An inducible expression system permitting the efficient purification of a recombinant antigen from Mycobacterium smegmatis.

A novel expression vector utilising the highly inducible acetamidase promoter of Mycobacterium smegmatis was constructed. High-level induction of a model antigen, the Mycobacterium leprae 35 kDa protein, was demonstrated in recombinant M. smegmatis grown in the presence of the acetamidase inducer acetamide. The recombinant protein could be simply and efficiently purified from the bacterial sonicate by virtue of a C-terminal 6-histidine tag, demonstrating that this purification strategy can be used for the mycobacteria. The histidine tag had no apparent effect on the protein conformation or immunogenicity, suggesting that the vector described may prove useful for the purification of native-like recombinant mycobacterial proteins from fast-growing mycobacterial hosts.

No evidence for linkage between leprosy susceptibility and the human natural resistance-associated macrophage protein 1 (NRAMP1) gene in French Polynesia.

In order to determine whether a human homolog (NRAMP1) to a murine candidate gene for resistance to mycobacteria influences susceptibility to human disease, we analyzed data from seven multicase leprosy families (84 individuals) from French Polynesia for linkage markers within the NRAMP1 gene and leprosy per se. Individual family members were typed at nine polymorphic loci within NRAMP1. In addition, three physically linked, polymorphic microsatellite markers-D2S104, D2S173 and D2S1471-were also typed. Linkage analyses were done using affected sibpair and LOD score methods employing different modes of inheritance with full and reduced penetrance. The results of this study strongly suggest that NRAMP1 is not linked to leprosy susceptibility in the French Polynesian families tested.

Aminoglycoside 2'-N-acetyltransferase genes are universally present in mycobacteria: characterization of the aac(2')-Ic gene from Mycobacterium tuberculosis and the aac(2')-Id gene from Mycobacterium smegmatis.

The genus Mycobacterium comprises clinically important pathogens such as M. tuberculosis, which has reemerged as a major cause of morbidity and mortality world-wide especially with the emergence of multidrug-resistant strains. The use of fast-growing species such as Mycobacterium smegmatis has allowed important advances to be made in the field of mycobacterial genetics and in the study of the mechanisms of resistance in mycobacteria. The isolation of an aminoglycoside-resistance gene from Mycobacterium fortuitum has recently been described. The aac(2')-Ib gene is chromosomally encoded and is present in all isolates of M. fortuitum. The presence of this gene in other mycobacterial species is studied here and genes homologous to that of M. fortuitum have been found in all mycobacterial species studied. In this report, the cloning of the aac(2')-Ic gene from M. tuberculosis H37Rv and the aac(2')-Id gene from M. smegmatis mc(2)155 is described. Southern blot hybridizations have shown that both genes are present in all strains of this species studied to date. In addition, the putative aac(2')-Ie gene has been located in a recent release of the Mycobacterium leprae genome. The expression of the aac(2')-Ic and aac(2')-Id genes has been studied in M. smegmatis and only aac(2')-Id is correlated with aminoglycoside resistance. In order to elucidate the role of the aminoglycoside 2'-N-acetyltransferase genes in mycobacteria and to determine whether they are silent resistance genes or whether they have a secondary role in mycobacterial metabolism, the aac(2')-Id gene from M. smegmatis has been disrupted in the chromosome of M. smegmatis mc(2)155. The disruptant shows an increase in aminoglycoside susceptibility along with a slight increase in the susceptibility to lysozyme.

Characterization of the Mycobacterium tuberculosis erp gene encoding a potential cell surface protein with repetitive structures.

Using the phoA gene fusion methodology adapted to mycobacteria, several Mycobacterium tuberculosis DNA fragments encoding exported proteins were recently identified. In this paper, the molecular cloning, genomic positioning, nucleotide sequence determination and transcriptional start site mapping of a new M. tuberculosis gene, identified by this methodology, are reported. This gene was called erp (for exported repetitive protein) and has a sequence similar to that of the Mycobacterium leprae 28 kDa antigen irg gene M. tuberculosis erp gene contains a putative iron box close to the mapped transcriptional start site. The predicted Erp protein displays a typical N-terminal signal sequence, a hydrophobic domain at the C-terminus and harbours repeated amino acid motifs. These structural features are reminiscent of cell-wall-associated surface proteins from Gram-positive bacteria. We found that these repeats are conserved among M. tuberculosis isolates, and are absent from the published M. leprae irg gene sequence. In addition to being present in M. leprae, erp sequences were found in other members of the M. tuberculosis complex, but not in other mycobacteria tested. These results suggest that erp might encode a cell surface component shared by major pathogenic mycobacteria.

Identification of mycobacterium tuberculosis DNA sequences encoding exported proteins by using phoA gene fusions.

The activity of bacterial alkaline phosphatase (PhoA) is dependent on it being exported across the plasma membrane. A plasmid vector (pJEM11) allowing fusions between phoA and genes encoding exported proteins was constructed to study protein export in mycobacteria. Introduction of the Mycobacterium fortuitum beta-lactamase gene (blaF*) into this vector led to the production in M. smegmatis of protein fusions with PhoA activity. A genomic library from M. tuberculosis was constructed in pJEM11 and screened in M. smegmatis for clones with PhoA activity. Sequences of the M. tuberculosis inserts directing the production of protein fusions in these PhoA-positive clones were determined. They include part of the already-known exported 19-kDa lipoprotein, a sequence with similarities to the exported 28-kDa antigen from M. leprae, a sequence encoding a protein sharing conserved amino acid motifs with stearoyl-acyl-carrier-protein desaturases, and unknown sequences. This approach thus appears to identify sequences directing protein export, and we expect that more extensive screening of such libraries will lead to a better understanding of protein export in M. tuberculosis.

Genetic control of susceptibility to leprosy in French Polynesia; no evidence for linkage with markers on telomeric human chromosome 2.

Several lines of evidence have suggested a role of genetic factors in susceptibility to leprosy. In the mouse, natural susceptibility to infection with mycobacteria is controlled by the chromosome 1 Bcg locus, a region which is syntenic with a fragment of the human chromosome 2q, region q31-q37. It has been postulated that a human homolog of the Bcg gene controls susceptibility to leprosy per se, and may be located on chromosome 2q. In order to test the influence of this putative gene on leprosy per se, we performed linkage analyses in a set of seven multicase French Polynesian pedigrees, using an affected sib pair method and the LOD score method employing different modes of inheritance. Family members were typed for eight polymorphic loci on chromosome 2q: CRYGP1, FN, TNP1, VIL, DES, INH, PAX3, and UGT1A1. Our data provide evidence against the presence of a gene controlling susceptibility to leprosy per se on human chromosome 2q in the French Polynesian population.

Transposition of an antibiotic resistance element in mycobacteria.

Bacterial resistance to antibiotics is often plasmid-mediated and the associated resistance genes encoded by transposable elements. Mycobacteria, including the human pathogens Mycobacterium tuberculosis and M. leprae, are resistant to many antibiotics, and their cell-surface structure is believed to be largely responsible for the wide range of resistance phenotypes. Antibiotic-resistance plasmids have so far not been implicated in resistance of mycobacteria to antibiotics. Nevertheless, antibiotic-modifying activities such as aminoglycoside acetyltransferases and phosphotransferases have been detected in fast-growing species. beta-lactamases have also been found in most fast- and slow-growing mycobacteria. To date no mycobacterial antibiotic-resistance genes have been isolated and characterized. We now report the isolation, cloning and sequencing of a genetic region responsible for resistance to sulphonamides in M. fortuitum. This region also contains an open reading frame homologous to one present in Tn1696 (member of the Tn21 family) which encodes a site-specific integrase. The mycobacterial resistance element is flanked by repeated sequences of 880 base pairs similar to the insertion elements of the IS6 family found in Gram+ and Gram- bacteria. The insertion element is shown to transpose to different sites in the chromosome of a related fast-growing species, M. smegmatis. The characterization of this element should permit transposon mutagenesis in the analysis of mycobacterial virulence and related problems.