The Mycobacterium tuberculosis SigD sigma factor controls the expression of ribosome-associated gene products in stationary phase and is required for full virulence.

During infection Mycobacterium tuberculosis is exposed to several environmental conditions depending on the stage and severity of the disease. To survive, M. tuberculosis uses alternate sigma factors to regulate its gene expression in response to the changing host environment. In order to better understand the way in which stress response genes are regulated, the extracytoplasmic sigma factor gene sigD was deleted and subsequently complemented in the CDC1551 strain of M. tuberculosis. The DeltasigD mutant strain exhibited an in vitro growth rate in rich medium identical to that of both the sigD-complemented and wild-type CDC1551 strains. Additionally, no differences were observed in short-term intracellular growth between the mutant, complemented, and wild-type bacteria within the J774A.1 macrophage cell line. However, tumour necrosis factor (TNF)-alpha levels in macrophages infected with the DeltasigD mutant were decreased as compared to levels observed in macrophages infected with the wild-type bacteria. In time-to-death studies, C3H mice infected with the DeltasigD mutant exhibited a mortality delay compared to those infected with either the complemented or wild-type strains. Although mice infected with the DeltasigD mutant died at a reduced rate, the bacillary loads in the lungs and spleen of these mice were comparable to those seen in mice infected with either the complemented or wild-type strains. Microarray analysis of the DeltasigD mutant relative to wild type revealed that SigD directs the expression of a small set of ribosomal genes and adenosine triphosphate transporters whose expression is normally induced during stationary phase growth in vitro. Altered expression of a subset of these genes was confirmed by quantitative reverse transcription polymerase chain reaction analysis. Promoter-like elements resembling the consensus sequence AGAAAG-N16-20-CGTTAA were found upstream of 19 of the genes underexpressed in the DeltasigD mutant suggesting this may be the recognition sequence for the M. tuberculosis SigD-holoenzyme, EsigmaD. These data indicate that the M. tuberculosis SigD sigma factor governs the expression of a small set of ribosomal genes typically expressed in stationary phase during in vitro growth and that loss of sigD reduces macrophage TNF-alpha secretion as well as the lethality of M. tuberculosis infection in mice.

Emergence of fluoroquinolone resistance in Mycobacterium tuberculosis during continuously dosed moxifloxacin monotherapy in a mouse model.

Fluoroquinolone resistance in tuberculosis may rapidly emerge. Mice infected with high titers of aerosolized Mycobacterium tuberculosis and treated for 8 weeks with four concentrations of moxifloxacin (0.125, 0.25, 0.50, and 1.0%) mixed into the diet had drug concentrations of 2.4, 4.1, 5.3, and 17.9 microg/ml, respectively, in blood. Selection of fluoroquinolone-resistant mutants occurred in all surviving mice.

Regulation of autolysins in teichuronic acid-containing Bacillus subtilis cells.

Bacillus subtilis cells grown under phosphate starvation induce teichuronic acid (TUA) synthesis while simultaneously repressing teichoic acid synthesis (TA). The turnover rates of TA-containing and TUA-containing walls are similar, indicating that autolysin function is similar and suggesting that modulation of autolytic function may be similar. In this study, it is demonstrated, utilizing fluorescein isothiocyanate (FITC)-dextran to probe the wall pH, that a low pH exists in the wall matrix. A second probe, cationized ferritin (CF), was used to observe cell surface protonation. Suspensions of B. subtilis cells containing either TA or TUA were aggregated with CF only after the addition of a proton-motive-force-dissipating agent. Respiring B. subtilis TUA-containing cells labelled with FITC-dextran exhibited little fluorescence. Conversely, fluorescence intensities exhibited by cells de-energized with nitrogen gas were significantly greater. The effects of protonmotive force on autolytic activity were studied by adding cell wall protein extract containing concentrated autolysin to exponentially growing TA-containing and TUA-containing B. subtilis cells. Both TUA-containing and TA-containing cells were lysed only after the addition of sodium azide. These data suggest that during normal growth the wall of TUA-containing B. subtilis cells is protonated, and proton-motive force influences autolytic regulation in both TUA-containing and TA-containing B. subtilis cells.