Isoniazid (isonicotinic acid hydrazide, INH) is one of the most widely used antituberculosis drugs, yet its precise target of action on Mycobacterium tuberculosis is unknown. A missense mutation within the mycobacterial inhA gene was shown to confer resistance to both INH and ethionamide (ETH) in M. smegmatis and in M. bovis. The wild-type inhA gene also conferred INH and ETH resistance when transferred on a multicopy plasmid vector to M. smegmatis and M. bovis BCG. The InhA protein shows significant sequence conservation with the Escherichia coli enzyme EnvM, and cell-free assays indicate that it may be involved in mycolic acid biosynthesis. These results suggest that InhA is likely a primary target of action for INH and ETH.
Previous work established that the principal sigma factor (RpoV) of virulent Mycobacterium bovis, a member of the Mycobacterium tuberculosis complex, restores virulence to an attenuated strain containing a point mutation (Arg-5153 His) in the 4.2 domain of RpoV. We used the 4.2 domain of RpoV as bait in a yeast two-hybrid screen of an M. tuberculosis H37Rv library and identified a putative transcription factor, WhiB3, which selectively interacts with the 4.2 domain of RpoV in virulent strains but not with the mutated (Arg-5153 His) allele. Infection of mice and guinea pigs with a M. tuberculosis H37Rv whiB3 deletion mutant strain showed that whiB3 is not necessary for in vivo bacterial replication in either animal model. In contrast, an M. bovis whiB3 deletion mutant was completely attenuated for growth in guinea pigs. However, we found that immunocompetent mice infected with the M. tuberculosis H37Rv whiB3 mutant strain had significantly longer mean survival times as compared with mice challenged with wild-type M. tuberculosis. Remarkably, the bacterial organ burdens of both mutant and wild-type infected mice were identical during the acute and persistent phases of infection. Our results imply that M. tuberculosis replication per se is not a sufficient condition for virulence in vivo. They also indicate a different role for M. bovis and M. tuberculosis whiB3 genes in pathogenesis generated in different animal models. We propose that M. tuberculosis WhiB3 functions as a transcription factor regulating genes that influence the immune response of the host.T he increased susceptibility of HIV-infected individuals and the emergence of multidrug-resistant strains of Mycobacterium tuberculosis (MTB) results in the death of 2-3 million people each year (1) and underscores the urgency of deciphering the molecular mechanisms of virulence of this pathogen. The highly variable protective efficacy of Mycobacterium bovis bacillus Calmette-Guérin in adults (0-80%; ref. 2) emphasizes the urgency for developing second-generation antituberculosis antimicrobial agents and vaccines. With these aims in mind, research stimulated by the advances in mycobacterial genetics (3, 4) has led to the identification of several genes that have been implicated in virulence (5-12).MTB requires sophisticated genetic mechanisms to recognize appropriate environmental signals and to convey this information to the transcriptional apparatus of the organism. The activation of bacterial sigma factors to regulate gene expression is an effective response mechanism that enables pathogens to respond instantly to a multitude of environmental signals. Bacterial 70 -type sigma factors are composed of four major regions, called regions 1, 2, 3 and 4 (13). Region 4 is subdivided further into sub regions 4.1 and 4.2; the latter is known to interact with the Ϫ35 region of promoters (13) and other transcription factors. Mutations in or close to the helix-turn-helix (HTH) motif in region 4.2 can result in either positive or negative effects on activation by transcri...
The Mycobacterium avium complex consists of epidemiologically distinct subsets. The classification of these subsets is complicated by a number of factors, including the ambiguous results obtained with phenotypic and genetic assays and the recent appreciation that human and avian strains appear to be distinct. In previous work, sequencing based on a 441-bp portion of the hsp65 gene has proven to efficiently classify isolates within the Mycobacterium genus but provides low resolution for distinguishing among members of the M. avium complex. Therefore, in this study, we have targeted the more variable 3 region of the hsp65 gene to determine whether it can effectively discriminate M. avium complex isolates at the levels of species and subspecies. Primers designed for this target consistently generated amplicons for all organisms classified as M. avium complex. Sequences obtained indicate that M. intracellulare is genetically divergent from M. avium organisms, and distinct sequevars were obtained for M. avium subsets, including M. avium subsp. avium (bird type), M. avium subsp. hominissuis, and M. avium subsp. paratuberculosis. In addition, sequence differences served to distinguish bovine from ovine strains of M. avium subsp. paratuberculosis. A unique profile for M. avium subsp. silvaticum was not obtained. These results indicate that sequencing the 3 region of the hsp65 gene can simply and unambiguously distinguish species and subspecies of the M. avium complex.
Mycobacterium avium comprises organisms that share the same species designation despite considerable genomic and phenotypic variability. To determine the degree and nature of variability between subspecies and strains of M. avium, we used multilocus sequencing analysis, studying 56 genetically diverse strains of M. avium that included all described subspecies. In total, 8,064 bp of sequence from 10 gene loci were studied, with 205 (2.5%) representing variable positions. The majority (149/205) of these variations were found among M. avium subsp. hominissuis organisms. Recombination was also evident in this subspecies. In contrast, there was comparatively little variability and no evidence of recombination within the pathogenic subspecies, M. avium subsp. paratuberculosis, M. avium subsp. avium, and M. avium subsp. silvaticum. Phylogenetic analysis showed that M. avium subsp. avium and M. avium subsp. silvaticum strains clustered together on one branch, while a distinct branch defined M. avium subsp. paratuberculosis organisms. Despite the independent origin of these pathogenic subspecies, an analysis of their rates of nonsynonymous (dN) to synonymous (dS) substitutions showed increased dN/dS ratios for both: 0.67 for M. avium subsp. paratuberculosis and 0.50 for M. avium subsp. avium/M. avium subsp. silvaticum, while the value was 0.08 for M. avium subsp. hominissuis organisms. In conclusion, M. avium subsp. hominissuis represents a diverse group of organisms from which two pathogenic clones (M. avium subsp. paratuberculosis and M. avium subsp. avium/M. avium subsp. silvaticum) have evolved independently.
The most significant mycobacterial diseases of free-living, captive and farmed deer are bovine tuberculosis, caused by Mycobacterium bovis, Johne's disease (paratuberculosis), caused by Mycobacterium avium subsp paratuberculosis (basonym M. paratuberculosis), and avian tuberculosis, caused principally by M. avium subsp avium. The first case of M. bovis infection in farmed deer was identified in New Zealand in 1978. In 1983, a voluntary scheme was introduced in New Zealand to control tuberculosis in farmed deer, followed by a compulsory tuberculosis control scheme in 1990. The primary control measure is the slaughter of infected animals, detected by skin testing and blood testing, together with movement control and vector control. The number of infected deer herds peaked in the mid 1990s at over 160 herds, but by 30 June 2002 this had been reduced to 79 (1.45%), and to 67 (1.23%) by June 2003. Deer-to-deer transmission occurs, but the majority of herd breakdowns are believed to be from infected vectors. Factors likely to affect the susceptibility of deer include age, environment, population density, exposure and genetics. Avian tuberculosis occasionally causes clinical disease in wild, captive and farmed deer in New Zealand and overseas. Mycobacterium intracellulare, and subspecies of M. avium other than M. paratuberculosis, are widespread throughout New Zealand and are thought to be largely responsible for the high level of sensitisation to avian purified protein derivative (PPD), which is used for comparison purposes in tuberculosis skin testing of deer in this country. Infections with these organisms are usually subclinical in farmed deer, although M. avium subsp avium commonly causes lesions in retropharyngeal, mesenteric and ileocaecal lymph nodes. These lesions cause problems because of their gross and microscopic similarity to those due to M. bovis infection. Birds and domestic animals are most likely to become infected via environmental contamination of food, water, bedding litter or soil, while carnivores or scavengers may also become infected by ingesting infected carcasses. Johne's disease has been reported in deer in the wild and in zoos, especially in North America, the United Kingdom (UK) and Europe. Since first being confirmed in farmed deer in New Zealand in 1979, the incidence of Johne's disease has increased steadily. To date, M. paratuberculosis has been identified in >600 farmed deer on 300 properties. The majority of cases have been identified from suspected tuberculous lesions submitted from deer slaughter plants. Clinically, Johne's disease in deer is similar to the disease in sheep and cattle, with typical signs of loss of weight and condition, and diarrhoea. However, outbreaks of Johne's disease frequently occur in young red deer, 8-15 months of age, whereas the clinical disease in sheep and cattle is sporadic and usually affects adults 3-5 years of age. The disease is characterised by a chronic granulomatous enteritis and lymphadenitis, especially affecting the jejunum and ileum and the m...
Isoniazid (INH) resistance of the Mycobacterium tuberculosis Complex (MtbC) is associated with both loss of catalase activity and mutation of the inhA gene. However, the relative contributions of these changes to resistance and to the loss of virulence for guinea-pigs is unknown. In this study, a virulent strain of Mycobacterium bovis, a member of the MtbC, was exposed to increasing concentrations of INH. Two INH-resistant strains were produced which had lost catalase activity. Strain WAg405, which had a higher resistance to INH, also had a mutation in the inhA gene. This demonstrated that loss of catalase activity and mutation of inhA had a cumulative effect on INH resistance. When a functional katG gene was integrated into the genome of WAg405 the INH resistance was greatly reduced. This indicated that most of the resistance had been caused by loss of catalase activity. While the parent INH-sensitive strain was virulent for guinea-pigs, the INH-resistant strains were significantly less virulent. Integration of a functional katG gene into the most resistant strain restored full virulence. This clearly established that katG is a virulence factor for M. bovis and that mutation of the inhA gene has no effect on virulence.
Identification of two groups of Mycobacterium paratuberculosis strains by restriction endonuclease analysis and DNA hybridization
Genomic DNA was prepared from four reference strains of Mycobacterium paratuberculosis and 46 isolates of this organism from New Zealand, Australia, Canada, and Norway and also from two mycobactin-dependent "wood pigeon" strains. The DNA was characterized by restriction endonuclease analysis, both with and without DNA hybridization, with a probe specific to a repetitive DNA sequence in M. paratuberculosis. Both techniques differentiated M. paratuberculosis strains into two groups, but DNA hybridization revealed more differences between strains within the larger group. All the strains from cattle and many strains from other animals belonged to this group. The second group of nine strains included the Faroe Islands strain, ail New Zealand sheep strains, and one New Zealand goat strain. Primary isolation of strains belonging to this group was difficult to achieve. DNA from acid-fast organisms harvested directly from intestinal tissues of sheep with Johne's disease was shown to have restriction and hybridization patterns identical to those of DNA obtained from M. paratuberculosis isolates cultured from the same tissues. Two Norwegian goat strains and the wood pigeon strains did not hybridize to the M. paratuberculosis probe and had restriction patterns very different from those of other M. paratuberculosis strains. The wood pigeon strains had restriction patterns very similar to those of strains of Mycobacterium avium, indicating that they should be classified as that species. The presence of two distinct groups of M. paratuberculosis strains and their predominant distribution in different host animals may be significant in management of mixed-animal farming operations.
We have identified a globally important clonal complex of M. bovis by deletion analysis of over one thousand strains from over 30 countries. We initially show that over 99% of the strains of Mycobacterium bovis, the cause of bovine tuberculosis, isolated from cattle in the Republic of Ireland and the UK are closely related and are members of a single clonal complex marked by the deletion of chromosomal region RDEu,1 and we named this clonal complex European 1 (Eu1). Eu1 strains were present at less than
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