Molecular Detection of Complement Resistance Genes (traT and iss) in some Enterobacteriaceae Isolates.
The Enterobacteriaceae family contains a large number of species that are causes for most common infections like nosocomial infections, urinary tract and wound infections, pneumonia, meningitis and septicemia (Ruiz et al., 2002). The pathogenicity of this group is due to several factors include adhesins, hemolysin secretion, serum resistance and biofilm creation. Also, it is probable that the genotypes and phylogenetic origin of Enterobacteriaceae varies according to geographical areas (Johnson et al., 2002 and Marty'nez et al., 2006). Outer membrane proteins (OMPs) are a group of proteins exist in the outer membrane of Gram-negative bacteria. These proteins preserve the bacteria in a aggressive environment and also assistance in a number of activities including moving of solute through the impassable outer membrane and signal transduction .These proteins are also complicated in connection and invasion of the bacteria (Koebnik et al., 2000). OMPs have different functions in the activation of the immune system of the host, such as resistance against antimicrobial peptides and activation of dendritic cells (Jeannin et al.,2000). Resistance to the bactericidal action of complement is a distinctive of all gram-negative bacteria that cause septicemia (Joiner, 1988). OMPs of some Gram-negative strains are possibly related with the sensitivity to the bactericidal action of complement (Futoma-Koloch et al., 2006). Previously the role of OMPs in resistance to bactericidal activity of complement was confirmed in S. typhimurium and Yenterocolitica, K. pneumoniae P mirabilis (Heffernan et al., 1994, Alberti et al., 1996 and Kaca et al., 2009). The bactericidal activity of complement is acquired by the transfer protein called traT which was showed in other studies in E. coli, Salmonella, Shigella and Klebsiella strains (Montenegro et al., 1985, Fernandez-Beros et al., 1990 and Wu et al., 2007).
The increased serum survival protein (iss) has an action in defense to serum complement (Nolan et al.,2003). The iss has been known for its activity in virulence of extraintestinal pathogenic Escherichia coli strains (ExPEC) (Hassan, 2011). The iss gene is recognized as one of the most common virulence genes in extraintestinal pathogenic strains in poultry (Badouei et al., 2015). The occurrence of immune resistance among
Enterobacteriaceae family was a cause to study the prevalence of genes associated with serum resistance among Enterobacteriaceae isolates in Babylon province as an indicator for appearance of resistance of Enterobacteriaceae infections .
MATERIALS AND METHODS
Isolation and Identification
Twenty-six clinical isolate of Enterobacteriaceae were collected from different clinical sources (urine, blood, stool and sputum) from patients in Al-Hilla teaching hospital /Babylon province during the period from November 2017 to March 2018. Specimens were cultured on selective media and recognized by biochemical tests as mentioned by forbes et al., 2007. Identification was confirmed by the automated method Vitek-2 system (BioMerieux, France).
Genetic detection of Virulence genes
The conventional PCR technique was used for recognition of virulence genes include (traT and iss).
Extraction of Bacterial DNA
The whole bacterial DNA was extracted from bacterial isolates by using Genomic DNA Mini Bacteria Kit that provided by the company (Geneaid, UK). The DNA solution was stored at -20[degrees]C till used in PCR.
Recognition of virulence genes in E. coli ,Klebsiella pneumonia, Shigella dysenteriae, Serratia marcescens, Salmonella typhi, Proteus vulgaris isolates was achieved by amplifying conventional PCR. The PCR primers were provided by (Macrogen company, Korea). The product size and sequences of the PCR primers are showed in Table 1.
The distribution of bacterial genes according to the site of infection
A total of 26 Enterobacteriaceae isolates were isolated from different clinical cases and were diagnosed by using vitek -2 system , the number each isolates were (5) E.coli, (5) K.pneumoniae, (5) Salmonella typhi, (5) Shigella dysentery, (2) Serratia marcescens and (4) Proteus vulgaris. The prevalence of traT and iss genes was 100% in both of respiratory and intestinal isolates while the percent of traT and iss genes in blood isolates were 100% and 50%, respectively whereas the prevalence of virulence genes in blood culture isolates which have (68.7%) and the occurrence of traT and iss genes observed in UTI isolates was 80 % and 60%, respectively (Table 1). The virulence-associated phenotypes including complement resistance, adhesion and invasion, and maintenance within macrophages in S. typhimurium have been caused by different members of OMPs group (Pulkkinen and Miller, 1991 and Heffernan et al., 1994). The contribution of OMPs has been showed in bacterial serum-resistance by their inactivation of complement at the C3, C9, and C5b-9 steps (Wooley et al., 1993 and Biedzka-sarek et al., 2005). The iss gene was first recognized in a human septicemic E. coli strain (Nolan et al., 1992). The iss and traT genes were present among 95.5% and 86.4% of E.coli strains of blood infections and only among 68.8% and 43.8% of the intestinal infections, respectively (Fernandez-Beros et al., 1990), this result is comparable with the current study. The occurrence of the iss gene was higher in tissue isolates that clarify the role of this protein in pathogenesis of a vain pathogenic E.coli APEC strains (Nolan et al., 1992 and Johnson et al., 2008a). The traT genes were existent in most of the ETEC E.coli strains, this is may be due to ColV plasmids that are capable to transmission fully among varied E. coli strains, giving these strains some virulence-related characteristics (Fernandez-Beros et al., 1990). Molecular detection of virulence factors genes among Enterobacteriaceae isolates.
The traT and iss genes which encoded important virulence factors that are linked with human serum resistance were genetically scanned by using PCR technique for recognition of the existence of these genes in 26 isolates of Enterobacteriaceae family, it was found that 21(80.7%) of Enterobacterial isolates were contained traT gene at 288bp while only 17(65.38%) of isolates were contained iss gene at 258bp. A group of outer membrane protein (OMP) genes has been documented in the Enterobacteriaceae species including Escherichia coli, Shigellaflexneri, Salmonella typhimurium, Klebsiella pneumoniae, Serratia marcescens, Proteus vulgaris, Proteus mirabilis, and Providencia stuartii. One or two peptidoglycan-associated main outer membrane proteins were found in all studied strains (Hofstra et al., 1980). The current data approved with other study which detect the commonness of traT in Gram negative bacteria, particularly E. coli, Salmonella, Shigella and Klebsiella, It was showed in a higher percentage among the E. coli strains isolated from the blood stream of patients with bacteremia/septicemia or from feces of patients with gastrointestinal infections (50-70%) while the incidence of traT in strains isolated from cases of urinary tract infections was variable (Montenegro et al., 1985).
The PCR result observed in Figure 1 shows that 100 % of Salmonella typhi and Serratia marcescens isolates gave positive result for traT gene. OMPs has significant role in pathogenesis of S. typhimurium and Yenterocolitica (Heffernan et al.,1994).
In the current study traT gene was identified in 80% K. pneumoniae and Shigella dysentery isolates, this result compatible with other study which found that traT gene was detected in (78.5%). of K. pneumoniae (Wasfi et al., 2016) while Kuo et al., 2017 (Kus et al., 2017) detected traT gene in 11.3% of K.pneumonia isolates. 75% and 60% of E. coli and Proteus isolates were positive for traT gene, respectively (Fig. 1), this result parallel with other study by Wooly et al., 1993 who showed that 57.1% of E.coli isolates were contained traT gene and Wu et al., 2007 showed presence of traT genes in most of the E.coli O149 isolates. Fernandez-Beros et al.,1990 showed that the iss and traT genes were existent among 95.5 % and 86.4 % of the E.coli blood isolates and only among 68.8 % and 43.8 % of the intestinal isolates, correspondingly. Previously it was described a ColV plasmid, among E.coli isolates from blood and intestinal sources, ColV plasmids confer Escherichia coli with some virulence genes including iss and traT (Aguero et al., 1984 and Skyberg et al., 2008). ColV plasmids are capable to transmission completely among diverse E. coli strains, providing those strains with several virulence-linked features (Fernandez-Beros et al., 1990).
The occurrence of iss gene product at 258 bp in E. coli and Shigella dysentery isolates was 80% while it was 60% among K. pneumonia ,Salmonella typhi isolates and 50% of Proteus vulgaris and Serratia marcescens isolates as showed in Fig. 2. This result comparable with a study of Badouei et al., 2015 who found that the occurrence of the iss gene in a vain E.coli strains was 90.3% in the septicemic isolates and 64.3% among cecal isolates and also approved with a study of Vaz et al., 2017 who observed the occurrence of iss gene was ranged from 75 to 91% among the ExPEC strains and was ranged from 49 to 57% among the fecal strains, while other study showed that 30% of uropathogenic E.coli isolates were positive for iss gene and only 8% of K.pneumoniae isolates were contained iss gene (Hassan, 2015).
The iss gene was represented one of the most prevalent virulence genes in extra-intestinal pathogenic strains and three alleles of iss were recognized among E. coli isolates (Johnson et al., 2008b). Human serum resistance among ExPEC permits persistence in the host's blood stream and can possibly distribute to cause human infections through the food chain is indistinct, it can colonize the intestinal area and prompt virulence gene transmission to human strains. For example, APEC strains and urogenital pathogenic E. coli (UPEC) causing human infections were revealed to share large genomic sequences (Johnson et al.,2008a and Kariyawasam et al.,2007).
The present study concluded that high distribution of genes encoded for outer membrane proteins responsible for human complement resistance among Enterobacteriaceae species isolated from different clinical infections and also these genes were detected among extraintestinal infections isolates.
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Hayder Shkhair Obayes Al-Janabi *, Mohanad Jawad Kadhim and Haider Turky Al-Mousawi
College of Biotechnology, Al-Qasim Green University, Babylon, Iraq.
* Correspondence: email@example.com; 009647808507535
(Received: 11 September 2018; accepted: 30 November 2018)
Caption: Fig. 1. Agarose gel electrophoresis image that shown the PCR product of a virulence factor gene (traT) at (258bp) in different bacterial isolates. Where M: Marker (2000-100bp), lane (1-5) E. coli, lane (6-10) K. pneumonia, lane (11-15) Salmonella typhi, lane (16-20) Shigella dysentery , lane (21-22) Serratia marcescens and lane (23-26) Proteus vulgaris.
Caption: Fig. 2. Agarose gel electrophoresis image that shown the PCR product of a virulence factor gene (iss) at (258 bp) in different bacterial isolates. Where M: Marker (2000-100bp), lane (1-5) E. coli, lane (6-10) K. pneumonia, lane (11-15) Salmonella typhi, lane (16-20) Shigella dysentery , lane (21-22) Serratia marcescens and lane (23-26) Proteus vulgaris.
Table 1. The size and sequences of primers used in current study Gene Primer Sequence size References name (bp) Iss F GGCAATGCTTATTACAGGATGTGC R GAGCAATATACCCGGGCTTCC 258 (Hassan, 2011) traT F GGTGTGGTGCGATGAGCACAG R CACGGTTCAGCCATCCCTGAG 288 (El Fertas-Aissani, et al., 2013) Table 2. The dissemination of genes among bacterial isolates according to the site of infection. Source of isolates traTn(%) issn(%) Respiratory infections 2/2 2/2 (100%) (100%) Intestinal infections 7/10 7/10 (70%) (70%) Blood 4/4 2/4 (100%) (50%) Urinary tract infections 8/10 6/10 (80%) (60%) Total 21/26 17/26 (80.7%) (65.3%) Table 3. The occurrence of virulence factors genes among bacterial species. Species Number traTn (%) issn (%) E.coli 5 3/5(60%) 4/5(80%) Klebsiella pneumonia 5 4/5(80%) 3/5(60%) Salmonella typhi 5 5/5(100%) 3/(60%) Shigella dysentery 5 4/5(80%) 4/5(80%) Proteus vulgaris 4 3/4(75%) 2/4(50%) Serratia marcescens 2 2/2(100%) 1/2(50%) Total 26 21/26(80.7%) 17/26(65.38%)
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|Title Annotation:||RESEARCH ARTICLE|
|Author:||Al-Janabi, Hayder Shkhair Obayes; Kadhim, Mohanad Jawad; Al-Mousawi, Haider Turky|
|Publication:||Journal of Pure and Applied Microbiology|
|Date:||Dec 1, 2018|
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