Heat shock regulation in the ftsH null mutant of Escherichia coli: dissection of stability and activity control mechanisms of σ32in vivo

The heat shock response of Escherichia coli is regulated by the cellular level and the activity of σ³², an alternative sigma factor for heat shock promoters. FtsH, a membrane-bound AAA-type metalloprotease, degrades σ³² and has a central role in the control of the σ³² level. The ftsH null mutant was isolated, and establishment of the Δ ftsH mutant allowed us to investigate control mechanisms of the stability and the activity of σ³² separately in vivo . Loss of the FtsH function caused marked stabilization and consequent accumulation of σ³² (≈20-fold of the wild type), leading to the impaired downregulation of the level of σ³². Surprisingly, however, Δ ftsH cells express heat shock proteins only two- to threefold higher than wild-type cells, and they also show almost normal heat shock response upon temperature upshift. These results indicate the presence of a control mechanism that downregulates the activity of σ³² when it is accumulated. Overproduction of DnaK/J reduces the activity of σ³² in Δ ftsH cells without any detectable changes in the level of σ³², indicating that the DnaK chaperone system is responsible for the activity control of σ³² in vivo . In addition, CbpA, an analogue of DnaJ, was demonstrated to have overlapping functions with DnaJ in both the activity and the stability control of σ³².     

Vaccination with SIVmac239Δnef activates CD4+ T cells in the absence of CD4+ T-cell loss

Background  Pathogenic HIV and SIV infections characteristically deplete central memory CD4⁺ T cells and induce chronic immune activation, but it is controversial whether this also occurs after vaccination with attenuated SIVs and whether depletion or activation of CD4⁺ T-cell play roles in protection against wild-type virus challenge.
Methods  Rhesus macaques were vaccinated with SIVmac239Δnef and quantitative and phenotypic polychromatic flow cytometry analyses were performed on mononuclear cells from blood, lymph nodes and rectal biopsies.
Results  Animals vaccinated with SIVmac239Δnef demonstrated no loss of CD4⁺ T cells in any tissue, and in fact CCR5⁺ and CD28⁺CD95⁺ central memory CD4⁺ T cells were significantly increased. In contrast, CD4⁺ T-cell numbers and CCR5 expression significantly declined in unvaccinated controls challenged with SIVmac239. Also, intracellular Ki67 increased acutely as much as 3-fold over baseline in all tissues after SIVmac239Δnef vaccination then declined following primary infection.
Conclusion  We demonstrated in this study that SIVmac239Δnef vaccination did not deplete CD4⁺ T cells but transiently activated and expanded the memory cell population. However, increases in numbers and activation of memory CD4⁺ T cells did not appear to influence protective immunity.     

Dissection of recognition determinants of Escherichia coli σ32 suggests a composite −10 region with an 'extended −10' motif and a core −10 element

σ³² controls expression of heat shock genes in Escherichia coli and is widely distributed in proteobacteria. The distinguishing feature of σ³² promoters is a long −10 region (CCCCATNT) whose tetra-C motif is important for promoter activity. Using alanine-scanning mutagenesis of σ³² and in vivo and in vitro assays, we identified promoter recognition determinants of this motif. The most downstream C (−13) is part of the −10 motif; our work confirms and extends recognition determinants of −13C. Most importantly, our work suggests that the two upstream Cs (−16, −15) constitute an 'extended −10' recognition motif that is recognized by K130, a residue universally conserved in β- and γ-proteobacteria. This residue is located in the α-helix of σDomain 3 that mediates recognition of the extended −10 promoter motif in other σs. K130 is not conserved in α- and δ-/ε-proteobacteria and we found that σ³² from the α-proteobacterium Caulobacter crescentus does not need the extended −10 motif for high promoter activity. This result supports the idea that K130 mediates extended −10 recognition. σ³² is the first Group 3 σ shown to use the 'extended −10' recognition motif.     

Mutational analysis of Escherichia coli σ28 and its target promoters reveals recognition of a composite −10 region, comprised of an 'extended −10' motif and a core −10 element

σ²⁸ controls the expression of flagella-related genes and is the most widely distributed alternative σ factor, present in motile Gram-positive and Gram-negative bacteria. The distinguishing feature of σ²⁸ promoters is a long −10 region (GCCGATAA). Despite the fact that the upstream GC is highly conserved, previous studies have not indicated a functional role for this motif. Here we examine the functional relevance of the GCCG motif and determine which residues in σ²⁸ participate in its recognition. We find that the GCCG motif is a functionally important composite element. The upstream GC constitutes an extended −10 motif and is recognized by R91, a residue in Domain 3 of σ²⁸. The downstream CG is the upstream edge of −10 region of the promoter; two residues in Region 2.4, D81 and R84, participate in its recognition. Consistent with their role in base-specific recognition of the promoter, R91, D81 and D84 are universally conserved in σ²⁸ orthologues. σ²⁸ is the second Group 3 σ shown to use an extended −10 region in promoter recognition, raising the possibility that other Group 3 σs will do so as well.     

Use of cell wall stress to characterize σ22 (AlgT/U) activation by regulated proteolysis and its regulon in Pseudomonas aeruginosa

MucA sequesters extracytoplasmic function (ECF) σ²² ( algT/U encoded) from target promoters including P algD for alginate biosynthesis. We have shown that cell wall stress (e.g. d -cycloserine) is a potent inducer of the algD operon. Here we showed that MucB, encoded by the algT-mucABCD operon, interacts with MucA in the sigma–sequestration complex. We hypothesized that AlgW protease (a DegS homologue) is activated by cell wall stress to cleave MucA and release σ²². When strain PAO1 was exposed to d -cycloserine, MucA was degraded within just 10 min, and σ²² was activated. However, in an algW mutant, MucA was stable with no increased σ²² activity. Studies on a yaeL mutant, defective in an RseP/YaeL homologue, suggest that YaeL protease cleaves MucA only after cleavage by AlgW. A defect in mucD , encoding a periplasmic HtrA/DegP homologue, caused MucA instability, suggesting MucD degrades cell wall stress signals. Overall, these data indicate that cell wall stress signals release σ²² by regulated intramembrane proteolysis (RIP). Microarray analyses identified genes of the early and late cell wall stress stimulon, which included genes for alginate production. The subset of genes in the σ²² regulon was then determined, which included gene products predicted to contribute to recovery from cell wall stress.