Authors
1 Department of Food Hygiene, Faculty of Veterinary Medicine, Aswan University, 81528 Aswan, Egypt
2 Department of Microbiology, Animal Health Research Institute (AHRI), Dokki
Abstract
Keywords
Main Subjects
Assiut University web-site: www.aun.edu.eg
INCIDENCE OF SHIGA TOXINS PRODUCING ESCHERICHIA COLI IN MEAT, MINCED MEAT, POULTRY MEAT AND CHILDREN DIARRHEA
MOHAMED KARMI 1 and SUSAN A. ISMAIL 2
1 Department of Food Hygiene, Faculty of Veterinary Medicine, Aswan University, 81528 Aswan, Egypt.
2 Department of Microbiology, Animal Health Research Institute (AHRI), Dokki.
Received: 27 May 2019; Accepted: 1 July 2019
ABSTRACT
A total of 200 samples of meat, minced meat, poultry meat and children diarrhea were collected from different shops in Aswan during 2018. These samples consist of 50 samples of each meat, minced meat, poultry meat and children diarrhea. Bacteriological examination of the samples was carried out for detection of Shiga toxins-producing Escherichia coli (STEC) followed by serological and genetic characterization for serotyping and for detection of some virulence genes including stx1, stx2 and eaeA genes. The incidence of E. coli in meat, minced meat, poultry meat and children diarrhea was (11/50) 22%, (9/50) 18%, (6/50) 12% and (6/50) 12%, respectively. Incidence of Shigatoxin – forming genes; stx1 ranged from 33-77% and stx2 ranged from 36-83%, while eaeA ranged from 16-36%. STEC were found in meat, minced meat, and poultry meat and transferred to children through contaminated food. Good processing procedures and sufficient temperatures should be confirmed during meat preparation to avoid infection and possible food poisoning from this dangerous pathogen.
Key words: Shiga toxins producing E. coli, meat, poultry meat, virulence genes.
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INTRODUCTION
Shiga toxins producing Escherichia coli (STEC) lives in the intestines of animals especially ruminants which considered the main source of infection for humans. STEC contaminates meat during slaughter, evisceration, handling and processing and found on the carcass surface, in minced meat and in undercooked burgers (Fries et al., 1996; Zhao et al., 2001). STEC are characterized basically by the production of Shigatoxins which causing cytotoxicity of the host cells through inhibition of protein synthesis, these toxins are not found in EPEC (Nataro and Kaper, 1998). STEC (or verotoxins producing Escherichia coli, VTEC) are very hazardeous group where it causing severe food poisoning; start from enteritis and ending by hemorrhagic colitis (HC), hemolytic uremic syndrome (HUS) and renal failure in human (Beutin et al., 2004; Blanco et al., 2004; Bolton, 2011). Symptoms of STEC infection start after 3-8 days and recovered after 10 days, some cases complicated to HC and about 3-7% into HUS (FSANZ, 2013). All human ages are susceptible for infection especially children and elderly (ICMSF, 2002). Normally infections start by HC and then complicated into
Corresponding author: Dr. Mohamed Karmi
E-mail address: karmy99@ yahoo.com
Present address: Department of Food Hygiene, Faculty of Veterinary Medicine, Aswan University, 81528 Aswan, Egypt
HUS, although some atypical cases of HUS starts directly without diarrhea (Verweyen et al., 2000). In addition to HC and HUS, STEC causes neonatal meningitis, nasocomial septicaemia and post surgical infections (Falagas and Gorbach, 1995). O157:H7 serotypes are more virulent than non-O157:H7 strains, although some non-O157:H7 are similar in virulence to O157:H7 causing mild non bloody diarrhea to HUS and death (Johnson et al., 2006). The main non-O157:H7 STEC strains are O26, O45, O103, O111, O121 and O145 and having the virulence genes of Shigatoxins and adhesion protein (stx and eae). Similarly, the most implicated foods are ground beef, burgers and cattle considered the main reservoir for non-O157:H7 strains (Arthur et al., 2002; Eklund et al., 2002; Liao et al., 2014). About 400 serotypes of STEC were identified and about 100 of them were described as a main cause of severe human infections and having the ability to produce one or more Shiga toxins (Bergey’s manual 2005). The similarity rate between STEC strains isolated from food and from human patients are 60%, so that Food was considered the most important and main source of infections (Miko et al., 2009). Meats have a special importance in transmission of STEC infection to human being which contaminated during slaughter or preparation (Cohen et al., 2007). In this work, we study the incidence of STEC in meat, minced meat, poultry and children diarrhea, serotyping of the isolates as well as some virulence genes such as Shiga toxins forming genes and adhesion protein gene.
MATERIALS AND METHODS
Samples
A total of 200 samples of meat, minced meat and poultry meat were collected from different shops in Aswan during 2018. Sterile swabs in 10 ml BPW were used for taking diarrheal swabs which were collected from children hospitals in Aswan city. These samples consist of 50 samples of each meat, minced meat, poultry meat and children diarrhea. Samples were transferred in low temperature to the laboratory in the faculty of veterinary medicine, Aswan University for bacteriological, biochemical, serological and genetic assays of STEC.
Isolation and Identification
Twenty five grams of each meat sample were aseptically transferred to sterile stomacher bag containing 225 ml Buffered Peptone Water (BPW). The bag content was homogenized using a Stomacher® 400 Circulator (Seward Ltd., UK) for 3 minute and incubated at 37 ºC for 12 hours. Loopful (10 µl) was taken from each BPW enrichment culture and from diarrheal swab wash after 12 hours incubation at 37°C and streaked on Eosin Methylene Blue Agar (EMB) plates (Oxoid, Code: CM0069) the culture plates were incubated aerobically at 37°C for 24 hours for EMB plates. Olive green colonies with metallic sheen on EMB were positive for pathogenic E. coli. Positive colonies were picked up for further biochemical and serological confirmation. Positive strains were confirmed with Gram's staining, Indole production, Methyl Red, Voges-Proskauer, Simmon`s citrate, Urease production and Triple Sugar Irone agar (Quinn et al., 1994; Adams and Moss, 1999). Positive E. coli isolates were tested for presence of somatic (O) and flagellar (H) antigens using latex agglutination test (Hampshire, UK) (Krishnan et al., 1987; March and Ratnam, 1989).
Genetic Characterization
Multiplex PCR assay of some virulence genes of E. coli O157:H7 including Shiga toxins-forming genes (stx1, stx2) and intimin gene (eaeA). DNA extraction was carried out by using QIAamp Mini Kit (Catalogue No: 51304) DNA purification kits (Qiagen, Germany) according to the manufacturer instructions. Primer sequences were used for stx1, stx2 and eaeA genes amplification (Gannon et al., 1992, 1997) (Table 1). Multiplex PCR amplification of stx1, stx2 and eaeA genes was carried out. Each reaction consists of 2.5 µl of 10x buffer, 12.5 µl master mix (Emerald Amp GT master mix (Takara, Code: RR310A), 1 µl each primer of 20 pmol concentrations, 6 µl DNA template and nuclease free water till 25 µl volume. Thermacycler (Eppendorf, Germany) was used with initial denaturation step at 94°C for 5 minutes followed by 30 PCR cycles, each consisting of 1 min of denaturation at 94°C; 1 minute of annealing at 58°C for 1 minute; extention at 72°C and final extension at 72°C for 10 minutes. PCR reaction mixtures were electrophoresed on 1.5% agarose gels and stained with ethidium bromide and visualized on UV transilluminator (Biometra) and analyzed using Biodoc Analyse Biomet (EL-Jakee et al., 2009).
RESULTS
The incidence of E. coli in meat, minced meat, poultry meat and children diarrhea was (11/50) 22%, (9/50) 18%, (6/50) 12% and (6/50) 12%, respectively (Table 2). E. coli serotypes isolated from meat were O111:H2, O125:H21, O128:H2, O26:H11, O55:H7 and O124, from minced meat were O128:H2, O119:H4, O44:H18, O26:H11, O111:H2, O55:H7, O78, from the poultry meat were O26:H11, O114:H21, O119:H4, O125:H21, O2:H6 and from children diarrhea were O119:H4, O111:H2, O128:H2, O114:H21, O124 (Table 3,4). Incidence of virulence genes were as the following; stx1 was (5/11) 45%, (7/9) 77%, (2/6) 33%, (3/6) 50%, stx2 was (4/11) 36%, (4/9) 44%, (5/6) 83%, (3/6) 50% and eaeA was (4/11) 36%, (3/9) 33%, (2/6) 33%, (1/6) 16% in meat, minced meat, poultry meat and children diarrhea were, respectively (Table 5).
Table 1: Primer sequences of virulence genes in E. coli.
Primer |
Oligonucleotide Sequence (5`- 3`) |
Product Size (bp) |
References |
stx1 (F) |
ACA CTG GAT GAT CTC AGT GG |
614 |
Gannon et al., 1992 |
stx1 (R) |
CTG AAT CCC CCT CCA TTA TG |
||
stx2 (F) |
CCA TGA CAA CGG ACA GCA GTT |
779 |
Gannon et al., 1992 |
stx2 (R) |
CCT GTC AAC TGA GCA GCA CTT TG |
||
eae A (F) |
GTG GCG AAT ACT GGC GAG ACT |
890 |
Gannon et al., 1997 |
eae A (R) |
CCC CAT TCT TTT TCA CCG TCG |
Table 2: Incidence of E. coli in meat, minced meat, poultry meat and children diarrhea.
Samples |
Number |
Positive number |
Percentage |
Meat |
50 |
11 |
22 |
Minced meat |
50 |
9 |
18 |
Poultry meat |
50 |
6 |
12 |
Children diarrhea |
50 |
6 |
12 |
Total |
200 |
32 |
16 |
Table 3: Serotypes of E. coli in meat, minced meat, poultry meat and children diarrhea.
Samples |
Serotype |
Number |
Percentage |
E. coli group |
Meat |
O111 : H2 |
3 |
27% |
EHEC |
O55 : H7 |
3 |
27% |
EPEC |
|
O125 : H21 |
2 |
18% |
ETEC |
|
O128 : H2 |
1 |
9 % |
ETEC |
|
O26 : H11 |
1 |
9% |
EHEC |
|
O124 |
1 |
9% |
EIEC |
|
Minced meat |
O128 : H2 |
3 |
33% |
ETEC |
O119 : H4 |
1 |
11% |
EPEC |
|
O44 : H18 |
1 |
11% |
EPEC |
|
O26 : H11 |
1 |
11% |
EHEC |
|
O111 : H2 |
1 |
11% |
EHEC |
|
O78 |
1 |
11% |
EPEC |
|
O55 : H7 |
1 |
11% |
EPEC |
|
Poultry meat |
O26 : H11 |
2 |
33% |
EHEC |
O114 : H21 |
1 |
11% |
EPEC |
|
O119 : H4 |
1 |
11% |
EPEC |
|
O2 : H6 |
1 |
11% |
EPEC |
|
O125 : H21 |
1 |
11% |
ETEC |
|
Children diarrhea |
O119 : H4 |
1 |
16% |
EPEC |
O111 : H2 |
2 |
33% |
EHEC |
|
O128 : H2 |
1 |
16% |
ETEC |
|
O124 |
1 |
16% |
EIEC |
|
O114 : H21 |
1 |
16% |
EPEC |
Table 4: Serotypic and genetic characterization of E. coli in meat, minced meat, poultry meat and children diarrhea.
Serotype |
stx1 |
stx2 |
eaeA |
Source |
O26: H11 |
+ |
+ |
+ |
Chicken& meat and minced meat |
O114: H21 |
- |
+ |
- |
Chicken and children stool |
O119: H4 |
+ |
+ |
- |
Chicken& minced meat and children stool |
O2 : H6 |
- |
+ |
- |
Chicken |
O125: H21 |
- |
+ |
+ |
Chicken |
O111: H2 |
+ |
+ |
+ |
Meat& minced meat and children stool |
O55: H7 |
+ |
- |
+ |
Meat and minced meat |
O125: H21 |
- |
+ |
+ |
Meat |
O124 |
- |
- |
- |
Meat and children stool |
O128: H2 |
+ |
- |
- |
Meat &minced meat and children stool |
O44: H18 |
+ |
- |
- |
Minced meat |
O78 |
+ |
+ |
- |
Minced meat |
Table 5: Serotypic and genetic characterization of E. coli in meat, minced meat, poultry meat and children diarrhea.
Sample |
stx1 |
stx2 |
eaeA |
|||
Number |
Percentage |
Number |
Percentage |
Number |
Percentage |
|
Meat |
5 |
45 |
4 |
36 |
4 |
36 |
Minced meat |
7 |
77 |
4 |
44 |
3 |
33 |
Poultry meat |
2 |
33 |
5 |
83 |
2 |
33 |
Children diarrhea |
3 |
50 |
3 |
50 |
1 |
16 |
DISCUSSION
In this study, results revealed that incidence of E. coli in meat (22%) and minced meat (18%) were higher than that in poultry meat (12%), contamination by E. coli in fresh meat and minced meat was higher than that of poultry meat may be due to the E. coli is a normal inhabitant of the large intestines of cattle and higher possibility of meat contamination during slaughter, evisceration, transport, preparation. Also, cattle are the main reservoir of STEC (Meng et al., 2013). Furthermore, minced meat may get contaminated from several steps during handling, mincing and storage so that it may be more harmful to the consumers and health (Eldaly et al., 1988). Incidence of E. coli in meat (22%) was lower than Momtaz et al. (2013) (29%), Farhan et al. (2014) (30%), Patricia et al. (2014) (36.1%) and Hyun-Jung et al. (2015) (42.3%) but higher than Kesava et al., 2011 (0.6%), Mohamed et al. (2013) (11%) and Sethulekshmi et al. (2016) (12.5%). Incidence of E. coli in minced meat (18%) was higher than Wenting et al. (2012) (5.2%), Perelle et al. (2007) (11%) and Mora et al. (2007) (11%), lower than Acheson, (2000) (21%), Panahee and Pourtaghi, (2016) (23.5%), Zaki and Elmahrouk, 2005 (44%), Badri et al. (2009) (45%), Hazarika et al. (2004) (56.8%) and Soliman and Tabiy (2006) (68%). Incidence of E. coli in poultry meat (12%) was similar to Momtaz et al., 2012 (11%), lower than Zende et al. (2013) (16.67%) and Nguyen et al. (2016) (92.7%), Hyun-Jung et al. (2015) (75.9%), Eyy and Arslan, 2012 (87.5%), Zhao et al. (2001) (38.7) and Momtaz and Jamshidi, (2012) (34.93%). Incidence in children diarrhea (12%) was similar to Elsheikh and Alassouli, (2001) (13%), lower than Bitzan et al. (1993) (51%), Awadallah et al. (2014) (20%), higher than Christina et al. (2011), (0.3%) and Kesava et al., 2011 (1.3%). Serotypes O111:H2 and O128:H2 were detected in meat, minced meat and diarrhea while serotype O119:H4 was detected in minced meat, poultry meat and diarrhea. Serotype O26:H11 was detected in meat, minced meat and poultry meat while serotype O114:H21 was detected in poultry meat and diarrhea. Serotype O125:H21 was detected in meat and poultry meat while serotype O124 was detected in meat and diarrhea. Serotype O55:H7 was detected in meat and minced meat while serotype O44:H18 and O78 were detected only in minced meat and serotype O2:H6 was detected only in poultry meat. It is noticed that most of serotypes were found in meat and minced meat and similar to serotypes of children diarrhea, there is a strong relation between serotypes of beef meat and human infections. O4, O5, O16, O26, O46, O48, O55, O91, O98, O111ab, O113, O117, O118, O119, O125, O126, O128, O145, O157 and O172 are the most famous EHEC serogroups. Beside the novel discovered serogroups such as: O176, O177, O178, O179, O180 and O181 (Scheutz and Strockbine, 2005). Identification of STEC strains depends basically on serological typing by using O and H antigens (Gyles, 2007). Not only O157 but also non-O157 strains are implicated in sever diseases to the consumers and in certain localities it may be more common than O157 in causing diarrhea and HUS (Pradel et al., 2000). Some authors stated that non-O157 STEC infections may be milder than O157 infections (Brooks et al., 2005). Shigatoxin forming genes (stx1, stx2) and adhesion gene (eaeA) were found in about (17/32) 53% of isolated E. coli, most of them occur in meat and minced meat and lower in poultry meat and children diarrhea. Presence of such genes in isolates is indication for contamination of meat with highly virulent strains of E. coli and higher potential of sever food poisoning infection to the consumers. Meat and meat products are frequently contaminated during preparation by the workers. Production of shigatoxins and adhesion protein intimin is the most characteristic feature of STEC. Shigatoxins (stx1 and stx2) have a cytotoxic effect through inhibition of protein synthsis and cell death while the adhesion protein, intimin, is a surface protein of cell wall which facilitates attachment of the bacteria to the intestinal cells. Genes; stx1 and stx2 are found in the temperate lambdoid bacteriophages of E. coli chromosome while eaeA gene is found in the pathogenicity island in the chromosome, known as the locus of enterocyte effacement (LEE) (Paton and paton, 1998).
CONCLUSION
Shigatoxin producing E. coli contaminate red meat, minced meat, poultry meat by relative incidence rates. Infection transferred to human being through consumption of meat and poultry meat that manifested in positive samples of children diarrhea. These Serotypes produce dangerous Shiga toxins which responsible for food poisoning, bloody diarrhea, Hemorrhagic Colitis and Hemolytic-Uremic Syndrome. Sufficient processing temperature should be confirmed during preparation to decrease incidence of high risk food poisoning and diseases.
ACKNOWLEDGEMENTS
I thank Faculty of Veterinary Medicine, Aswan University for Financial support and Veterinarian Susan Ismail for her technical support and help in isolation of bacteria.
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معدل حدوث ميکروب الأيشريکية القولونية المنتجة لسموم الشيجا فى اللحوم الحمراء واللحوم المفرومة
ولحوم الدواجن وٳسهال الأطفال
محمد کرمى ، سوزان إسماعيل
E-mail: karmy99@yahoo.com Assiut Univers ity web-site: www.aun.edu.eg
أجريت هذه الدراسة على عدد 200 عينة من اللحوم الحمراء واللحوم المفرومة ولحوم الدواجن وٳسهال الأطفال و تتکون من 50 عينة من کل منها تم تجميعها من المحال المختلفة لبيع اللحوم فى محافظة أسوان فى عام 2018. تم فحص هذه العينات بکتريولوجيا وکيميائيا و سيرولوجيا وجينيا للکشف على ميکروب الأيشريکية القولونية المنتجة لسموم الشيجا والجينات الخاصة بها وهم stx1, stx2 and eaeA. وقد أوضحت النتائج أن معدل حدوث ميکروب الأيشريکية القولونية فى اللحوم الحمراء واللحوم المفرومة ولحوم الدواجن وٳسهال الأطفال هو 22% و 18% و 12% و 12% على التوالى بينما معدل حدوث جينات الضراوة کالتالى: جين الشيجاتوکسين 1 هو 33-77% و جين الشيجاتوکسين 2 هو 36-83% وجين الأنتيمين أ هو 16-36%. نستخلص من هذه الدراسة أن ميکروب الأيشريکية القولونية المنتجة لسموم الشيجا موجود فى اللحوم الحمراء واللحوم المفرومة ولحوم الدواجن وينتقل إلى الأطفال من خلال الأطعمة الملوثة. تنصح الدراسة بضرورة التأکد من الطبخ الجيد و الحرارة الکافية للحوم قبل تناولها حتى يمکن تجنب العدوى والتسمم الغذائى بهذا الميکروب الخطير.