SEROTYPES AND VIRULENCE PROFILES OF NON-O157 SHIGA TOXIN PRODUCING E. COLI ISOLATED FROM BEEF, CHICKEN MEAT AND ITS PRODUCTS

Document Type : Research article

Author

Department of Food Hygiene and Control, Faculty of Veterinary Medicine, University of Sadat City, Egypt.

Abstract

This study was conducted on 300 samples (150 beef and 150 chicken meat) collected from Menofia, Cairo and El-Kalyobia governorates for detection of STEC. STEC were isolated from beef and chicken meat on Trypticase Soya Broth and Sorbitol MacConkey agar supplemented with cefixime and tellurite supplements and were biochemically identified. Further identifications were performed including Vero cells cytotoxicity assay and PCR technique for specific VT1/VT2 and eae genes. Vero cells cytotoxicity assay was performed on 130 suspected colonies obtained from 300 samples collected from raw meat and meat products (150) and raw chicken and products (150) revealed that 56 of E. coli isolates were STEC. By PCR, 56 (100%) of the 56 strains were confirmed to be STEC. In comparison to Vero cells cytotoxicity, the sensitivity of PCR were 100%. The most common serogroups of STEC in samples were O111, O26, O103, O119, O128, O86, O45, O146, O119 and O121. E.coli O111, O26, O103, O91, O86 and O119 that proved to have Stx1 and Stx2 genes. E.coli O128 and O121 had only Stx1, while E.coli O146 had only Stx2.Concerning the eae gene responsible for the attaching and effacing lesions, E. coli O111 and O26 isolates proved to possess such gene. In conclusion raw beef, raw chicken and products constitute an important reservoir of STEC infection to man and it was declared that PCR technique is the most rapid, sensitive and efficient approach for detection of STEC in beef and chicken products.

Keywords


SEROTYPES AND VIRULENCE PROFILES OF NON-O157 SHIGA TOXIN PRODUCING  E. COLI ISOLATED FROM BEEF, CHICKEN MEAT AND ITS PRODUCTS

 

REYAD SHAWISH

Department of Food Hygiene and Control, Faculty of Veterinary Medicine, University of Sadat City, Egypt.

 

Email: reyad.rabea@vet.usc.edu.eg                                                                        Assiut University web-site: www.aun.edu.eg

 

 

 

ABSTRACT

 

 

Received at: 13/10/2015

 

 

Accepted: 31/10/2015

 

This study was conducted on 300 samples (150 beef and 150 chicken meat) collected from Menofia, Cairo and El-Kalyobia governorates for detection of STEC. STEC were isolated from beef and chicken meat on Trypticase Soya Broth and Sorbitol MacConkey agar supplemented with cefixime and tellurite supplements and were biochemically identified. Further identifications were performed including Vero cells cytotoxicity assay and PCR technique for specific VT1/VT2 and eae genes. Vero cells cytotoxicity assay was performed on 130 suspected colonies obtained from 300 samples collected from raw meat and meat products (150) and raw chicken and products (150) revealed that 56 of E. coli isolates were STEC. By PCR, 56 (100%) of the 56 strains were confirmed to be STEC. In comparison to Vero cells cytotoxicity, the sensitivity of PCR were 100%. The most common serogroups of STEC in samples were O111, O26, O103, O119, O128, O86, O45, O146, O119 and O121. E.coli O111, O26, O103, O91, O86 and O119 that proved to have Stx1 and Stx2 genes. E.coli O128 and O121 had only Stx1, while E.coli O146 had only Stx2.Concerning the eae gene responsible for the attaching and effacing lesions, E. coli O111 and O26 isolates proved to possess such gene. In conclusion raw beef, raw chicken and products constitute an important reservoir of STEC infection to man and it was declared that PCR technique is the most rapid, sensitive and efficient approach for detection of STEC in beef and chicken products.

 

 

Key words: STEC; Serovars; Genotypes; meat and products

 

 


INTRODUCTION

 

Pathogenic E. coli have been broadly classified into two major categories; the diarrheagenic E. coli and the extraintestinal pathogenic E. coli. Among the diarrheagenic E. coli, there are currently six categories including enteropathogenic E. coli (EPEC), enterotoxigenic E. coli (ETEC),enteroinvasive E. coli (EIEC), enteroaggregative E. coli (EAEC), diffusivelyadherent E. coli (DAEC) and enterohemorrhagic E. coli (EHEC)/Shiga toxin-producing E. coli (STEC) Xiaodong. (2010).

 

 Shiga toxin–producing E. coli (STEC), also known as verotoxin-producing E. coli (VTEC) or enterohaemorrhagic E. coli (EHEC), have been known as a group of highly pathogenic E.coli strains producing one or more Shiga toxins (Monaghan et al., 2011). The term verocytoxin producing E. coli was derived from observation of strains producing a toxin with a profound and irreversible cytopathic effect on Vero cells "African green monkey kidney" (Konowalchuk et al., 1977).

 

STEC represent a hazardous public health problem worldwide causing various human gastrointestinal tract diseases, including watery or bloody diarrhea and might develop a life-threatening diseases, such as hemorrhagic colitis (HC), Thrombotic Thrombocytopenic Purpura (TTP) and Haemolytic Uraemic Syndrome (HUS). The later is characterized by thrombocytopenia, microangiopathic haemolytic anaemia and acute renal failure (Pennington, 2010).

 

STEC strains produce two powerful phage-encoded cytotoxins causing tissue damage in humans and animals, called Shiga toxins or verotoxins (Stx1/VT1 and Stx2/VT2), which are the common feature and main virulence factors of STEC and are directly correlated with human pathogenicity (Lindgren et al., 1993). Stx2 is the most powerful toxin, and the toxin producing strains are usually associated with more severe infections (Muniesa et al., 2004 and Gyles, 2007). In addition, some STEC strains can tightly attach and form attaching and effacing lesions to intestinal epithelial cells through an adhesin called intimin, which is encoded by the eae gene.

 

The aim of the present study was to determine the occurrence, serovars and virulence gene profile of STEC isolated from raw beef, beef products, raw chicken and chicken products samples collected at the retail level in Egypt.

 

MATERIALS and METHODS

 

Isolation of STEC from meat and chicken meat samples:

This study included 300 random locally raw beef (50), 100 produced beef product samples (raw kofta, beef burger, fresh sausage and beef luncheon), raw chicken (50) and 100 produced chicken product samples (chicken burger, chicken sausage and chicken luncheon) were collected from different super markets at Menofia, Cairo and El-Kalyobia governorates, Egypt in clean sterile containers and transported with a minimum of delay to the laboratory.

 

25 g of each beef product was added into 225 ml of Tryptic Soy Broth and incubated overnight at 37 oC. Subculture was done from Tryptic Soya broth on Sorbitol MacConkey Agar (SMAC) with cefixime and tellurite to obtain the suspected colonies of the concerned bacteria. The obtained colonies were prepared for VCA to detect STEC. Positive samples were confirmed to be STEC by PCR reaction to determine the type of Stx and serotyping. (Konowalchuk et al., 1977).

 

Vero cell assay of the suspected E. coli strains

The cytotoxicity of the suspected E. coli isolates for vero cells was determined by using tissue culture supernatant and thereby detecting only high level of production of these cytotoxins based onKonowalchuk et al. (1977).

 

This test was carried out in 96 well tissue culture plates. 90µL of sterile physiological saline was added to each of the test wells, while 50µL of the physiological saline was added to the negative control wells. 60 µL of the bacterial lysates was added to each well. 50µL of RPMI medium containing 10% calf serum, 2mM L-glutamin, 100 U penicillin/ml and 100 µg streptomycin /ml were added to each one of the test wells.A suspension of vero cells was prepared and 50 µL of this suspension was seeded in each well of the test wells. 50 µL of 1% SDS solution was added to each of the positive control wells. The plates were incubated at 37oC in 5% CO2 atmosphere, observed daily by using inverted microscope for detection of cell lysis and vacuolation.

 

Serotyping E. coli isolates

The isolates were serologically identified according to Kok et al. (1996) by using rapid diagnostic E.coli antisera sets (DENKA SEIKEN Co., Japan) for detection of the Shiga toxin-producing Escherichia coli serovars.

 

Detection of Stx1, Stx2 and eae genes of STEC isolated from samples using Multiplex PCR:

The multiplex PCR was performed as described by Paton and Paton, 1998 at the laboratory of infectious diseases and Internal medicine, faculty of Veterinary Medicine, University of Sadat City, Egypt.

 

Genomic DNA extraction: Chromosomal DNA was isolated from STEC isolates using

Gene JET Genomic DNA Purification Kit   (Fermentas)

 

DNA amplification for Multiplex PCR reaction.

20 ng of chromosomal DNA was used per reaction, where amplifications were performed in 25ul of buffer solution containing 3uM of oligonucleotides, 200uM of each deoxynucleoside triphosphate, 3.5 mM MgCl2 and 2.5U of DNA Taq polymerase. Mixtures were overlaid with mineral oil and amplification was performed in PCR thermal cycler. Samples were subjected to 35 PCR cycles, each consisting of 1 min of denaturation at95°C; 2 min of annealing at 65°C for the first 10 cycles, decrementing to 60°C by cycle 15; and 1.5 min of elongation at 72°C, incrementing to 2.5 min from cycles 25 to 35. Amplified DNA fragments were resolved by gel electrophoresis (Sambrook et al., 1989) using 2 % (w/v) agarose. Gels were stained with 0.5 mg of ethidium bromide per ml for 15 min, and documented with a UVP documentation system.

 

 

Table 1: Primer sequence of shiga toxin producing E.coli.

 

Gene

Primer sequence

Predicted size

Reference

Stx1

5'- ATAAATCGCCATTCGTTGACTAC -3'

5'- AGAACGCCCACTGAGATCATC - 3'

180 bp

Paton and Paton (1998)

Stx2

5'- GGCACTGTCTGAAACTGCTCC -3'

5'- TCGCCAGTTATCTGACATTCTG -3'

255 bp

Paton and Paton (1998)

eae

5 ' GCATCACAAGCGTACGTTCC 3 '

5' CCACCTGCAGCAACAAGAGG 3'

384 bp

Paton and Paton (1998)

RESULTS

 

Table 2: Comparison of the results of cultivation on SMAC medium with VCA and multiplex polymerase chain reaction (PCR) for detection of STEC in raw beef, beef products, raw chicken and chicken products.

 

Samples

No. of examined samples

No. of +ve colonies   on SMA medium

No. of samples +ve VCA.

No. of samples tested by PCR and were +ve VCA.

Raw beef

50

29

15 (51.72 %)

15 (100 %)

Beef products

100

44

18 (40.90%)

18 (100 %)

Raw chicken

50

22

10 (45.45%)

10 (100 %)

Chicken products

100

35

13 (37.14%)

13 (100 %)

Total

300

130

56 (42.08%)

56 (100 %)

 

Table 3: Incidence of Shiga toxin producing E. coli (STEC) serovars isolated from examined meat and its products samples.

 

E.coli Serovars

Raw beef

Beef products

Raw chicken

Chicken products

O111

4

5

3

4

O26

3

3

1

2

O103

1

1

1

--

O91

--

2

--

2

O119

1

--

1

--

O128

2

2

1

2

O86

2

1

1

1

O146

1

1

--

1

O45

--

1

2

--

O121

1

2

--

2

 

Table 4: Occurrence of some virulence genes in serovars of Shiga toxin-producing E. coli (STEC) isolated from raw beef and beef products.

 

Serovars

No. of examined isolates

Stx1 alone

Stx2 alone

Stx1&Stx2

eae

NO.

%

NO.

%

No.

%

No.

%

O111

8

0.0

0.0

4

50

4

50

6

75

O26

4

4

100

4

100

4

100

0.0

0.0

O103

3

0.0

0.0

3

100

0.0

0.0

0.0

0.0

Other STEC

18

8

44.4

10

55.5

0.0

0.0

0.0

0.0

Total

33

12

36.6

21

63.6

8

24.3

6

18.2

 

Table 5: Occurrence of some virulence genes in serovars of Shiga toxin-producing E. coli (STEC) from raw chicken and chicken products.

 

Serovars

No. of examined isolates

Stx1 alone

Stx2 alone

Stx1&Stx2

eae

NO.

%

NO.

%

No.

%

No.

%

O111

6

6

100

6

100

6

100

3

50

O26

4

4

100

2

50

0.0

0.0

0.0

0.0

Other

13

4

30.7

9

69.2

0.0

0.0

0.0

0.0

Total

23

14

60.9

17

73.9

6

26.1

3

13.0

 

 

 

Photo 1: Cytotoxic effect of Shiga toxin containing bacterial lysate of STEC on Vero cells.

 

The Cytopathic effects of Shiga toxin containing bacterial lysate of STEC were observed after incubation with culture filtrates there was a change from spindle-shaped cells characteristic of normal Vero cells to round and shriveled cells, and these changes were followed by gradual destruction of the monolayer.

 

 

 

Figure 2: Agarose gel shows six positive strains of EHEC for shiga toxin 1 and shiga toxin 2 and eae genes. 180 bp, 255bp, 384 bp respectively isolated from beef.

Lane (M): MW marker = 100 bp DNA ladder (Promega).

Lane (1): Positive Control (E. coli O157H7 provided by Animal Health research Institute, Egypt).

Lane 2- O86 has stx2 genes

Lane 3- O121 has stx2 genes

Lane 4- O111 has the 3 genes stx1, stx2 and eae genes

Lane 5- O103 harbor stx1 and stx2genes

Lane 6- Negative Control.

 

                                   

 

Figure 3 Agarose gel shows six positive strains of EHEC for shiga toxin 1 and shiga toxin 2 and eae genes. 180 bp, 255bp, 384 bp respectively isolated from chicken.

Lane (M): MW marker = 100 bp DNA ladder (Promega).

Lane (1): Positive Control (E. coli O157H7 provided by Animal Health research Institute, Egypt).

Lane 2- O146 harbor stx2 genes

Lane 3- O91 harbor stx1 and stx2genes

Lane 4- O103 harbor stx1 and stx2genes

Lane 5- O45 has stx1 genes

Lane 6- negative control.

Lane 7- O86 has stx2 genes

 


DISCUSSION

 

Shiga toxin-producing E. coli (STEC) is a serious public health concern worldwide. This pathogen causes diarrhea, hemorrhagic colitis and hemolytic-uremic syndrome. Shiga toxin produced by STEC has been considered a prime virulence factor. Shiga toxins are classified into two groups, Stx1 and Stx2, on the basis of immunological properties. Though O157:H7 is the most predominant serovars isolated from sporadic cases and outbreaks, more than 100 serovars of non-O157 STEC have been isolated from animals and humans (Abd –EL-All, 2005). Since most of the food poisonings due to STEC are related to the consumption of beef or beef products, cattle have been considered a major reservoir of STEC. However, other vehicles, such as contaminated water, vegetables, and fruits, have been increasingly recognized as an infection source of STEC (Shima   et al., 2006).

 

The results recorded in Table (2) showed that from 300 meat samples collected from raw beef (50), 100 produced beef product samples, raw chicken (50) and 100 produced chicken product samples were collected from different super markets at Menofia, Cairo and El-Kalyobia governorate, 130 samples yielded positive culture SMAC-CT. Further identifications of the isolated colonies were performed by Vero cells cytotoxicity assay which revealed that 56 of E. coli isolates (42.08%) were verotoxin producing E. coli. The results obtained in this study agreed with Ramotar et al. (1995) who reported that SMAC was positive for only 30 % of verocytotoxin-positive samples. In comparison to Vero cells cytotoxicity, the sensitivity of PCR were 100 %. PCR test was compared with Vero cytotoxicity assay for a number of reasons. Firstly, the profound sensitivity of Vero cells to Stx which was first observed by Konowalchuk et al. (1977), Secondly, the cytotoxicity for this cellline remains the "gold standard" for confirmation of putativeSTX-producing isolates (Byomi, 1995). In comparison of PCR and Vero cells cytotoxicity 56 out of 56 (100 %) positive cases by PCR were also positive by Vero cells cytotoxicity. The usefulness of PCR requires no emphasis as a means for detection of shiga toxins encoding genes from the DNA material extracted from meat and products. Interestingly, the results obtained in this study agreed with that of Ramotar et al. (1995) who  evaluated a method for rapid detection of verotoxin-producing E. coli in stool samples by PCR and detected 34 of 36 (94%) of  samples that were positive by colony blot and free verotoxin (FVT) that was performed by using vero cell monolayers. Similarly, Zaki and El-Adrosy (2007) reported that PCR is sensitive and fast method for detection of STEC.

 

The Cytotoxic effect of shiga toxin cotaining bacterial lysate on vero cells was illustrated in photo (1). In the present study vero cytotoxicity assays was used as screening test for STEC. The test was done only on samples that gave characteristic colonies on sorbitol monitol agar plates. Detection of STEC was done on basis of positive VCA. The positive samples were confirmed by serotyping using polyvalent and monovalent "O" Escherchia coli antisera. Further confirmation was done by using multiplex PCR reaction to determine the type of Stx.

 

Paton and Paton, (1998) stated that Vero cytotoxicity assay has played animportant role in establishing a diagnosis of STEC infection,particularly where subsequent isolation of the causative organismhas proven to be a difficult task. When testing such crude samples,the sensitivity is influenced by the abundance of STEC, the totalamount and potency of the STX produced by the organism concerned,and the degree to which the particular STX is released from thebacterial cells. PCR provide rapid and valuable diagnostic method while, detection of Stx by tissue culture cytotoxicity is labor-intensive, time-consuming,and cumbersome. Not all microbiology laboratories perform tissueculture work with Vero cell monolayers available on demand. Moreover,rapid diagnosis is important, and the results of cytotoxicitytesting are generally not available befor 48 to 72 hrs. (Paton and Paton, 1998). The current results agree, to some extent, with those recorded by Hussein & Bollinger (2005) and Hussein (2007) as they found non O157 STEC to be more prevalent in beef products than E. coli O157. The prevalence rates of non O157 STEC ranged from 2.4 to 30.0% in ground beef, from 17.0 to 49.2% in sausage. Testing other beef products revealed prevalence rates of 19.0% (Zhao et al., 2001) and 62.5% (Samadpour     et al., 1994).

 

However, (Smith and Scotland, 1988.) pointed out that the two examined samples were positive VCA and were confirmed to be non-STEC, Since the presence of cytoxicity in a crudefiltrate could be due to other bacterial products or toxins, positivesamples should always be confirmed and typed by testing forneutralization of cytotoxicity by specific preferably monoclonalantibodies to Stx1 or Stx2.Moreover, Abd-El-Latif (2003) detected two STEC which were positive for VCA while only one of them was positive to PCR.

 

Table (3) revealed that the serological identification of shiga-toxin producing E.coli isolated from the examined raw beef samples were O111, O26, O103, O119, O128, O86, O146 and O121, from beef products samples, the isolated serovars O111, O26, O91, O103 ,O86,O121,O128 O146 and O45.But the isolated serovars from raw chicken were O111, O26, O103, O119, O128, O86 and O45, while those from chicken products were O111, O26, O91, O128, O86, O121 and O146.

Fantelli and Stephan (2001) detected EHEC or STEC in 2.3% of minced meat samples, while Abd-El-Latif (2003) isolated EHEC from minced meat, burger and sausage in 16% of the samples.

 

Shiga toxin producing E. coli (STEC) organism of different serovars have been isolated from human and from apparently healthy domestic animals .Many of these isolates were typical STEC belonging to serovars O26, O111 and O157 (Karamali, 1989). Also, verotoxin producing E. coli (VTEC) non O157 serovars O26, O103, O111 are among the most important emergency food borne pathogen groups particularly O26 which able to cause large spectrum of illness in human as hemorrhagic colitis (HC) to hemolytic uremic syndrome (HUS) and thrombotic thrombocytopenic purpura (TTP) (Dambrosio et al., 2007).

 

Enterohaemorragic Escherichia coli (EHEC) constitutes a subset of STEC serovars including E.coli O157 and non - O157 serogroups like O26, O111, O103, and O145. STEC may be transmitted from animal reservoirs to human not only via ingestion of contaminated food or water but also by contact with STEC-positive animal or with their environment (Alfredo et al., 2005). 

 

Enterohaemorrhagic E.coli (EHEC) produces two types of illness, haemorrhagic colitis and hemolytic uraemic syndrome (HUS). Haemorrhagic colitis results from colonic mucosal oedema, errosion and haemorrhage. The incubation period is 3 to 4 days. The symptoms start by sudden pain followed by watery diarrhea, nausea and vomition in the early stages of illness and abdominal distension with severe pain after the onset, disease progress over 2 days to bloody diarrhea. Haemorrhagic colitis was primarily foodbrone and was associated most frequently with E. coli as recorded by Riley (1987), Bhong et al. (2008), Lee et al. (2009) and Xiaodong(2010).

 

Table [4&5] illustrates STEC isolated from meat product samples have virulence genes. The use of Multiplex PCR with specific primers for Stx1, Stx2 and eae genes revealed the presence or absence of these genes in the tested isolates. The obtained results showed that  the isolates E. coli O111, O26, O103, O91, O86 and O119 had Stx1 and Stx2 genes while, E.coli O128 and O121 had  only Stx1. E.coli O146 had  only Stx2.Concerning the eae gene responsible for the attaching and effacing lesions, E. coli O111 and  O26 isolates possessed this gene.

 

According to, Hornitzky et al. (2002); Jenkenis et al. (2002) and Bollinger (2004) stated that serotypes O111, O26, O103, O128, O121, O91, O86 and O119 are Shiga toxin-producing E. coli (STEC). All of  the STEC isolates produced 1, 2, 3 or 4 virulence factors (i.e. Stx1, Stx2, Stx1&stx2 or eae) and were lethal to Vero (African green monkey cells). Therefore, the potential public health risk of these isolates should not be ignored.

 

In Egypt, many studies have been reported the prevalence of E.coli O157 in meat or milk products (Sayed et al., 2001; Mohammed, 2002, and Abd-Ell-All, 2005) while, few studies have reported the prevalence of non-O157 (Byomi et al., 2001 and Abd-El-All, 2005).

 

Bettleheim (2000) reported that STEC serovars other than O157H7, such as O111, O103, O26, and O145 are emerging human pathogens predominantly in Europe, Australia, and South America.

 

On conclusion, the raw beef and Chicken meat and its products were contaminated with non-O157 shiga toxin producing E.coli. By using the PCR assay on the basis of Stx1 and Stx2 genes is a more practical and reliablemethod for molecular epidemiological studies of STECstrains because of its ability to determine, meat and products should be considered a major reservoir of STEC.

 

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Sambrook, J.; Fritsch, E.F. and Maniatis, T. (1989): Molecular cloning: Laboratory Manual. 2nd Edition, Cold spring, Harbor, New York, USA.

Sayed, A.M.; Abou El-Alla, A.A.; Abd El-Hafez, M.M.; Hussein, A.A. and Hassanien, Z.A. (2001): Prevalence of Escherichia coli with special reference to E.coli O157: H7 in some retail meat products in Assiut Governorate. Assiut. Vet. Med. J., 45(90): 146-155.

Shima, K.; Wu, Y.; Sugimoto, N.; Asakura, M.; Nishimura, K. and Yamasaki, S. (2006): Comparison of a PCR-Restriction Fragment Length Polymorphism(PCR-RFLP) Assay to Pulsed-Field Gel Electrophoresis To Determine the Effect of Repeated Subculture and Prolonged Storage on RFLP Patterns of Shiga Toxin Producing Escherichia coli O157:H7._ J. CLinc. Mcrbiol., 44(11): 3963–3968.

Smith, H.R. and Scotland, S.M. (1988): Vero cytotoxin-producing strains of Escherichia coli. J. Med. Microbiol. 26: 77-85.

Samadpour, M.; Ongerth, J.E.; Liston, J.; Tran, N.; Nguyen, D.; Whittman, T. S.; Wilson, R.A. and Tarr, P.I. (1994): Occurrence of Shiga-like toxin-producing Escherichia coli in retail fresh seafood, beef, lamb, pork, and poultry from grocery stores in Seattle, Washington. Appl. Environ. Microbiol. 60: 1038–1040.

Xiaodong, X. (2010):Pathogenic E.coli in retail meats. Dissertation submitted to the Faculty of the GraduateSchool of the University of Maryland, College Park, in partial fulfillment of the requirements for the degree of Doctor of Philosophy 2010.

Zaki, M.E. and El-Adrosy, H. (2007): Diagnosis of Shiga toxin producing Escherichia coli infection,contribution of genetic amplification technique. J. Microb. Infect. 9: 200-203.

Zhao, C.; Ge, B.; De Villena, J.; Sudler, R.; Yeh, E.; Zhao, S.; White, D.G.; Wagner, D. and Meng, J. (2001): Prevalence of Campylobacter spp., Escherichia coli, and Salmonella serovars in retail chicken, turkey, pork, and beef from the Greater Washington, DC area. Appl. Environ. Microbiol. 67: 5431–5436.


 

 

تصنيف وتوصيف العترات الحقلية المصرية للميکروب القولونى المفرز لتوکسين شيجا

 فى اللحوم والدواجن ومنتجاتها

 

رياض ربيع شاويش

E mail: reyad.rabea@vet.usc.edu.eg             Assiut University web-site: www.aun.edu.eg

 

 اجريت هذه الدراسة علي عدد 300 عينة شملت اللحوم ومنتجاتها (150 عينة) والدواجن ومنتجاتها (150 عينة) تم تجميعها من محافظة المنوفية والقاهرة. تم فحص العينات معمليا لعزل الميکروب القولوني المفرز لتوکسين شيجا أولا بطريقة العزل علي الوسط المخصص (SMAC-Media) والذى أسفر عن وجو130عينة ايجابية للميکروب القولوني تم  تأکيدها باستخدام الطرق البيوکيميائية. کذلک تم اختبار العينات الايجابية باستخدام VCA) vero cell assay) لتحديد العترات المفرزة لتوکسين شيجا. بعد ذلک تم تصنيف العينات الايجابية لاختبار VCA سيرولوجيا وکذلک تم تأکيدها باستخدام تفاعل البلمرة المتسلسل المتعدد (Multiplex PCR) لتحديد نوع الجين المسئول عن افراز سموم شيجا. هذا وقد أسفر فحص العينات عن تواجد 56 عينة ايجابية لاختبارVCA تم تأکيدهم جميعا بالاختبارات السيرولوجية وکذلک باستخدام تفاعل البلمرة المتسلسل المتعدد (Multiplex PCR) بنسبة 100% مما يؤکد کفاءة وسرعة اختبار تفاعل البلمرة المتسلسل في تشخيص الميکروب القولونى المفرز لتوکسين شيجا. کما أسفر استخدام تفاعل البلمرة المتسلسل المتعدد (Multiplex PCR) بواسطة بادئات لجينات شيجا توکسين1 Stx1 وشيجا توکسين2 Stx2  و eae عن وجود او غياب هذه الجينات في العينات المعزولة. وکانت أکثر المعزولات من اللحوم والدواجن هي O111, O26, O103, O119, O128, O86, O45, O146, O119 and O121. E.coli O111, O26, O103, O91, O86 and O119.  بالاضافة الى ما سبق لوحظ ارتفاع معدل الاصابة في الاشخاص والحيوانات المصابة بالاسهال عن الاشخاص والحيوانات السليمة ظاهريا مما يؤکد علي دور الميکوب القولوني المفرز لتوکسين شيجا في حدوث الاسهال في الانسان.

 

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