Alternative sigma factors and the regulation of flagellar gene expression

AbstractMicroorganisms survive stresses by alternating the expression of genes suitable for surviving the immediate and present danger and eventually adapt to new conditions. Many bacteria have evolved a multiprotein "molecular machinery" designated the "Stressosome" that integrates different stress signals and activates alternative sigma factors for appropriate downstream responses. We and others have identified orthologs of some of the Bacillus subtilis stressosome components, RsbR, RsbS, RsbT and RsbUVW in several mycobacteria and we have previously reported mutual interactions among the stressosome components RsbR, RsbS, RsbT and RsbUVW from Mycobacterium marinum. Here we provide evidence that "STAS" domains of both RsbR and RsbS are important for establishing the interaction and thus critical for stressosome assembly. Fluorescence microscopy further suggested co-localization of RsbR and RsbS in multiprotein complexes visible as co-localized fluorescent foci distributed at scattered locations in the M. marinum cytoplasm; the number, intensity and distribution of such foci changed in cells under stressed conditions. Finally, we provide bioinformatics data that 17 (of 244) mycobacteria, which lack the RsbRST genes, carry homologs of Bacillus cereus genes rsbK and rsbM indicating the existence of alternative σF activation pathways among mycobacteria.

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Alternative Sigma Factors in the Free State Are Equilibrium Mixtures of Open and Compact Conformations

Biochemistry ◽

10.1021/bi1011173 ◽

2010 ◽

Vol 49 (45) ◽

pp. 9809-9819 ◽

Cited By ~ 2

Author(s):

Paromita Raha ◽

Suranjana Chattopadhyay ◽

Srijata Mukherjee ◽

Ruchira Chattopadhyay ◽

Koushik Roy ◽

...

Keyword(s):

Sigma Factors ◽

Free State ◽

Alternative Sigma Factors

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More pieces in the promoter jigsaw: recognition of −10 regions by alternative sigma factors

Molecular Microbiology ◽

10.1111/j.1365-2958.2009.06692.x ◽

2009 ◽

Vol 72 (4) ◽

pp. 809-811 ◽

Cited By ~ 2

Author(s):

Stephen J. W. Busby

Keyword(s):

Sigma Factors ◽

Alternative Sigma Factors

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FlhF and Its GTPase Activity Are Required for Distinct Processes in Flagellar Gene Regulation and Biosynthesis in Campylobacter jejuni

Journal of Bacteriology ◽

10.1128/jb.00884-09 ◽

2009 ◽

Vol 191 (21) ◽

pp. 6602-6611 ◽

Cited By ~ 39

Author(s):

Murat Balaban ◽

Stephanie N. Joslin ◽

David R. Hendrixson

Keyword(s):

Gene Expression ◽

Gene Regulation ◽

Campylobacter Jejuni ◽

Regulatory System ◽

Flagellar Gene ◽

Gtpase Activity ◽

Gtp Hydrolysis ◽

Genetic Analyses ◽

Flagellar Biosynthesis ◽

Two Component

ABSTRACT FlhF proteins are putative GTPases that are often necessary for one or more steps in flagellar organelle development in polarly flagellated bacteria. In Campylobacter jejuni, FlhF is required for σ54-dependent flagellar gene expression and flagellar biosynthesis, but how FlhF influences these processes is unknown. Furthermore, the GTPase activity of any FlhF protein and the requirement of this speculated activity for steps in flagellar biosynthesis remain uncharacterized. We show here that C. jejuni FlhF hydrolyzes GTP, indicating that these proteins are GTPases. C. jejuni mutants producing FlhF proteins with reduced GTPase activity were not severely defective for σ54-dependent flagellar gene expression, unlike a mutant lacking FlhF. Instead, these mutants had a propensity to lack flagella or produce flagella in improper numbers or at nonpolar locations, indicating that GTP hydrolysis by FlhF is required for proper flagellar biosynthesis. Additional studies focused on elucidating a possible role for FlhF in σ54-dependent flagellar gene expression were conducted. These studies revealed that FlhF does not influence production of or signaling between the flagellar export apparatus and the FlgSR two-component regulatory system to activate σ54. Instead, our data suggest that FlhF functions in an independent pathway that converges with or works downstream of the flagellar export apparatus-FlgSR pathway to influence σ54-dependent gene expression. This study provides corroborative biochemical and genetic analyses suggesting that different activities of the C. jejuni FlhF GTPase are required for distinct steps in flagellar gene expression and biosynthesis. Our findings are likely applicable to many polarly flagellated bacteria that utilize FlhF in flagellar biosynthesis processes.

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Flagellar Biogenesis of Xanthomonas campestris Requires the Alternative Sigma Factors RpoN2 and FliA and Is Temporally Regulated by FlhA, FlhB, and FlgM

Journal of Bacteriology ◽

10.1128/jb.01152-08 ◽

2009 ◽

Vol 191 (7) ◽

pp. 2266-2275 ◽

Cited By ~ 33

Author(s):

Tsuey-Ching Yang ◽

Yu-Wei Leu ◽

Hui-Chen Chang-Chien ◽

Rouh-Mei Hu

Keyword(s):

Transcriptional Activation ◽

Type Iii Secretion ◽

Xanthomonas Campestris ◽

Sigma Factors ◽

Structural Genes ◽

Protein Levels ◽

Alternative Sigma Factors ◽

Complicated Process ◽

System F ◽

Flagellar Biogenesis

ABSTRACT In prokaryotes, flagellar biogenesis is a complicated process involving over 40 genes. The phytopathogen Xanthomonas campestris pv. campestris possesses a single polar flagellum, which is essential for the swimming motility. A σ54 activator, FleQ, has been shown to be required for the transcriptional activation of the flagellar type III secretion system (F-T3SS), rod, and hook proteins. One of the two rpoN genes, rpoN2, encoding σ54, is essential for flagellation. RpoN2 and FleQ direct the expression of a second alternative sigma FliA (σ28) that is essential for the expression of the flagellin FliC. FlgM interacts with FliA and represses the FliA regulons. An flgM mutant overexpressing FliC generates a deformed flagellum and displays an abnormal motility. Mutation in the two structural genes of F-T3SS, flhA and flhB, suppresses the production of FliC. Furthermore, FliA protein levels are decreased in an flhB mutant. A mutant defective in flhA, but not flhB, exhibits a decreased infection rate. In conclusion, the flagellar biogenesis of Xanthomonas campestris requires alternative sigma factors RpoN2 and FliA and is temporally regulated by FlhA, FlhB, and FlgM.

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Real-time flagellar gene expression

Genome Biology ◽

10.1186/gb-2001-2-8-reports0024 ◽

2001 ◽

Vol 2 (8) ◽

Cited By ~ 1

Author(s):

Rachel Brem

Keyword(s):

Gene Expression ◽

Real Time ◽

Flagellar Gene

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Classic Spotlight: the Heat Shock Response and the Discovery of Alternative Sigma Factors in Escherichia coli

Journal of Bacteriology ◽

10.1128/jb.00576-16 ◽

2016 ◽

Vol 198 (19) ◽

pp. 2550-2550

Author(s):

Richard L. Gourse

Keyword(s):

Escherichia Coli ◽

Heat Shock ◽

Heat Shock Response ◽

Sigma Factors ◽

Alternative Sigma Factors ◽

Shock Response

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Transcriptional Regulation and Mechanism of SigN (ZpdN), a pBS32-Encoded Sigma Factor in Bacillus subtilis

mBio ◽

10.1128/mbio.01899-19 ◽

2019 ◽

Vol 10 (5) ◽

Cited By ~ 4

Author(s):

Aisha T. Burton ◽

Aaron DeLoughery ◽

Gene-Wei Li ◽

Daniel B. Kearns

Keyword(s):

Dna Damage ◽

Bacillus Subtilis ◽

Sigma Factor ◽

Consensus Sequence ◽

Sigma Factors ◽

Sequencing Analysis ◽

Dependent Manner ◽

Content Type ◽

Alternative Sigma Factors ◽

Bona Fide

ABSTRACT Laboratory strains of Bacillus subtilis encode many alternative sigma factors, each dedicated to expressing a unique regulon such as those involved in stress resistance, sporulation, and motility. The ancestral strain of B. subtilis also encodes an additional sigma factor homolog, ZpdN, not found in lab strains due to being encoded on the large, low-copy-number plasmid pBS32, which was lost during domestication. DNA damage triggers pBS32 hyperreplication and cell death in a manner that depends on ZpdN, but how ZpdN mediates these effects is unknown. Here, we show that ZpdN is a bona fide sigma factor that can direct RNA polymerase to transcribe ZpdN-dependent genes, and we rename ZpdN SigN accordingly. Rend-seq (end-enriched transcriptome sequencing) analysis was used to determine the SigN regulon on pBS32, and the 5′ ends of transcripts were used to predict the SigN consensus sequence. Finally, we characterize the regulation of SigN itself and show that it is transcribed by at least three promoters: PsigN1, a strong SigA-dependent LexA-repressed promoter; PsigN2, a weak SigA-dependent constitutive promoter; and PsigN3, a SigN-dependent promoter. Thus, in response to DNA damage SigN is derepressed and then experiences positive feedback. How cells die in a pBS32-dependent manner remains unknown, but we predict that death is the product of expressing one or more genes in the SigN regulon. IMPORTANCE Sigma factors are utilized by bacteria to control and regulate gene expression. Some sigma factors are activated during times of stress to ensure the survival of the bacterium. Here, we report the presence of a sigma factor that is encoded on a plasmid that leads to cellular death after DNA damage.

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ScrG, a GGDEF-EAL Protein, Participates in Regulating Swarming and Sticking in Vibrio parahaemolyticus

Journal of Bacteriology ◽

10.1128/jb.01510-06 ◽

2007 ◽

Vol 189 (11) ◽

pp. 4094-4107 ◽

Cited By ~ 41

Author(s):

Yun-Kyeong Kim ◽

Linda L. McCarter

Keyword(s):

Gene Expression ◽

Biofilm Formation ◽

Vibrio Parahaemolyticus ◽

Capsular Polysaccharide ◽

Colony Morphology ◽

Flagellar Gene ◽

Surface Mobility ◽

New Gene ◽

Synthesis And Degradation

ABSTRACT In this work, we describe a new gene controlling lateral flagellar gene expression. The gene encodes ScrG, a protein containing GGDEF and EAL domains. This is the second GGDEF-EAL-encoding locus determined to be involved in the regulation of swarming: the first was previously characterized and named scrABC (for “swarming and capsular polysaccharide regulation”). GGDEF and EAL domain-containing proteins participate in the synthesis and degradation of the nucleotide signal cyclic di-GMP (c-di-GMP) in many bacteria. Overexpression of scrG was sufficient to induce lateral flagellar gene expression in liquid, decrease biofilm formation, decrease cps gene expression, and suppress the ΔscrABC phenotype. Removal of its EAL domain reversed ScrG activity, converting ScrG to an inhibitor of swarming and activator of cps expression. Overexpression of scrG decreased the intensity of a 32P-labeled nucleotide spot comigrating with c-di-GMP standard, whereas overexpression of scrG Δ EAL enhanced the intensity of the spot. Mutants with defects in scrG showed altered swarming and lateral flagellin production and colony morphology (but not swimming motility); furthermore, mutation of two GGDEF-EAL-encoding loci (scrG and scrABC) produced cumulative effects on swarming, lateral flagellar gene expression, lateral flagellin production and colony morphology. Mutant analysis supports the assignment of the primary in vivo activity of ScrG to acting as a phosphodiesterase. The data are consistent with a model in which multiple GGDEF-EAL proteins can influence the cellular nucleotide pool: a low concentration of c-di-GMP favors surface mobility, whereas high levels of this nucleotide promote a more adhesive Vibrio parahaemolyticus cell type.

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