PT subunits were expressed in E. coli, but unfortunately these failed to assemble into the mature toxin and were insufficiently immunogenic to be considered selleck as potential vaccine candidates
[16]. It is now understood that assembly and secretion of the mature toxin requires several auxiliary genes that were discovered more recently, and these genes are part of the ptl section of the click here ptx-ptl operon [17]. In this publication, we report the construction of recombinant B. pertussis strains expressing increased levels of rPT or rPT and PRN. These strains were generated by a multiple allelic- exchange process: insertion of the mutations that abolish the catalytic activity of subunit S1, insertion of a second copy of the ptx cluster of the five PT structural genes of the ptx-ptl operon with their promoter and terminator into an abandoned gene elsewhere on the chromosome, then insertion of a second copy of the prn gene into a second inactive gene locus. The organization of ptl auxiliary genes present in the ptx-ptl operon was not modified. Enhanced production of rPT and PRN by manipulation of gene copy number has been largely used with multi-copy plasmid vectors and reported to enhance the production of bacterial toxins [18, 19], in particular PT [20]. However,
genes tandemly repeated in this way may have significantly negative consequences on strain genetic stability in a GMP-regulated, vaccine-manufacturing environment. In addition, PRN expression could also be increased by manipulation of the PRN promoter [21]. The allelic-exchange vectors
INCB018424 used in earlier B. pertussis recombinant strains require mutations on the chromosome, particularly the mutation affecting rpsL that results from selection of spontaneous streptomycin-resistant mutants as required in earlier allelic-exchange procedures [22]. Such mutations affecting housekeeping genes may impair virulence, hence the expression of virulence factors including PT, FHA and PRN. In contrary, pSS4245 used in this study harbours streptomycin resistant gene from Tn5 which is functional in B. pertussis but not in E. coli, hence streptomycin was used to select against E. coli donor cell and I-SceI nuclease activity in the plasmid was then functioned as the counter selectable Methane monooxygenase marker in the recombinant B. pertussis through subsequent homologous recombination and does not require or leave auxiliary mutations. The strains reported here produce unaltered levels of the other antigens in particular FHA. These constructs will prove useful for the manufacture of affordable human acellular Pertussis vaccines. Results Mutation of the S1 gene in the B. Pertussis chromosome To introduce the two mutations R9K and E129G into the S1 subunit, a two-stage approach was used to avoid the possibility of recombination in the region between the two mutations that would cause the loss of one of the mutations.