N. S. Hibler

Arrest of mycobacterial phagosome maturation is caused by a block in vesicle fusion between stages controlled by rab5 and rab7.

Mycobacterium tuberculosis and the closely related organism Mycobacterium bovis can survive and replicate inside macrophages. Intracellular survival is at least in part attributed to the failure of mycobacterial phagosomes to undergo fusion with lysosomes. The transformation of phagosomes into phagolysosomes involves gradual acquisition of markers from the endosomal compartment. Members of the rab family of small GTPases which confer fusion competence in the endocytic pathway are exchanged sequentially onto the phagosomal membranes in the course of their maturation. To identify the step at which the fusion capability of phagosomes containing mycobacteria is compromised, we purified green fluorescent protein-labeled M. bovis BCG phagosomal compartments (MPC) and compared GTP-binding protein profiles of these vesicles with latex bead phagosomal compartments (LBC). We report that the MPC do not acquire rab7, specific for late endosomes, even 7 days postinfection, whereas this GTP-binding protein is present on the LBC within hours after phagocytosis. By contrast, rab5 is retained and enriched with time on the MPC, suggesting fusion competence with an early endosomal compartment. Prior infection of macrophages withM. bovis BCG also affected the dynamics of rab5 and rab7 acquisition by subsequently formed LBC. Selective exclusion of rab7, coupled with the retention of rab5 on the mycobacterial phagosome, may allow organisms from the M. tuberculosis complex to avert the usual physiological destination of phagocytosed material.

In vitro phosphorylation of AlgR, a regulator of mucoidy in Pseudomonas aeruginosa, by a histidine protein kinase and effects of small phospho-donor molecules

AlgR is a transcriptional regulator of mucoidy in Pseudomonas aeruginosa, a critical virulence factor expressed in cystic fibrosis. AlgR belongs to the superfamily of bacterial signal transduction systems, and has been shown to bind to the algD promoter, a critical point in the regulation of mucoidy. This protein, like other typical response regulators, contains highly conserved residues known to be critical for the phosphorylation and signal transduction processes. However, a typical second component Interacting with AlgR has not been identified. Here we demonstrate that AlgR undergoes phosphorylation in vitro when interacting with the well‐characterized histidine protein kinase CheA. These results Indicate that AlgR is capable of undergoing phosphorylation typical of other two‐component signal transduction systems. Moreover, the phosphotransfer reaction between CheA and AlgR was found to be affected by the presence of carbamoyl phosphate, acetyl phosphate, and salts of phosphoramidic acid, recently shown to act as small‐molecular‐weight phospho‐donors in the process of phosphorylation of several response regulators. These findings suggest that AlgR may react with intermediary metabolites such as carbamoyl phosphate and acetyl phosphate, and that these processes may play a role in the control of mucoidy in P. aeruginosa.

Response of Mycobacterium tuberculosis to reactive oxygen and nitrogen intermediates.

BackgroundMycobacterium tuberculosis is a significant human pathogen capable of replicating in mononuclear phagocytic cells. Exposure to reactive oxygen and nitrogen intermediates is likely to represent an important aspect of the life cycle of this organism. The response of M. tuberculosis to these agents may be of significance for its survival in the hostMaterials and MethodsPatterns of de novo proteins synthesized in M. tuberculosis H37Rv exposed to compounds that generate reactive oxygen and nitrogen intermediates were studied by metabolic labeling and two-dimensional electrophoresisResultsMenadione, a redox cycling compound which increases intracellular superoxide levels, caused enhanced synthesis of seven polypeptides, six of which appeared to be heat shock proteins. Chemical release of nitric oxide induced eight polypeptides of which only one could be identified as a heat shock protein. Nitric oxide also exhibited a mild inhibitory action on general protein synthesis in the concentration range tested. Hydrogen peroxide did not cause differential gene expression and exerted a generalized inhibition in a dose-dependent manner. Cumene hydroperoxide caused mostly inhibition but induction of two heat shock proteins was detectable.ConclusionsThe presented findings indicate major differences between M. tuberculosis and the paradigms of oxidative stress response in enteric bacteria, and are consistent with the multiple lesions found in oxyR of this organism. The effect of hydrogen peroxide, which in Escherichia coli induces eight polypeptides known to be controlled by the central regulator oxyR, appears to be absent in M. tuberculosis. Superoxide and nitric oxide responses, which in E. coli overlap and are controlled by the same regulatory system soxRS, represent discrete and independent phenomena in M. tuberculosis.