Substitutions in the Escherichia coli RNA polymerase sigma70 factor that affect recognition of extended -10 elements at promoters

Towards a rational approach to promoter engineering: understanding the complexity of transcription initiation in prokaryotes

Promoter sequences are important genetic control elements. Through their interaction with RNA polymerase they determine transcription strength and specificity, thereby regulating the first step in gene expression. Consequently, they can be targeted as elements to control predictability and tuneability of a genetic circuit, which is essential in applications such as the development of robust microbial cell factories. This review considers the promoter elements implicated in the three stages of transcription initiation, detailing the complex interplay of sequence-specific interactions that are involved, and highlighting that DNA sequence features beyond the core promoter elements work in a combinatorial manner to determine transcriptional strength. In particular, we emphasize that, aside from promoter recognition, transcription initiation is also defined by the kinetics of open complex formation and promoter escape, which are also known to be highly sequence specific. Significantly, we focus on how insights into these interactions can be manipulated to lay the foundation for a more rational approach to promoter engineering.

A Tripartite, Hierarchical Sigma Factor Cascade Promotes Hormogonium Development in the Filamentous Cyanobacterium Nostoc punctiforme

Cyanobacteria are prokaryotes capable of oxygenic photosynthesis, and frequently, nitrogen fixation as well. As a result, they contribute substantially to global primary production and nitrogen cycles. Furthermore, the multicellular filamentous cyanobacteria in taxonomic subsections IV and V are developmentally complex, exhibiting an array of differentiated cell types and filaments, including motile hormogonia, making them valuable model organisms for studying development. To investigate the role of sigma factors in the gene regulatory network (GRN) controlling hormogonium development, a combination of genetic, immunological, and time-resolved transcriptomic analyses were conducted in the model filamentous cyanobacterium Nostoc punctiforme, which, unlike other common model cyanobacteria, retains the developmental complexity of field isolates. The results support a model where the hormogonium GRN is driven by a hierarchal sigma factor cascade, with sigJ activating the expression of both sigC and sigF, as well as a substantial portion of additional hormogonium-specific genes, including those driving changes to cellular architecture. In turn, sigC regulates smaller subsets of genes for several processes, plays a dominant role in promoting reductive cell division, and may also both positively and negatively regulate sigJ to reinforce the developmental program and coordinate the timing of gene expression, respectively. In contrast, the sigF regulon is extremely limited. Among genes with characterized roles in hormogonium development, only pilA shows stringent sigF dependence. For sigJ-dependent genes, a putative consensus promoter was also identified, consisting primarily of a highly conserved extended -10 region, here designated a J-Box, which is widely distributed among diverse members of the cyanobacterial lineage.IMPORTANCE Cyanobacteria are integral to global carbon and nitrogen cycles, and their metabolic capacity coupled with their ease of genetic manipulation make them attractive platforms for applications such as biomaterial and biofertilizer production. Achieving these goals will likely require a detailed understanding and precise rewiring of these organisms' GRNs. The complex phenotypic plasticity of filamentous cyanobacteria has also made them valuable models of prokaryotic development. However, current research has been limited by focusing primarily on a handful of model strains which fail to reflect the phenotypes of field counterparts, potentially limiting biotechnological advances and a more comprehensive understanding of developmental complexity. Here, using Nostoc punctiforme, a model filamentous cyanobacterium that retains the developmental range of wild isolates, we define previously unknown definitive roles for a trio of sigma factors during hormogonium development. These findings substantially advance our understanding of cyanobacterial development and gene regulation and could be leveraged for future applications.

Enhanced basepair dynamics pre-disposes protein-assisted flips of key bases in DNA strand separation during transcription initiation

Localized separation of strands of duplex DNA is a necessary step in many DNA-dependent processes, including transcription and replication.

Transcription Initiation by Mix and Match Elements: Flexibility for Polymerase Binding to Bacterial Promoters

Bacterial RNA polymerase is composed of a core of subunits (β β′, α1, α2, ω), which have RNA synthesizing activity, and a specificity factor (σ), which identifies the start of transcription by recognizing and binding to sequence elements within promoter DNA. Four core promoter consensus sequences, the –10 element, the extended –10 (TGn) element, the –35 element, and the UP elements, have been known for many years; the importance of a nontemplate G at position -5 has been recognized more recently. However, the functions of these elements are not the same. The AT-rich UP elements, the –35 elements (–35TTGACA–30), and the extended –10 (15TGn–13) are recognized as double-stranded binding elements, whereas the –5 nontemplate G is recognized in the context of single-stranded DNA at the transcription bubble. Furthermore, the –10 element (–12TATAAT–7) is recognized as both double-stranded DNA for the T:A bp at position –12 and as nontemplate, single-stranded DNA from positions –11 to –7. The single-stranded sequences at positions –11 to –7 as well as the –5 contribute to later steps in transcription initiation that involve isomerization of polymerase and separation of the promoter DNA around the transcription start site. Recent work has demonstrated that the double-stranded elements may be used in various combinations to yield an effective promoter. Thus, while some minimal number of contacts is required for promoter function, polymerase allows the elements to be mixed and matched. Interestingly, which particular elements are used does not appear to fundamentally alter the transcription bubble generated in the stable complex. In this review, we discuss the multiple steps involved in forming a transcriptionally competent polymerase/promoter complex, and we examine what is known about polymerase recognition of core promoter elements. We suggest that considering promoter elements according to their involvement in early (polymerase binding) or later (polymerase isomerization) steps in transcription initiation rather than simply from their match to conventional promoter consensus sequences is a more instructive form of promoter classification.

The essential activities of the bacterial sigma factor

Transcription is the first and most heavily regulated step in gene expression. Sigma (σ) factors are general transcription factors that reversibly bind RNA polymerase (RNAP) and mediate transcription of all genes in bacteria. σ Factors play 3 major roles in the RNA synthesis initiation process: they (i) target RNAP holoenzyme to specific promoters, (ii) melt a region of double-stranded promoter DNA and stabilize it as a single-stranded open complex, and (iii) interact with other DNA-binding transcription factors to contribute complexity to gene expression regulation schemes. Recent structural studies have demonstrated that when σ factors bind promoter DNA, they capture 1 or more nucleotides that are flipped out of the helical DNA stack and this stabilizes the promoter open-complex intermediate that is required for the initiation of RNA synthesis. This review describes the structure and function of the σ⁷⁰ family of σ proteins and the essential roles they play in the transcription process.

Sequence determinants spanning -35 motif and AT-rich spacer region impacting Ehrlichia chaffeensis Sigma 70-dependent promoter activity of two differentially expressed p28 outer membrane protein genes

Ehrlichia chaffeensis is an obligate intracellular tick-borne bacterium which causes the disease, human monocytic ehrlichiosis. Ehrlichia chaffeensis contains only two sigma factors, σ32 and σ70. It is difficult to study E. chaffeensis gene regulation due to lack of a transformation system. We developed an Escherichia coli-based transcription system to study E. chaffeensis transcriptional regulation. An E. coli strain with its σ70 repressed with trp promoter is used to express E. chaffeensis σ70. The E. coli system and our previously established in vitro transcription system were used to map transcriptional differences of two Ehrlichia genes encoding p28-outer membrane proteins 14 and 19. We mapped the -10 and -35 motifs and the AT rich spacers located between the two motifs by performing detailed mutational analysis. Mutations within the -35 motif of the genes impacted transcription differently, while -10 motif deletions had no impact. The AT-rich spacers also contributed to transcriptional differences. We further demonstrated that the domain 4.2 of E. chaffeensis σ70 is important for regulating promoter activity and the deletion of region 1.1 of E. chaffeensis σ70 causes enhancement of the promoter activity. This is the first study defining the promoters of two closely related E. chaffeensis genes.

Molecular Mechanisms of Transcription Initiation at gal Promoters and their Multi-Level Regulation by GalR, CRP and DNA Loop

Studying the regulation of transcription of the gal operon that encodes the amphibolic pathway of d-galactose metabolism in Escherichia coli discerned a plethora of principles that operate in prokaryotic gene regulatory processes. In this chapter, we have reviewed some of the more recent findings in gal that continues to reveal unexpected but important mechanistic details. Since the operon is transcribed from two overlapping promoters, P1 and P2, regulated by common regulatory factors, each genetic or biochemical experiment allowed simultaneous discernment of two promoters. Recent studies range from genetic, biochemical through biophysical experiments providing explanations at physiological, mechanistic and single molecule levels. The salient observations highlighted here are: the axiom of determining transcription start points, discovery of a new promoter element different from the known ones that influences promoter strength, occurrence of an intrinsic DNA sequence element that overrides the transcription elongation pause created by a DNA-bound protein roadblock, first observation of a DNA loop and determination its trajectory, and piggybacking proteins and delivering to their DNA target.

Differential role of base pairs on gal promoters strength

Sequence alignments of promoters in prokaryotes postulated that the frequency of occurrence of a base pair at a given position of promoter elements reflects its contribution to intrinsic promoter strength. We directly assessed the contribution of the four base pairs in each position in the intrinsic promoter strength by keeping the context constant in Escherichia coli cAMP-CRP (cAMP receptor protein) regulated gal promoters by in vitro transcription assays. First, we show that base pair frequency within known consensus elements correlates well with promoter strength. Second, we observe some substitutions upstream of the ex-10 TG motif that are important for promoter function. Although the galP1 and P2 promoters overlap, only three positions where substitutions inactivated both promoters were found. We propose that RNA polymerase binds to the -12T base pair as part of double-stranded DNA while opening base pairs from -11A to +3 to form the single-stranded transcription bubble DNA during isomerization. The cAMP-CRP complex rescued some deleterious substitutions in the promoter region. The base pair roles and their flexibilities reported here for E. coli gal promoters may help construction of synthetic promoters in gene circuitry experiments in which overlapping promoters with differential controls may be warranted.

Bacterial sigma factors: a historical, structural, and genomic perspective

Transcription initiation is the crucial focal point of gene expression in prokaryotes. The key players in this process, sigma factors (σs), associate with the catalytic core RNA polymerase to guide it through the essential steps of initiation: promoter recognition and opening, and synthesis of the first few nucleotides of the transcript. Here we recount the key advances in σ biology, from their discovery 45 years ago to the most recent progress in understanding their structure and function at the atomic level. Recent data provide important structural insights into the mechanisms whereby σs initiate promoter opening. We discuss both the housekeeping σs, which govern transcription of the majority of cellular genes, and the alternative σs, which direct RNA polymerase to specialized operons in response to environmental and physiological cues. The review concludes with a genome-scale view of the extracytoplasmic function σs, the most abundant group of alternative σs.

σ(ECF) factors of gram-positive bacteria: a focus on Bacillus subtilis and the CMNR group

The survival of bacteria to different environmental conditions depends on the activation of adaptive mechanisms, which are intricately driven through gene regulation. Because transcriptional initiation is considered to be the major step in the control of bacterial genes, we discuss the characteristics and roles of the sigma factors, addressing (1) their structural, functional and phylogenetic classification; (2) how their activity is regulated; and (3) the promoters recognized by these factors. Finally, we focus on a specific group of alternative sigma factors, the so-called σ(ECF) factors, in Bacillus subtilis and some of the main species that comprise the CMNR group, providing information on the roles they play in the microorganisms' physiology and indicating some of the genes whose transcription they regulate.

The σ70 region 1.2 regulates promoter escape by unwinding DNA downstream of the transcription start site

The mechanisms of abortive synthesis and promoter escape during initiation of transcription are poorly understood. Here, we show that, after initiation of RNA synthesis, non-specific interaction of σ⁷⁰ region 1.2, present in all σ⁷⁰ family factors, with the non-template strand around position −4 relative to the transcription start site facilitates unwinding of the DNA duplex downstream of the transcription start site. This leads to stabilization of short RNA products and allows their extension, i.e. promoter escape. We show that this activity of σ⁷⁰ region 1.2 is assisted by the β-lobe domain, but does not involve the β′-rudder or the β′-switch-2, earlier proposed to participate in promoter escape. DNA sequence independence of this function of σ⁷⁰ region 1.2 suggests that it may be conserved in all σ⁷⁰ family factors. Our results indicate that the abortive nature of initial synthesis is caused, at least in part, by failure to open the downstream DNA by the β-lobe and σ region 1.2.

Redefining Escherichia coli σ(70) promoter elements: -15 motif as a complement of the -10 motif

Classical elements of σ(70) bacterial promoters include the -35 element ((-35)TTGACA(-30)), the -10 element ((-12)TATAAT(-7)), and the extended -10 element ((-15)TG(-14)). Although the -35 element, the extended -10 element, and the upstream-most base in the -10 element ((-12)T) interact with σ(70) in double-stranded DNA (dsDNA) form, the downstream bases in the -10 motif ((-11)ATAAT(-7)) are responsible for σ(70)-single-stranded DNA (ssDNA) interactions. In order to directly reflect this correspondence, an extension of the extended -10 element to a so-called -15 element ((-15)TGnT(-12)) has been recently proposed. I investigated here the sequence specificity of the proposed -15 element and its relationship to other promoter elements. I found a previously undetected significant conservation of (-13)G and a high degeneracy at (-15)T. I therefore defined the -15 element as a degenerate motif, which, together with the conserved stretch of sequence between -15 and -12, allows treating this element analogously to -35 and -10 elements. Furthermore, the strength of the -15 element inversely correlates with the strengths of the -35 element and -10 element, whereas no such complementation between other promoter elements was found. Despite the direct involvement of -15 element in σ(70)-dsDNA interactions, I found a significantly stronger tendency of this element to complement weak -10 elements that are involved in σ(70)-ssDNA interactions. This finding is in contrast to the established view, according to which the -15 element provides a sufficient number of σ(70)-dsDNA interactions, and suggests that the main parameter determining a functional promoter is the overall promoter strength.

Phage-borne factors and host LexA regulate the lytic switch in phage GIL01

The Bacillus thuringiensis temperate phage GIL01 does not integrate into the host chromosome but exists stably as an independent linear replicon within the cell. Similar to that of the lambdoid prophages, the lytic cycle of GIL01 is induced as part of the cellular SOS response to DNA damage. However, no CI-like maintenance repressor has been detected in the phage genome, suggesting that GIL01 uses a novel mechanism to maintain lysogeny. To gain insights into the GIL01 regulatory circuit, we isolated and characterized a set of 17 clear plaque (cp) mutants that are unable to lysogenize. Two phage-encoded proteins, gp1 and gp7, are required for stable lysogen formation. Analysis of cp mutants also identified a 14-bp palindromic dinBox1 sequence within the P1-P2 promoter region that resembles the known LexA-binding site of Gram-positive bacteria. Mutations at conserved positions in dinBox1 result in a cp phenotype. Genomic analysis identified a total of three dinBox sites within GIL01 promoter regions. To investigate the possibility that the host LexA regulates GIL01, phage induction was measured in a host carrying a noncleavable lexA (Ind(-)) mutation. GIL01 formed stable lysogens in this host, but lytic growth could not be induced by treatment with mitomycin C. Also, mitomycin C induced β-galactosidase expression from GIL01-lacZ promoter fusions, and induction was similarly blocked in the lexA (Ind(-)) mutant host. These data support a model in which host LexA binds to dinBox sequences in GIL01, repressing phage gene expression during lysogeny and providing the switch necessary to enter lytic development.

Mechanism of bacterial transcription initiation: RNA polymerase - promoter binding, isomerization to initiation-competent open complexes, and initiation of RNA synthesis

Initiation of RNA synthesis from DNA templates by RNA polymerase (RNAP) is a multi-step process, in which initial recognition of promoter DNA by RNAP triggers a series of conformational changes in both RNAP and promoter DNA. The bacterial RNAP functions as a molecular isomerization machine, using binding free energy to remodel the initial recognition complex, placing downstream duplex DNA in the active site cleft and then separating the nontemplate and template strands in the region surrounding the start site of RNA synthesis. In this initial unstable "open" complex the template strand appears correctly positioned in the active site. Subsequently, the nontemplate strand is repositioned and a clamp is assembled on duplex DNA downstream of the open region to form the highly stable open complex, RP(o). The transcription initiation factor, σ(70), plays critical roles in promoter recognition and RP(o) formation as well as in early steps of RNA synthesis.

DNA bending and looping in the transcriptional control of bacteriophage phi29

Recent studies on the regulation of phage phi29 gene expression reveal new ways to accomplish the processes required for the orderly gene expression in prokaryotic systems. These studies revealed a novel DNA-binding domain in the phage main transcriptional regulator and the nature and dynamics of the multimeric DNA-protein complex responsible for the switch from early to late gene expression. This review describes the features of the regulatory mechanism that leads to the simultaneous activation and repression of transcription, and discusses it in the context of the role of the topological modification of the DNA carried out by two phage-encoded proteins working synergistically with the DNA.

6S RNA binding to Esigma(70) requires a positively charged surface of sigma(70) region 4.2

6S RNA is a small, non-coding RNA that interacts with sigma(70)-RNA polymerase and downregulates transcription at many promoters during stationary phase. When bound to sigma(70)-RNA polymerase, 6S RNA is engaged in the active site of sigma(70)-RNA polymerase in a manner similar enough to promoter DNA that the RNA can serve as a template for RNA synthesis. It has been proposed that 6S RNA mimics the conformation of DNA during transcription initiation, suggesting contacts between RNA polymerase and 6S RNA or DNA may be similar. Here we demonstrate that region 4.2 of sigma(70) is critical for the interaction between 6S RNA and RNA polymerase. We define an expanded binding surface that encompasses positively charged residues throughout the recognition helix of the helix-turn-helix motif in region 4.2, in contrast to DNA binding that is largely focused on the N-terminal region of this helix. Furthermore, negatively charged residues in region 4.2 weaken binding to 6S RNA but do not similarly affect DNA binding. We propose that the binding sites for promoter DNA and 6S RNA on region 4.2 of sigma(70) are overlapping but distinct, raising interesting possibilities for how core promoter elements contribute to defining promoters that are sensitive to 6S RNA regulation.

Construction and functional analyses of a comprehensive sigma54 site-directed mutant library using alanine-cysteine mutagenesis

The sigma(54) factor associates with core RNA polymerase (RNAP) to form a holoenzyme that is unable to initiate transcription unless acted on by an activator protein. sigma(54) is closely involved in many steps of activator-dependent transcription, such as core RNAP binding, promoter recognition, activator interaction and open complex formation. To systematically define sigma(54) residues that contribute to each of these functions and to generate a resource for site specific protein labeling, a complete mutant library of sigma(54) was constructed by alanine-cysteine scanning mutagenesis. Amino acid residues from 3 to 476 of Cys(-)sigma(54) were systematically mutated to alanine and cysteine in groups of two adjacent residues at a time. The influences of each substitution pair upon the functions of sigma(54) were analyzed in vivo and in vitro and the functions of many residues were revealed for the first time. Increased sigma(54) isomerization activity seldom corresponded with an increased transcription activity of the holoenzyme, suggesting the steps after sigma(54) isomerization, likely to be changes in core RNAP structure, are also strictly regulated or rate limiting to open complex formation. A linkage between core RNAP-binding activity and activator responsiveness indicates that the sigma(54)-core RNAP interface changes upon activation.

Mutational analysis of Escherichia coli sigma28 and its target promoters reveals recognition of a composite -10 region, comprised of an 'extended -10' motif and a core -10 element

Sigma28 controls the expression of flagella-related genes and is the most widely distributed alternative sigma factor, present in motile Gram-positive and Gram-negative bacteria. The distinguishing feature of sigma28 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 sigma28 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 sigma28. 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 sigma28 orthologues. Sigma28 is the second Group 3 sigma shown to use an extended -10 region in promoter recognition, raising the possibility that other Group 3 sigmas will do so as well.

Dissection of recognition determinants of Escherichia coli sigma32 suggests a composite -10 region with an 'extended -10' motif and a core -10 element

Sigma32 controls expression of heat shock genes in Escherichia coli and is widely distributed in proteobacteria. The distinguishing feature of sigma32 promoters is a long -10 region (CCCCATNT) whose tetra-C motif is important for promoter activity. Using alanine-scanning mutagenesis of sigma32 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 beta- and gamma-proteobacteria. This residue is located in the alpha-helix of sigmaDomain 3 that mediates recognition of the extended -10 promoter motif in other sigmas. K130 is not conserved in alpha- and delta-/epsilon-proteobacteria and we found that sigma32 from the alpha-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. Sigma32 is the first Group 3 sigma shown to use the 'extended -10' recognition motif.

Identification of a hypervariable region containing new Legionella pneumophila Icm/Dot translocated substrates by using the conserved icmQ regulatory signature

Legionella pneumophila is an intracellular pathogen that has been shown to utilize the Icm/Dot type IV secretion system for pathogenesis. This system was shown to be composed of Icm/Dot complex components, accessory proteins, and a large number of translocated substrates. In this study, comparison of the icmQ regulatory regions from many Legionella species revealed a conserved regulatory sequence that includes the icmQ -10 promoter element. Mutagenesis of this conserved regulatory element indicated that each of the nucleotides in it affects the level of expression of the icmQ gene but not in a uniform fashion. A genomic analysis discovered that four additional genes in L. pneumophila contain this conserved regulatory sequence, which was found to function similarly in these genes as well. Examination of these four genes indicated that they are dispensable for intracellular growth, but two of them were found to encode new Icm/Dot translocated substrates (IDTS). Comparison of the genomic regions encoding these two IDTS among the four available L. pneumophila genomic sequences indicated that one of these genes is located in a hypervariable genomic region, which was shown before to contain an IDTS-encoding gene. Translocation analysis that was performed for nine proteins encoded from this hypervariable genomic region indicated that six of them are new IDTS which are translocated into host cells in an Icm/Dot-dependent manner. Furthermore, a bioinformatic analysis indicated that additional L. pneumophila genomic regions that contain several neighboring IDTS-encoding genes are hypervariable in gene content.

Promoter activation by repositioning of RNA polymerase

Spo0A, a classical two-component-type response regulator in Bacillus subtilis, binds to a specific DNA sequence found in many promoters to repress or activate the transcription of over 100 genes. On the spoIIG promoter, one of the Spo0A binding sites, centered at position -40, overlaps a consensus -35 element that may also interact with region 4 of the sigma A (sigma(A)) subunit of RNA polymerase. Molecular modeling corroborated by genetic evidence led us to propose that the binding of Spo0A to this site repositions sigma(A) region 4 on the promoter. Therefore, we used a chemical nuclease, p-bromoacetamidobenzyl-EDTA-Fe, that was covalently tethered to a single cysteine in region 4 of sigma(A) to map the position of sigma(A) on the promoter. The results indicated that in the absence of Spo0A, sigma(A) region 4 of the RNA polymerase was located near the -35 element sequence centered at position -40. However, in the presence of Spo0A, sigma(A) region 4 was displaced downstream from the -35 element by 4 bp. These and other results support the model in which the binding of Spo0A to the spoIIG promoter stimulates promoter utilization by repositioning prebound RNA polymerase and stabilizing the repositioned RNA polymerase-promoter complex at a new position that aligns sigma(A) region 2 with the -10 region sequences of the promoter, thus facilitating open complex formation.

Isolation and characterization of putative Pseudobutyrivibrio ruminis promoters

Novel plasmids were constructed for the analysis of DNA fragments from the rumen bacterium Pseudobutyrivibrio ruminis. Five previously unidentified promoters were characterized using a novel primer extension method to identify transcription start sites. The genes downstream of these promoters were not identified, and their activity in expression of genomic traits in wild-type P. ruminis remains putative. Comparison with promoters from this and closely related species revealed a consensus sequence resembling the binding motif for the RNA polymerase sigma(70)-like factor complex. Consensus -35 and -10 sequences within these elements were TTGACA and ATAATATA respectively, interspaced by 15-16 bp. The consensus for the -10 element was extended by one nucleotide upstream and downstream of the standard hexamer (indicated in bold). Promoter strengths were measured by reverse transcription quantitative PCR and beta-glucuronidase assays. No correlation was found between the composition and context of elements within P. ruminis promoters, and promoter strength. However, a mutation within the -35 element of one promoter revealed that transcriptional strength and choice of transcription start site were sensitive to this single nucleotide change.

Specific Recognition of the -10 Promoter Element by the Free RNA Polymerase σ Subunit

Bacterial RNA polymerase holoenzyme relies on its sigma subunit for promoter recognition and opening. In the holoenzyme, regions 2 and 4 of the sigma subunit are positioned at an optimal distance to allow specific recognition of the -10 and -35 promoter elements, respectively. In free sigma, the promoter binding regions are positioned closer to each other and are masked for interactions with the promoter, with sigma region 1 playing a role in the masking. To analyze the DNA-binding properties of the free sigma, we selected single-stranded DNA aptamers that are specific to primary sigma subunits from several bacterial species, including Escherichia coli and Thermus aquaticus. The aptamers share a consensus motif, TGTAGAAT, that is similar to the extended -10 promoter. We demonstrate that recognition of this motif by sigma region 2 occurs without major structural rearrangements of sigma observed upon the holoenzyme formation and is not inhibited by sigma regions 1 and 4. Thus, the complex process of the -10 element recognition by RNA polymerase holoenzyme can be reduced to a simple system consisting of an isolated sigma subunit and a short aptamer oligonucleotide.

The -11A of promoter DNA and two conserved amino acids in the melting region of sigma70 both directly affect the rate limiting step in formation of the stable RNA polymerase-promoter complex, but they do not necessarily interact

Formation of the stable, strand separated, 'open' complex between RNA polymerase and a promoter involves DNA melting of approximately 14 base pairs. The likely nucleation site is the highly conserved -11A base in the non-template strand of the -10 promoter region. Amino acid residues Y430 and W433 on the sigma70 subunit of the RNA polymerase participate in the strand separation. The roles of -11A and of the Y430 and W433 were addressed by employing synthetic consensus promoters containing base analog and other substitutions at -11 in the non-template strand, and sigma70 variants bearing amino acid substitutions at positions 430 and 433. Substitutions for -11A and for Y430 and W433 in sigma70 have small or no effects on formation of the initial RNA polymerase-promoter complex, but exert their effects on subsequent steps on the way to formation of the open complex. As substitutions for Y430 and W433 also affect open complex formation on promoter DNA lacking the -11A base, it is concluded that these amino acid residues have other (or additional) roles, not involving the -11A. The effects of the substitutions at -11A of the promoter and Y430 and W433 of sigma70 are cumulative.

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.

Escherichia coli RNA polymerase recognition of a sigma70-dependent promoter requiring a -35 DNA element and an extended -10 TGn motif

Escherichia coli sigma70-dependent promoters have typically been characterized as either -10/-35 promoters, which have good matches to both the canonical -10 and the -35 sequences or as extended -10 promoters (TGn/-10 promoters), which have the TGn motif and an excellent match to the -10 consensus sequence. We report here an investigation of a promoter, P(minor), that has a nearly perfect match to the -35 sequence and has the TGn motif. However, P(minor) contains an extremely poor sigma70 -10 element. We demonstrate that P(minor) is active both in vivo and in vitro and that mutations in either the -35 or the TGn motif eliminate its activity. Mutation of the TGn motif can be compensated for by mutations that make the -10 element more canonical, thus converting the -35/TGn promoter to a -35/-10 promoter. Potassium permanganate footprinting on the nontemplate and template strands indicates that when polymerase is in a stable (open) complex with P(minor), the DNA is single stranded from positions -11 to +4. We also demonstrate that transcription from P(minor) incorporates nontemplated ribonucleoside triphosphates at the 5' end of the P(minor) transcript, which results in an anomalous assignment for the start site when primer extension analysis is used. P(minor) represents one of the few -35/TGn promoters that have been characterized and serves as a model for investigating functional differences between these promoters and the better-characterized -10/-35 and extended -10 promoters used by E. coli RNA polymerase.

6S RNA regulation of pspF transcription leads to altered cell survival at high pH

6S RNA is a highly abundant small RNA that regulates transcription through direct interaction with RNA polymerase. Here we show that 6S RNA directly inhibits transcription of pspF, which subsequently leads to inhibition of pspABCDE and pspG expression. Cells without 6S RNA are able to survive at elevated pH better than wild-type cells due to loss of 6S RNA-regulation of pspF. This 6S RNA-dependent phenotype is eliminated in pspF-null cells, indicating that 6S RNA effects are conferred through PspF. Similar growth phenotypes are seen when PspF levels are increased in a 6S RNA-independent manner, signifying that changes to pspF expression are sufficient. Changes in survival at elevated pH most likely result from altered expression of pspABCDE and/or pspG, both of which require PspF for transcription and are indirectly regulated by 6S RNA. 6S RNA provides another layer of regulation in response to high pH during stationary phase. We propose that the normal role of 6S RNA at elevated pH is to limit the extent of the psp response under conditions of nutrient deprivation, perhaps facilitating appropriate allocation of diminishing resources.

Extended -10 motif is critical for activity of the cspA promoter but does not contribute to low-temperature transcription

Bacterial promoters belonging to the extended -10 class contain a conserved TGn motif upstream of the -10 promoter consensus element. Open promoter complexes can be formed on some extended -10 Escherichia coli promoters at temperatures as low as 6 degrees C, when complexes on most promoters are closed. The promoter of cspA, a gene that codes for the major cold shock protein CspA of E. coli, contains an extended -10 motif. CspA is dramatically induced upon temperature downshift from 37 to 15 degrees C, and its cold shock induction has been attributed to transcription, translation, and mRNA stabilization effects. Here, we show that though the extended -10 motif is critical for high-level expression of cspA, it does not contribute to low-temperature expression. In fact, transcription from the wild-type cspA promoter is cold sensitive in vitro and in vivo. Thus, transcription appears to play little or no role in low-temperature induction of cspA expression.

Positive autoregulation of cI is a dispensable feature of the phage lambda gene regulatory circuitry

Complex gene regulatory circuits contain many features that are likely to contribute to their operation. It is unclear, however, whether all these features are necessary for proper circuit behavior or whether certain ones are refinements that make the circuit work better but are dispensable for qualitatively normal behavior. We have addressed this question using the phage lambda regulatory circuit, which can persist in two stable states, the lytic state and the lysogenic state. In the lysogenic state, the CI repressor positively regulates its own expression by stimulating transcription from the P(RM) promoter. We tested whether this feature is an essential part of the regulatory circuitry. Several phages with a cI mutation preventing positive autoregulation and an up mutation in the P(RM) promoter showed near-normal behavior. We conclude that positive autoregulation is not necessary for proper operation of the lambda circuitry and speculate that it serves a partially redundant function of stabilizing a bistable circuit, a form of redundancy we term "circuit-level redundancy." We discuss our findings in the context of a two-stage model for evolution and elaboration of regulatory circuits from simpler to more complex forms.

Transcriptional takeover by σ appropriation: remodelling of the σ 70 subunit of Escherichia coli RNA polymerase by the bacteriophage T4 activator MotA and co-activator AsiA

Activation of bacteriophage T4 middle promoters, which occurs about 1 min after infection, uses two phage-encoded factors that change the promoter specificity of the host RNA polymerase. These phage factors, the MotA activator and the AsiA co-activator, interact with theσ70specificity subunit ofEscherichia coliRNA polymerase, which normally contacts the −10 and −35 regions of host promoter DNA. Like host promoters, T4 middle promoters have a good match to the canonicalσ70DNA element located in the −10 region. However, instead of theσ70DNA recognition element in the promoter's −35 region, they have a 9 bp sequence (a MotA box) centred at −30, which is bound by MotA. Recent work has begun to provide information about the MotA/AsiA system at a detailed molecular level. Accumulated evidence suggests that the presence of MotA and AsiA reconfigures protein–DNA contacts in the upstream promoter sequences, without significantly affecting the contacts ofσ70with the −10 region. This type of activation, which is called ‘σappropriation’, is fundamentally different from other well-characterized models of prokaryotic activation in which an activator frequently serves to forceσ70to contact a less than ideal −35 DNA element. This review summarizes the interactions of AsiA and MotA withσ70, and discusses how these interactions accomplish the switch to T4 middle promoters by inhibiting the typical contacts of the C-terminal region ofσ70, region 4, with the host −35 DNA element and with other subunits of polymerase.

The strong efficiency of the Escherichia coli gapA P1 promoter depends on a complex combination of functional determinants

The Escherichia coli multi-promoter region of the gapA gene ensures a high level of GAPDH (glyceraldehyde-3-phosphate dehydrogenase) production under various growth conditions. In the exponential phase of growth, gapA mRNAs are mainly initiated at the highly efficient gapA P1 promoter. In the present study, by using site-directed mutagenesis and chemical probing of the RPo (open complex) formed by Esigma70 (holoenzyme associated with sigma70) RNAP (RNA polymerase) at promoter gapA P1, we show that this promoter is an extended -10 promoter that needs a -35 sequence for activity. The -35 sequence compensates for the presence of a suboptimal -10 hexamer. A tract of thymine residues in the spacer region, which is responsible for a DNA distortion, is also required for efficient activity. We present the first chemical probing of an RPo formed at a promoter needing both a -10 extension and a -35 sequence. It reveals a complex array of RNAP-DNA interactions. In agreement with the fact that residue A-11 in the non-template strand is flipped out in a protein pocket in previously studied RPos, the corresponding A residue in gapA P1 promoter is protected in RPo and is essential for activity. However, in contrast with some of the previous findings on RPos formed at other promoters, the -12 A:T pair is opened. Strong contacts with RNAP occur both with the -35 sequence and the TG extension, so that the sigma4 and sigma2 domains may simultaneously contact the promoter DNA. RNAP-DNA interactions were also detected immediately downstream of the -35 hexamer and in a more distal upstream segment, reflecting a wrapping of RNAP by the core and upstream promoter DNA. Altogether, the data reveal that promoter gapA P1 is a very efficient promoter sharing common properties with both extended -10 and non-extended -10 promoters.

Substitutions in Region 2.4 of σ70 Allow Recognition of the σS-Dependent aidB Promoter

The strict dependence of transcription from the aidB promoter (PaidB) on the Esigma(S) form of RNA polymerase is because of the presence of a C nucleotide as the first residue of the -10 promoter sequence (-12C), which does not allow an open complex formation by Esigma(70). In this report, sigma(70) mutants carrying either the Q437H or the T440I single amino acid substitutions, which allow -12C recognition by sigma(70), were tested for their ability to carry out transcription from PaidB. The Gln-437 and Thr-440 residues are located in region 2.4 of sigma(70) and correspond to Gln-152 and Glu-155 in sigma(S). Interestingly, the Q437H mutant of sigma(70), but not T440I, was able to promote an open complex formation and to initiate transcription at PaidB. In contrast to T440I, a T440E mutant was proficient in carrying out transcription from PaidB. No sigma(70) mutant displayed significantly increased interaction with a PaidB mutant in which the -12C was substituted by a T (PaidB((C12T))), which is also efficiently recognized by wild type sigma(70). The effect of the T440E mutation suggests that the corresponding Glu-155 residue in sigma(S) might be involved in -12C recognition. However, substitution to alanine of the Glu-155 residue, as well as of Gln-152, in the sigma(S) protein did not significantly affect Esigma(S) interaction with PaidB. Our results reiterate the importance of the -12C residue for sigma(S)-specific promoter recognition and strongly suggest that interaction with the -10 sequence and open complex formation are carried out by different determinants in the two sigma factors.

Phage T4 early promoters are resistant to inhibition by the anti-sigma factor AsiA

Phage T4 early promoters are transcribed in vivo and in vitro by the Escherichia coli RNA polymerase holoenzyme Esigma(70). We studied in vitro the effects of the T4 anti-sigma(70) factor AsiA on the activity of several T4 early promoters. In single-round transcription, promoters motB, denV, mrh.2, motA wild type and UP element-deleted motA are strongly resistant to inhibition by AsiA. The alpha-C-terminal domain of Esigma(70) is crucial to this resistance. DNase I footprinting of Esigma(70) and Esigma(70)AsiA on motA and mrh.2 shows extended contacts between the holoenzyme with or without AsiA and upstream regions of these promoters. A TG --> TC mutation of the extended -10 motif in the motA UP element-deleted promoter strongly increases susceptibility to inhibition by AsiA, but has no effect on the motA wild-type promoter: either the UP element or the extended -10 site confers resistance to AsiA. Potassium permanganate reactivity shows that the two structure elements are not equivalent: with AsiA, the motA UP element-deleted promoter opens more slowly whereas the motA TC promoter opens like the wild type. Changes in UV laser photoreactivity at position +4 on variants of motA reveal an analogous distinction in the roles of the extended -10 and UP promoter elements.

The regulation of bacterial transcription initiation

Bacteria use their genetic material with great effectiveness to make the right products in the correct amounts at the appropriate time. Studying bacterial transcription initiation in Escherichia coli has served as a model for understanding transcriptional control throughout all kingdoms of life. Every step in the pathway between gene and function is exploited to exercise this control, but for reasons of economy, it is plain that the key step to regulate is the initiation of RNA-transcript formation.