Antibiotic Susceptibility Patterns and Virulence-Associated Factors of Vancomycin-Resistant Enterococcal Isolates from Tertiary Care Hospitals

This study explored the prevalence of multi-drug resistance and virulence factors of enterococcal isolates obtained from various clinical specimens (n = 1575) including urine, blood, pus, tissue, catheter, vaginal wash, semen, and endotracheal secretions. Out of 862 enterococcal isolates, 388 (45%), 246 (29%), 120 (14%), and 108 (13%) were identified as Enterococcus faecalis, Enterococcus faecium, Enterococcus durans, and Enterococcus hirae, respectively, using standard morphological and biochemical methods. The antibiotic resistance profile of all these enterococcal isolates was checked using the disc diffusion technique. High-level resistance was observed for benzylpenicillin (70%) and vancomycin (43%) among E. faecalis and E. faecium isolates, respectively. This study also revealed the prevalence of ‘multi-drug resistance (resistant to 3 antibiotic groups)’ among the vancomycin-resistant enterococcal strains, and this was about 11% (n = 91). The virulence determinants associated with vancomycin resistance (VR) were determined phenotypically and genotypically. About 70 and 39% of E. faecalis and E. faecium isolates showed to be positive for all four virulence factors (gelatinase, protease, hemolysin, and biofilm). Among the several virulence genes, gelE was the most common virulence gene with a prevalence rate of 76 and 69% among E. faecalis and E. faecium isolates, respectively. More than 50% of VRE isolates harbored other virulence genes, such esp, asa, ace, and cylA. Similarly, the majority of the VR enterococcal isolates (n = 88/91) harbored vanA gene and none of them harbored vanB gene. These results disclose the importance of VR E. faecalis and E. faecium and the associated virulence factors involved in the persistence of infections in clinical settings.


Introduction
Enterococci has been the most important causative agent of endocarditis and hospitalacquired infections for virtually from the last century. Enterococci are the most dominant pathogens among nosocomial urinary tract infection (UTI), bacteremia, and wound infections [1]. Nowadays, the majority of nosocomial infections are extremely difficult to treat with the available antibiotics, leading to high morbidity and mortality worldwide. Their intrinsic resistance to common antibiotics (penicillin, nalidixic acid, clindamycin,
The 91 enterococcal isolates (37 of E. faecalis and 54 of E. faecium) showing resistance to 5 antibiotics, namely benzylpenicillin, erythromycin, ciprofloxacin, teicoplanin, and vancomycin, were used to determine the MIC of these five antibiotics by the MDT (microdilution technique) and VITEK 2 system and compared to find out any discrep-ancy between these two results. According to the MDT, the MIC of benzylpenicillin for 72 VRE isolates was ≥32 µg/mL, and for the remaining 19 strains the MIC was 16 µg/mL. The VITEK 2 system also revealed a similar MIC value of benzylpenicillin. The MIC of erythromycin for 34 isolates was 4 µg/mL, and for the remaining 57 isolates the MIC value was >8 µg/mL. The same trend of the result was obtained from VITEK 2. The MDT revealed the MIC value of ciprofloxacin of 4 µg/mL (intermediate) for 7 VRE isolates, and for the remaining 84 isolates the MIC was 8 µg/mL (resistant region), whereas the VITEK 2 system displayed that the MIC of ciprofloxacin was 8 µg/mL (resistant region) for all the 91 isolates. Similarly, the MIC of teicoplanin was in the resistance region (MIC ≥ 32 µg/mL) for 88 isolates out of 91 MDR isolates. For the remaining three isolates, the MIC was found within a sensitive region (2 µg/mL), whereas according to the VITEK 2 system, the MIC of teicoplanin for 80 strains was ≥32 µg/mL, for 6 strains the MIC was 16 µg/mL (resistant region), and for the remaining 5 strains the MIC was 4 µg/mL (intermediate resistant). According to vancomycin, both the MDT and VITEK 2 system displayed an MIC of ≥32 µg/mL (resistant region) for all 91 strains (Table 4). Even though the MIC values acquired from the VITEK 2 system and reference method, MDT, were majorly agreed upon, some discrepancy errors were determined, and these are displayed in Table 5.

Detection of Virulence Phenotypes among VRE Isolates
The VR E. faecalis (n = 37) and E. faecium (n = 54) showing resistance to five antibiotics were evaluated for VR-associated virulence determinants such as gelatinase, protease, hemolysin, and biofilm production.
Tables S2 and S3 show the complete details of the virulence phenotypic factors associated with VRE isolates. Gelatinase activity was detected in 71 VRE isolates (78%), and a clear zone was observed around the colonies. Among these 71 gelatinase-positive VRE, 31 (84%) were from E. faecalis and 40 (74%) were from E. faecium. Out of 59 isolates, 28 (76%) from E. faecalis and 31 (58%) from E. faecium) were positive for protease activity. According to the hemolysis assay, 33 (89%) E. faecalis isolates and 30 (56%) E. faecium strains were positive for hemolysis ( Figure 2). S 91 91 * According to Chi square test the MIC value determined by VITEK system and MDT was statistically significant (p < 0.006). Table 5. Discrepancies between VITEK 2 system and the reference method, MDT, in determining the minimum inhibitory concentration of antibiotics against 91 enterococcal isolates.

Antibiotics
No

Detection of Virulence Phenotypes among VRE Isolates
The VR E. faecalis (n = 37) and E. faecium (n = 54) showing resistance to five antibiotics were evaluated for VR-associated virulence determinants such as gelatinase, protease, hemolysin, and biofilm production.
Tables S2 and S3 show the complete details of the virulence phenotypic factors associated with VRE isolates. Gelatinase activity was detected in 71 VRE isolates (78%), and a clear zone was observed around the colonies. Among these 71 gelatinase-positive VRE, 31 (84%) were from E. faecalis and 40 (74%) were from E. faecium. Out of 59 isolates, 28 (76%) from E. faecalis and 31 (58%) from E. faecium) were positive for protease activity. According to the hemolysis assay, 33 (89%) E. faecalis isolates and 30 (56%) E. faecium strains were positive for hemolysis ( Figure 2).  Biofilm detection was carried out using a crystal violet assay and showed that 32 (87%) E. faecalis and 36 (67%) E. faecium strains formed biofilm, but their biofilm-forming strength varied from the isolates. Among these, 51% (n = 19) of E. faecalis and 28% (n = 15) of E. faecium were found to be strong biofilm producers. Similarly, 27% (n = 10) of E. faecalis and 37% (n = 20) of E. faecium strains were moderate biofilm producers, and the remaining isolates (three of E. faecalis and seven of E. faecium) were weak producers ( Figure 3). Overall, the results showed that out of the 37 isolates of E. faecalis, 26 (70%), and out of 54 isolates of E. faecium, 21 (39%) showed themselves to be positive for all of the phenotypic virulence factors tested in this study. strength varied from the isolates. Among these, 51% (n = 19) of E. faecalis and 28% (n = 15) of E. faecium were found to be strong biofilm producers. Similarly, 27% (n = 10) of E. faecalis and 37% (n= 20) of E. faecium strains were moderate biofilm producers, and the remaining isolates (three of E. faecalis and seven of E. faecium) were weak producers ( Figure 3). Overall, the results showed that out of the 37 isolates of E. faecalis, 26 (70%), and out of 54 isolates of E. faecium, 21 (39%) showed themselves to be positive for all of the phenotypic virulence factors tested in this study.

Correlation between Virulence Phenotypes and Genotypes
The correlation between the phenotypic and genotypic virulence determinants of enterococcal isolates was statistically assessed at different levels against one another (chisquare and Fisher's Exact test). The strongest association was found between the gelatinase activity and their encoding gene gelE. All the gelE-positive isolates of E. faecalis (n = 28) and E. faecium (n = 37) were gelatinase-positive and their correlation was highly significant (chi-square p = 0.0001, Fisher's Exact test p = 0.0001) ( Table 6). Among the 24 isolates of sprE-positive E. faecalis, 16 isolates showed protease activity, and the remaining 8 isolates showed negative protease activity (chi-square p = 0.0388, Fisher's Exact test p = 0.0300). In the case of E. faecium, all the sprE-positive isolates ((n = 26) were positive for protease activity. The association between protease and sprE gene was highly significant (chi-square p = 0.0001, Fisher's Exact test p = 0.0001) ( Table 7). A similar statistically significant correlation was observed among hemolysis-positive isolates. Out of 23 cylA-positive E. faecalis isolates, all are positive for hemolysis activity (chi-square p = 0.0001, Fisher's Exact test p = 0.0001). In the case of E. faecium, 28 cylA-positive isolates were positive for

Correlation between Virulence Phenotypes and Genotypes
The correlation between the phenotypic and genotypic virulence determinants of enterococcal isolates was statistically assessed at different levels against one another (chisquare and Fisher's Exact test). The strongest association was found between the gelatinase activity and their encoding gene gelE. All the gelE-positive isolates of E. faecalis (n = 28) and E. faecium (n = 37) were gelatinase-positive and their correlation was highly significant (chi-square p = 0.0001, Fisher's Exact test p = 0.0001) ( Table 6). Among the 24 isolates of sprE-positive E. faecalis, 16 isolates showed protease activity, and the remaining 8 isolates showed negative protease activity (chi-square p = 0.0388, Fisher's Exact test p = 0.0300). In the case of E. faecium, all the sprE-positive isolates ((n = 26) were positive for protease activity. The association between protease and sprE gene was highly significant (chi-square p = 0.0001, Fisher's Exact test p = 0.0001) ( Table 7). A similar statistically significant correlation was observed among hemolysis-positive isolates. Out of 23 cylA-positive E. faecalis isolates, all are positive for hemolysis activity (chi-square p = 0.0001, Fisher's Exact test p = 0.0001). In the case of E. faecium, 28 cylA-positive isolates were positive for hemolysis and 2 cylA-positive isolates were negative for hemolysis (chi-square p = 0.0301, Fisher Exact test p = 0.0152) ( Table 8) The biofilm-producing ability of E. faecalis was correlated with gelE and sprE; however, their correlation was statistically nonsignificant (chi-square p = 0.9388, Fisher's Exact test p = 0.3996 for E. faecalis and chi-square p = 0.7417, Fisher's Exact test p = 0.6750 for E. faecium) ( Table 9). Although, a good significant correlation was observed between esp, ace, and asaI genes and the biofilm-forming ability of E. faecalis and E. faecium isolates (Table 10). Table 9. Phenotypic and genotypic correlation between biofilm-forming ability and gelE and sprE genes.

Discussion
Nowadays, enterococci are considered one of the major nosocomial pathogens due to their intrinsic nature of resistance to several antibiotics including beta lactam and glycopeptide antibiotics. In particular, vancomycin-resistant enterococci (VRE) have become a challenging issue among public healthcare communities. Several studies have investigated the risk factors associated with VRE from various regions of India and few or no more studies have been reported from Tamil Nadu. The overall frequency of enterococcal isolates in this study was 55%. One earlier study [18] reported on the incidence of VRE at a tertiary care hospital in Northern India, and this frequency was about 7.9%. Another study [19] reported that the incidence of enterococcal infection in Ethiopia is about 6.2%. This high deviation might be due to variation in the study participants and a steady increase in the frequency of enterococcal infections among the hospital settings, etc.
The high frequency of enterococcal isolates was obtained from the age group of 41-65 (n = 359, 42%) and was followed by >65 age group (n = 202, 23%). The pediatric group (1-5 age group) showed the lowest frequency of enterococcal isolates (n = 46, 5%). Most of the enterococcal isolates were attained from the urology department (n = 329, 38%) and were followed by outpatients (281, 33%). A contrasting result was reported by Jahansepas et al. [17] who found that the highest frequency of enterococcal strains was from outpatient (29%) and internal ward (23%) rather than the urology department (8%) or other sources. According to the gender-wise distribution of enterococcal isolates, females showed a higher frequency (n = 514, 60%) than males (n = 348, 40%), and this may be due to the increased number of samples received and the high prevalence of urinary tract infections and another infection among women compared to men. This report is on the contrary to that of Karna et al. [1] who reported that enterococcal infection is more common in males (73.9%) than females. Among the various specimens collected, urine showed a high number of enterococcal isolates (n = 335, 39%). This result is correlated with Karna et al. [1] who reported that urine is the major source of enterococcal strains rather than any other sources such as blood, pus, etc.
The prevalence of VRE among the clinical specimens in this study was found to be 31%. Among them, 11% of VRE was obtained from outpatients and the remaining 20% of VRE was from hospitalized patients, including those in urology, ICU, surgery, pediatrics, and hematology departments. Similarly, the prevalence of VRE in Nepal was 25.3% [1] (Karna et al., 2019) and 21.4% in Iran [20]. However, the majority of previous studies [21][22][23] reported a lower prevalence of VRE compared to our study report. Such variation in VRE prevalence may be due to variation in geographical location, duration of hospital exposure, usage of medical devices, sample size, etc. [1]. The highest frequency of VR is observed among E. faecalis (43%) compared to that of E. faecium (35%) and E. durans (9.2%); however, multi-drug resistance (resistance to three antibiotics categories) is highly observed among E. faecium (22%) compared to that of E. faecalis (9.5%). This result is more prospectively comparable with other studies [1,24,25] which reported an increased occurrence rate of vancomycin resistance among E. faecium compared to E. faecalis. A nationwide prevalence study on the epidemiology of VRE was carried out with 142 healthcare institutions in Switzerland, and it was disclosed that a high case of VRE infections may be due to nosocomial distribution [26]. Amongst the eleven antibiotics used in this study, the highest resistance of enterococcal isolates was observed to benzylpenicillin (38%) and vancomycin and erythromycin (31%), followed by high-level gentamycin (30%). This result is more in agreement with the report of Sreeja et al. [27] and Karna et al. [1]. Another study by Bhatt et al. [24] reported that enterococcal strains exhibited up to 95% of beta lactum resistance, and this high-level resistance may be due to a low affinity between the penicillin-binding protein of the enterococcal isolates and an antibiotic [28]. We also found that 4% of E. faecalis and 11% of E. faecium were resistant to linezolid. This same trend of findings was demonstrated in Europe [29], the United States and Taiwan [30], and India [18]. Linezolid resistance among enterococcal isolates remains uncommon in India; however, the current study report indicates a gradual emergence of linezolid resistance in recent years.
The current study's results also reveal the prevalence rate of MDR (28%), which is defined by resistance to at least three antibiotic categories [31]. The MDR was more frequent among E. faecium (52%) than E. faecalis (27%), and a similar finding was reported by Maschieto et al. [32]; Karna et al. [1]. The highest proportion of E. faecium may be due to its ability to become resistant to multiple antibiotics. Conversely, the current MDR prevalence rate is less than other studies reported from Nepal [1], Ethiopia [23], and Slovenia [25], indicating the lower frequency of MDR in our country. A high-level prevalence rate of MDR isolates was reported from surgical wound infections and blood cultures of patients with bacteremia collected from Minia University hospital, Egypt. The isolates were resistant to cefepime, ampicillin, tetracycline, erytromycin, vancomycin, and linezolid [33]. The prevalence rate of MDR in the current study at least to five antibiotics is about 11% (n = 91) and is most frequent among E. faecium strains (n = 54) compared to E. faecalis (n = 37), indicating the dissemination of MDR pathogens in healthcare communities. The majority of the vancomycin-resistant enterococcal isolates obtained from the inpatients of Algerian hospitals were found to be resistant to at least five antibiotics in addition to glycopeptides [34].
The minimum inhibitory (MIC) concentration of 5 antibiotics for the 91 VRE isolates (showing resistance to five antibiotics) was determined by the VITEK 2 and MDT assay, and the results are compared in order to discover any discrepancy between the two methods.
The study results showed that the MIC values obtained for five antibiotics were higher than the MIC values of previous studies [1,35], indicating the high-level resistance of VRE isolates from Tamil Nadu, a south Indian state. Further, variation in MIC and the sensitivity/resistance pattern of VRE isolates from various countries may be due to sampling size, duration of hospital exposure/stays, geographical location, etc. [1]. The MIC of benzylpenicillin and erythromycin for 91 VRE isolates obtained from the MDT is agreed with their MIC obtained from VITEK 2. However, there was no discrepancy between the reference method (MDT) and VITEK 2 for benzylpenicillin, as well as erythromycin and vancomycin, whereas six minor errors for ciprofloxacin were observed. In line with teicoplanin, one major error and five minor errors were determined between the two methods. These results disclose the reasonable accuracy of the VITEK 2 system. Generally, the VITEK 2 system is an easy system to handle and provides results rapidly with a reasonable accuracy in clinical microbiology laboratories [36].
The pathogenicity of the clinical enterococcal isolates is mainly associated with their virulence factors that facilitate adherence, invasiveness, etc. [37]. In this study, the prevalence of virulence factors among E. faecalis and E. faecium differed significantly. Further, the frequency of virulence factors such as gelatinase, protease, and hemolysin were higher among E. faecalis (73%) compared to E. faecium (54%). This result is concurrent with reports from previous studies [13,17,22,25]. Phenotypic studies have also showed that gelatinase and hemolysin are the virulence determinants present with a high frequency among VRE isolates, followed by their biofilm-producing ability. This result is consistent with genotypic studies, in which gelE prevalence among VRE isolates is higher than any other genes, followed by asaI gene. This result is agreed with by Heidari et al. [38] and Shokoohizadeh et al. [22], who reported gelE and asaI as the most common virulence genes among VR E. faecalis, but is in contrast with Jahansepas et al. [17] who found that esp is the most frequent gene present in VRE. The lowest frequency of the gene amongst VRE was hyl, and this report is in agreement with the results reported by Jahansepas et al. [17] and Golob et al. [25]). The cylA gene was detected in 62% of E. faecalis and 56% of E. faecium strains, and this is in contrast with Jahansepas et al. [17] who did not detect the cylA gene in any of the 35 VRE isolates. A simultaneous presence of all the seven virulence genes was observed in 9% of VRE isolates (n = 8, three from E. faecalis and five from E. faecium).
The study also revealed that the majority of the isolates showing themselves as phenotypically positive for hemolysis, confirmed genotypically via expressing cylA gene as hemolysis, is explained by cylA gene, which is a prerequisite for activating cylL L/S [39]. Few isolates positive for hemolysis due to a lack of cylA gene may be explained by a low level or the downregulation of gene expression. Overall, a good correlation was observed between gelatinase phenotype and its biomarker gene gelE, protease phenotype and sprE gene, and hemolysis phenotype and cylA gene. However, the biofilm-forming phenotype was majorly associated with esp, ace, and asaI genes. The virulence genes associated with the biofilm-forming ability vary from enterococcal isolates.
The distribution of virulence genes is highly frequent among E. faecalis compared to E. faecium isolates. A high frequency of multiple determinants could effectively contribute to bacterial colonization and their pathogenesis among humans. The majority of the isolates (more than 85%) in this study harbored the vanA gene and showed high-level resistance to vancomycin (MIC > 32 µg/mL) and teicoplanin (MIC > 32 µg/mL), which is the critical feature of the VanA phenotype. This result is correlated with Ghoshal et al. [40] in India, Talebi et al. [41] in Iran, and Benamrouche et al. [34] in Algeria, who reported the presence of vanA gene and the complete absence of vanB among the VRE isolates. Recent studies by George et al. [42] in Southi Arabia and Moosavian et al. [43] in Iran reported that the majority of vancomycin resistance (more than 60%) among enterococcal isolates is due to vanA gene; nearly less than 5% of the isolates harbored vanC gene, and the remaining isolates showed themselves to be positive to vanB gene. The major reason for the differences in the existence of resistance among the various regions is mostly based on the usage of antibiotics in hospitals [17].

Study Design and Period of Sampling
The study was carried out at various tertiary care hospitals located in and around Tamil Nadu, a south Indian state, from 2018 to 2020. Specimens including urine, blood, pus, tissue, catheter, vaginal wash, semen, and endotracheal wash were collected from both outpatients and inpatients, including those on ICU, surgery, pediatric, urology, and hematology wards. Samples were collected from every patient after obtaining their written consent in a well-structured questionnaire to collect the data of the study participants. The patients' historical and clinical data were obtained by 2 experienced nurses.
All the media, reagents, and antibiotics used in this study were purchased from Hi media, India.

Screening and Identification of Enterococcus
All the collected specimens (urine, pus, tissue, catheter, vaginal wash, semen, and endotracheal wash) were inoculated onto blood agar, chocolate agar, and Mac Conkey agar using the spread plate method. All the plates were incubated at 37 • C for 48 h. The blood samples were inoculated into brain heart infusion broth and incubated at 37 • C for 24 h. The pure culture of each isolate was obtained by subculturing them 3-4 times. Enterococcal isolates were screened using colony morphology, Gram's staining, and bile esculin hydrolysis. Among the enterococcal isolates, Enterococcus faecalis and Enterococcus faecium were differentiated based on mannitol, sorbitol, arabinose fermentation, and arginine hydrolysis. Similarly, Enterococcus hirae and Enterococcus durans were differentiated based on acid production from melibiose, and sucrose as E. hirae are able to produce acid from melibiose and sucrose, whereas E. durans is negative in the fermentation of both sugars [44].

Phenotypic Analysis of Virulence Factors among VRE
The VRE isolates were phenotypically assessed for their virulence factors, such as gelatinase, protease, hemolysis activity, and biofilm production. The positive control (methicillin-resistant Staphylococcus aureus: gelatinase, protease, and biofilm production, and β-hemolytic Streptococcus culture: hemolysis) for each test was used to compare the VRE in all the tests.

Gelatinase Activity
Gelatinase assay was performed by inoculating the isolates in brain heart infusion (BHI) agar supplemented with gelatin (3%, Sigma, Bangalore, India) and incubated at 37 • C. After 48 h of incubation, Frazier solution was flooded on the plate, and a halo zone was observed around the colony.

Protease Activity
The protease-producing ability of the isolates was assessed by inoculating the isolates in BHI agar supplemented with 1.5% of skimmed milk and incubated at 37 • C for 48 h. The clear halo zone around the colonies indicates the protease activity of the isolates.

Hemolytic Activity
The ability of bacterial isolates to lyse the blood cells was analyzed by inoculating the isolates on a blood agar plate (5% defibrinated blood) and incubating at 37 • C up to 72 h. The clear halo zone around the colony indicates the hemolytic potential of the isolates.

Biofilm Production Test
Biofilm assay was performed using the quantitative microtiter plate method as described by Stepanović et al. [45]. Briefly, the colonies of each isolate were suspended in physiological saline to reach the OD 570 0.5 McFarland. The wells of the 96-microtiter plate were provided with the addition of 180 µL of trypticase soy broth (TSB) supplemented with 0.5% glucose and 20 µL of the bacterial suspension. The negative control was maintained simultaneously without bacterial suspension. The plate was incubated statistically at 37 • C for 48 h. Then, the broth was drawn off, and three successive washings of the wells were conducted with 300 µL of sterilized phosphate-buffered saline (PBS). The fixative e agent, methanol (200 µL), was added for 20 min, tapped and air dried for 30 min in an inverted position. Finally, the crystal violet stain (200 µL) was added to the biofilm. After 15 min of incubation, the wells were rinsed with water and air dried for 30 min. The wells were provided with destainer, 33% acetic acid (200 µL), and the plate was incubated at room temperature for 30 min under static conditions. The biofilm formation was quantified by measuring the OD 570 using a microtiter plate reader. The tested isolates were classified based on their biofilm-forming potential according to the OD reading as conducted by Stepanović et al. [45] and Cui et al. [46].

Genotypic Characterization of Virulence Factors from VRE
The isolates showing multi-drug resistance, including vancomycin resistance, were further analyzed for the presence of virulence genes, such as gelE, sprE, esp, ace, asaI, and hyl, cylA. In addition, they were assessed for their type of vancomycin resistance using vanA and vanB primer. Genomic DNA was extracted from the test isolates using QIAamp DNA kits (QIAGEN, Hilden, German). PCR amplification was carried out using various primers, as listed in Table S1. The PCR products were confirmed by gel electrophoresis (1.2% agarose) and visualized under UV light.

Statistical Analysis
The values are given as percentages. A Chi-square test and Fisher's exact test were used to correlate the phenotypic and genotypic assessment of the virulence factors of vancomycin-resistant isolates using Graphpad Prism (Version 6). A p value < 0.05 was considered statistically significant.

Conclusions
The results of the current study show that the detection of enterococci from clinical samples is highly imperative. The overall prevalence of VRE and MDR in our study is 31 and 11%, respectively, explaining the high incidence of VRE and MDR strains in the hospital settings. Thus, a regular investigation is a prerequisite in order to prevent the dissemination of MDR pathogens. In addition, the presence of vancomycin-resistant and MDR E. faecalis and E. faecium strains could be an alarming situation in hospital settings. The high prevalence rate of virulence determinants reported in this study could reveal the necessity of a multifaceted approach to control and prevent the dissemination of MDR pathogens. These results could be of interest for epidemiologists who are engaged in the surveillance of antibiotics of resistance and/or the control of a correct antibiotic policy in the studied geographical area.
Supplementary Materials: The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/antibiotics12060981/s1, Table S1: Details of primers used to amplify the virulence genes (gelE, sprE, esp, ace, asa, hyl, cylA, vanA, vanB) from vancomycin resistant enterococcal isolates; Table S2: Phenotypic and genotypic profile of virulence factors associated with vancomycin resistant E. faecalis isolates; Table S3: Phenotypic and genotypic profile of virulence factors associated with vancomycin resistant E. faecium isolates. References [45,46]   Informed Consent Statement: Written informed consent was obtained from all the patients who are attending various outpatient and inpatient services within the hospital. The methodologies included in this study were followed by approval committee guidelines and regulations.