (pigeon and chicken) and geographical location.

4. Conclusions

These results show that, the ducks are not only the important sources of ESBL & ACBL producing E. coli but they are also potential carriers of STEC harboring ESBL & ACBL genes. Total 92.5 % STEC were found to be positive for ESBL/ACBL production. These STEC may be transmitted to human beings & other animals through environmental contamination i.e. contamination of land and water bodies with duck fecal droppings or through direct consumption of eggs and meat of ducks soiled with duck feces.

Acknowledgments

The authors sincerely acknowledge the Department of Microbiology, West Bengal University of Animal & Fishery Sciences, 37 K.B. Sarani, Kolkata 700037, West Bengal, India for the kind guidance, funding and entire laboratory facilities for this experimental work.

Conflict of interest

The authors declare that there is no conflict of interest. References

Beutin, L., Geier, D., Steinrück, H., Zimmermann, S., & Scheutz, F. (1993). Prevalence and some properties of verotoxin (Shiga-like toxin)-producing Escherichia coli in seven different species of healthy domestic animals. J. Clin. Microbiol., 31(9), 2483-2488. doi: 10.1128/JCM.31.9.2483-2488.1993. Cao, V., Lambert, T., Nhu, D. Q., Loan, H. K., Hoang, N. K., Arlet, G., & Courvalin, P. (2002). Distribution of extended-spectrum P-lactamases in clinical isolates of Enterobacteriaceae in Vietnam. Antimicro. Agents Chem., 46(12), 3739-3743. doi: 10.1128/AAC.46.12.3739-3743.2002. Clinical and Laboratory Standards Institute (2014). Performance standards for antimicrobial susceptibility testing: Twenty-fourth informational supplement, CLSI Document M100-S24. ISBN: 1562388975. Espié, E., Grimont, F., Mariani-Kurkdjian, P., Bouvet, P., Haeghe-baert, S., Filliol, I., Loirat, C., Decludt, B., Minh, N. N. T., Vaillant, V., & de Valk, H. (2008). Surveillance of hemolytic uremic syndrome in children less than 15 years of age, a system to monitor 0157 and non-0157 Shiga toxin-producing Escherichia coli infections in France, 1996-2006. The Ped. Inf. Dis. J., 27(7), 595-601. doi: 10.1097/INF.0b013e31816a062f. Farooq, S., Hussain, I., Mir, M. A., Bhat, M. A., & Wani, S. A. (2009). Isolation of atypical enteropathogenic Escherichia coli and Shiga toxin 1 and 2f-producing Escherichia coli from avian species in India. L. Appl. Microbiol., 48(6), 692-697. doi: 10.1111/j.1472-765X.2009.02594.x. Féria, C., Ferreira, E., Correia, J. D., Gonjalves, J., & Canija, M. (2002). Patterns and mechanisms of resistance to P-lactams and P-lactamase inhibitors in uropathogenic Escherichia coli isolat-

ed from dogs in Portugal. J. Antimicrobial Chem, 49(1), 7785. doi: 10.1093/jac/49.1.7.

Geser, N., Stephan, R., & Hächler, H. (2012). Occurrence and characteristics of extended-spectrum ß-lactamase (ESBL) producing Enterobacteriaceae in food producing animals, minced meat and raw milk. BMC Vet. Res, 8(1), 21. doi: 10.1186/1746-6148-8-21.

Jamshidi, A., Razmyar, J., & Fallah, N. (2016). Detection of eaeA, hlyA, stx1 and stx2 genes in pathogenic Escherichia coli isolated from broilers affected with colibacillosis. Iranian J. Vet. Med., 10(2), 97-103. https://www.sid.ir/en/journal/ViewPaper. aspx?id=507695.

Hussein, H. S. (2007). Prevalence and pathogenicity of Shiga toxin-producing Escherichia coli in beef cattle and their products. J. Ani. Sc., 85(Suppl 13), E63-E72. doi: 10.2527/jas.2006-421.

Karch, H., Tarr, P. I., & Bielaszewska, M. (2005). Enterohaemor-rhagic Escherichia coli in human medicine. Int. J. Med. Microbiol, 295(6-7), 405-418. doi: 10.1016/j.ijmm.2005.06.009.

Karmali, M. A., Gannon, V., & Sargeant, J. M. (2010). Verocyto-toxin-producing Escherichia coli (VTEC). Vet. Microbiol, 140(3-4), 360-370. doi: 10.1016/j.vetmic.2009.04.011.

Keen, J. E., Wittum, T. E., Dunn, J. R., Bono, J. L., & Durso, L. M. (2006). Shiga-toxigenic Escherichia coli O157 in agricultural fair livestock, United States. Emerging Inf. Dis., 12(5), 780. doi: 10.3201%2Feid1205.050984.

King, L. A., Filliol-Toutain, I., Mariani-Kurkidjian, P., Vaillant, V., Vernozy-Rozand, C., Ganet, S., Pihier, N., Niaudet, P., & de Valk, H. (2010). Family outbreak of Shiga toxin-producing Escherichia coli O123: H-, France, 2009. Emerging Inf. Dis., 16(9), 1491. doi: 10.3201/eid1609.100472. '

Mahanti, A., Samanta, I., Bandopaddhay, S., Joardar, S. N., Dutta, T. K., Batabyal, S., Sar, T. K. & Isore, D. P. (2013). Isolation, molecular characterization and antibiotic resistance of Shiga Toxin-Producing Escherichia coli (STEC) from buffalo in India. Letters in Appl. Microbiol, 56(4), 291-298. doi: 10.1111/lam.12048.

Mahanti, A., Samanta, I., Bandyopadhyay, S., Joardar, S. N., Dutta, T. K., & Sar, T. K. (2014). Isolation, molecular characterization and antibiotic resistance of Enterotoxigenic E. coli (ETEC) and Necrotoxigenic E. coli (NTEC) from healthy water buffalo. Vet. Arhiv., 84(3), 241-250. doi: 10.1111/lam.12048.

O'Brien, A. D., Newland, J. W., Miller, S. F., Holmes, R. K., Smith, H. W., & Formal, S. B. (1984). Shiga-like toxin-converting phages from Escherichia coli strains that cause hemorrhagic colitis or infantile diarrhea. Science., 226(4675), 694-696. doi: 10.1126/science.6387911.

Osek, J. & Gallien, P. (2002). Molecular analysis of Escherichia coli O157 strains isolated from cattle and pigs by the use of PCR and pulsed-field gel electrophoresis methods. Vet. Medic-ina-Praha., 47(6), 149-158. doi: 10.17221/5819-VETMED.

Paton, J. C. & Paton, A. W. (1998a). Pathogenesis and diagnosis of Shiga toxin-producing Escherichia coli infections. Clinical microbiology reviews, 11(3), 450-479. doi: 10.1128/CMR.11.3.450.

Paton, A. W. & Paton, J. C. (1998b). Detection and Characterization of Shiga Toxigenic Escherichia coli by Using Multiplex PCR Assays for stx 1, stx 2, eaeA, Enterohemorrhagic E. coli hlyA, rfb O111, and fb O157. J. Clin. Microbiol, 36(2), 598602. https://www.ncbi.nlm.nih.gov/pubmed/9466788.

Quinn, P. J., Carter, M. E., Markey, B., & Carter, G. R. (1994). Vet. Clin. Microbiol. Wolfe Publication, London, UK. 254258. ISBN: 0723417113.

Schroeder, C. M., Meng, J., Zhao, S., DebRoy, C., Torcolini, J., Zhao, C., McDermott, P. F., Wagner, D. D., Walker, R. D. & White, D. G. (2002). Antimicrobial resistance of Escherichia coli O26, 0103, O111, O128, and O145 from animals and humans. Emerging Inf. Dis., 8(12), 1409. doi: 10.3201%2Feid0812.020770. '

Tan, T.Y., Ng, L.S.Y., He, J., Koh, T.H., & Hsu, L.Y. (2009). Evaluation of screening methods to detect plasmid-mediated AmpC in Escherichia coli, Klebsiella pneumoniae, and Proteus mirabilis. Antimicrob. Agents Chemother, 53, 146-149. doi: 10.1128/AAC.00862-08.

Wani, S. A., Samanta, I., Bhat, M. A., & Nishikawa, Y. (2004). Investigation of shiga toxin producing Escherichia coli in avian species in India. Letters in Appl. Microbiol., 39(5), 389-394. doi: 10.1111/j.1472-765X.2004.01586.x.

Weill, F. X., Lailler, R., Praud, K., Kerouanton, A., Fabre, L., Brisabois, A., Grimont, P. A. D., & Cloeckaert, A. (2004). Emergence of extended-spectrum-ß-lactamase (CTX-M-9)-producing multiresistant strains of Salmonella enterica serotype Virchow in poultry and humans in France. J. Clin. Microbiol., 42(12), 5767-5773. doi: 10.1128/JCM.42.12.5767-5773.2004.

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