Mycobacterium tuberculosis phagosome

The arrest of Mycobacterium tuberculosis phagosome maturation in infected macrophages is a phenomenon of dual significance both for the pathogenesis of tuberculosis and as a model system to study interference of microbes with membrane trafficking and organelle biogenesis in host cells. Among other factors, compartment-specialized regulators of vesicular trafficking and other parts of membrane fusion machinery are likely to play a role in these processes. Here we summarize the emerging view of mycobacterial phagosome maturation arrest in the context of the dynamic processes of intracellular membrane trafficking.     

Monoglycosyldiacylphenol-phthiocerol of Mycobacterium tuberculosis and Mycobacterium bovis

The structure of a minor glycolipid of M. tuberculosis (strain Canetti) is shown to be 2-O-methyl-alpha-L-rhamnosyldiacylphenol-phthiocerol. A similar compound with non-methylated rhamnose as sugar moiety was also detected. In the course of this work, the structure of mycoside B from Mycobacterium bovis was reexamined, and was shown to be identical to that of the 2-O-methylrhamnosyldiacylphenol-phthiocerol of the Canetti strain, while it was described as a 2-O-methyl-beta-D-rhamnosyl derivative in the literature. This result is in agreement with the known close relationship between M. tuberculosis and M. bovis. Careful examination of chromatographic fractions containing the above mentioned lipids showed that the occurrence of mycoloyl residues in some phenol-phthiocerol glycolipids, postulated in the literature, was likely to be due to the presence of glycerol monomycolate contaminants.     

Virulence of Mycobacterium tuberculosis

Abstract Different strains of Candida albicans show varied sensitivities to the peptide analogues bacilysin, polyoxins and nikkomycins. From a sensitive strain, B2630, spontaneous mutants were selected for resistance to each analogue; certain mutants showed cross-resistance to other analogues and associated defects in peptide transport. A bacilysin-resistant mutant was cross resistant to the other analogues and to m -fluorophenylalanyl-Ala (FPA) but retained sensitivity to m -fluorophenylalanyl-Ala—Ala (FPAA). It showed defective dipeptide transport but normal oligopeptide transport. A revertant, selected for its ability to utilize Ala-Ala as sole nitrogen source, regained wild-type dipeptide transport activity and analogue sensitivity. Thus, C. albicans has distinguishable mechanisms for dipeptide and oligopeptide transport which can be exploited for uptake of peptide-drug adducts.     

Recombineering in Mycobacterium tuberculosis

Genetic dissection of M. tuberculosis is complicated by its slow growth and its high rate of illegitimate recombination relative to homologous DNA exchange. We report here the development of a facile allelic exchange system by identification and expression of mycobacteriophage-encoded recombination proteins, adapting a strategy developed previously for recombineering in Escherichia coli. Identifiable recombination proteins are rare in mycobacteriophages, and only 1 of 30 genomically characterized mycobacteriophages (Che9c) encodes homologs of both RecE and RecT. Expression and biochemical characterization show that Che9c gp60 and gp61 encode exonuclease and DNA-binding activities, respectively, and expression of these proteins substantially elevates recombination facilitating allelic exchange in both M. smegmatis and M. tuberculosis. Mycobacterial recombineering thus provides a simple approach for the construction of gene replacement mutants in both slow- and fast-growing mycobacteria.     

Comparative pathogenesis of Mycobacterium marinum and Mycobacterium tuberculosis

A thorough understanding of Mycobacterium tuberculosis pathogenesis in humans has been elusive in part because of imperfect surrogate laboratory hosts, each with its own idiosyncrasies. Mycobacterium marinum is the closest genetic relative of the M. tuberculosis complex and is a natural pathogen of ectotherms. In this review, we present evidence that the similar genetic programmes of M. marinum and M. tuberculosis and the corresponding host immune responses reveal a conserved skeleton of Mycobacterium host–pathogen interactions. While both species have made niche-specific refinements, an essential framework has persisted. We highlight genetic comparisons of the two organisms and studies of M. marinum in the developing zebrafish. By pairing M. marinum with the simplified immune system of zebrafish embryos, many of the defining mechanisms of mycobacterial pathogenesis can be distilled and investigated in a tractable host/pathogen pair.     

Deciphering sulfoglycolipids of Mycobacterium tuberculosis

For 4 decades, in vivo and in vitro studies have suggested that sulfoglycolipids (SGLs) play a role in the virulence or pathogenesis of the tubercle bacilli. However, the SGL structure and biosynthesis pathway remain only partially elucidated. Using the modern tools of structural analysis, including MALDI-time-of-flight MS, MS/MS, and two-dimensional NMR, we reevaluated the structure of the different SGL acyl (di-, tri-, and tetra-acylated) forms of the reference strain Mycobacterium tuberculosis H37Rv, as well as those produced by the mmpL8 knockout strains previously described to intracellularly accumulate di-acylated SGL. We report here the identification of new acyl forms: di-acylated SGL esterified by simple fatty acids only, as well as mono-acylated SGL bearing a hydroxyphthioceranoic acid, which were characterized in the wild-type strain. In a clinical strain, a complete family of mono-acylated SGLs was characterized in high abundance for the first time. For the mmpL8 mutant, SGLs were found to be esterified i) by an oxophthioceranoic acid, never observed so far, and ii) at nonconventional positions in the case of the unexpected tri-acylated forms. Our results further confirm the requirement of MmpL8 for the complete assembly of the tetra-acylated forms of SGL and also provide, by the discovery of new intermediates, insights in terms of the possible SGL biosynthetic pathways.     

Prospective on Mycobacterium tuberculosis proteomics

Mycobacterium tuberculosis, the causative agent of tuberculosis, remains one of the most prevalent human pathogens in the world. Knowledge regarding the bacilli's physiology as well as its mechanisms of virulence, immunogenicity, and pathogenesis has increased greatly in the last three decades. However, the function of about one-quarter of the Mtb coding genome and the precise activity and protein networks of most of the Mtb proteins are still unknown. Protein mass spectrometry and a new interest in research toward the field of functional proteomics have given a new light to the study of this bacillus and will be the focus of this review. We will also discuss new perspectives in the proteomics field, in particular targeted mass spectrometry methods and their potential applications in TB research and discovery.     

Growth of Mycobacterium tuberculosis Biofilms

Mycobacterium tuberculosis, the etiologic agent of human tuberculosis, has an extraordinary ability to survive against environmental stresses including antibiotics. Although stress tolerance of M. tuberculosis is one of the likely contributors to the 6-month long chemotherapy of tuberculosis ¹, the molecular mechanisms underlying this characteristic phenotype of the pathogen remain unclear. Many microbial species have evolved to survive in stressful environments by self-assembling in highly organized, surface attached, and matrix encapsulated structures called biofilms ^2-4. Growth in communities appears to be a preferred survival strategy of microbes, and is achieved through genetic components that regulate surface attachment, intercellular communications, and synthesis of extracellular polymeric substances (EPS) ^5,6. The tolerance to environmental stress is likely facilitated by EPS, and perhaps by the physiological adaptation of individual bacilli to heterogeneous microenvironments within the complex architecture of biofilms ⁷.In a series of recent papers we established that M. tuberculosis and Mycobacterium smegmatis have a strong propensity to grow in organized multicellular structures, called biofilms, which can tolerate more than 50 times the minimal inhibitory concentrations of the anti-tuberculosis drugs isoniazid and rifampicin ^8-10. M. tuberculosis, however, intriguingly requires specific conditions to form mature biofilms, in particular 9:1 ratio of headspace: media as well as limited exchange of air with the atmosphere ⁹. Requirements of specialized environmental conditions could possibly be linked to the fact that M. tuberculosis is an obligate human pathogen and thus has adapted to tissue environments. In this publication we demonstrate methods for culturing M. tuberculosis biofilms in a bottle and a 12-well plate format, which is convenient for bacteriological as well as genetic studies. We have described the protocol for an attenuated strain of M. tuberculosis, mc²7000, with deletion in the two loci, panCD and RD1, that are critical for in vivo growth of the pathogen ⁹. This strain can be safely used in a BSL-2 containment for understanding the basic biology of the tuberculosis pathogen thus avoiding the requirement of an expensive BSL-3 facility. The method can be extended, with appropriate modification in media, to grow biofilm of other culturable mycobacterial species.Overall, a uniform protocol of culturing mycobacterial biofilms will help the investigators interested in studying the basic resilient characteristics of mycobacteria. In addition, a clear and concise method of growing mycobacterial biofilms will also help the clinical and pharmaceutical investigators to test the efficacy of a potential drug.     

Streptomycin Uptake by Mycobacterium tuberculosis

Data are presented indicating that (14)C-streptomycin uptake by tubercle bacilli increases as a function of exposure time, is directly and proportionately related to concentration, and involves at least two phases.