Xavier Nassif

Antigenic variation of pilin regulates adhesion of Neisseria meningitidis to human epithelial cells

Pili have been shown to play an essential role in the adhesion of Neisseria meningitidis to epithelial cells. However, among piliated strains, both inter‐ and intrastrain variability exist with respect to their degree of adhesion to epithelial cells in vitro (Virji et al., 1992). This suggests that factors other than the presence of pili per se are involved in this process. The N. meningitidis pilin subunit undergoes extensive antigenic variation. Piliated low‐ and high‐adhesive derivatives of the same N. meningitidis strain were selected and the nucleotide sequence of the pilin gene expressed in each was determined. The highly adhesive derivatives had the same pilin sequence. The alleles encoding the pilin subunit of the low‐adhesive derivatives were completely different from the one found in the high‐adhesive isolates. Using polyclonal antibodies raised against one hyperadhesive variant, it was confirmed that the low‐adhesive piliated derivatives expressed pilin variants antigenically different from the highly adhesive strains. The role of antigenic variation in the adhesive process of N. meningitidis was confirmed by performing allelic exchanges of the pilE locus between low‐and high‐adhesive isolates. Antigenic variation has been considered a means by which virulent bacteria evade the host immune system. This work provides genetic proof that a bacterial pathogen, N. meningitidis, can use antigenic variation to modulate their degree of virulence.

The Neisseria meningitidis haemoglobin receptor: its role in iron utilization and virulence

The Neisseris meningitidis haemoglobin receptor gene, hmbR, was cloned by complementation in a porphyrin‐requiring Escherichia coli mutant. hmbR encodes an 89.5 kDa outer membrane protein which shares amino acid homology with the TonB‐dependent receptors of Gram‐negative bacteria. HmbR had the highest similarity to Neisseria transferrin and lactoferrin receptors. The utilization of haemoglobin as an iron source required internalization of the haemin moiety by the cell. The mechanism of haemin internalization via the haemoglobin receptor was TonB‐dependent in E. coli. A N. meningitidis hmbR mutant was unable to use haemoglobin but could still use haemin as a sole iron source. The existence of a second N. meningitidis receptor gene, specific for haemin, was shown by the isolation of cosmids which did not hybridize with the hmbR probe, but which were able to complement an E. coli hemA aroB mutant on haemin‐supplemented plates. The N. meningitidis hmbR mutant was attenuated in an infant rat model for meningococcal infection, indicating that haemoglobin utilization is important for N. meningitidis virulence.

Type IV pilus biogenesis in Neisseria meningitidis: PilW is involved in a step occurring after pilus assembly, essential for fibre stability and function

Type IV pili (Tfp) play a critical role in the pathogenic lifestyle of Neisseria meningitidis and N. gonorrhoeae, notably by facilitating bacterial attachment to human cells, but our understanding of their biogenesis, during which the fibres are assembled in the periplasm, then emerge onto the cell surface and are stabilized, remains fragmentary. We therefore sought to identify the genes required for Tfp formation in N. meningitidis by screening a genome‐wide collection of mutants for those that were unable to form aggregates, another phenotype mediated by these organelles. Fifteen proteins, of which only seven were previously characterized, were found to be essential for Tfp biogenesis. One novel component, named PilW, was studied in more detail. We found that PilW is an outer‐membrane protein necessary for the stabilization of the fibres but not for their assembly or surface localization, because Tfp could be restored on the surface in a pilW mutant by a mutation in the twitching motility gene pilT. However, Tfp‐linked properties, including adherence to human cells, were not restored in a pilW/T mutant, which suggests that PilW is also essential for the functionality of the fibres. Together with the finding that PilW is important for the stability of PilQ multimers, our results extend the current model for Tfp biogenesis by suggesting that a multiprotein machinery in the outer‐membrane is involved in the terminal stage of Tfp biogenesis during which growing fibres are not only stabilized, but also become perfectly functional.

Type IV pilus retraction in pathogenic Neisseria is regulated by the PilC proteins

Pathogenic Neisseria express type IV pili (tfp), which have been shown to play a central role in the interactions of bacteria with their environment. The regulation of piliation thus constitutes a central element in bacterial life cycle. The PilC proteins are outer membrane‐associated proteins that have a key role in tfp biogenesis since PilC‐null mutants appear defective for fibre expression. Moreover, tfp are also subjected to retraction, which is under the control of the PilT nucleotide‐binding protein. In this work, we bring evidence that fibre retraction involves the translocation of pilin subunits to the cytoplasmic membrane. Furthermore, by engineering meningococcal strains that harbour inducible pilC genes, and with the use of meningococcus–cell interaction as a model for the sequential observation of fibre expression and retraction, we show that the PilC proteins regulate PilT‐mediated fibre retraction.

PilX, a pilus‐associated protein essential for bacterial aggregation, is a key to pilus‐facilitated attachment of Neisseria meningitidis to human cells

The attachment of pathogenic Neisseria species to human cells, in which type IV pili (Tfp) play a key but incompletely defined role, depends on the ability of these bacteria to establish contacts with the target cells but also interbacterial interactions. In an effort to improve our understanding of the molecular mechanisms of N. meningitidis adherence to human cells, we screened a collection of defined mutants for those presenting reduced attachment to a human cell line. Besides underscoring the central role of Tfp in this process, this analysis led to the identification of mutants interrupted in a novel gene termed pilX, that displayed an adherence as impaired as that of a non‐piliated mutant but quantitatively and qualitatively unaltered fibres. Moreover, the pilX gene, which encodes a pilin‐like protein that copurifies with Tfp fibres, was also found to be essential for bacterial aggregation. We provide here several piece of evidence suggesting that PilX has intrinsic aggregative but no adhesive properties and that the reduced numbers of adherent bacteria seen with a pilX mutant result from the absence of interbacterial interactions. These data extend the current model for Tfp‐facilitated adherence of N. meningitidis to human cells by suggesting that the pili lead to an increase in net initial adherence primarily by mediating a cooperation between the bacteria, which is supported by the finding that a major effect on initial adherence could be observed in a wild‐type (WT) genetic background after a mechanical removal of the bacterial aggregates.

Interactions of pathogenic Neisseria with host cells. Is it possible to assemble the puzzle

Neisseria meningitidis and Neisseria gonorrhoeae are human pathogens that have to interact with mucosa and/or cellular barriers for their life cycles to progress. Even though they both give rise to dramatically different diseases, the use of in vitro models has shown that most of the mechanisms mediating cellular interactions are common to N. meningitidis and N. gonorrhoeae. This suggests that bacterial cell interactions may be essential not only for pathogenesis but also for other aspects of the bacterial life cycle that are common to both N. meningitidis and N. gonorrhoeae. This manuscript will review the most recent developments concerning the mechanisms mediating cellular interaction of pathogenic Neisseria and will then try to put them into the perspective of pathogenesis and bacterial life cycle.

Activation of ErbB2 receptor tyrosine kinase supports invasion of endothelial cells by Neisseria meningitidis

ErbB2 is a receptor tyrosine kinase belonging to the family of epidermal growth factor (EGF) receptors which is generally involved in cell differentiation, proliferation, and tumor growth, and activated by heterodimerization with the other members of the family. We show here that type IV pilus–mediated adhesion of Neisseria meningitidis onto endothelial cells induces tyrosyl phosphorylation and massive recruitment of ErbB2 underneath the bacterial colonies. However, neither the phosphorylation status nor the cellular localization of the EGF receptors, ErbB3 or ErbB4, were affected in infected cells. ErbB2 phosphorylation induced by N. meningitidis provides docking sites for the kinase src and leads to its subsequent activation. Specific inhibition of either ErbB2 and/or src activity reduces bacterial internalization into endothelial cells without affecting bacteria-induced actin cytoskeleton reorganization or ErbB2 recruitment. Moreover, inhibition of both actin polymerization and the ErbB2/src pathway totally prevents bacterial entry. Altogether, our results provide new insight into ErbB2 function by bringing evidence of a bacteria-induced ErbB2 clustering leading to src kinase phosphorylation and activation. This pathway, in cooperation with the bacteria-induced reorganization of the actin cytoskeleton, is required for the efficient internalization of N. meningitidis into endothelial cells, an essential process enabling this pathogen to cross host cell barriers.

Molecular Analysis and Experimental Virulence of French and North American Escherichia coli Neonatal Meningitis Isolates: Identification of a New Virulent Clone

Phylogenetic relationships, virulence factors, alone and in specific combinations, and virulence in a rat meningitis model were examined among 132 isolates of Escherichia coli neonatal meningitis from France and North America. Isolates belonging to phylogenetic groups A (n=11), D (n=20), and B2 (n=99) had similar high prevalence rates of the siderophores aerobactin and yersiniabactin and the K1 capsule (>/=70%) yet induced different level of experimental bacteremia. Ectochromosomal DNA-like domains involved in blood-brain barrier passage (PAI III(536) [sfa/foc and iroN; 34%]; GimA [ibeA and ptnC; 38%]; PAI II(J96) [hly, cnf1, and hra; 10%]) were restricted to B2 isolates. Among group B2 isolates, representatives of the O45:K1 clonal group (n=30), which lacked these domains, were as able as the archetypal O18:K1 strain C5 to cause meningitis. Molecular epidemiology combined with experimental virulence assays demonstrate that known virulence factors are insufficient to fully explain the pathophysiology of ECNM and to allow for rational search for new virulence factors.

Interaction of pathogenic neisseriae with nonphagocytic cells.

The ability to interact with nonphagocytic cells is a crucial virulence attribute of the meningococcus and the genococcus. Like most bacterial pathogens, Neisseria meningitidis and Neisseria gonorrhoeae initiate infections by colonizing the mucosal epithelium, which serves as the site of entry. After this step, both bacteria cross the intact mucosal barrier. While N. gonorrhoeae is likely to remain in the subepithelial matrix, where it initiates an intense inflammatory reaction, N. meningitidis enters the bloodstream, and eventually the cerebrospinal fluid to cause meningitis. Both pathogens have evolved very similar mechanisms for interacting with host cells. Surface structures that influence bacterium-host interactions include pili, the meningococcal class 5 outer membrane proteins or the gonococcal opacity proteins, lipooligosaccharide, and the meningococcal capsule. This review examines what is known about the roles these structures play in bacterial adhesion and invasion, with special emphasis, on pilus-mediated adhesion. Finally, the importance of these structures in neisserial pathogenesis is discussed.

Comparative genomics identifies the genetic islands that distinguish Neisseria meningitidis, the agent of cerebrospinal meningitis, from other Neisseria species.

ABSTRACT Neisseria meningitidis colonizes the nasopharynx and, unlike commensal Neisseria species, is capable of entering the bloodstream, crossing the blood-brain barrier, and invading the meninges. The other pathogenic Neisseria species, Neisseria gonorrhoeae, generally causes an infection which is localized to the genitourinary tract. In order to investigate the genetic basis of this difference in disease profiles, we used a strategy of genomic comparison. We used DNA arrays to compare the genome of N. meningitidis with those of N. gonorrhoeae and Neisseria lactamica, a commensal of the nasopharynx. We thus identified sequences conserved among a representative set of virulent strains which are either specific to N. meningitidis or shared with N. gonorrhoeae but absent from N. lactamica. Though these bacteria express dramatically different pathogenicities, these meningococcal sequences were limited and, in contrast to what has been found in other pathogenic bacterial species, they are not organized in large chromosomal islands.