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Background Enterococcus is ubiquitous in nature and is a commensal of both the bovine and human gastrointestinal (GI) tract. It is also associated with clinical infections in humans. Subtherapeutic administration of antibiotics to cattle selects for antibiotic resistant enterococci in the bovine GI tract. Antibiotic resistance genes (ARGs) may be present in enterococci following antibiotic use in cattle. If located on mobile genetic elements (MGEs) their dissemination between Enterococcus species and to pathogenic bacteria may be promoted, reducing the efficacy of antibiotics. Results We present a comparative genomic analysis of twenty-one Enterococcus spp. isolated from bovine feces including Enterococcus hirae ( n  = 10), Enterococcus faecium ( n  = 3), Enterococcus villorum ( n  = 2), Enterococcus casseliflavus ( n  = 2), Enterococcus faecalis ( n  = 1), Enterococcus durans ( n  = 1), Enterococcus gallinarum ( n  = 1) and Enterococcus thailandicus ( n  = 1). The analysis revealed E. faecium and E. faecalis from bovine feces share features with human clinical isolates, including virulence factors. The Tn 917 transposon conferring macrolide-lincosamide-streptogramin B resistance was identified in both E. faecium and E. hirae , suggesting dissemination of ARGs on MGEs may occur in the bovine GI tract. An E. faecium isolate was also identified with two integrative conjugative elements (ICEs) belonging to the Tn 916 family of ICE, Tn 916 and Tn 5801 , both conferring tetracycline resistance. Conclusions This study confirms the presence of enterococci in the bovine GI tract possessing ARGs on MGEs, but the predominant species in cattle, E. hirae is not commonly associated with infections in humans. Analysis using additional complete genomes of E. faecium from the NCBI database demonstrated differential clustering of commensal and clinical isolates, suggesting that these strains may be specifically adapted to their respective environments.

For a One-Health investigation of antimicrobial resistance (AMR) in Enterococcus spp., isolates from humans and beef cattle along with abattoirs, manured fields, natural streams, and wastewater from both urban and cattle feedlot sources were collected over two years. Species identification of Enterococcus revealed distinct associations across the continuum. Of the 8430 isolates collected, Enterococcus faecium and Enterococcus faecalis were the main species in urban wastewater (90%) and clinical human isolates (99%); Enterococcus hirae predominated in cattle (92%) and feedlot catch-basins (60%), whereas natural streams harbored environmental Enterococcus spp. Whole-genome sequencing of E. faecalis (n = 366 isolates) and E. faecium (n = 342 isolates), revealed source clustering of isolates, indicative of distinct adaptation to their respective environments. Phenotypic resistance to tetracyclines and macrolides encoded by tet(M) and erm(B) respectively, was prevalent among Enterococcus spp. regardless of source. For E. faecium from cattle, resistance to β-lactams and quinolones was observed among 3% and 8% of isolates respectively, compared to 76% and 70% of human clinical isolates. Clinical vancomycin-resistant E. faecium exhibited high rates of multi-drug resistance, with resistance to all β-lactam, macrolides, and quinolones tested. Differences in the AMR profiles among isolates reflected antimicrobial use practices in each sector of the One-Health continuum.

Globally, fermented foods (FFs), which may be traditional or industrially-produced, are major sources of nutrition. In the traditional practice, the fermentation process is driven by communities of virtually uncharacterized microflora indigenous to the food substrate. Some of these flora can have virulent or antibiotic resistance properties, posing risk to consumers. Others, such as Enterococcus faecalis and Enterococcus faecium , may also be found in such foods. Enterococci that harbor antibiotic resistance or virulence factors can cycle among animals, food, humans and the environment, thereby transferring these harmful properties at the gene level to harmless commensals in the food matrix, animals and humans. In this work, several microbial isolates obtained from different FF sources were analyzed for their identity and virulence and/or antibiotic resistance properties. For identification aiming at enterococci, isolates that were Gram-positive and catalase- and oxidase-negative were subjected to multiple tests including for growth in broth containing 6.5% NaCl, growth and hydrolytic activity on medium containing bile-esculin, hemolytic activity on blood agar, and growth at 45°C and survival after incubation at 60°C for 30 min. Furthermore, the isolates were tested for susceptibility/resistance to a select group of antibiotics. Finally, the isolates were molecularly-characterized with respect to species identity and presence of virulence-encoding genes by amplification of target genes. Most sources contained enterococci, in addition to most of them also containing Gram-negative flora. Most of these also harbored virulence factors. Several isolates were also antibiotic-resistant. These results strongly suggest attention should be given to better control presence of such potentially pathogenic species.

Background This study investigates the safety evaluation of enterocin-producing 11 E. mundtii and two E. faecium strains previously isolated from small livestock colostrums. Enterococcus species do not possess Generally Recognized as Safe (GRAS) status. Hence, it is critical to scrutinize enterococci’s antibiotic resistance, virulence characteristics, and biogenic amine production capabilities in order to assess their safety before using them as starter or adjunct cultures. Results Enterococcus strains showed susceptibility to medically significant antibiotics. Multiple-drug resistance (MDR) was found in only E. faecium HC121.4, and its multiple antibiotic resistance (MAR) index was detected to be 0.22. The tetL and aph(3')-IIIa were the most commonly found antibiotic resistance genes in the strains. However, E. mundtii strains HC56.3, HC73.1, HC147.1, and E. faecium strain HC121.4 were detected to lack any of the antibiotic resistance genes examined in this study. Only E. mundtii HC166.3 showed hemolytic activity, while none of the strains engage in gelatinase activity. The strains were identified to have virulence factor genes with a low rate. None of the virulence factor genes could be detected in E. mundtii HC26.1, HC56.3, HC73.1, HC165.3, HC166.8, and E. faecium HC121.4. The E. mundtii HC73.2 strain displayed the highest presence of virulence factor genes, namely gelE , efaA fs , cpd , and ccf . Similarly, the E. mundtii HC112.1 strain showed a significant presence of genes efaA fm , ccf , and acm . There was no decarboxylation of histidine, ornithine, or lysine seen in any of the strains. Nevertheless, E. faecium HC121.4 and HC161.1 strains could decarboxylate tyrosine, but E. mundtii HC26.1, HC56.3, HC73.1, HC73.2, HC112.1, HC147.1, HC155.2, HC165.3, HC166.3, HC166.5, and HC166.8 strains only showed a limited capacity for tyrosine decarboxylation. None of the strains possessed the hdc , odc , or ldc genes, but all of them had the tdc gene. Conclusion The E. mundtii HC56.3 and HC73.1 strains were deemed appropriate for utilization in food production. Using the remaining 11 strains as live cultures in food production activities could pose a possible risk to consumer health.

The intestinal microbiota is an important contributor to the health of preterm infants, and may be destabilized by a number of environmental factors and treatment modalities. How to promote the development of a healthy microbiota in preterm infants is largely unknown. We collected fecal samples from 45 breastfed preterm very low birth weight (birth weight < 1500 g) infants from birth until 60 days postnatal age to characterize the intestinal microbiota development during the first weeks of life in preterm infants. Fecal microbiota composition was determined by 16S rRNA amplicon sequencing. The main driver of microbiota development was gestational age; antibiotic use had strong but temporary effects and birth mode had little influence. Microbiota development proceeded in four phases indicated by the dominance of Staphylococcus, Enterococcus, Enterobacter , and finally Bifidobacterium . The Enterococcus phase was only observed among the extremely premature infants and appeared to delay the microbiota succession. The results indicate that hospitalized preterm infants receiving breast milk may develop a normal microbiota resembling that of term infants.

Subclinical mastitis poses a hidden threat to dairy productivity and animal health, often harbouring antimicrobial-resistant pathogens. It is becoming increasingly recognized that Enterococcus species cause mastitis in dairy cows. Accurately characterizing the regional epidemiology of enterococcal mastitis, determining its correlations with management variables, and comprehending its effects on udder health all depend on accurate species information. This study investigated the occurrence, antibiotic resistance and virulence factors of Enterococcus faecalis and Enterococcus faecium in cow dung and milk samples from cows with subclinical mastitis. Subclinical mastitis was identified in 39.0% (68/174) of cows and 27.8% (194/696) of quarters, based on results from the California Mastitis Test (CMT) and somatic cell counts (SCC), respectively. Matrix-Assisted Laser Desorption/Ionization Time-of-Flight Mass Spectrometry (MALDI-TOF-MS) and Polymerase Chain Reaction (PCR) targeting the ddl gene confirmed the predominance of E. faecalis (93%) and E. faecium (6.4%) in milk samples, while cow dung samples yielded only E. faecalis (100%). Notably, among the E. faecalis isolates from milk samples, 17.2% exhibited vancomycin resistance, whereas streptomycin resistance was found in a smaller proportion of isolates (6.8%). All (100%) E. faecium isolates from the same milk samples showed resistance to vancomycin. The findings also revealed that 11 (32.3%) of E. faecium isolates from cow dung were resistant to vancomycin. Multidrug resistance (MDR) was observed in 20.6% of milk and 6.8% of cow dung isolates. The vanA gene was the most prevalent antibiotic resistance gene (ARG), detected in 96% of E. faecalis isolates. Virulence profiling of Enterococcus spp. isolates showed varying gene prevalence in milk ( asa1 : 33.3%, ace : 12.7%, esp : 10%) and cow dung samples ( gelE : 53.2%, hyl : 38.2%). This study has indicated a significant occurrence of antimicrobial-resistant E. faecalis and E. faecium strains obtained from subclinical cattle mastitis. These findings emphasize the role of Enterococcus spp., especially vancomycin-resistant strains, as emerging threats in bovine subclinical mastitis, with possible implications for zoonotic transmission and antimicrobial stewardship in dairy systems.

To investigate the molecular characteristics and biofilm-forming ability of 116 Enterococcus faecium ( Efm ) and 72 Enterococcus faecalis ( Efs ) isolates obtained from patients with bloodstream infections (BSI) at a Chinese hospital between July 2011 and March 2018. The presence of glycopeptide resistance genes and five virulence genes ( esp , gelE , asa1 , hyl , and cylA ) was screened using two multiplex PCR. MLST was used to assess the clonality. Crystal violet staining was used to detect biofilms. Vancomycin resistance was detected in 30.1% of Efm and 2.8% of Efs isolates, respectively. All VRE strains carried the vanA gene. The esp , gelE , asa1 , and cylA genes in 72 Efs strains were detected at 62.5%, 84.7%, 84.7%, and 69.4%, respectively. Among the 116 Efm isolates, 74.1% and 25.8% carried esp and hyl , respectively. The esp gene was significantly associated with vancomycin-resistant Efm (VREfm) compared to vancomycin-susceptible Efm (VSEfm). In total, 91.7% of Efs and 20.0% of Efm produced biofilms. Twenty-six STs were identified among the 72 Efs isolates, with ST4 (29.2%) being the predominant. In total, 116 Efm strains were grouped into 26 STs, with ST78 (46.6%) being the predominant. Both VREfm (41.7%) and VSEfm (48.8%) were dominant in ST78. There is no clear evidence suggesting that some STs are associated with vancomycin resistance or biofilm formation. Both Efm and Efs BSI isolates showed a polyclonal pattern with a dominant clone and many unique types, implying the coexistence of clonal dissemination and an influx of new clones. The horizontal transmission of resistance genes may play a more important role in VREfm prevalence than clonal expansion.

Coastal water quality is facing increasing threats due to human activities. Their contamination by sewage discharges poses significant risks to the environment and public health. We aimed to investigate the presence of antibiotic-resistant Enterococcus in beach waters. Over a 10-month period, samples were collected from four beaches in the State of São Paulo (Brazil). Enterococcus isolates underwent matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF/MS) and molecular analysis for accurate genus and species identification. The antimicrobial susceptibility for 14 antibiotics was evaluated using the disc diffusion method followed by a multidrug-resistance (MDR) classification. PCR amplification method was used to detect antimicrobial resistance genes (ARGs). Our findings revealed the prevalence of Enterococcus faecalis, E. faecium and E. hirae. Out of 130 isolates, 118 were resistant to multiple antibiotics. The detection of resistance genes provided evidence of the potential transfer of antibiotic resistance within the environment. Our findings underscore the necessity for continuous research and surveillance to enhance understanding of the pathogenicity and antimicrobial resistance mechanisms of Enterococcus, which is crucial to implement effective measures to preserve the integrity of coastal ecosystems.

Vancomycin-resistant enterococci (VRE) are a major public health concern, yet little is known about their circulation in fish. This study investigated the occurrence, glycopeptide resistance genotypes, virulence characteristics, and sequence types (STs) of VRE isolated from diseased fishes and humans. Isolates were identified using multiplex polymerase chain reaction (PCR) assay and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), and tested for antimicrobial susceptibility. VRE isolates were screened for the presence of glycopeptide resistance genes and eight virulence genes. Multilocus sequence typing (MLST) was determined to assess the clonality of VRE isolates from fishes and humans. Among 60 human samples, 20 Enterococcus species isolates (33.33%) including Enterococcus faecalis and Enterococcus faecium (10 of each), were identified. The overall prevalence of E. faecalis was 42.86% (30/70) in Oreochromis niloticus and 48.0% (24/50) in Clarias gariepinus . E. faecium was found in 15.71% (11/70) of Oreochromis niloticus and 14.0% (7/50) of Clarias gariepinus . Over 50% of human isolates were multidrug resistant (MDR) and 30% exhibited an extensive drug resistant (XDR) phenotype. Fish isolates also displayed high MDR (70.83%) and XDR (29.17%) rates. Forty-nine (53.26%; 34 from fish and 15 from human) isolates were VRE including 30 isolates of E. faecalis (VREfs) and 19 isolates of E. faecium (VREfm). The vanA gene was the most frequent among VREfs (83.33%) and VREfm (100%) isolates. The vanB gene was found in 26.67% of VREfs and 15.79% of VREfm. Three out of 10 VREfm (30%) and 2/24 (8.33%) VREfs isolates of fish origin carried both vanA and vanB genes. vanC gene was found in 13.33% (4/30) of VREfs of human and fish origin. One VREfs isolate from human urine carried both vanA and vanC genes. High frequency of the virulence genes  gelE , sprE , asa1 , esp, and cylA were observed;  efa  and ace gene was more associated with VREfs, while hyl  gene was more frequently detected in VREfm. Different combinations of virulence genes suggesting synergistic pathogenic potential. MLST revealed both overlapping and host-specific STs among the examined Enterococcus isolates from humans and fish. Experimental infection of O. niloticus with VREfs and VREfm caused a 100% and 60% mortality rate within 6 days postinfection, respectively with characteristic disease symptoms. The emergence of VRE and the high prevalence of virulence traits could be regarded as an alarming situation. The call for increased infection control and antibiotic stewardship measures is timely and relevant to combat the spread of VRE in fish and humans.

This study presents the empirical findings of an in-depth genomic analysis of Enterococcus faecalis and Enterococcus lactis isolates from South Africa. It offers valuable insights into their genetic characteristics and their significant implications for public health. The study uncovers nuanced variations in the gene content of these isolates, despite their similar GC contents, providing a comprehensive view of the evolutionary diversity within the species. Genomic islands are identified, particularly in E. faecalis , emphasizing its propensity for horizontal gene transfer and genetic diversity, especially in terms of antibiotic resistance genes. Pangenome analysis reveals the existence of a core genome, accounting for a modest proportion of the total genes, with 2157 core genes, 1164 shell genes, and 4638 cloud genes out of 7959 genes in 52 South African E. faecalis genomes (2 from this study, 49 south Africa genomes downloaded from NCBI, and E. faecalis reference genome). Detecting large-scale genomic rearrangements, including chromosomal inversions, underscores the dynamic nature of bacterial genomes and their role in generating genetic diversity. The study uncovers an array of antibiotic resistance genes, with trimethoprim, tetracycline, glycopeptide, and multidrug resistance genes prevalent, raising concerns about the effectiveness of antibiotic treatment. Virulence gene profiling unveils a diverse repertoire of factors contributing to pathogenicity, encompassing adhesion, biofilm formation, stress resistance, and tissue damage. These empirical findings provide indispensable insights into these bacteria’s genomic dynamics, antibiotic resistance mechanisms, and virulence potential, underlining the pressing need to address antibiotic resistance and implement robust control measures.