A common gene pool for the Neisseria FetA antigen.

Meningococcal FetA is an iron-regulated, immunogenic outer membrane protein and vaccine component. The most diverse region of this protein is a previously defined variable region (VR) that has been shown to be immunodominant. In this analysis, a total of 275 Neisseria lactamica isolates, collected during studies of nasopharyngeal bacterial carriage in infants, were examined for the presence of a fetA gene. The fetA VR nucleotide sequence was determined for 217 of these isolates, with fetA apparently absent from 58 isolates, the majority of which belonged to the ST-624 clonal complex. The VR in N. lactamica was compared to the same region in N. meningitidis, N. gonorrhoeae, and a number of other commensal Neisseria. Identical fetA variable region sequences were identified among commensal and pathogenic Neisseria, suggesting a common gene pool, differing from other antigens in this respect. Carriage of commensal Neisseria species, such as N. lactamica, that express FetA may be involved in the development of natural immunity to meningococcal disease.

Antigenic diversity of meningococcal enterobactin receptor FetA, a vaccine component.

Meningococcal FetA (FrpB), an iron-regulated outer-membrane protein and vaccine component, was shown to be highly diverse: a total of 60 fetA alleles, encoding 56 protein sequences, were identified from 107 representative Neisseria meningitidis isolates. Phylogenetic analysis established that the allelic variants had been generated by both point mutation and horizontal genetic exchange. Nucleotide substitution was unevenly distributed in the gene, which contained both conserved and variable sequence regions. The most conserved region of the translated peptide sequence corresponded to an amino-terminal domain of the protein and the most diverse region to a previously identified variable region (VR). A nomenclature system for the peptides encoded by the VR was devised which classified 24 variants into 5 FetA variant families. On the basis of these data, murine polyclonal sera specific for four FetA variants were generated. The reactivities of these sera in whole-cell ELISA experiments were consistent with the hypothesis that the VR encoded an immunodominant epitope and indicated that the sera reacted mainly with variants against which they were raised. The diversity of this protein is likely to limit its effectiveness as a vaccine component.

Distribution of surface protein variants among hyperinvasive meningococci: implications for vaccine design.

The bacterium Neisseria meningitidis is a major cause of meningitis and septicemia worldwide. Outer membrane proteins (OMPs) are candidates in the search for comprehensive meningococcal vaccines; however, the formulation of OMP vaccines is complicated by antigenic diversity, which is generated by high levels of genetic reassortment and strong positive selection in the meningococcal antigen genes. The genetic and antigenic diversity of three OMPs (FetA, PorA, and PorB) among a global collection of meningococcal isolates representative of the major hyperinvasive clonal complexes was determined. There was evidence for antigenic structuring among the three OMPs that could not be explained purely by descent. These observations violated the predictions of the clonal and epidemic clonal models of population structure but were in concordance with models of strain structure which propose that host immunity selects for nonoverlapping antigen combinations. The patterns of antigenic variant combinations suggested that an OMP-based vaccine with as few as six PorA and five FetA variant sequences could generate homologous immune responses against all 78 isolates examined.