Mycobacterium ulcerans is found in aquatic ecosystems and causes Buruli ulcer in humans, a neglected but devastating necrotic disease of subcutaneous tissue that is rampant throughout West and Central Africa. Here, we report the complete 5.8-Mb genome sequence of M. ulcerans and show that it comprises two circular replicons, a chromosome of 5632 kb and a virulence plasmid of 174 kb. The plasmid is required for production of the polyketide toxin mycolactone, which provokes necrosis. Comparisons with the recently completed 6.6-Mb genome of Mycobacterium marinum revealed >98% nucleotide sequence identity and genome-wide synteny. However, as well as the plasmid, M. ulcerans has accumulated 213 copies of the insertion sequence IS2404, 91 copies of IS2606, 771 pseudogenes, two bacteriophages, and multiple DNA deletions and rearrangements. These data indicate that M. ulcerans has recently evolved via lateral gene transfer and reductive evolution from the generalist, more rapid-growing environmental species M. marinum to become a niche-adapted specialist. Predictions based on genome inspection for the production of modified mycobacterial virulence factors, such as the highly abundant phthiodiolone lipids, were confirmed by structural analyses. Similarly, 11 protein-coding sequences identified as M. ulcerans-specific by comparative genomics were verified as such by PCR screening a diverse collection of 33 strains of M. ulcerans and M. marinum. This work offers significant insight into the biology and evolution of mycobacterial pathogens and is an important component of international efforts to counter Buruli ulcer.
The role of biofilms in the pathogenesis of mycobacterial diseases remains largely unknown. Mycobacterium ulcerans, the etiological agent of Buruli ulcer, a disfiguring disease in humans, adopts a biofilm-like structure in vitro and in vivo, displaying an abundant extracellular matrix (ECM) that harbors vesicles. The composition and structure of the ECM differs from that of the classical matrix found in other bacterial biofilms. More than 80 proteins are present within this extracellular compartment and appear to be involved in stress responses, respiration, and intermediary metabolism. In addition to a large amount of carbohydrates and lipids, ECM is the reservoir of the polyketide toxin mycolactone, the sole virulence factor of M. ulcerans identified to date, and purified vesicles extracted from ECM are highly cytotoxic. ECM confers to the mycobacterium increased resistance to antimicrobial agents, and enhances colonization of insect vectors and mammalian hosts. The results of this study support a model whereby biofilm changes confer selective advantages to M. ulcerans in colonizing various ecological niches successfully, with repercussions for Buruli ulcer pathogenesis.
DNA sequence analysis of regions from plasmid pIP417 and chromosome BF8 which encode 5-nitroimidazole resistance in Bacteroides strains allowed the identification of two open reading frames corresponding to new genes, nimA (528 bp) and nimB (492 bp). Either gene may confer 5-nitroimidazole resistance to susceptible strains of Bacteroides. The encoded polypeptides have deduced molecular masses of 20.1 and 18.6 kDa, respectively, and share about 73% identity and 85% similarity. A new insertion sequence (IS) element named IS1168 lies 14 bases upstream of the nimA gene. The complete sequence of IS1168 was determined. A similar IS exists 12 bp upstream of the nimB gene. About 60% of the BF8 IS element was also sequenced and shown to be almost identical to IS1168.
We investigated the metabolism of dimetridazole (1,2-dimethyl-5-nitroimidazole) (DMZ) by the resting cell method in a susceptible strain of Bacteroides fragilis and in the same strain containing the nimA gene, which conferred resistance to 5-nitroimidazole drugs. In both cases, under strict anaerobic conditions DMZ was metabolized without major ring cleavage or nitrate formation. However, one of two distinct metabolic pathways is involved, depending on the susceptibility of the strain. In the susceptible strain, the classical reduction pathway of nitroaromatic compounds is followed at least as far as the nitroso-radical anion, with further formation of the azo-dimer: 5,5-azobis-(1,2-dimethylimidazole). In the resistant strain, DMZ is reduced to the amine derivative, namely, 5-amino-1,2-dimethylimidazole, preventing the formation of the toxic form of the drug. The specificity of the six-electron reduction of the nitro group, which is restricted to 4-and 5-nitroimidazole, suggests an enzymatic reaction. We thus conclude that nimA and related genes may encode a 5-nitroimidazole reductase.
A PCR method was developed for detection of the nim genes encoding 5-nitroimidazole resistance in Bacteroides spp. Two PCR primers specific for nim genes were designed. They allowed amplification of a 458-bp fragment from all characterized plasmid-and chromosome-borne metronidazole resistance genes. The specificity of the method was tested with DNA from metronidazole-sensitive Bacteroides spp. strains and from other strains of unrelated species. Each DNA preparation was analyzed with and without an internal positive control to verify that the absence of PCR amplification product was not due to inhibition of the Taq polymerase inhibitors. By this technique, two newly discovered metronidazole-resistant clinical strains of Bacteroides fragilis were shown to harbor resistance genes undetectable by Southern blotting. In spite of the sequence divergence of the nim genes, the PCR method is thus suitable for epidemiological investigations. The amplification method also revealed that nim-related resistance genes were not present in either Streptomyces strain S6670, a natural producer of 2-nitroimidazole, or in Enterococcus faecalis strains, which have been suggested to possess metronidazole-inactivating enzyme.
Clostridium perfringens is a ubiquitous gram-positive pathogen that is present in the air, soil, animals, and humans. Although C. perfringens is strictly anaerobic, vegetative and stationary cells can survive in a growth-arrested stage in the presence of oxygen and/or low concentrations of superoxide and hydroxyl radicals. Indeed, it possesses an adaptive response to oxidative stress, which can be activated in both aerobic and anaerobic conditions. To identify the genes involved in this oxidative stress response, C. perfringens strain 13 mutants were generated by Tn916 insertional mutagenesis and screened for resistance or sensitivity to various oxidative stresses. Three of the 12 sensitive mutants examined harbored an independently inserted single copy of the transposon in the same operon as two genes orthologous to the ydaD and ycdF genes of Bacillus subtilis, which encode a putative NADPH dehydrogenase. Complementation experiments and knockout experiments demonstrated that these genes are both required for efficient resistance to oxidative stress in C. perfringens and are probably responsible for the production of NADPH, which is required for maintenance of the intracellular redox balance in growth-arrested cells. Other Tn916 disrupted genes were also shown to play important roles in the oxidative stress response. This is the first time that some of these genes (e.g., a gene encoding an ATP-dependent RNA helicase, the beta-glucuronidase gene, and the gene encoding the atypical iron sulfur prismane protein) have been shown to be involved in the oxidative response.
The genetic organization of two different 5-nitroimidazole (5-Ni) resistance genes was investigated: nimC and nimD from Bacteroides plasmids plP419 and plP421, respectively. The nimC gene (492 bp) and the nimD gene (495 bp) directed the synthesis of polypeptides with deduced molecular masses of 18.37 kDa and 1848 kDa, respectively. The predicted proteins showed 6 7 4 3 % identity and 78-91 O/ O similarity with the products of two other nimA and nimB genes previously described and could be derived from a common ancestral gene. An insertion sequence element (IS1170) was identified upstream of the nimC gene. IS1170 is 1604 bp in length and is flanked by'imperfect inverted repeats (15 bp). IS1770 is similar to the Bacteroides insertion sequence element IS942 with an identity of 70% a t the nucleotide level. The single copy of IS1170 present on plasmid plP419 is integrated 24 bp upstream of the initiation codon of nimC. Similar genetic organization was found on plasmid plP421. One copy of another insertion sequence (151169) was found 4 bp upstream of the first ATG codon of the nimD gene. This element (1325 bp) shows a strong homology a t the nucleotide level (70% identity) with IS1186 and IS1168 found to be associated with the Bacteroides carbapenem resistance gene cfiA, and the 5-Ni'genes nimA and nimB, respectively. There is strong evidence that, as in the case of the &A gene, the transcription of the four nim genes so far studied is directed by outward-oriented promoters, carried on the right ends of the different insertion sequence elements.
The Rhizobium strain ORS571, which is associated with the tropical legume Sesbania rostrata, has the property of growing in the free‐living state at the expense of ammonia or N2 as sole nitrogen source. Five mutants, isolated as unable to form colonies on plates under conditions of nitrogen fixation, were studied. All of them, which appear as Fix‐ in planta, are nif mutants. With mutant 5740, nitrogenase activity of the crude extract was restored by addition of pure Mo‐Fe protein of Klebsiella pneumoniae. A 13‐kb BamHI DNA fragment from the wild‐type strain, which hybridized with a probe carrying the nifHDK genes of K. pneumoniae, was cloned in vector pRK290 to yield plasmid pRS1. The extent of homology between the probe and the BamHI fragment was estimated at 4 kb and hybridization with K. pneumoniae nifH, nifK, and possibly nifD was detected. The pRS1 plasmid was introduced into the sesbania rhizobium nif mutants. Genetic complementation was observed with strain 5740(pRS1) both in the free‐living state and in planta. It thus appears that biochemistry and genetics of nitrogen fixation in this particular Rhizobium strain can be performed with bacteria grown under non‐symbiotic conditions.
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