Control of the alternative sigma factor sigmaE in Escherichia coli

Signal transduction pathways that communicate information from the cell envelope to the cytoplasm of bacteria are crucial to maintain cell envelope homeostasis. In Escherichia coli, one of the key pathways that ensures the integrity of the cell envelope during stress and normal growth is controlled by the alternative sigma factor sigmaE. Recent studies have elucidated the signal transduction pathway that activates sigmaE in response to misfolded outer membrane porins. Unfolded porins trigger the degradation of the sigmaE-specific antisigma factor RseA by the sequential action of two inner membrane proteases, leading to release of sigmaE from RseA, and induction of the stress response. This mechanism of signal transduction, regulated intramembrane proteolysis, is used in transmembrane signaling pathways from bacteria to humans.     

SigmaE is an essential sigma factor in Escherichia coli.

SigmaE is an alternative sigma factor that controls the extracytoplasmic stress response in Escherichia coli. SigmaE is essential at high temperatures but was previously thought to be nonessential at temperatures below 37 degrees C. We present evidence that sigmaE is an essential sigma factor at all temperatures. Cells lacking sigmaE are able to grow at low temperatures because of the presence of a frequently arising, unlinked suppressor mutation.     

Identification of UvrY as the cognate response regulator for the BarA sensor kinase in Escherichia coli

BarA is a membrane-associated protein that belongs to a subclass of tripartite sensors of the two-component signal transduction system family. In this study, we report that UvrY is the cognate response regulator for BarA of Escherichia coli. This conclusion is based upon homologies with analogous two-component systems and demonstrated by both biochemical and genetic means. We show that the purified BarA protein is able to autophosphorylate when incubated with [gamma-(32)P]ATP but not with [alpha-(32)P]ATP or [gamma-(32)P]GTP. Phosphorylated BarA, in turn, acts as an efficient phosphoryl group donor to UvrY but not to the non-cognate response regulators ArcA, PhoB, or CpxR. The specificity of the transphosphorylation reaction is further supported by the fact that UvrY can receive the phosphoryl group from BarA-P but not from the non-cognate tripartite sensor ArcB-P or ATP. In addition, genetic evidence that BarA and UvrY mediate the same signal transduction pathway is provided by the finding that both uvrY and barA mutant strains exhibit the same hydrogen peroxide hypersensitive phenotype. These results provide the first biochemical evidence as well as genetic support for a link between BarA and UvrY, suggesting that the two proteins constitute a new two-component system for gene regulation in Escherichia coli.     

Controlled induction of the RpoS regulon in Escherichia coli, using an RpoS-expressing plasmid

RpoS, an alternative sigma factor produced by many gram-negative bacteria, primarily controls genes that are expressed in stationary phase in response to nutrient deprivation. To test the idea that induction of RpoS in the exponential phase, when RpoS is not normally expressed, increases RpoS-dependent gene expression, we constructed a plasmid carrying the rpoS gene under the control of an IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible T7lac promoter. Northern and Western analyses revealed that levels of RpoS mRNA and protein, respectively, increased in response to the inducer IPTG. Assays of changes in RpoS-dependent functions (catalase activity and glycogen accumulation), confirmed that induced RpoS was functional in exponential phase and was sufficient for the expression of RpoS-dependent functions. Controlled expression of RpoS and RpoS-dependent genes by plasmid-encoded rpoS may thus offer a useful tool for the study of RpoS-dependent gene expression.     

The flgE gene of Campylobacter coli is under the control of the alternative sigma factor sigma54.

The flgE gene encoding the flagellar hook protein of Campylobacter coli VC167-T1 was cloned by immunoscreening of a genomic library constructed in lambdaZAP Express. The flgE DNA sequence was 2,553 bp in length and encoded a protein with a deduced molecular mass of 90,639 Da. The sequence had significant homology to the 5' and 3' sequences of the flgE genes of Helicobacter pylori, Treponema phagedenis, and Salmonella typhimurium. Primer extension analysis indicated that the VC167 flgE gene is controlled by a sigma54 promoter. PCR analysis showed that the flgE gene size and the 5' and 3' DNA sequences were conserved among C. coli and C. jejuni strains. Southern hybridization analyses confirmed that there is considerable sequence identity among the hook genes of C. coli and C. jejuni but that there are also regions within the genes which differ. Mutants of C. coli defective in hook production were generated by allele replacement. These mutants were nonmotile and lacked flagellar filaments. Analyses of flgE mutants indicated that the carboxy terminus of FlgE is necessary for assembly of the hook structure but not for secretion of FlgE and that, unlike salmonellae, the lack of flgE expression does not result in repression of flagellin expression.     

The response regulator expM is essential for the virulence of Erwinia carotovora subsp. carotovora and acts negatively on the sigma factor RpoS (sigma s).

The main virulence factors of Erwinia carotovora subsp. carotovora, the secreted, extracellular cell-wall-degrading enzymes, are controlled by several regulatory mechanisms. We have isolated transposon mutants with reduced virulence on tobacco. One of these mutants, with a mutation in a gene designated expM, was characterized in this study. This mutant produces slightly reduced amounts of extracellular enzymes in vitro and the secretion of the enzymes is also affected. The expM wild-type allele was cloned together with an upstream gene, designated expL, that has an unknown function. The expM gene was sequenced and found to encode a protein with similarity to the RssB/SprE protein of Escherichia coli and the MviA protein of Salmonella typhimurium. These proteins belong to a new type of two-component response regulators that negatively regulate the stability of the Sigma factor RpoS (sigma s) at the protein level. The results of this study suggest that ExpM has a similar function in E. carotovora subsp. carotovora. We also provide evidence that the overproduction of RpoS in the expM mutant is an important factor for the reduced virulence phenotype and that it partly causes the observed phenotype seen in vitro. However, an expM/rpoS double mutant is still affected in secretion of extracellular enzymes, suggesting that ExpM in addition to RpoS also acts on other targets.     

The Mycobacterium tuberculosis mysB gene product is a functional equivalent of the Escherichia coli sigma factor, KatF

Mycobacterium tuberculosis, the causative agent of tuberculosis, may remain dormant within its host for many years. The nature of this dormant or latent state is not known, but it may be a specialized form of the stationary growth phase. In Escherichia coli, KatF (or RpoS) is the major stationary phase sigma factor regulating an array of genes expressed in this phase of growth. A potential M. tuberculosis katF homologue was cloned using a fragment of the E. coli katF gene as a probe. DNA sequence analysis of a resultant clone showed 100% identity to a fragment of DNA encoding the M. tuberculosis mysA and mysB genes. Overexpression of mysB in M. bovis BCG resulted in an increase in katG mRNA and catalase and peroxidase activity, and an increase in sensitivity of the cells to isoniazid. An increase in katG promoter activity from a reporter vector was demonstrated when mysB was overexpressed from the same plasmid, indicating a direct relationship between MysB and katG expression.     

Regulation of the alternative sigma factor sigma(E) during initiation,adaptation, and shutoff of the extracytoplasmic heat shock response in Escherichia coli

The alternative sigma factor sigma(E) is activated in response to stress in the extracytoplasmic compartment of Escherichia coli. Here we show that sigma(E) activity increases upon initiation of the stress response by a shift to an elevated temperature (43 degrees C) and remains at that level for the duration of the stress. When the stress is removed by a temperature downshift, sigma(E) activity is strongly repressed and then slowly returns to levels seen in unstressed cells. We provide evidence that information about the state of the cell envelope is communicated to sigma(E) primarily through the regulated proteolysis of the inner membrane anti-sigma factor RseA, as the degradation rate of RseA is correlated with the changes in sigma(E) activity throughout the stress response. However, the relationship between sigma(E) activity and the rate of degradation of RseA is complex, indicating that other factors may cooperate with RseA and serve to fine-tune the response.     

RcsB and RcsC: a two-component regulator of capsule synthesis in Escherichia coli.

Colanic acid capsule synthesis in Escherichia coli K-12 is regulated by RcsB and RcsC. The amino acid sequences of these two proteins, deduced from the nucleotide sequence reported here, demonstrate their homology to environmentally responsive two-component regulators that have been reported in both gram-positive and gram-negative bacteria. In our model, RcsC acts as the sensor and RcsB acts as the receiver or effector to stimulate capsule synthesis from cps genes. In addition, RcsC shows limited homology to the other effectors in its C terminus. Fusions of rcsC to phoA that resulted in PhoA+ strains demonstrated that RcsC is a transmembrane protein with a periplasmic N-terminal domain and cytoplasmic C-terminal domain. Additional control of this regulatory network is provided by the dependence on the alternate sigma factor, RpoN, for the synthesis of RcsB. The rcsB and rcsC genes, which are oriented convergently with their stop codons 196 base pairs apart, are separated by a long direct repeat including two repetitive extragenic palindromic sequences.