Isolation and sequence of a Mycobacterium tuberculosis sigma factor

A DNA segment from Mycobacterium tuberculosis containing a gene for a putative sigma factor was isolated and sequenced. The protein encoded by this gene is 92% similar to the Mycobacterium smegmatis sigma factor MysB, and has been designated Mtu SigB. A Mycobacterium leprae homologue of mysB and mtu sigB was identified in the database.     

The Brevibacterium flavum sigma factor SigB has a role in the environmental stress response

We have previously cloned a gene encoding a SigB, a principal-like sigma factor in Brevibacterium flavum, which was induced by several stress conditions. To clarify the in vivo function of this sigma factor, the sigB gene was disrupted by a homologous recombination, replacing the internal essential coding region in B. flavum chromosome by a kanamycin resistance marker gene. This mutation dramatically decreased vegetative growth rates of B. flavum. Studies of the effect of the sigB mutation on growth and viability of the cells under conditions of stress showed that the sigB mutant had increased susceptibility to acid, salt, alcohol, heat and cold stress. The plasmid-born wild-type sigB gene complemented the mutation. Based on the results, we propose that SigB has a role in vegetative growth and in response to various environmental stresses.     

The systems approach to the prespore-specific activation of sigma factor SigF in Bacillus subtilis

The prespore-specific activation of sigma factor SigF (σ^F) in Bacillus subtilis has been explained mainly by two factors, i.e., the transient genetic asymmetry and the volume difference between the mother cell and the prespore. Here, we systematically surveyed the effect of these two factors on sporulation using a quantitative modeling and simulation architecture named hybrid functional Petri net with extension (HFPNe). Considering the fact that the transient genetic asymmetry and the volume difference in sporulation of B. subtilis finally bring about the concentration difference in two proteins SpoIIAB (AB) and SpoIIAA (AA) between the mother cell and the prespore, we have surveyed the effect of AB and AA concentration on the prespore-specific activation of σ^F occurring in the early stage of sporulation. Our results show that the prespore-specific activation of σ^F could be governed by the ratio of AA to AB rather than their concentrations themselves. Our model also suggests that B. subtilis could maximize the ratio of AA to AB in the prespore and minimize it in the mother cell by employing both the transient genetic asymmetry and the volume difference simultaneously. This might give a good explanation to the co-occurrence of the transient asymmetry and the volume difference during sporulation of B. subtilis. In addition, we suggest for the first time that the σ^F activation in the prespore might be switched off by the decrease in the ratio of AA to AB after the transient genetic asymmetry is to an end by completion of DNA translocation into the prespore.     

SigF, a new sigma factor required for a motility system of Myxococcus xanthus

A new sigma factor, SigF, was identified from the social and developmental bacterium Myxococcus xanthus. SigF is required for fruiting body formation during development as well as social motility during vegetative growth. Analysis of gene expression indicates that it is possible that the sigF gene is involved in regulation of an unidentified gene for social motility.     

The SigB sigma factor mediates high-temperature responses in the cyanobacterium Synechocystis sp. PCC6803

The sigma factors of RNA polymerase play central roles when bacteria adapt to different environmental conditions. We studied heat-shock responses in the cyanobacterium Synechocystis sp. PCC6803 using the sigma factor inactivation strains deltasigB, deltasigD and deltasigBD. The SigB factor was found to be important for short-term heat-shock responses and acquired thermotolerance. The normal high-temperature induction of the hspA gene depended on the SigB factor. The SigD sigma factor had a role in high-temperature responses as well, and the double inactivation strain deltasigBD grew more slowly at 43 degrees C than the deltasigB and deltasigD strains.     

The alternative sigma factor SigH regulates major components of oxidative and heat stress responses in Mycobacterium tuberculosis

Mycobacterium tuberculosis is a specialized intracellular pathogen that must regulate gene expression to overcome stresses produced by host defenses during infection. SigH is an alternative sigma factor that we have previously shown plays a role in the response to stress of the saprophyte Mycobacterium smegmatis. In this work we investigated the role of sigH in the M. tuberculosis response to heat and oxidative stress. We determined that a M. tuberculosis sigH mutant is more susceptible to oxidative stresses and that the inducible expression of the thioredoxin reductase/thioredoxin genes trxB2/trxC and a gene of unknown function, Rv2466c, is regulated by sigH via expression from promoters directly recognized by SigH. We also determined that the sigH mutant is more susceptible to heat stress and that inducible expression of the heat shock genes dnaK and clpB is positively regulated by sigH. The induction of these heat shock gene promoters but not of other SigH-dependent promoters was markedly greater in response to heat versus oxidative stress, consistent with their additional regulation by a heat-labile repressor. To further understand the role of sigH in the M. tuberculosis stress response, we investigated the regulation of the stress-responsive sigma factor genes sigE and sigB. We determined that inducible expression of sigE is regulated by sigH and that basal and inducible expression of sigB is dependent on sigE and sigH. These data indicate that sigH plays a central role in a network that regulates heat and oxidative-stress responses that are likely to be important in M. tuberculosis pathogenesis.