Abstract
General Background: Escherichia coli is a widely distributed species that includes strains ranging from highly pathogenic to harmless avirulent isolates, often found in the human gut. Specific Background: E. coli pathogenicity is determined by virulence factors like adhesins, invasins, toxins, and capsules, which are often transferred horizontally via phages and plasmids. Knowledge Gap: Despite advancements in understanding E. coli virulence, there is a need to further understand genetic factors contributing to urinary tract infections, especially in regions with high antibiotic resistance. Aims: The study investigated the prevalence of virulence genes and antibiotic resistance in E. coli strains from UTI patients at Al Hussien Teaching Hospital in Iraq. Results: The study reveals the presence of specific virulence genes in UPEC strains from a specific region, suggesting the potential involvement of the pap AH gene in UTI pathogenesis. Novelty: This study reports the prevalence of specific virulence genes in UPEC strains from a specific region, indicating the potential role of the pap AH gene in UTI pathogenesis. Implications: The study indicates that UPEC strains, characterized by high virulence factors like pap AH, are promising vaccine targets, necessitating further research for effective prevention strategies.
Highlights:
- E. coli strains show high antibiotic resistance in UTI patients.
- pap AH gene is crucial for UPEC virulence.
- Virulence factors like pap AH are potential vaccine targets.
Keywords: E. coli, UTI, virulence factors, antibiotic resistance, pap AH gene
Introduction
From infants to the elderly, urinary tract infections (UTIs) are among the most prevalent and widespread bacterial diseases in the world [1, 2]. A UTI is defined as having more than 105 bacteria per milliliter in the urine. In clinical terms, urinary tract infections (UTIs) are classified as either simple or complex cases based on the existence of structural or neurological abnormalities of the urinary system [3,4] as in Figure 3. Of all the bacteria, Escherichia coli, is the most common cause, responsible for about 80–90% of infections [5]. The urethra is the most common site of E. coli infection, which is followed by the bacteria's ascent to the bladder. The pathotype of extraintestinal pathogenic Escherichia coli that was originally identified from the urine of patients with urinary tract infections is known as uropathogenic Escherichia coli (UPEC). Normally, E. coli is present in the lower gastrointestinal tract of humans as a commensal flora. The term "UPEC" came up because they were different from those that were cultivated from stool specimens of healthy people and those that caused diarrhoea. The most significant indicator of pathogenicity in UPEC strains is their ability to adhere to host epithelial cells in the urinary tract, but they also have a large number of secreted (toxins, iron-acquisition systems) and structural (fimbriae, pili, flagella) virulence factors that are important to the pathogenesis [6] Figure 2. Escherichia coli is a Gram-negative bacillus that is a member of the Enterobacteriaceae family and is found in the human gastrointestinal system as a component of the microbiota. It rarely causes illness unless the host has weakened immune system, and it typically coexists peacefully with its host. Not many E. coli strains, though, have the ability to diverge from their commensal counterpart and become pathogenic. This means that some virulence characteristics that allow these strains to adapt to new environments and cause a wide range of diseases are acquired by them through plasmids, pathogenicity islands, or DNA horizontal transfer of transposons [7]. Complicated microbial populations encased in an extracellular polymeric substance (EPS) matrix that they self-produce are known as biofilms. Bacterial cells that are attached to both stationary surfaces and one another (living or inanimate) are found in biofilms [8]. Antibiotics, antiseptics, and disinfectants cannot reach bacterial cells living in this kind of sessile biofilm [9, 10]. Catheter-associated urinary tract infections (CAUTIs) are among the infections linked to indwelling medical devices that are caused by biofilm formation [11, 12]. One of the main contributing factors to the pathophysiology of CAUTIs is biofilm growth on the surface of a urinary catheter [13]. E. coli is one of the most prevalent species implicated in biofilm-related illnesses; it is especially crucial in urinary tract infections (UTIs), which can result in chronic infections [14]. The bacteria possess a variety of potential virulence factors, such as cytotoxic necrotising factor 1 (cnf1), A fimbrial adhesin (afa), S fimbriae (sfa), and pyelonephritis-associated pili (pap) [15]. The majority function as invasive and sticky elements that set off certain signalling pathways that inflame and harm the kidneys. There have been reports of their interventions in cases of cystitis, urethritis, and pyelonephritis [16. 17]. Since most isolates have substantial resistance to a variety of antimicrobial agent classes, including tetracyclines, penicillins, cephalosporins, aminoglycosides, fluoroquinolones, and macrolides, the advent of antimicrobial resistance highlights the significance of UPEC [18]. Consequently, the majority of treatment alternatives are ineffective, which raises the expense of hospital stays and therapy.
Aim of the Study
The study's objective was to determine whether certain biofilm genes were present in E. coli by using the molecular technique of PCR
Methods
Urine Specimens
Between December 2023 and February 2024, fifty urine specimens were taken from patients suffering from urinary tract infections at Al-Hussein Teach Hospital in Thi-Qar, Iraq.
In order to minimise any microbiological and artifactual contaminations, midstream samples were collected in the morning and sent straight to the laboratory at 4°C in a sterile container [19].
E. coli Identification
The urine specimens were found to contain E. coli bacteria, as per the methodology developed by Bailey and Scott 19. Urine samples were stored at 37°C for 24 hours after being grown on nutrient agar (NA), MacConkey agar (MCA), and eosin-methylene blue (EMB) agar (Merck, Germany). In the MCA, the suspected colonies were identified as lactose-positive (pink in colour), while in the EMB agar medium, suspicious colonies were identified as green with metallic shine. The E. coli isolates were identified by Gramme staining, the Api20E test, and the Polymerase Chian Reaction (PCR) [19].
Antimicrobial Susceptibility Test
Using the disc diffusion method as described by references [20], the sensitivity of the isolated organisms to eight antibiotics was evaluated. The antimicrobials that were tested are from the cephems (ampicillin 10 mg, amoxicillin-clavulanate 20/10 mg, ceftazidime 30 mg, aztreonam 30 mg, gentamicin 10 mg, levofloxacin 5 mg, cefotaxime 30 mg, and trimethoprim 5 mg) classes, as well as the β-lactam, aminoglycoside, quinolones and fluoroquinolones, folate pathway inhibitors, and penicillin.
Polymerase Chain Reaction (PCR)
To identify the biofilm genes and E. coli molecules genetically, conventional PCR was employed to amplify the target DNA using certain primer pairs (Table 1&2).
Target Gene | Oligonucleotide Sequence (5’-3’) | Amplicon Size (bp.) | References |
16sRNAE. coli | F: AGAGTTTGATCMTGGCTCAGR: CCGTCAATTCATTTGAGTTT | 919 bp | [21] |
Primer name | Sequences 5'-'3 | TM | PCR product | Reference |
papAH | F ATGGCAGTGGTGTCTTTTGGTGR CGTCCCACCATACGTGCTCTTC | 61°C | 720bp | [22] |
saf | F CTCCGGAGAACTGGGTGCATCTTACR CGGAGGAGTAATTACAAACCTGGCA | 71°C | 410bp | [23] |
Preparation of PCR primers
In accordance with manufacturing instructions, the primers are prepared by dissolving the lyophilised primers in TE (Tris-EDTA) buffer to create a stock solution with a concentration of 100 pmole/Ml. Primer working solutions were made by diluting the stock solution with TE buffer and spinning down to an overnight temperature of 4°C. This resulted in a final working solution (10 pmole/Ml) for each primer.
The agrose gel electrophoresis method was used to analyse the multi-gene PCR results in the following steps:
1. 1% Using 1X TBE, agarose gel was made, dissolved in a water bath at 100 °C for 15 minutes, and then allowed to cool to 50–60 °C. Russell and Sambrook (2001)21.
2. The agarose gel solution was then mixed with 2µL of ethidium bromide dye.
3. After positioning the comb correctly, the tray was filled with agarose gel solution. The comb was then gently removed from the tray and 10µl of PCR product and 5ul of (1500 bp Ladder) were added to each comb well. The tray was then allowed to solidify for 15 minutes at room temperature.
4. After fixing the gel tray in the electrophoresis chamber, 1X TBE buffer was added to it. After that, electric current was run for 30 minutes at 110 volts and then for 60 minutes at 75 volts.
The PCR products were observed by the use of an ultraviolet transilluminator.
Conventional PCR detection reaction
PCR master mix reaction preparation
PCR master mix reaction was prepared according to company instructions (transgenbiotech inc.china) Table -3
as shown in link :- https://www.transgenbiotech.com/pcr_enzyme/easytaq_dna_polymerase.html
Component | Quantities |
EasyTaq® DNA Polymerase | 500 U×1 |
10×EasyTaq® Buffer and Mgcl2 | 1.2 ml×1 |
2.5 mM dNTPs | 800 μl×1 |
6×DNA Loading Buffer | 1 ml×1 |
Reaction Setup
Subsequently, the aforementioned PCR master mix reaction components are put into standard PCR tubes along with the Multiplex PCR as lyophilised materials that contain all additional components required for the PCR reaction, including Taq DNA Polymerase, dNTPs, and 6 mM MgCl2, pH 8.7. After that, the tube was centrifuged for three minutes using an Exispin vortex. then put into a thermocycler for multigene PCR.
PCR Thermocycling Conditions
As indicated in Table-4, PCR thermocycler conditions for every gene were completed using a traditional PCR thermocycler equipment.
Component | 50μl reaction |
10 µM Forward Primer | 0.5 µl |
10 µM Reverse Primer | 0.5 µl |
Template DNA | Variable |
Easy Taq 2X Master Mix with Standard Buffer | 12.5 μl |
Nuclease-free water | Variable |
Total | 25 μl |
No. of cycles cycle | Time | Temperature(˚C) | Step |
1 | 3 min | 94 | Initial denaturation |
35 | 30sec | 94 | Denaturation |
30 sec | Variables according to (primer's TM) | Annealing | |
1 min | 72 | Extension | |
1 | 5 min | 72 | Final extension |
- | ∞ | -4 | Hold temperature |
Result and Discussion
According to the findings of the current study, E. coli is the primary cause of UTIs. Out of 50 samples that were collected, around 10 isolates of E. coli were found, which is consistent with several studies that found a high incidence of E. coli 24. The following were the findings of the test for antibiotic sensitivity: Beta-Lactam (amoxicillin-clavulanate) accounted for 80% of the resistance reported in this study, which was in line with another study25,26. The reason for this increased resistance could be that the majority of E. coli isolates contain beta-lactamase. The penicillins group, ampicillin, had 100% of the resistance; the percentage of ampicillin is similar to a previous study25. The antibiotic aztreonam belonged to the monobactams group, whereas the resistance percentage to ceftazidime varied among the cephems group, where it was ceftazidime 70% and cefotaxime 60%,27,28,29, which corresponded with ceftazidime results in the current study. Our analysis disagreed with the study that was published 28 .Additionally, 50% of the UPEC isolates had gentamicin resistance, according to the data. This result was in line with Al-Taai24. Furthermore, 30% of the antibiotics were levofloxacin, which is a member of the quinolone and fluoroquinolone groups; the resistance percentage was established at 25%, while 50% of the group is composed of trimethoprim.DNA was extracted from 10 bacterial isolates, including E. coli, using a genomic DNA minikit, according to 30.Similar outcomes were also seen when the DNA samples were subjected to gel electrophoresis analysis, as Figure 3 illustrates. Here, DNA bands indicative of purified DNA samples were found. Ten isolates of E. coli were subjected to molecular identification using specific primers for the PCR amplification of 16S rRNA; all of the isolates produced positive results. Figure 4.
The existence and activity of a few potential virulence factors determine how severe an infection is. The UPEC adherence into the renal epithelial cells is necessary for the initiation of infection. Among the key components of UPEC adherence to the renal epithelium and the ensuing damage are fibrinal factors (afa, sfa, and pap) 31, 32. PCR was performed on each of these isolates to identify the presence of the Pap AH and saf genes. The papAH gene was looked at for each of them. The findings revealed that 10 (100%) of these isolates had these genes, despite the fact that six of them carried saf genes. Figures 5 and 6. Several investigations, including ones conducted in Mexico and India 33, 34, showed outcomes that were similar to ours.According to the current study, there is a correlation between having adherence genes and antibiotic resistance. It also found that the highly resistant isolates contain both genes, which clarifies the crucial role these genes play in resistance.The low number of samples obtained, the absence of molecular analysis of antibiotic resistance genes, and the absence of urine sample assessment of healthy paediatric children as a control group were the limitations of the current investigation.
Conclusion
We hypothesize that the increased frequency of the pap and sfa genes may be the cause of the patients' UTIs. High virulence factor prevalence can help UPEC strains colonize the urogenital tract more easily, which increases the bacteria's ability to adhere to target cells and make them more harmful. Therefore, these genes may be the focus of a vaccination designed to prevent E. coli infections. To ascertain the pathophysiology of UTIs and to discover the virulence factors of E. coli strains that cause them, more research is necessary.
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