Eric Jacobs

Cloning and characterization of Neisseria meningitidis genes encoding the transferrin-binding proteins Tbp1 and Tbp2.

Genes tbp1 and tbp2, encoding the transferrin-binding proteins Tbp1 and Tbp2, have been isolated from two strains of Neisseria meningitidis. The tbp2 and tbp1 open reading frames are tandemly arranged in the genome with an 87-bp intergenic region, and the DNA region upstream from the tbp2-coding sequence contains domains homologous to Escherichia coli promoter consensus motives. Nucleotide sequence analysis suggests the existence of a Tbp1 precursor carrying an N-terminal signal peptide with a peptidase I cleavage site and of a Tbp2 precursor with N-terminal homology to lipoproteins, including a peptidase II cleavage site. Comparison of the Tbp1 deduced amino acid (aa) sequences from both strains showed about 76% aa homology, while those of Tbp2 revealed only about 47% aa homology. These comparisons should be extended to other Neisseria strains in order to evaluate further this genetic divergence further.

Characterization of genetic exchanges between various highly divergent tbpBs, having occurred in Neisseria meningitidis

Transferrin-binding protein B (TbpB) from Neisseria is an outer membrane-associated extracellular protein involved in iron capture during bacterial infection. The tbpB genes display extensive divergences throughout the open reading frame (ORF) that have presumably been selected under the pressure of the immune system. Early studies suggested that they could possibly constitute two distantly related groups of genes (sharing less than 57% identical nt). However, the analysis of one tbpB suggested the existence of a greater genetic diversity, and the occurrence of horizontal genetic exchanges leading to rearrangements of highly divergent ORFs. This study has confirmed this and revealed the occurrence of genetic exchanges having involved at least three types of very distantly related tbpBs. These rearrangements resulted from recombination events having occurred at very similar positions within an ORF region encoding a highly structured protein domain, probably due to constraints imposed by protein function and mode(s) of folding. These new data also provide valuable tools for epidemiological studies and evaluation of TbpBs as candidate vaccines.

Molecular characterization of hybrid Tbp2 proteins from Neisseria meningitidis

Transferrin‐binding protein 2 (Tbp2) from Neisseria is an outer membrane‐associated extracellular lipoprotein that is involved in iron capture within the infected host. The analysis of tbp2 clones isolated from various bacterial strains revealed extensive divergences throughout the open reading frame (ORF), with predicted amino acid (aa) sequences displaying 47% to 83% identity. Such a variability is likely to have resulted from the selective pressure exerted by the host immune system, but raises questions regarding the existing constraints for conservation of protein function. Indeed, the neisserial Tbp2s include a large structured domain, extending throughout the N‐terminal half of the protein (∼270–290 aa), which is extremely stable and whose conformational integrity is required for efficient binding to human transferrin (hTf). In this work, a functional study of Tbp2s encoded by hybrid genes constructed by reassorting highly divergent tbp2 sequences in the region of the ORF encoding this structured domain was performed. The data demonstrate that the determinant intramolecular interactions allowing formation of a stable Tbp2 structure able to interact efficiently with hTf or/and that the Tbp2 residues involved in the interaction with hTf are not well conserved. However, a number of rearrangements appeared to generate genes encoding proteins which have retained structural stability and hTf‐binding capacity. This suggested that despite the extreme aa sequence divergence and the conformational constraints, horizontal genetic exchanges, which are known to occur in neisserial populations, may have contributed significantly to the generation of sequence variation within tbp2 ORFs. The analysis of two tbp2clones characterized in this work supports this hypothesis.