Shaynoor Dramsi

Entry of Listeria monocytogenes into hepatocytes requires expression of InIB, a surface protein of the internalin multigene family

The intracellular bacterium Listeria monocytogenes can invade several types of normally non‐phagocytic cells. Entry into cultured epithelial cells requires the expression of inIA, the first gene of an operon, comprising two genes: inIA, which encodes internalin, an 800‐amino‐acid protein, and inIB, which encodes a 630‐amino‐acid protein. Several genes homologous to inIA are detected in the genome of L. monocytogenes; InIB is one of them. We have assessed the role of inIB In invasiveness of L. monocytogenes by constructing isogenic chromosomal deletion mutants in the inIAB locus. Our findings indicate that: i) inIB is required for entry of L. monocytogenes into hepatocytes, but not into intestinal epithelial cells; ii) inIB encodes a surface protein; iii) internalin plays a role for entry into some hepatocyte cell lines. These results provide the first insight into the cell tropism displayed by L. monocytogenes.

A single amino acid in E‐cadherin responsible for host specificity towards the human pathogen Listeria monocytogenes

Human E‐cadherin promotes entry of the bacterial pathogen Listeria monocytogenes into mammalian cells by interacting with internalin (InlA), a bacterial surface protein. Here we show that mouse E‐cadherin, although very similar to human E‐cadherin (85% identity), is not a receptor for internalin. By a series of domain‐swapping and mutagenesis experiments, we identify Pro16 of E‐cadherin as a residue critical for specificity: a Pro→Glu substitution in human E‐cadherin totally abrogates interaction, whereas a Glu→Pro substitution in mouse E‐cadherin results in a complete gain of function. A correlation between cell permissivity and the nature of residue 16 in E‐cadherins from several species is established. The location of this key specificity residue in a region of E‐cadherin not involved in cell–cell adhesion and the stringency of the interaction demonstrated here have important consequences not only for the understanding of internalin function but also for the choice of the animal model to be used to study human listeriosis: mouse, albeit previously widely used, and rat appear as inappropriate animal models to study all aspects of human listeriosis, as opposed to guinea‐pig, which now stands as a small animal of choice for future in vivo studies.

InlB: an invasion protein of Listeria monocytogenes with a novel type of surface association

Listeria monocytogenes is an intracellular bacterial pathogen that expresses several surface proteins critical for the infectious process. Such proteins include InlA (internalin) and InlB, involved in bacterial entry into the host cell, and ActA, required for bacterially induced actin‐based motility. Although the molecular mechanisms of attachment of InlA and ActA have been characterized, essentially nothing is known about how InlB is anchored to the bacterial surface. Using a genetic approach, we demonstrate that the last 232 amino acids of InlB are both necessary and sufficient for anchoring this protein to the bacterial surface. An InlB mutant protein deleted for the last 232 amino acids was secreted and not detected at the cell surface. A ‘domain‐swapping’ strategy in which these 232 amino acids were used to replace the normal cell wall‐anchoring domain of InlA resulted in a chimeric protein that was anchored to the cell surface and able to confer entry. Interestingly, surface association of InlB also occurred when InlB was added externally to bacteria, suggesting that association may be able to occur after secretion. This association was productive for invasion, as it conferred bacterial entry into host cells. The C‐terminal anchoring region in InlB contains 80‐amino‐acid repeats beginning with the sequence GW that is also present in a newly identified surface‐associated bacteriolysin of L. monocytogenes, called Ami. Addition of GW repeats to the C‐terminal of InlB improves anchoring of the protein to the cell surface. These and other data suggest that such ‘GW’ repeats may constitute a novel motif for cell‐surface anchoring in Listeria and other Gram‐positive bacteria. This motif may have important consequences for the release of surface proteins involved in interactions with eukaryotic cells.

Assembly and role of pili in group B streptococci

Streptococcus agalactiae[group B streptococcus (GBS)] is the leading cause of neonatal pneumonia, sepsis and meningitis. An in silico genome analysis indicated that GBS strain NEM316 encodes five putative sortases, including the major class A sortase enzyme and four class C sortases. The genes encoding the class C sortases are tandemly arranged in two different loci, srtC1‐C2 and srtC3‐C4, with a similar genetic organization and are thought to be involved in pilus biosynthesis. Each pair of sortase genes is flanked by LPXTG protein encoding genes, two upstream and one downstream, and a divergently transcribed regulatory gene located upstream from this locus. We demonstrated that strain NEM316 expresses only the srtC3‐C4 locus, which encodes three surface proteins (Gbs1474, Gbs1477 and Gbs1478) that polymerize to form appendages resembling pili. Structural and functional analysis of this locus revealed that: (i) the transcriptional activator RogB is required for expression of the srtC3‐C4 operon; (ii) Gbs1477, and either SrtC3 or SrtC4 are absolutely required for pilus biogenesis; and (iii) GBS NEM316 pili are composed of three surface proteins, Gbs1477, the bona fide pilin which is the major component, Gbs1474, a minor associated component, and Gbs1478, a pilus‐associated adhesin. Surprisingly, pilus‐like structures can be formed in the absence of the two minor components, i.e. the putative anchor Gbs1474 or the adhesin Gbs1478. Adherence assays showed that Gbs1478 confers adhesive capacity to the pilus. This study provides the first evidence that adhesive pili are also present in Gram‐positive pathogens.

Pleiotropic control of Listeria monocytogenes virulence factors by a gene that is autoregulated

Evidence for ptelotropic activation of virulence genes in Listeria monocytogenes is presented. A complementation study of a spontaneous prfA‐deletion mutant and analysis of cassette and transposon insertion mutants showed that the gene prfA activates the transcription of four independent genes which code for a phosphatidyl‐inositol‐specific phospholipase C (gene plcA), listeriolysin O (gene hlyA), a metallo‐protease (gene prtA) and a lecithinase (gene prtC). Transcription of prfA is not constitutive. During the growth phase, two peaks of prfA transcript accumulation were observed: the first was during exponential growth, and the second was at the beginning of the stationary phase. In addition, two prf4‐specific transcripts of 2.2 kb and 1 kb are detected. Early in exponential growth, prfA is co‐transcribed with plcA which lies upstream prfA, giving rise to the 2.2 kb plcA‐prfA transcript. In late‐exponential growth and at the beginning of the stationary phase, prfA transcripts of 1 kb are predominantly detected. Our results demonstrate that since prfA controls plcA transcription, it also regulates its own synthesis.

The surface protein HvgA mediates group B streptococcus hypervirulence and meningeal tropism in neonates

Lethal meningitis triggered by the hypervirulent group B streptococcus clone ST-17 is mediated by a novel surface protein called HvgA.

Dual Role for Pilus in Adherence to Epithelial Cells and Biofilm Formation in Streptococcus agalactiae

Streptococcus agalactiae is a common human commensal and a major life-threatening pathogen in neonates. Adherence to host epithelial cells is the first critical step of the infectious process. Pili have been observed on the surface of several gram-positive bacteria including S. agalactiae. We previously characterized the pilus-encoding operon gbs1479-1474 in strain NEM316. This pilus is composed of three structural subunit proteins: Gbs1478 (PilA), Gbs1477 (PilB), and Gbs1474 (PilC), and its assembly involves two class C sortases (SrtC3 and SrtC4). PilB, the bona fide pilin, is the major component; PilA, the pilus associated adhesin, and PilC, are both accessory proteins incorporated into the pilus backbone. We first addressed the role of the housekeeping sortase A in pilus biogenesis and showed that it is essential for the covalent anchoring of the pilus fiber to the peptidoglycan. We next aimed at understanding the role of the pilus fiber in bacterial adherence and at resolving the paradox of an adhesive but dispensable pilus. Combining immunoblotting and electron microscopy analyses, we showed that the PilB fiber is essential for efficient PilA display on the surface of the capsulated strain NEM316. We then demonstrated that pilus integrity becomes critical for adherence to respiratory epithelial cells under flow-conditions mimicking an in vivo situation and revealing the limitations of the commonly used static adherence model. Interestingly, PilA exhibits a von Willebrand adhesion domain (VWA) found in many extracellular eucaryotic proteins. We show here that the VWA domain of PilA is essential for its adhesive function, demonstrating for the first time the functionality of a prokaryotic VWA homolog. Furthermore, the auto aggregative phenotype of NEM316 observed in standing liquid culture was strongly reduced in all three individual pilus mutants. S. agalactiae strain NEM316 was able to form biofilm in microtiter plate and, strikingly, the PilA and PilB mutants were strongly impaired in biofilm formation. Surprisingly, the VWA domain involved in adherence to epithelial cells was not required for biofilm formation.

Molecular and Genetic Determinants of the Listeria monocytogenes Infectious Process

Listeria monocytogenes was first characterized in 1926 following an outbreak of listeriosis in laboratory animals (MURRAY et al. 1926). However, it was not until the 1980s that an unambiguous link was established between the human disease and the consumption of Listeria-contaminated foodstuffs (SCHLECH et al. 1983). Immunosuppressed individuals, pregnant women, foetuses and neonates are most susceptible to Listeria infection. Human listeriosis is characterized by a high mortality rate, with clinical features including meningitis or meningo-encephalitis, septicemia, abortion, and perinatal infections (GRAY and KILLINGER 1966). If diagnosed early, listeriosis can be successfully treated by the administration of high doses of antibiotics, most frequently ampicillin or penicillin, either alone or in combination with aminoglycosides.

FbpA, a novel multifunctional Listeria monocytogenes virulence factor

Listeria monocytogenes is a Gram‐positive intracellular bacterium responsible for severe opportunistic infections in humans and animals. Signature‐tagged mutagenesis (STM) was used to identify a gene named fbpA, required for efficient liver colonization of mice inoculated intravenously. FbpA was also shown to be required for intestinal and liver colonization after oral infection of transgenic mice expressing human E‐cadherin. fbpA encodes a 570‐amino‐acid polypeptide that has strong homologies to atypical fibronectin‐binding proteins. FbpA binds to immobilized human fibronectin in a dose‐dependent and saturable manner and increases adherence of wild‐type L. monocytogenes to HEp‐2 cells in the presence of exogenous fibronectin. Despite the lack of conventional secretion/anchoring signals, FbpA is detected using an antibody generated against the recombinant FbpA protein on the bacterial surface by immunofluorescence, and in the membrane compartment by Western blot analysis of cell extracts. Strikingly, FbpA expression affects the protein levels of two virulence factors, listeriolysin O (LLO) and InlB, but not that of InlA or ActA. FbpA co‐immunoprecipitates with LLO and InlB, but not with InlA or ActA. Thus, FbpA, in addition to being a fibronectin‐binding protein, behaves as a chaperone or an escort protein for two important virulence factors and appears as a novel multifunctional virulence factor of L. monocytogenes.

Shaping a bacterial genome by large chromosomal replacements, the evolutionary history of Streptococcus agalactiae

Bacterial populations are subject to complex processes of diversification that involve mutation and horizontal DNA transfer mediated by transformation, transduction, or conjugation. Tracing the evolutionary events leading to genetic changes allows us to infer the history of a microbe. Here, we combine experimental and in silico approaches to explore the forces that drive the genome dynamics of Streptococcus agalactiae, the leading cause of neonatal infections. We demonstrate that large DNA segments of up to 334 kb of the chromosome of S. agalactiae can be transferred through conjugation from multiple initiation sites. Consistently, a genome-wide map analysis of nucleotide polymorphisms among eight human isolates demonstrated that each chromosome is a mosaic of large chromosomal fragments from different ancestors suggesting that large DNA exchanges have contributed to the genome dynamics in the natural population. The analysis of the resulting genetic flux led us to propose a model for the evolutionary history of this species in which clonal complexes of clinical importance derived from a single clone that evolved by exchanging large chromosomal regions with more distantly related strains. The emergence of this clone could be linked to selective sweeps associated with the reduction of genetic diversity in three regions within a large panel of human isolates. Up to now sex in bacteria has been assumed to involve mainly small regions; our results define S. agalactiae as an alternative paradigm in the study of bacterial evolution.