Sequence conservation of pilus subunits in Neisseria meningitidis.

The rapid onset and dramatic consequences of Neisseria meningitidis infections make the design of a broadly protective vaccine a priority for public health. There is an ongoing quest for meningococcal components that are surface exposed, widely conserved and can induce protective antibodies. Type IV pili (Tfp) are filamentous structures with a key role in pathogenesis that extend beyond the surface of the bacteria and have demonstrated vaccine potential. However, extensive antigenic variation of PilE, the major subunit of Tfp, means that they are currently considered to be unsuitable vaccine components. Recently it has been shown that Tfp also contain low abundance pilins ComP, PilV and PilX in addition to PilE. This prompted us to examine the prevalence and sequence diversity of these proteins in a panel of N. meningitidis disease isolates. We found that all minor pilins are highly conserved and the major pilin genes are also highly conserved within the ST-8 and ST-11 clonal complexes. These data have important implications for the re-consideration of pilus subunits as vaccine antigens.

Identification of meningococcal genes necessary for colonization of human upper airway tissue.

Neisseria meningitidis is an exclusively human pathogen that has evolved primarily to colonize the nasopharynx rather than to cause systemic disease. Colonization is the most frequent outcome following meningococcal infection and a prerequisite for invasive disease. The mechanism of colonization involves attachment of the organism to epithelial cells via bacterial type IV pili (Tfp), but subsequent events during colonization remain largely unknown. We analyzed 576 N. meningitidis mutants for their capacity to colonize human nasopharyngeal tissue in an organ culture model to identify bacterial genes required for colonization. Eight colonization-defective mutants were isolated. Two mutants were unable to express Tfp and were defective for adhesion to epithelial cells, which is likely to be the basis of their attenuation in nasopharyngeal tissue. Three other mutants are predicted to have lost previously uncharacterized surface molecules, while the remaining mutants have transposon insertions in genes of unknown function. We have identified novel meningococcal colonization factors, and this should provide insights into the survival of this important pathogen in its natural habitat.

AP endonuclease paralogues with distinct activities in DNA repair and bacterial pathogenesis.

Oxidative stress is a principal cause of DNA damage, and mechanisms to repair this damage are among the most highly conserved of biological processes. Oxidative stress is also used by phagocytes to attack bacterial pathogens in defence of the host. We have identified and characterised two apurinic/apyrimidinic (AP) endonuclease paralogues in the human pathogen Neisseria meningitidis. The presence of multiple versions of DNA repair enzymes in a single organism is usually thought to reflect redundancy in activities that are essential for cellular viability. We demonstrate here that these two AP endonuclease paralogues have distinct activities in DNA repair: one is a typical Neisserial AP endonuclease (NApe), whereas the other is a specialised 3'-phosphodiesterase Neisserial exonuclease (NExo). The lack of AP endonuclease activity of NExo is shown to be attributable to the presence of a histidine side chain, blocking the abasic ribose-binding site. Both enzymes are necessary for survival of N. meningitidis under oxidative stress and during bloodstream infection. The novel functional pairing of NExo and NApe is widespread among bacteria and appears to have evolved independently on several occasions.

Immunization with live Neisseria lactamica protects mice against meningococcal challenge and can elicit serum bactericidal antibodies.

Natural immunity against Neisseria meningitidis is thought to develop following nasopharyngeal colonization with this bacterium or other microbes expressing cross-reactive antigens. Neisseria lactamica is a commensal of the upper respiratory tract which is often carried by infants and young children; epidemiological evidence indicates that colonization with this bacterium can elicit serum bactericidal activity (SBA) against Neisseria meningitidis, the most validated correlate of protective immunity. Here we demonstrate experimentally that immunization of mice with live N. lactamica protects animals against lethal meningococcal challenge and that some, but not all, strains of N. lactamica elicit detectable SBA in immunized animals regardless of the serogroup of N. meningitidis. While it is unlikely that immunization with live N. lactamica will be implemented as a vaccine against meningococcal disease, understanding the basis for the induction of cross-protective immunity and SBA should be valuable in the design of subunit vaccines for the prevention of this important human infection.

Identification of novel antigens that protect against systemic meningococcal infection.

Systemic infection with Neisseria meningitidis leads to a devastating, septicaemic illness with a high mortality, particularly in children. Currently, there are no vaccines to prevent disease caused by strains of N. meningitidis serogroup B, the commonest isolate in developed countries. Here, we describe the identification of vaccine candidates that protect mice against lethal challenge with this bacterium. A total 11 meningococcal proteins that are necessary for establishing systemic infection were expressed as recombinant antigens and assessed for their ability to protect animals against live bacterial challenge; the lactate permease (LctP) and ExbB, which is required for iron acquisition, elicited protective immunity. Both LctP and ExbB are expressed by a wide range of pathogenic isolates of N. meningitidis. Targeting bacterial factors required for pathogenesis may lead to new vaccines to protect individuals from this important human pathogen.