Influence of the Alternative Sigma Factor RpoN on Global Gene Expression and Carbon Catabolism in Enterococcus faecalis V583.

The alternative sigma factor σ54 has been shown to regulate the expression of a wide array of virulence-associated genes, as well as central metabolism, in bacterial pathogens. In Gram-positive organisms, the σ54 is commonly associated with carbon metabolism. In this study, we show that the Enterococcus faecalis alternative sigma factor σ54 (RpoN) and its cognate enhancer binding protein MptR are essential for mannose utilization and are primary contributors to glucose uptake through the Mpt phosphotransferase system. To gain further insight into how RpoN contributes to global transcriptional changes, we performed microarray transcriptional analysis of strain V583 and an isogenic rpoN mutant grown in a chemically defined medium with glucose as the sole carbon source. Transcripts of 340 genes were differentially affected in the rpoN mutant; the predicted functions of these genes mainly related to nutrient acquisition. These differentially expressed genes included those with predicted catabolite-responsive element (cre) sites, consistent with loss of repression by the major carbon catabolite repressor CcpA. To determine if the inability to efficiently metabolize glucose/mannose affected infection outcome, we utilized two distinct infection models. We found that the rpoN mutant is significantly attenuated in both rabbit endocarditis and murine catheter-associated urinary tract infection (CAUTI). Here, we examined a ccpA mutant in the CAUTI model and showed that the absence of carbon catabolite control also significantly attenuates bacterial tissue burden in this model. Our data highlight the contribution of central carbon metabolism to growth of E. faecalis at various sites of infection.IMPORTANCE Hospital-acquired infections account for 2 billion dollars annually in increased health care expenses and cause more than 100,000 deaths in the United States alone. Enterococci are the second leading cause of hospital-acquired infections. They form biofilms at surgical sites and are often associated with infections of the urinary tract following catheterization. Nutrient uptake and growth are key factors that influence their ability to cause disease. Our research identified a large set of genes that illuminate nutrient uptake pathways in enterococci. Perturbation of the metabolic circuit reduces virulence in a rabbit endocarditis model, as well as in catheter-associated urinary tract infection in mice. Targeting metabolic pathways that are important in infection may lead to new treatments against multidrug-resistant enterococcal infections.

Extracytoplasmic Function σ Factors as Tools for Coordinating Stress Responses.

The ability of bacterial core RNA polymerase (RNAP) to interact with different σ factors, thereby forming a variety of holoenzymes with different specificities, represents a powerful tool to coordinately reprogram gene expression. Extracytoplasmic function σ factors (ECFs), which are the largest and most diverse family of alternative σ factors, frequently participate in stress responses. The classification of ECFs in 157 different groups according to their phylogenetic relationships and genomic context has revealed their diversity. Here, we have clustered 55 ECF groups with experimentally studied representatives into two broad classes of stress responses. The remaining 102 groups still lack any mechanistic or functional insight, representing a myriad of systems yet to explore. In this work, we review the main features of ECFs and discuss the different mechanisms controlling their production and activity, and how they lead to a functional stress response. Finally, we focus in more detail on two well-characterized ECFs, for which the mechanisms to detect and respond to stress are complex and completely different: Escherichia coli RpoE, which is the best characterized ECF and whose structural and functional studies have provided key insights into the transcription initiation by ECF-RNAP holoenzymes, and the ECF15-type EcfG, the master regulator of the general stress response in Alphaproteobacteria.

Expansion and re-classification of the extracytoplasmic function (ECF) σ factor family.

Extracytoplasmic function σ factors (ECFs) represent one of the major bacterial signal transduction mechanisms in terms of abundance, diversity and importance, particularly in mediating stress responses. Here, we performed a comprehensive phylogenetic analysis of this protein family by scrutinizing all proteins in the NCBI database. As a result, we identified an average of ∼10 ECFs per bacterial genome and 157 phylogenetic ECF groups that feature a conserved genetic neighborhood and a similar regulation mechanism. Our analysis expands previous classification efforts ∼50-fold, enriches many original ECF groups with previously unclassified proteins and identifies 22 entirely new ECF groups. The ECF groups are hierarchically related to each other and are further composed of subgroups with closely related sequences. This two-tiered classification allows for the accurate prediction of common promoter motifs and the inference of putative regulatory mechanisms across subgroups composing an ECF group. This comprehensive, high-resolution description of the phylogenetic distribution of the ECF family, together with the massive expansion of classified ECF sequences and an openly accessible data repository called 'ECF Hub' (https://www.computational.bio.uni-giessen.de/ecfhub), will serve as a powerful hypothesis-generator to guide future research in the field.

Characterization of four nuclear-encoded plastid RNA polymerase sigma factor genes in the liverwort Marchantia polymorpha: blue-light- and multiple stress-responsive SIG5 was acquired early in the emergence of terrestrial plants.

The plastids of plant cells each contain their own genome, and a bacterial-type RNA polymerase called plastid-encoded plastid RNA polymerase (PEP) is involved in transcription of this genome. While the catalytic core subunits are encoded by the plastid genome, the specificity subunit of PEP, sigma, is generally encoded by the nuclear genome and imported into plastids from the cytoplasm after translation. In this study, we identified and analyzed four sigma factor genes from the nuclear genome of a liverwort, Marchantia polymorpha. Phylogenetic analysis suggested that three of the four genes were orthologous to vascular plant genes and thus they were named MpSIG1, MpSIG2 and MpSIG5. The remaining gene was named MpSIGX. The gene products were predicted to localize to the plastid, and this prediction was experimentally demonstrated by expressing yellow fluorescent protein fusion genes in vivo. As with SIG5 genes of other plant species, expression of MpSIG5 was induced by blue-light irradiation and also under various stress conditions, indicating that the regulatory mechanism responsible is conserved among divergent plant species. However, while the major role of SIG5 in vascular plants is to repair the damaged PSII reaction center through psbD gene transcription, the relevant blue-light-responsive promoter (psbD-BLRP) was not found in M. polymorpha and psbD transcript accumulation did not occur in conjunction with MpSIG5 induction. Thus, the physiological role of SIG5 is probably divergent among plant phyla.

A mutation of the RNA polymerase ß' subunit (rpoC) confers cephalosporin resistance in Bacillus subtilis.

In bacteria, mutations affecting the major catalytic subunits of RNA polymerase (encoded by rpoB and rpoC) emerge in response to a variety of selective pressures. Here we isolated a Bacillus subtilis strain with high-level resistance to cefuroxime (CEF). Whole-genome resequencing revealed only one missense mutation affecting an invariant residue in close proximity to the C-terminal DNA-binding domain of RpoC (G1122D). Genetic reconstruction experiments demonstrate that this substitution is sufficient to confer CEF resistance. The G1122D mutation leads to elevated expression of stress-responsive regulons, including those of extracytoplasmic function (ECF) σ factors (σ(M), σ(W), and σ(X)) and the general stress σ factor (σ(B)). The increased CEF resistance of the rpoC(G1122D) strain is lost in the sigM rpoC(G1122D) double mutant, consistent with a major role for σ(M) in CEF resistance. However, a sigM mutant is very sensitive to CEF, and this sensitivity is still reduced by the G1122D mutation, suggesting that other regulatory effects are also important. Indeed, the ability of the G1122D mutation to increase CEF resistance is further reduced in a triple mutant strain lacking three ECF σ factors (σ(M), σ(W), and σ(X)), which are known from prior studies to control overlapping sets of genes. Collectively, our findings highlight the ability of mutations in RNA polymerase to confer antibiotic resistance by affecting the activity of alternative σ factors that control cell envelope stress-responsive regulons.

Evolutionary analysis of prokaryotic heat-shock transcription regulatory protein σ³².

Heat-stress to any living cell is known to trigger a universal defense response, called heat-shock response, with rapid induction of tens of different heat-shock proteins. Bacterial heat-shock genes are transcribed by the σ(32)-bound RNA polymerase instead of the normal σ(70)-bound RNA polymerase. In this study, the diversity in sequence, variation in secondary structure and function amongst the different functional regions of the proteobacterial σ(32) family of proteins, and their phylogenetic relationships have been analyzed. Bacterial σ(32) proteins can be subdivided into different functional regions which are referred to as regions 2, 3, and 4. There is a great deal of sequence conservation among the functional regions of proteobacterial σ(32) family of proteins though some mutations are also present in these regions. Region 2 is the most conserved one, while region 4 has comparatively more variable sequences. In the present work, we tried to explore the effects of mutations in these regions. Our study suggests that the sequence diversities due to natural mutations in the different regions of proteobacterial σ(32) family lead to different functions. So far, this study is the first bioinformatic approach towards the understanding of the mechanistic details of σ(32) family of proteins using the protein sequence information only. This study therefore may help in elucidating the hitherto unknown molecular mechanism of the functionalities of σ(32)family of proteins.

Genome diversity of the TetR family of transcriptional regulators in a metal-reducing bacterial family Geobacteraceae and other microbial species.

Members of the TetR family of bacterial transcriptional regulators affect expression of genes whose products are involved in a variety of important functions, including osmotic stress, catabolic pathways, homeostasis, biosynthesis of antibiotics, expression of efflux pumps, multidrug resistance, and virulence of pathogenic bacteria. We used genome sequence information to carry out phylogenetic classification of 864 TetR family members with a special focus on TetR regulators in Geobacteraceae, an environmentally important family of delta-Proteobacteria. The genome of Geobacter sulfurreducens, a model representative of Geobacteraceae, contains nine genes from the tetR family. Several of these genes are located immediately upstream of operons encoding functionally important c-type cytochromes. Computational analyses identified the presence of conserved promoters and other regulatory binding sites upstream of several G. sulfurreducens tetR genes. This suggests the possibility of an intermediary role of TetR family proteins in Geobacteraceae in regulatory cascades involving a variety of sigma factors. In order to understand the role of the TetR regulatory family in Geobacteraceae, we have inferred phylogenetic relationships among the Geobacteraceae TetR proteins and their homologs in other microbial species.

Evolution of the RpoS regulon: origin of RpoS and the conservation of RpoS-dependent regulation in bacteria.

The RpoS sigma factor in proteobacteria regulates genes in stationary phase and in response to stress. Although of conserved function, the RpoS regulon may have different gene composition across species due to high genomic diversity and to known environmental conditions that select for RpoS mutants. In this study, the distribution of RpoS homologs in prokaryotes and the differential dependence of regulon members on RpoS for expression in two gamma-proteobacteria (Escherichia coli and Pseudomonas aeruginosa) were examined. Using a maximum-likelihood phylogeny and reciprocal best hits analysis, we show that the RpoS sigma factor is conserved within gamma-, beta-, and delta-proteobacteria. Annotated RpoS of Borrelia and the enteric RpoS are postulated to have separate evolutionary origins. To determine the conservation of RpoS-dependent gene expression across species, reciprocal best hits analysis was used to identify orthologs of the E. coli RpoS regulon in the RpoS regulon of P. aeruginosa. Of the 186 RpoS-dependent genes of E. coli, 50 proteins have an ortholog within the P. aeruginosa genome. Twelve genes of the 50 orthologs are RpoS-dependent in both species, and at least four genes are regulated by RpoS in other gamma-proteobacteria. Despite RpoS conservation in gamma-, beta-, and delta-proteobacteria, RpoS regulon composition is subject to modification between species. Environmental selection for RpoS mutants likely contributes to the evolutionary divergence and specialization of the RpoS regulon within different bacterial genomes.

The third pillar of bacterial signal transduction: classification of the extracytoplasmic function (ECF) sigma factor protein family.

The ability of a bacterial cell to monitor and adaptively respond to its environment is crucial for survival. After one- and two-component systems, extracytoplasmic function (ECF) sigma factors - the largest group of alternative sigma factors - represent the third fundamental mechanism of bacterial signal transduction, with about six such regulators on average per bacterial genome. Together with their cognate anti-sigma factors, they represent a highly modular design that primarily facilitates transmembrane signal transduction. A comprehensive analysis of the ECF sigma factor protein family identified more than 40 distinct major groups of ECF sigma factors. The functional relevance of this classification is supported by the sequence similarity and domain architecture of cognate anti-sigma factors, genomic context conservation, and potential target promoter motifs. Moreover, this phylogenetic analysis revealed unique features indicating novel mechanisms of ECF-mediated signal transduction. This classification, together with the web tool ECFfinder and the information stored in the Microbial Signal Transduction (MiST) database, provides a comprehensive resource for the analysis of ECF sigma factor-dependent gene regulation.

Stringent promoter recognition and autoregulation by the group 3 sigma-factor SigF in the cyanobacterium Synechocystis sp. strain PCC 6803.

The cyanobacteirum Synechocystis sp. strain PCC 6803 possesses nine species of the sigma (sigma)-factor gene for RNA polymerase (RNAP). Here, we identify and characterize the novel-type promoter recognized by a group 3 sigma-factor, SigF. SigF autoregulates its own transcription and recognizes the promoter of pilA1 that acts in pilus formation and motility in PCC 6803. The pilA1 promoter (PpilA1-54) was recognized only by SigF and not by other sigma-factors in PCC 6803. No PpilA1-54 activity was observed in Escherichia coli cells that possess RpoF (sigma(28)) for fragellin and motility. Studies of in vitro transcription for PpilA1-54 identified the region from -39 to -7 including an AG-rich stretch and a core promoter with TAGGC (-32 region) and GGTAA (-12 region) as important for transcription. We also confirmed the unique PpilA1-54 architecture and further identified two novel promoters, recognized by SigF, for genes encoding periplasmic and phytochrome-like phototaxis proteins. These results and a phylogenetic analysis suggest that the PCC 6803 SigF is distinct from the E. coli RpoF or RpoD (sigma(70)) type and constitutes a novel eubacterial group 3 sigma-factor. We discuss a model case of stringent promoter recognition by SigF. Promoter types of PCC 6803 genes are also summarized.

Group 2 sigma factors in cyanobacteria.

Group 1 and group 2 sigma factors are sigma factors of bacterial RNA polymerase responsible for transcription from consensus-type promoters. Thus, these sigma factors form the framework for basic transcriptional regulation in bacteria. Cyanobacteria are known to have various group 2 sigma factors, typically more than 4, but only recently the particular function of each sigma factor is being elucidated. In response to environmental signals such as nutrients, light and temperature, cyanobacteria change their transcriptional profile first by activating specific transcription factors and subsequently by modifying the basic transcriptional machinery, which is often involved in the regulation of group 2 sigma factors. In this article, we give an overview of the composition and evolution of group 2 sigma factors in cyanobacteria and summarize what was presently revealed regarding their function.

The sigma factors of Mycobacterium tuberculosis.

Mycobacterium tuberculosis is a remarkable pathogen capable of adapting and surviving in various harsh conditions. Correct gene expression regulation is essential for the success of this process. The reversible association of different sigma factors is a common mechanism for reprogramming bacterial RNA polymerase and modulating the transcription of numerous genes. Thirteen putative sigma factors are encoded in the M. tuberculosis genome, several being important for virulence. Here, we analyse the latest information available on mycobacterial sigma factors and discuss their roles in the physiology and virulence of M. tuberculosis.

An unusual primary sigma factor in the Bacteroidetes phylum.

The presence of housekeeping gene promoters with a unique consensus sequence in Bacteroides fragilis, previously described by Bayley et al. (2000, FEMS Microbiol Lett 193: 149-154), suggested the existence of a particular primary sigma factor. The single rpoD-like gene observed in the B. fragilis genome, and similarly in those of other members of the Bacteroidetes phylum, was found to be essential. It encodes a protein, sigma(ABfr), of only 32.7 kDa that is produced with equal abundance during all phases of growth and was concluded to be the primary sigma factor. sigma(ABfr) and its orthologues in the Bacteroidetes are unusual primary sigma factors in that they lack region 1.1, have a unique signature made up of 29 strictly identical amino acids and are the only RpoD factors that cluster with the RpoS factors. Although binding to the Escherichia coli core RNA polymerase, sigma(ABfr) does not support transcription initiation from any promoter when it is part of the heterologous holoenzyme, while in the reconstituted homologous holoenzyme it does so only from typical B. fragilis, including rrs, promoters but not from the lacUV5 or RNA I promoters.

Regulation of the FecI-type ECF sigma factor by transmembrane signalling.

Induction of the ferric citrate transport genes of Escherichia coli K-12 involves a signalling cascade that starts at the cell surface and proceeds to the cytoplasm. Three specific proteins are involved: FecA in the outer membrane, FecR in the cytoplasmic membrane, and FecI in the cytoplasm. The binding of dinuclear ferric citrate to FecA causes substantial structural changes in FecA, triggering the signal cascade. The amino-proximal end of FecA interacts with the carboxy-proximal end of FecR in the periplasm. FecR then transmits the signal across the cytoplasmic membrane into the cytoplasm and activates the FecI sigma factor, which binds to the RNA polymerase core enzyme and directs the RNA polymerase to the promoter upstream of the fecABCDE transport genes to initiate transcription. Transcription of the fecIR regulatory genes and the fec transport genes is repressed by the Fur protein loaded with Fe(2+). Therefore, transcription of the fec transport genes is subjected to double control: cells first detect iron deficiency and respond by synthesis of the regulatory proteins FecI and FecR, which initiate transcription of the fec transport genes, provided ferric citrate is available. FecI belongs to the extracytoplasmic function sigma factors, which are widespread among bacteria. With the recent sequencing of complete microbial genomes, it has become apparent that the FecIRA cascade is now a paradigm for the regulatory control of FecI family sigmas in Gram-negative bacteria.

An inventory of genes encoding RNA polymerase sigma factors in 31 completely sequenced eubacterial genomes.

Sigma factors are important elements involved in transcriptional regulation of gene expression by conferring promoter specificity to RNA polymerase. The number of sigma factor encoding genes in 31 completely sequenced bacterial genomes were compared. Two unrelated families of sigma factors, the sigma70- and the sigma54-family were identified previously. The sigma70-family can be further subdivided into two distantly related groups: the sigma70 subfamily and the poorly characterized ECF subfamily. A total of 215 sigma factors could be attributed to these subfamilies. The construction of phylogenetic trees allows subclassifications of sigma factor encoding genes within the subfamilies. With the exception of Deinococcus radiodurans, all species possess a housekeeping primary sigma factor. Free-living species possess a higher number of both sigma70-type and ECF alternative sigma factors than pathogens or symbionts associated with animals. Different bacterial species exhibit large differences in the number of alternative sigma factor encoding genes and consequently huge flexibility in their transcriptional regulatory patterns. Transcriptional regulation in terms of regulons controlled by alternative sigma factors is a late evolving phenomenon. The current nomenclature for sigma factor encoding genes is confusing and should be revised.

Three new nuclear genes, sigD, sigE and sigF, encoding putative plastid RNA polymerase sigma factors in Aarabidopsis thaliana.

Three new nuclear genes (sigD, sigE and sigF) of Arabidopsis thaliana, encoding putative plastid RNA polymerase sigma factors, were identified and analyzed. Phylogenetic analysis revealed that higher plant sigma factors fell into at least four distinct subgroups within a diverse protein family. In addition, Arabidopsis sig genes contained conserved chromosomal intron sites, indicating that these genes arose by DNA duplication events during plant evolution. Transcript analyses revealed two alternatively spliced transcripts generated from the sigD region, one of which is predicted to encode a sigma protein lacking the carboxy-terminal regions 3 and 4. Finally, the amino-terminal sequence of the sigF gene product was shown to function as a plastid-targeting signal using green fluorescent protein fusions.

Functional analysis of PvdS, an iron starvation sigma factor of Pseudomonas aeruginosa.

In Pseudomonas aeruginosa, iron modulates gene expression through a cascade of negative and positive regulatory proteins. The master regulator Fur is involved in iron-dependent repression of several genes. One of these genes, pvdS, was predicted to encode a putative sigma factor responsible for the transcription of a subset of genes of the Fur regulon. PvdS appears to belong to a structurally and functionally distinct subgroup of the extracytoplasmic function family of alternative sigma factors. Members of this subgroup, also including PbrA from Pseudomonas fluorescens, PfrI and PupI from Pseudomonas putida, and FecI from Escherichia coli, are controlled by the Fur repressor, and they activate transcription of genes for the biosynthesis or the uptake of siderophores. Evidence is provided that the PvdS protein of P. aeruginosa is endowed with biochemical properties of eubacterial sigma factors, as it spontaneously forms 1:1 complexes with the core fraction of RNA polymerase (RNAP, alpha(2)betabeta' subunits), thereby promoting in vitro binding of the PvdS-RNAP holoenzyme to the promoter region of the pvdA gene. These functional features of PvdS are consistent with the presence of structural domains predicted to be involved in core RNAP binding, promoter recognition, and open complex formation. The activity of pyoverdin biosynthetic (pvd) promoters was significantly lower in E. coli overexpressing the multicopy pvdS gene than in wild-type P. aeruginosa PAO1 carrying the single gene copy, and pvd::lacZ transcriptional fusions were silent in both pfrI (the pvdS homologue) and pfrA (a positive regulator of pseudobactin biosynthetic genes) mutants of P. putida WCS358, while they are expressed at PAO1 levels in wild-type WCS358. Moreover, the PvdS-RNAP holoenzyme purified from E. coli lacked the ability to generate in vitro transcripts from the pvdA promoter. These observations suggest that at least one additional positive regulator could be required for full activity of the PvdS-dependent transcription complex both in vivo and in vitro. This is consistent with the presence of a putative activator binding site (the iron starvation box) at variable distance from the transcription initiation sites of promoters controlled by the iron starvation sigma factors PvdS, PfrI, and PbrA of fluorescent pseudomonads.

Eubacterial sigma-factors.

The initiation of transcription is the most important step for gene regulation in eubacteria. To initiate transcription, RNA polymerase has to associate with a small protein, known as a sigma-factor. The sigma-factor directs RNA polymerase to a specific class of promoter sequences. Most bacterial species synthesize several different sigma-factors that recognize different consensus sequences. This variety in sigma-factors provides bacteria with the opportunity to maintain basal gene expression as well as for regulation of gene expression in response to altered environmental or developmental signals. This review focuses on the function, regulation and distribution of the 14 different classes of sigma-factors that are presently known.

The extracytoplasmic function sigma factors: role and regulation.

Alternative sigma factors provide a means of regulating gene expression in response to various extracellular changes. One such class of sigma factors appears to control a variety of functions, including expression of heat-shock genes in Escherichia coli, biosynthesis of alginates and carotenoids in Pseudomonas aeruginosa and Myxococcus xanthus, respectively, iron uptake in E. coli and Pseudomonas spp., nickel and cobalt efflux in Alcaligenes europhus, plant pathogenicity in Pseudomonas syringae and synthesis of outer membrane proteins in Photobacterium sp. strain SS9. Most of these activities deal with extracytoplasmic functions, and such sigmas have been designated as ECF sigma factors. They have also been characterized in Mycobacteria as well as gram-positive bacteria such as Streptomyces coelicolor and Bacillus subtilus and the archaea Sulpholobus acidocaldarius. ECF factors belong to a subfamily of the sigma 70 class, based on their sequence conservation and function across bacterial species. The promoter consensus sequences recognized by the ECF factors are also highly conserved. In most of the cases, the activity of these factors is modulated by a cognate inner membrane protein that has been shown, both in E. coli and in P. aeruginosa, to act as an anti-sigma activity. This inner membrane protein is presumed to serve as a sensor and signalling molecule, allowing an adaptive response to specific environmental change. Presumably, an on-and-off switch of the anti-sigma activity leads to the release of the sigma factor and thereby to the co-ordinate transcription of the specific regulon it governs.