Document Type : Original researches
Abstract
Keywords
Main Subjects
Occurrence of shiga-toxigenic and extended-spectrum β-lactamase (ESBL) Producing E. coli in some varieties of cheese and its public health hazzard.
By
A.M. Koriem1 and O.A. Sadek2
1Bacteriology Department, Assiut Lab., Animal Health Research Institute, Agricultural Research Center (ARC), Egypt.
2Department of Food Hygiene, Assiut Lab., Animal Health Research Institute, Agricultural Research Center (ARC), Egypt.
ABSTRACT
The capability of pathogenic shiga toxin-producing E. coli (STEC) to produce the toxins Stx1 and Stx2, which cause intestinal disorders, makes their presence in dairy products a public health problem. This study major goal was to identify the presence of ESBL-producing E. coli and shiga toxins in several cheese varieties that are sold in and around Assiut City. Ninety random samples of white soft cheese, including Kariesh, Domiati, and Tallaga cheese (30 of each), were collected and checked for the presence of E. coli, which were 86.7, 0.0, and 16.7%, respectively. A total of 31 E. coli isolates (34.4%) were recovered from 90 samples. Twelve E. coli isolates were positive for ESBL production and were multidrug-resistant. Ten of which were molecularly examined for the detection of shiga toxins (Stx1 and Stx2) genes and a fliC-specific gene for E. coli O175:H7. Two isolates harbored Stx1, four isolates harbored Stx2 virulence gene, and seven isolates were E. coli O175:H7. The susceptibility to ten antimicrobial agents was evaluated by the disk diffusion method. The results of antimicrobial susceptability testing showed high sensitivity to colistin (CL), Ciprofloxacin (CP), trimethoprim-sulfamethoxazole (COT), gentamicin (GEN), and tetracycline (TE) with 90.3, 87.1, 83.8, 80.6, and 58.1%, respectively,while resistance to amoxicillin (AMX), Erythromycin (E), ampicillin (AMP), cefotaxime (CTX), and amoxicillin-clavulanic acid (AMC) with 93.6, 93.6, 77.5,51.5 and 48.4%, respectively. The acquired initial findings revealed sanitary and hygienic deficiencies throughout the production process of Kariesh cheese and showed that these products able to contain multidrug-resistant and virulent strains of E. coli and may play a role in the spread of antimicrobial- resistant (AMR) to other microorganisms, posing a risk to public health. This implies that soft cheese needs to be viewed as a medium through which possibly harmful germs can spread. To get thorough findings, more research and analysis of more samples are still required..
Keywords: Occurrence, E. coli, shiga-toxins,kareish cheese,PCR
Introduction
One of the fundamental dietary groups for humans is cheeses. But unpasteurized milk is frequently used to make fresh white cheese, which is then sold in open marketplaces. Contamination with harmful germs may become more likely as a result. It is extremely concerning for public health when multidrug-resistant pathogenic microorganisms are found in food (De la Rosa-Hernández et al. 2018).
In the different geographical locations in Egypts, traditional methods are used to manufacturing fresh, soft cheeses. The conventional manufacturing process comprises curd formation, renneting, and preparation for marketing. This cheese is manufactured without starter cultures from raw milk that has typically been heat-treated. Microbial contamination of cheese may originate from various sources during processing (Temelli et al. 2006), storage (Brito et al. 2008) or by contamination from workers (Callon et al. 2008).
In Egypt, white soft cheese varieties such as Domiati, Tallaga, and Kariesh are the most popular local types (Hegazy et al. 2012). Cheese is a valuable dairy product and an essential component of a balanced diet, but it has also been a perfect medium for the growth and multiplication of numerous bacteria, including Salmonella and E. coli, which could pose a risk to the public's health (Zakary et al. 2011).
Shiga toxigenic E. coli (STEC) is a significant foodborne zoonotic pathogen that causes hemorrhagic colitis, hemolytic uremic syndrome, and mild to severe diarrhea,
STEC virulence genes including, intimin (eae) and hemolysin (hlyA), as well as shiga toxin genes stx1 and stx2 (Gyles, 2007).
Shiga toxin-producing E. coli (STEC), and verotoxin-producing E. coli (VTEC), has drawn significant attention as a global public health concern for a variety of sporadic infections and major outbreaks. This is because there are fewer, or frequently non effective antibiotics available for controlling of infections caused by such bacteria. Additionally,the most well-known serotype of E. coli, O157:H7, has become more resistant to drugs in recent years, leading to significant issues in healthcare settings across the globe (Spano et al. 2017). One of the major global health concerns of this century is multidrug resistance (MDR), and its global spread is becoming more prevalent. This is especially problematic in developing countries where non compliance with the implementation of regulation over the supply, use, and withdrawal period of antibiotics in veterinary, human, and food animal agriculture ( Adamu et al. 2018).
Two forms of shiga toxin types (stx1&2) as well as subtypes that predominate in the pathogenicity of STEC are recognized, and they are known to have a significant role in determining the severity of sickness (Cavalcanti et al. 2020).
Global public health issues are increasingly being caused by E. coli, which produces narrow and extended-spectrum β-lactamases (ESBL) (Feng et al. 2018). Plasmid-mediated β-lactamase enzymes, known as ESBLs, are highly effective in hydrolyzing monobactams, penicillin, and cephalosporins of the third and fourth generations, with the exception of cephamycin and carbapenem (Hassuna et al. 2020).
Cheese may be regarded as a possible cause of foodborne infections. The most significant foodborne pathogen contaminates the cheese during the post-processing stage (Vrdoljak et al. 2016). It has been established that animals that can harbor a number of zoonotic infections, such as E. coli, which produces beta-lactamases. (Carattoli, 2008). Hence, the main objective of the current research was to determine the occurrence and characteristics of shiga toxin and ESBL-producing E. coli from some varieties of soft cheese sold and in and around Assiut City, hoping to provide detailed information about the presence of multiple antidrug resistance (MAR) E. coli, which is proposed as a major concern to human health.
Materials and methods
Samples collection:
A total of 90 randomized samples of white soft cheese, including 30 each of Kariesh, Domiati, and Tallaga cheese, were gathered from street vendors, dairy shops, and supermarkets in the Assiut governorates and placed in sterile polyethylene bags under aseptic conditions and safety precautions. The samples were promptly delivered to the lab after being stored in an ice box (2-4oC) for isolation and identification of E coli .
Preparation of samples (APHA, 2004):
Separately, 10 g of each processed cheese sample was added to 90 ml of sterile buffered peptone water (BPW) in a sterile polyethylene stomacher bag. The mixture was then completely homogenized for three minutes using a stomacher (Seward Stomacher 80, BioMaster, England) before the samples were incubated.
Isolation and identification of E. coli:
One ml from each BPW was transferred to 5 ml MacConkey broth tube and incubated at 37° C for 24 hrs. A loopful from each incubated broth tube was streaked on MacConkey (MAC) agar (Merck, Germany) and incubated aerobically at 37°C for 24 h. The suspected E. coli pink colonies were streaked on Eosin Methylene Blue Agar (EMB), and incubated for 24 h. at 37°. Morphologically typical colonies with metallic sheen were picked up and subcultured on nutrient agar slope at 37° C for 24 hrs for morphological and biochemical identification of E. coli, according to Quinn et al.( 2011).
Phenotypic detection of E. coli O157: H7:
Sorbitol MacConkey agar medium (Oxoid, England) plates were used to disseminate the isolates of E. coli. then the plates were incubated for twenty-four hours at 35 oC. According to FDA (2002), the growth of E. coli on MacConkey agar supplemented with sorbitol results in colorless, pale-colored, sorbitol-negative colonies (typical E. coli 0157: H7).
Antimicrobial susceptibility testing:
Antibiotic susceptibility testing was performed by the Kirby Bauer disc diffusion method according to the Clinical Laboratory Standards Institute guidelines (Sigma-Aldrich, USA) for the isolated E. coli strains against 10 antimicrobial agents, and the results were interpreted according to CLSI (2020). Briefly, the inoculum concentration was standardized by turbidimetry correspond to 0.5 on the McFarland turbidity standard and then dispersed on Mueller-Hinton agar plates (Himedia) using sterile swabs. The used antimicrobials agents were erythromycin (E), ampicillin (AMP), amoxicillin(AMX), amoxicillin-clavulanic acid (AMC), cefotaxime (CTX), colistin (CL), Ciprofloxacin (CP), gentamicin (GEN), tetracycline (TE) and trimethoprim-sulfamethoxazole (COT) . The diameter of the zone of inhibition generated by each antibiotic disc was measured and interpreted (CLSI, 2020). Isolates that exhibited resistance to three or more antibiotic classes were categorized as multidrugresistant (MDR) (Magiorakos et al. 2012). Isolates in this study with intermediate susceptibility were classified as resistant.
Extended Spectrum b-Lactamases (ESBL) testing :Using the double-disc synergy test (DDST) diffusion method, ESBL production was detected in all E. coli isolates that produced ESBLs. Tests were conducted using cefotaxime (CTX 30 μg) and amoxicillin-clavulanic acid (AMC 20/10 μg). When cefotaxime and cefotaxime-clavulanic acid had a zone diameter greater than 5 mm, it was deemed to be ESBL positive. (CLSI, 2020).
Molecular detection of shiga toxins (Stx1 and Stx2) genes and fliC specific gene oF E. coli O175:H7 in some E. coli isolates by application of PCR assay:
“Application of PCR assay was performed in Reference Lab for veterinary quality control on poultry production, Animal Health Research Institute, Doki , Giza, Egypt”.Ten isolates were selected from ESBL-identified E. coli and subjected to PCR (polymerase chain reaction) assays to identify the characteristic fliC-specific gene for E. coli O175:H7 and the shiga toxins (Stx1 and Stx2) genes. DNA extraction from samples was performed using the QIAamp DNA Mini kit (Qiagen, Germany, GmbH) with modifications from the manufacturer’s recommendations. All DNA samples were stored at -20°C until tested for the existence of shiga toxins (Stx1 and Stx2) genes and fliC-specific gene for E. coli O175:H7 in E. coli isolates using specific primers supplied from Metabion (Germany) as shown in Table (A). PCR amplification and analysis of the PCR products were performed as previously described by Sadek and Koriem (2022).
Statistical analysis: statistical analysis of data was done with the Chi square test to determine whether there was a significant difference between them, and a "P" value of less than 0.05 was deemed statistically significant. Data were analyzed using GraphPad Prism 9.5.1 software (GraphPad Software Inc., San Diego, CA, USA).
Table ( A ) : Primers sequences, target genes, amplicon sizes and cycling conditions.
|
Target gene |
Primers sequences |
Amplified segment (bp) |
Primary denaturation |
Amplification (35 cycles) |
Final extension |
Reference
|
||
|
Secondary denaturation |
Annealing |
Extension |
||||||
|
Stx1 |
ACACTGGATGATCTCAGTGG |
614 |
94˚C 5 min. |
94˚C 30 sec. |
58˚C 40 sec. |
72˚C 45 sec. |
72˚C 10 min. |
Dipineto et al. 2006
|
|
CTGAATCCCCCTCCATTATG |
||||||||
|
Stx2 |
CCATGACAACGGACAGCAGTT |
779 |
||||||
|
CCTGTCAACTGAGCAGCACTTTG |
||||||||
|
Escherichia coli O157:H7 fliC |
GCGCTGTCGAGTTCTATCGAGC |
625 |
94˚C 5 min. |
94˚C 30 sec. |
57˚C 40 sec. |
72˚C 45 sec. |
72˚C 10 min. |
Fratamico et al. 2000 |
|
CAACGGTGACTTTATCGCCATTCC |
||||||||
Results
Totally thirty one positive samples (34.4%) out of 90 examined soft cheese samples were E coli positive represented 26 (86.7%, ) out of 30 kariesh cheese, 5 (16.7% ) out of 30 tallaga cheese while domiati cheese were negative for E coli (Table 1). Twelve E. coli isolates mainly from Kariesh cheese were positive for ESBL- production and were multidrug-resistant. Ten isolates were selected from ESBL-identified E. coli and subjected to gene-specific polymerase chain reaction (PCR) assays to identify the characteristic fliC-specific gene for E. coli O175:H7 and the shiga toxins (Stx1 and Stx2) genes.7 out of 10 ESBL-producing E. coli were confirmed as E. coli O175:H7 by phenotyping which were sorbitol negative and gave pale colonies in MacConkey sorbitol agar and genotyping by fliC-specific gene for E. coli O175:H7. Two isolates harbored Stx1, four isolates harbored Stx2 virulence genes, and seven isolates were O175:H7 (Table 3).
Table (1) : Incidence of E.coli in cheese varieties.
|
Type of Cheese**
|
No of Samples
|
Positive Samples
|
Negtive Samples
|
||
|
No |
%
|
No |
%
|
||
|
Kariesh
|
30 |
26 |
86.7
|
4 |
13.3
|
|
Domiati
|
30 |
0 |
0
|
30 |
100
|
|
Tallaga
|
30 |
5 |
16.7
|
25 |
83.3
|
|
total |
90 |
31 |
34.4
|
59 |
65.6
|
** High significance differences between types cheese types (P<0.0001, χ2 = 56.19)
Table (2) : Antimicrobial susceptibility of E. coli isolated from cheese samples (n : 31).
|
antibiotics |
sensitive** |
resistant** |
||
|
No |
% |
No |
% |
|
|
Amoxicillin (AMX) 20μg (μg)
(μg)
|
2 |
6.4 |
29 |
93.6 |
|
ampicillin (AMP)10 μg |
7 |
22.5 |
24 |
77.5 |
|
amoxicillin-clavulanic acid (AMC)20/10 μg |
16 |
51.6 |
15 |
48.4 |
|
cefotaxime (CTX)30 μg |
15 |
48.4 |
16 |
51.6 |
|
tetracycline (TE)30 μg |
18 |
58.1 |
13 |
41.9 |
|
ciprofloxacin (CP) 5μg |
27 |
87.1 |
4 |
12.9 |
|
gentamicin (GEN)10 μg |
25 |
80.6 |
6 |
19.4 |
|
erythromycin (E)15 μg |
2 |
6.4 |
29 |
93.6 |
|
colistin (CL)10 μg |
28 |
90.3 |
3 |
9.7 |
|
trimethoprim-sulfamethoxazole (COT) 1.25/23.75 μg |
26 |
83.8 |
5 |
16.2 |
** High significance differences among sensitivity of different types of antibiotics (P<0.0001, χ2 =119.4)
** High significance difference among resistant of different types of antibiotics (P<0.0001, χ2 =119.4)
Table (3): PCR results for detection of Stx1, Stx2, fliC genes in ten isolates of ESBL-producing E. coli .
|
Serial number of tested E. coli |
ESBL-production |
Colony colour on MacConkey sorbitol agar |
Stx1 gene |
Stx2 gene |
O157:H7 fliC gene |
|
1 |
+ |
Red colony |
- |
+ |
Not tested |
|
2 |
+ |
Pale colony |
- |
+ |
+ |
|
3 |
++++++ |
Pale colony |
+ |
- |
+ |
|
4 |
+ |
Pale colony |
- |
- |
+ |
|
5 |
+ |
Red colony |
- |
+ |
Not tested |
|
6 |
+ |
Pale colony |
- |
- |
+ |
|
7 |
+ |
Red colony |
+ |
- |
Not tested |
|
8 |
+ |
Pale colony |
- |
- |
+ |
|
9 |
+ |
Pale colony |
- |
+ |
+ |
|
10 |
+ |
Pale colony |
- |
- |
+ |
Figure (1): Agarose gel electrophoresis patterns of uniplex PCR amplification products for E. coli O157:H7 fliC gene. Lane L, DNA ladder marker (100 bp). Lane P, control positive E. coli O157:H7 fliC gene (625 bp). Lane N, negative control. Lanes 2,3,4,6,8,9 and 10 positive E. coli O157:H7 isolates for fliC gene.
Figure (2): Agarose gel electrophoresis patterns of uniplex PCR amplification products for E. coli Stx1 genes. Lane L, DNA ladder marker (100 bp). Lane P, control positive E. coli Stx1 (614 bp) genes. Lane N, negative control. Lanes 3 and 7 positive E. coli isolates for Stx1 gene. Lanes 1,2,4,5,6,8-10, negative E. coli isolates for Stx1 genes.
Figure (3): Agarose gel electrophoresis patterns of uniplex PCR amplification products for E. coli Stx2 genes. Lane L, DNA ladder marker (100 bp). Lane P, control positive E. coli Stx2 (779bp) genes. Lane N, negative control. Lanes 1,2,5 and 9 positive E. coli isolates for Stx2 gene. Lanes 3,4, 6,7,8 and 10, negative E. coli isolates for Stx2 genes.
Discussion
Current outbreaks of foodborne disease have been recorded due to the ingestion of contaminated products infected with pathogenic organisms or their toxins, in particular E. coli, which is considered an essential cause of diarrhea in humans. Based on the current research, the total occurrence of E. coli species was 34.4% of the examined cheese samples ( Table 1). Lower incidence was reported by ELBagoury et al. (2019) 13.33% and Heikal et al. (2014) 26.7%,, while higher icedience, privately reported by AbdEL-Tawab et al. (2020) 42.5 % and Imre et al. (2022), 83.8%. The reported results are markedly influenced by the study design, seasonal and geographic variations, the testing methods (including the culture media and growth temperatures), or the differences in hygiene and milking practices (Metz et al. 2020).
Table (1) also revealed that E. coli could be isolated from examined Kareish cheese samples with an incidence rate of 86.7%. A nearly similar finding were reported by Sobeih et al. (2023) ; Mohamed et al. (2020) ; Ibrahim et al. (2019) and Ombark et al. (2016), while a lower incidence were reported by Farag et al. (2023) ; Omr & Abdeen (2023) ; Ibrahim et al. (2022) ; AbdEL-Tawab et al. (2020) ; El Bagoury et al.( 2019) ; El-nahas et al. (2015), and Awad (2016). On the contrary, AboZeed (2014) could not detect E. coli from the examined Kariesh cheese. According to the Egyptian Standard for Karish cheese (1008/4/2005), it should be free from E. coli. It is advised to follow proper manufacturing practices, as well as distribution and retail storage practices, to ensure cheese's microbiological safety
It is evident from Table (1) that E. coli could not be isolated from the examined Damietta cheese samples. The obtained data are in close agreement with Thabet (2003), who reported that E. coli could not be isolated from the examined Damietta cheese samples,which may be due to the storage of Damietta cheese in salted whey for more than 8 weeks before marketing, which inhibt the growth of E. coli. A higher incidence rate was obtained by Kursun et al. (2011), who detected E. coli in 40% of the examined samples, while Ibrahim et al. (2022) reported a high incidence of E. coli 20%. in Domiati cheese .In contrast, a lower incidence of 2.8% was reported by El Bagoury et al. ( 2019).
The result of table (1) declared that the prevalence of E. coli in Tallaga cheese was 16.7%. The same result was obtained by Sobeih et al. (2023). On the contrary, El Bagoury et al. ( 2019) could not detect E. coli from the examined Tallaga cheese. AbdEL-Tawab et al. (2020) reported a high prevalence of 32% of E. coli in Tallaga cheese, while a lower prevalence was reported by Ahmed (2012).
significant variations between the incidence of E. coli in examined cheese samples (P<0.0001, χ2 = 56.19). Interestingly, from statistical analysis it is clear that, Damietta cheese is of suprior quality than Kareish cheese and tallaga cheese based on zero prevalence of E. coli. Contamination of milk and milk products with E. coli is largely due to unhygienic conditions during production, processing, handling, and distribution. E. coli is a good indicator of fecal contamination which exists as a normal microflora of the intestinal tract of humans and warmblooded animals (Ibrahim et al. 2020).
From a sanitary perspective, inadequate sanitation and using of row or inadequate heat treated milk in cheese manufacturing could be the cause of the high percentage of E. coli found in soft cheese samples (Najand and Ghanbarpour, 2006). The isolation of E. coli represents a serious public health hazard because some strains of E. coli may belong to enteropathogenic, toxigenic, or both groups, which cause severe gastrointestinal disturbance. (Thomas et al. 2016).
Antimicrobial resistance is recognized as a worldwide problem in human and veterinary practices. The unselective and inaccurate use of antimicrobials as well as their use as growth-promoting agents, has led to increase in antibiotic residues in food products of animal origin. These residues allowing the emerging of resistant bacteria through several encoding antibiotic resistance genes (Cheng et al. 2020). Consequently, food of animal origin constitute an ultimate environment for the development of different high pathogenic and resistant bacteria (Kim et al. 2022).
Antimicrobial sensitivity testing for all 31 E. coli isolates against ten different antibiotics (Table 2) showed high sensitivity to colistin (CL), Ciprofloxacin (CP), trimethoprim-sulfamethoxazole (COT), gentamicin (GEN), tetracycline (TE), and amoxicillin-clavulanic acid (AMC) with 90.3, 87.1, 83.8, 80.6, 58.1, and 51.6%, respectively, while resistance to amoxicillin (AMX), Erythromycin (E), ampicillin (AMP), cefotaxime (CTX), and amoxicillin-clavulanic acid (AMC) with 93.6, 93.6, 77.5, 51.5, and 48.4%, respectively. Current data were nearly in contact with Omr & Abdeen (2023), who revealed that E. coli strains showed higher sensitivity to gentamicin, ciprofloxacin, and amoxicillin/clavulanic acid,while Ibrahim et al. (2022) revealed that the highest resistance was found against Erythromycin (100%), followed by Oxacillin (94%), Cefepime (82%), Penicillin G (76.5%), Ceftriaxone (70.5%), both Ampicillin and Cefotaxime, and both Tetracycline and Sulphamethoxazol (41.2%). Antibiotic resistance results from the repeated, and overuse of antibiotics in animal and human treatments from infections (Yohannes, 2018). Similar studies were recorded, Elmonir et al. (2018) found that STEC isolates were resist to ampicillin and tetracycline, and Jamali et al. (2018) showed that E. coli isolated from milk samples were highly resistant to tetracycline. Additionally, El Bagoury et al. (2019) reported that all E. coli isolated from white soft cheeses were mainly resistant to erythromycin. Furthermore, Alsayeqh et al. (2021), in their review of antimicrobial-resistant pathogens from foods, revealed that E. coli showed the highest resistance against erythromycin, tetracycline, ampicillin, amoxicillin, oxacillin, and penicillin G, as well as showed resistance against cefotaxime and cefoxitin. Also, Kasem et al. (2021) reported higher antibiotic resistance in E. coli against erythromycin, cefotaxime, and penicillin G.
The data analysis revealed that there were highly statistically significant variations concerning the antimicrobial sensitivity of different antibiotics (P<0.0001, χ2 =119.4), there were also highly significant variations concerning the antimicrobial resistance of different antibiotics (P<0.0001, χ2 =119.4). In general the drug resistance rate of ESBL-producing E. coli was higher than that of ESBL-negative E. coli.
From the public health point of view, 12 ( 38.7% ) out of 31 identified E. coli strains, exhibited multi-antibiotic resistance (MAR), having the ability to resist at least one antimicrobial of three or more different classes of antibiotics. A nearly similar finding was reported by Rahman et al. (2017), who mentioned that 28.13% of E. coli isolates from milk were MAR. Moreover, Ombarak et al. (2018) revealed that 29.7% of the E. coli isolated from Kareish cheese was AMR. Puig-Peña et al. (2020) revealed that 30.1% of E. coli were AMR. lower results of antibiotic resistance were reported by Hammad et al. (2022), who revealed that 7.8% of E. coli strains from Kareish cheese samples were AMR.
Phenotypic confirmation of ESBL- production showed that 12 isolates of the total of 31 E. coli isolates were ESBL- producers. A nearly similar finding was reported by Joseph and Kalyanikutty (2022), who reported that ESBL- producers were found in 26.75%, while a higher incidence was recorded by Ahmed (2021), who found that 84.61% of ESBL was from dairy products. Enzymes that have evolved from narrow-spectrum parent enzymes, known as ESBLs, are inhibited by β-lactamase inhibitors such as clavulanic acid and have hydrolytic activity against penicillins, aztreonam, and extended-spectrum cephalosporins (cefoxitin or cefotaxime), but not against cephamycins or carbapenems (Lee et al. 2012).
The World Health Organization (WHO), established a list of antibiotic-resistant bacteria that represent the biggest threat to human health, known as the global priority pathogens list. This list is separated into three primary categories according to the need for new antibiotics and their urgency. Enterobacteriaceae that produce ESBL and are resistant to carbapenems are classified as critical list priority one (Shrivastava et al. 2018).
The molecular assay of the 7 out of the selected 10 phenotypic ESBL-positive E. coli isolates which were sorbitol negative and gave pale colonies in MacConkey sorbitol agar were confirmed as E. coli O157:H7 isolates for fliC gene-specific of E. coli O175:H7 (Table 3 and Figure 1). Nearly similar findings were obtained by Sobeih et al. (2023), while a lower incidence in the rate range of 7% –12% was detected in previous studies by Amagliani et al. (2016), Imre et al. (2022), and Farag et al. (2023). In contrast, Abebe et al. (2023) and El-Baz (2019). could not detect E. coli O157:H7 in milk products. According to Rahimi et al. (2012), the acidity of the sample determines whether E. coli O157:H7 survives in food; the bacteria die when the pH drops below 3.5. Therefore, the acidity and the temperature at which the cheese was processed may be the inhibition cause of the lack of E. coli O157:H7 in the yogurt and cheese samples. The presence of this pathogen represents a potential health risk to the consumers. Therefore, good hygienic measures should be applied during production. Also, periodic control and examination must be carried out by the health authorities to provide a healthy and safe product for the consumers.
Table 3 of the current study displays two E. coli isolates with a 20% presence of the Stx1 gene and four isolates with a 40% presence of the Stx2 gene, with a total prevalence rate of 60% for both. Farag et al. (2023) found nearly similar results, reporting 40% detection of both Stx1 and Stx2 positive E. coli isolates in Karish cheese. Conversely, higher results were recorded by Vanitha et al. (2018), Elafify et al. (2020), and Elbehiry et al. (2021). But Taha et al. (2019) detected them at different rates. Freedman et al. (2016) stated that stx2 is more virulent and causes more severe symptoms than stx1.
From the public health point of view, the pathogenic group of E. coli known as shiga toxin-producing E. coli (STEC) is a major foodborne pathogen that contributes significantly to foodborne infections and outbreaks with symptoms ranging from mild to bloody diarrhea and hemolytic uremic syndrome, which can lead to kidney failure (FAO/WHO, 2018). Furthermore, a number of recent studies have shown that all STEC strains (VTEC) are pathogenic, extremely harmful, and can result in serious illness or even death, particularly in young children and the elderly (Koutsoumanis et al. 2020). Lastly, the discovery of STEC contamination in samples that met both national and international legal requirements highlights the need for new, more stringent microbiological criteria.
Conclusion
The current study results indicated that handling and manufacturing of Kariesh cheese are done with inadequate cleanliness,which incomply with Egyptian standard requirements. The presence of coliforms and E. coli in kariesh cheese indicates a potential fecal contamination and enteropathogen, making it a vehicle for the transmission of certain food-poisoning germs to consumers. As a result, it is advised to make kareish cheese using premium non contaminated raw milk. Additionally, every milk used to make kareish cheese needs to be pasteurized or ultraheat treated (UHT). Antibiotics are thought to be the primary treatment for E. coli, but since they are overused and misused, multidrug-resistant bacteria have arisen and are now a global threat to public health. For the purpose of preventing STEC infections in human, raw milk must be heat-treated effectively before being consumed or processed. In order to eliminate the public health risk associated with STECs, consideration should also be given to the concepts of hazard analysis and critical control points. Excellent hygiene systems, flawless manufacturing systems, and moreover further studies are needed to assess the prevalence of VTEC in different dairy products in addition to ways to prevent and eleminate these pathogens from dairy products to protect consumers from health hazards.
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