Arto S. Baghdayan

Modulation of virulence within a pathogenicity island in vancomycin-resistant Enterococcus faecalis

Enterococci are members of the healthy human intestinal flora, but are also leading causes of highly antibiotic-resistant, hospital-acquired infection. We examined the genomes of a strain of Enterococcus faecalis that caused an infectious outbreak in a hospital ward in the mid-1980s (ref. 2), and a strain that was identified as the first vancomycin-resistant isolate in the United States, and found that virulence determinants were clustered on a large pathogenicity island, a genetic element previously unknown in this genus. The pathogenicity island, which varies only subtly between strains, is approximately 150 kilobases in size, has a lower G + C content than the rest of the genome, and is flanked by terminal repeats. Here we show that subtle variations within the structure of the pathogenicity island enable strains harbouring the element to modulate virulence, and that these variations occur at high frequency. Moreover, the enterococcal pathogenicity island, in addition to coding for most known auxiliary traits that enhance virulence of the organism, includes a number of additional, previously unstudied genes that are rare in non-infection-derived isolates, identifying a class of new targets associated with disease which are not essential for the commensal behaviour of the organism.

Role of Enterococcus faecalis Surface Protein Esp in the Pathogenesis of Ascending Urinary Tract Infection

ABSTRACT Enterococcus faecalis bacteria isolated from patients with bacteremia, endocarditis, and urinary tract infections more frequently express the surface protein Esp than do fecal isolates. To assess the role of Esp in colonization and persistence of E. faecalis in an animal model of ascending urinary tract infection, we compared an Esp+strain of E. faecalis to its isogenic Esp-deficient mutant. Groups of CBA/J mice were challenged transurethrally with 108 CFU of either the parent or mutant strain, and bacteria in the urine, bladder, and kidneys were enumerated 5 days postinfection. Significantly higher numbers of bacteria were recovered from the bladder and urine of mice challenged with the parent strain than from the bladder and urine of mice challenged with the mutant. Colonization of the kidney, however, was not significantly different between the parent and mutant strains. Histopathological evaluations of kidney and bladder tissue done at 5 days postinfection did not show marked histopathological changes consistent with inflammation, mucosal hyperplasia, or apoptosis, and there was no observable difference between the mice challenged with the parent and those challenged with the mutant. We conclude that, while Esp does not influence histopathological changes associated with acute urinary tract infections, it contributes to colonization and persistence of E. faecalis at this site.

Enterococcal Surface Protein, Esp, Enhances Biofilm Formation by Enterococcus faecalis

ABSTRACT Enterococci play a dual role in human ecology. They serve as commensal organisms of the gastrointestinal tract and are also leading causes of multiple antibiotic-resistant hospital-acquired infection. Many nosocomial infections result from the ability of microorganisms to form biofilms. The molecular mechanisms involved in enterococcal biofilm formation are only now beginning to be understood. Enterococcal surface protein, Esp, has been reported to contribute to biofilm formation by Enterococcus faecalis. Recent studies have shown that enterococci form biofilms independently of Esp expression. To precisely determine what role Esp plays in E. faecalis biofilm formation, Esp was expressed on the cell surface of genetically well-defined, natively Esp-deficient strains, and isogenic Esp-positive and Esp-deficient strains were compared for their biofilm-forming ability. The results show that Esp expression leads to a significant increase in biofilm formation, irrespective of the strain tested. The contribution of Esp to biofilm formation was found to be most pronounced in the presence of 0.5% (wt/vol) or greater glucose. These results unambiguously define Esp as a key contributor to the ability of E. faecalis to form biofilms.

Pathogenic enterococci: new developments in the 21st century

Enterococci, traditionally viewed as Gram-positive commensal bacteria inhabiting the alimentary canals of humans and animals, are now acknowledged to be organisms capable of causing life-threatening infections in humans, especially in the nosocomial environment. The existence of enterococci in such a dual role is facilitated, at least in part, by its intrinsic and acquired resistance to virtually all antibiotics currently in use. Beginning with the initial identification of a ‘streptococci of fecal origin’ in the late 19th century, enterococci have been studied for over a century now. A number of comprehensive reviews during this time have addressed various aspects of enterococci, including classification, biology, virulence, antibiotic resistance and so on. This review specifically addresses the important advances in the field of enterococcal research that have occurred since the beginning of the 21st century. Most notable among these developments have been the insights into enterococcal genomes and pathogenicity.

Putative Surface Proteins Encoded within a Novel Transferable Locus Confer a High-Biofilm Phenotype to Enterococcus faecalis

Enterococci are opportunistic pathogens and among the leading causes of nosocomial infections. Enterococcus faecalis, the dominant species among infection-derived isolates, has recently been recognized as capable of forming biofilms on abiotic surfaces in vitro as well as on indwelling medical devices. A few bacterial factors known to contribute to biofilm formation in E. faecalis have been characterized. To identify additional factors which may be important to this process, we utilized a Tn917-based insertional mutagenesis strategy to generate a mutant bank in a high-biofilm-forming E. faecalis strain, E99. The resulting mutant bank was screened for mutants exhibiting a significantly reduced ability to form biofilms. One mutant, P101D12, which showed greater than 70% reduction in its ability to form biofilms compared to the wild-type parent, was further characterized. The single Tn917 insertion in P101D12 was mapped to a gene, bee-2, encoding a probable cell wall-anchored protein. Sequence information for the region flanking bee-2 revealed that this gene was a member of a locus (termed the bee locus for biofilm enhancer in enterococcus) comprised of five genes encoding three putative cell wall-anchored proteins and two probable sortases. Contour-clamped homogeneous electric field gel and Southern hybridization analyses suggested that the bee locus is likely harbored on a large conjugative plasmid. Filter mating assays using wild-type E99 or mutant P101D12 as a donor confirmed that the bee locus could transfer conjugally at high frequency to recipient E. faecalis strains. This represents the first instance of the identification of a mobile genetic element conferring biofilm-forming property in E. faecalis.

In vitro adhesive properties and virulence factors of Enterococcus faecalis strains

Twenty-nine Enterococcus faecalis isolates from patients with endocarditis or bacteremia or from stools of healthy volunteers were investigated for their ability to adhere to Int-407 and Girardi heart cell lines and for the presence of known enterococcal virulence factors. Eight strains (27.6%) adhered predominantly to Int-407 cells. The adherence of enterococci was enhanced by proteolytic digestion, suggesting that some cell binding components become surface-exposed after treatment with trypsin. The occurrence of known potential virulence factors of enterococci among these strains was determined and was as follows: enterococcal surface protein (72.4%), gelatinase (58.6%), aggregation substance (48.3%) and cytolysin (17.2%). Bacterial adherence was not significantly associated with any of these virulence factors.

Horizontal transfer of virulence genes encoded on the Enterococcus faecalis pathogenicity island

Enterococcus faecalis, a leading cause of nosocomial antibiotic resistant infections, frequently possesses a 150 kb pathogenicity island (PAI) that carries virulence determinants. The presence of excisionase and integrase genes, conjugative functions and multiple insertion sequence elements suggests that the PAI, or segments thereof, might be capable of horizontal transfer. In this report, the transfer of the E. faecalis PAI is demonstrated and a mechanism for transfer elucidated. In filter matings, chloramphenicol resistance was observed to transfer from strain MMH594b, a clinical isolate possessing the PAI tagged with a cat marker, to OG1RF (pCGC) with a frequency of 3.2 × 10−10 per donor. Secondary transfer from primary transconjugant TCRFB1 to strain JH2SS in filter and broth matings occurred with a frequency of 1 and 2 × 10−1 per donor respectively. Analysis of the transconjugants demonstrated that a 27 744 bp internal PAI segment was capable of excision and circularization in the donor, and is mobilized as a cointegrate with a pTEF1‐like plasmid. High‐frequency transfer also occurred from TCRFB1 to JH2SS during transient colonization of the mouse gastrointestinal tract. This is the first demonstration of the horizontal transfer of PAI‐encoded virulence determinants in E. faecalis and has implications for genome evolution and diversity.

Genetic variation and evolution of the pathogenicity island of Enterococcus faecalis.

Enterococcus faecalis is a leading cause of nosocomial infections and is known for its ability to acquire and transfer virulence and antibiotic resistance determinants from other organisms. A 150-kb pathogenicity island (PAI) encoding several genes that contribute to pathogenesis was identified among antibiotic-resistant clinical isolates. In the current study, we examined the structure of the PAI in a collection of isolates from diverse sources in order to gain insight into its genesis and dynamics. Using multilocus sequence typing to assess relatedness at the level of strain background and microarray analysis to identify variations in the PAI, we determined the extent to which structural variations occur within the PAI and also the extent to which these variations occur independently of the chromosome. Our findings provide evidence for a modular gain of defined gene clusters by the PAI. These results support horizontal transfer as the mechanism for accretion of genes into the PAI and highlight a likely role for mobile elements in the evolution of the E. faecalis PAI.

Presence of Pathogenicity Island Genes in Enterococcus faecalis Isolates from Pigs in Denmark

ABSTRACT Enterococcus faecalis isolates of porcine origin were screened for the presence of a previously identified pathogenicity island (PAI). By using the esp gene as a genetic marker for the presence of this PAI, 9 esp-positive and 10 esp-negative isolates of porcine origin were investigated by use of a designed oligonucleotide array. The results indicated the clustering of esp-positive strains by multilocus sequence typing (MLST), but surprisingly, all strains investigated contained parts of the PAI. None of the strains of animal origin investigated belonged to previously identified MLST complex 2, where most isolates from patients cluster. Five of the nine esp-positive E. faecalis isolates of animal origin belonged to the same PAI complex as human isolate MMH594 but differed in their sequence types, which strongly indicates the horizontal transfer of the PAI between enterococci of porcine and human origin.

The N-Terminal Domain of Enterococcal Surface Protein, Esp, Is Sufficient for Esp-Mediated Biofilm Enhancement in Enterococcus faecalis

Enterococci have emerged as one of the leading causes of nosocomial bloodstream, surgical site, and urinary tract infections. More recently, enterococci have been associated with biofilms, which are bacterial communities attached to a surface and encased in an extracellular polymeric matrix. The enterococcal cell surface-associated protein, Esp, enhances biofilm formation by Enterococcus faecalis in a glucose-dependent manner. Mature Esp consists of a nonrepeat N-terminal domain and a central region made up of two types of tandem repeats followed by a C-terminal membrane-spanning and anchor domain. This study was undertaken to localize the specific domain(s) of Esp that plays a role in Esp-mediated biofilm enhancement. To achieve this objective, we constructed in-frame deletion mutants expressing truncated forms of Esp in an isogenic background. By comparing strains expressing the mutant forms of Esp to those expressing wild-type Esp, we found that the strain expressing Esp lacking the N-terminal domain formed biofilms that were quantitatively less in biovolume than the strain expressing wild-type Esp. Furthermore, an E. faecalis strain expressing only the N-terminal domain of Esp fused to a heterologous protein anchor formed biofilms that were quantitatively similar to those formed by a strain expressing full-length Esp. This suggested that the minimal region contributing to Esp-mediated biofilm enhancement in E. faecalis was confined to the nonrepeat N-terminal domain. Expression of full-length E. faecalis Esp in heterologous host systems of esp-deficient Lactococcus lactis and Enterococcus faecium did not enhance biofilm formation as was observed for E. faecalis. These results suggest that Esp may require interaction with an additional E. faecalis-specific factor(s) to result in biofilm enhancement.