The sigma subunit conserved region 3 is part of “5'-face” of active center of Escherichia coli RNA polymerase

XACT-Seq Comprehensively Defines the Promoter-Position and Promoter-Sequence Determinants for Initial-Transcription Pausing

Pausing by RNA polymerase (RNAP) during transcription elongation, in which a translocating RNAP uses a "stepping" mechanism, has been studied extensively, but pausing by RNAP during initial transcription, in which a promoter-anchored RNAP uses a "scrunching" mechanism, has not. We report a method that directly defines the RNAP-active-center position relative to DNA with single-nucleotide resolution (XACT-seq; "crosslink-between-active-center-and-template sequencing"). We apply this method to detect and quantify pausing in initial transcription at 4¹¹ (∼4,000,000) promoter sequences in vivo in Escherichia coli. The results show initial-transcription pausing can occur in each nucleotide addition during initial transcription, particularly the first 4 to 5 nucleotide additions. The results further show initial-transcription pausing occurs at sequences that resemble the consensus sequence element for transcription-elongation pausing. Our findings define the positional and sequence determinants for initial-transcription pausing and establish initial-transcription pausing is hard coded by sequence elements similar to those for transcription-elongation pausing.

Bacterial RNA polymerase caps RNA with various cofactors and cell wall precursors

Bacterial RNA polymerase is able to initiate transcription with adenosine-containing cofactor NAD+, which was proposed to result in a portion of cellular RNAs being ‘capped’ at the 5′ end with NAD+, reminiscent of eukaryotic cap. Here we show that, apart from NAD+, another adenosine-containing cofactor FAD and highly abundant uridine-containing cell wall precursors, UDP-Glucose and UDP-N-acetylglucosamine are efficiently used to initiate transcription in vitro. We show that the affinity to NAD+ and UDP-containing factors during initiation is much lower than their cellular concentrations, and that initiation with them stimulates promoter escape. Efficiency of initiation with NAD+, but not with UDP-containing factors, is affected by amino acids of the Rifampicin-binding pocket, suggesting altered RNA capping in Rifampicin-resistant strains. However, relative affinity to NAD+ does not depend on the −1 base of the template strand, as was suggested earlier. We show that incorporation of mature cell wall precursor, UDP-MurNAc-pentapeptide, is inhibited by region 3.2 of σ subunit, possibly preventing targeting of RNA to the membrane. Overall, our in vitro results propose a wide repertoire of potential bacterial RNA capping molecules, and provide mechanistic insights into their incorporation.

TFIIB is only ∼9 Å away from the 5'-end of a trimeric RNA primer in a functional RNA polymerase II preinitiation complex

Recent X-ray crystallographic studies of Pol II in complex with the general transcription factor (GTF) IIB have begun to provide insights into the mechanism of transcription initiation. These structures have also shed light on the architecture of the transcription preinitiation complex (PIC). However, structural characterization of a functional PIC is still lacking, and even the topological arrangement of the GTFs in the Pol II complex is a matter of contention. We have extended our activity-based affinity crosslinking studies, initially developed to investigate the interaction of bacterial RNA polymerase with σ, to the eukaryotic transcription machinery. Towards that end, we sought to identify GTFs that are within the Pol II active site in a functioning PIC. We provide biochemical evidence that TFIIB is located within ∼9 Å of the -2 site of promoter DNA, where it is positioned to play a role in de novo transcription initiation.

Structural basis of transcription initiation by bacterial RNA polymerase holoenzyme

The bacterial RNA polymerase (RNAP) holoenzyme containing σ factor initiates transcription at specific promoter sites by de novo RNA priming, the first step of RNA synthesis where RNAP accepts two initiating ribonucleoside triphosphates (iNTPs) and performs the first phosphodiester bond formation. We present the structure of de novo transcription initiation complex that reveals unique contacts of the iNTPs bound at the transcription start site with the template DNA and also with RNAP and demonstrate the importance of these contacts for transcription initiation. To get further insight into the mechanism of RNA priming, we determined the structure of initially transcribing complex of RNAP holoenzyme with 6-mer RNA, obtained by in crystallo transcription approach. The structure highlights RNAP-RNA contacts that stabilize the short RNA transcript in the active site and demonstrates that the RNA 5'-end displaces σ region 3.2 from its position near the active site, which likely plays a key role in σ ejection during the initiation-to-elongation transition. Given the structural conservation of the RNAP active site, the mechanism of de novo RNA priming appears to be conserved in all cellular RNAPs.

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.

RNA polymerase II transcription: structure and mechanism

A minimal RNA polymerase II (pol II) transcription system comprises the polymerase and five general transcription factors (GTFs) TFIIB, -D, -E, -F, and -H. The addition of Mediator enables a response to regulatory factors. The GTFs are required for promoter recognition and the initiation of transcription. Following initiation, pol II alone is capable of RNA transcript elongation and of proofreading. Structural studies reviewed here reveal roles of GTFs in the initiation process and shed light on the transcription elongation mechanism. This article is part of a Special Issue entitled: RNA Polymerase II Transcript Elongation.

RNA polymerase II-TFIIB structure and mechanism of transcription initiation

To initiate gene transcription, RNA polymerase II (Pol II) requires the transcription factor IIB (B). Here we present the crystal structure of the complete Pol II-B complex at 4.3 A resolution, and complementary functional data. The results indicate the mechanism of transcription initiation, including the transition to RNA elongation. Promoter DNA is positioned over the Pol II active centre cleft with the 'B-core' domain that binds the wall at the end of the cleft. DNA is then opened with the help of the 'B-linker' that binds the Pol II rudder and clamp coiled-coil at the edge of the cleft. The DNA template strand slips into the cleft and is scanned for the transcription start site with the help of the 'B-reader' that approaches the active site. Synthesis of the RNA chain and rewinding of upstream DNA displace the B-reader and B-linker, respectively, to trigger B release and elongation complex formation.

Promoter Escape by Escherichia coli RNA Polymerase

Promoter escape is the process that an initiated RNA polymerase (RNAP) molecule undergoes to achieve the initiation-elongation transition. Having made this transition, an RNAP molecule would be relinquished from its promoter hold to perform productive (full-length) transcription. Prior to the transition, this process is accompanied by abortive RNA formation-the amount and pattern of which is controlled by the promoter sequence information. Qualitative and quantitative analysis of abortive/productive transcription from several Escherichia coli promoters and their sequence variants led to the understanding that a strong (RNAP-binding) promoter is more likely to be rate limited (during transcription initiation) at the escape step and produce abortive transcripts. Of the two subelements in a promoter, the PRR (the core Promoter Recognition Region) was found to set the initiation frequency and the rate-limiting step, while the ITS (the Initial Transcribed Sequence region) modulated the ratio of abortive versus productive transcription. The highly abortive behavior of E. coli RNAP could be ameliorated by the presence of Gre (transcript cleavage stimulatory) factor(s), linking the first step in abortive RNA formation by the initial transcribing complexes (ITC) to RNAP backtracking. The discovery that translocation during the initiation stage occurs via DNA scrunching provided the source of energy that converts each ITC into a highly unstable "stressed intermediate." Mapping all of the biochemical information onto an X-ray crystallographic structural model of an open complex gave rise to a plausible mechanism of transcription initiation. The chapter concludes with contemplations of the kinetics and thermodynamics of abortive initiation-promoter escape.

Informatics development: challenges and solutions for MALDI mass spectrometry

Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) has been successfully applied to elucidating biological questions trough the analysis of proteins, peptides, and nucleic acids. Here, we review the different approaches for analyzing the data that is generated by MALDI-MS. The first step in the analysis is the processing of the raw data to find peaks that correspond to the analytes. The peaks are characterized by their areas (or heights) and their centroids. The peak area can be used as a measure of the quantity of the analyte, and the centroid can be used to determine the mass of the analyte. The masses are then compared to models of the analyte, and these models are ranked according to how well they fit the data and their significance is calculated. This allows the determination of the identity (sequence and modifications) of the analytes. We show how this general data analysis workflow is applied to protein and nucleic acid chemistry as well as proteomics.

Plant sigma factors and their role in plastid transcription

Plant sigma factors determine the promoter specificity of the major RNA polymerase of plastids and thus regulate the first level of plastome gene expression. In plants, sigma factors are encoded by a small family of nuclear genes, and it is not yet clear if the family members are functionally redundant or each paralog plays a particular role. The review presents the analysis of the information on plant sigma factors obtained since their discovery a decade ago and focuses on similarities and differences in structure and functions of various paralogs. Special attention is paid to their interaction with promoters, the regulation of their expression, and their role in the development of a whole plant. The analysis suggests that though plant sigma factors are basically similar, at least some of them perform distinct functions. Finally, the work presents the scheme of this gene family evolution in higher plants.

Region 1.2 of the RNA polymerase sigma subunit controls recognition of the -10 promoter element

Recognition of the -10 promoter consensus element by region 2 of the bacterial RNA polymerase sigma subunit is a key step in transcription initiation. sigma also functions as an elongation factor, inducing transcription pausing by interacting with transcribed DNA non-template strand sequences that are similar to the -10 element sequence. Here, we show that the region 1.2 of Escherichia coli sigma70, whose function was heretofore unknown, is strictly required for efficient recognition of the non-template strand of -10-like pause-inducing DNA sequence by sigma region 2, and for sigma-dependent promoter-proximal pausing. Recognition of the fork-junction promoter DNA by RNA polymerase holoenzyme also requires sigma region 1.2 and thus resembles the pause-inducing sequence recognition. Our results, together with available structural data, support a model where sigma region 1.2 acts as a core RNA polymerase-dependent allosteric switch that modulates non-template DNA strand recognition by sigma region 2 during transcription initiation and elongation.

Region 3.2 of the sigma subunit contributes to the binding of the 3'-initiating nucleotide in the RNA polymerase active center and facilitates promoter clearance during initiation

Region 3.2 of the RNA polymerase sigma subunit forms a loop that protrudes toward RNA polymerase active center and partially blocks RNA exit channel. To provide some insights into the functional role of this region, we studied a deletion variant of the Escherichia coli sigma(70) subunit that lacked amino acids 513-519 corresponding to the tip of the loop. The deletion had multiple effects on transcription initiation including: (i) a significant decrease in the amount of short abortive RNAs synthesized during initiation, (ii) defects in promoter escape, (iii) loss of the contacts between the sigma subunit and the nascent RNA during initiation and, finally, (iv) dramatic increase in the K(m) value for the 3'-initiating nucleotide. At the same time, the mutation did not impair promoter opening and the binding of the 5'-initiating purine nucleotide. In summary, our data demonstrate an important role of sigma region 3.2 in the binding of initiating substrates in RNA polymerase active center and in the process of promoter clearance.

Structural perspective on mutations affecting the function of multisubunit RNA polymerases

High-resolution crystallographic structures of multisubunit RNA polymerases (RNAPs) have increased our understanding of transcriptional mechanisms. Based on a thorough review of the literature, we have compiled the mutations affecting the function of multisubunit RNA polymerases, many of which having been generated and studied prior to the publication of the first high-resolution structure, and highlighted the positions of the altered amino acids in the structures of both the prokaryotic and eukaryotic enzymes. The observations support many previous hypotheses on the transcriptional process, including the implication of the bridge helix and the trigger loop in the processivity of RNAP, the importance of contacts between the RNAP jaw-lobe module and the downstream DNA in the establishment of a transcription bubble and selection of the transcription start site, the destabilizing effects of ppGpp on the open promoter complex, and the link between RNAP processivity and termination. This study also revealed novel, remarkable features of the RNA polymerase catalytic mechanisms that will require additional investigation, including the putative roles of fork loop 2 in the establishment of a transcription bubble, the trigger loop in start site selection, and the uncharacterized funnel domain in RNAP processivity.

Direct modulation of RNA polymerase core functions by basal transcription factors

Archaeal RNA polymerases (RNAPs) are recruited to promoters through the joint action of three basal transcription factors: TATA-binding protein, TFB (archaeal homolog of TFIIB), and TFE (archaeal homolog of TFIIE). Our results demonstrate several new insights into the mechanisms of TFB and TFE during the transcription cycle. (i) The N-terminal Zn ribbon of TFB displays a surprising degree of redundancy for the recruitment of RNAP during transcription initiation in the archaeal system. (ii) The B-finger domain of TFB participates in transcription initiation events by stimulating abortive and productive transcription in a recruitment-independent function. TFB thus combines physical recruitment of the RNAP with an active role in influencing the catalytic properties of RNAP during transcription initiation. (iii) TFB mutations are complemented by TFE, thereby demonstrating that both factors act synergistically during transcription initiation. (iv) An additional function of TFE is to dynamically alter the nucleic acid-binding properties of RNAP by stabilizing the initiation complex and destabilizing elongation complexes.

The role of RNA polymerase sigma subunit in promoter-independent initiation of transcription

In bacteria, initiation of transcription depends on the RNA polymerase sigma subunit, which brings catalytically proficient RNA polymerase core to promoters by binding to specific DNA elements located upstream of the transcription start point. Here, we study sigma-dependent synthesis of a transcript that is used to prime replication of the single-stranded genome of bacteriophage M13. We show that, in this system, sigma plays no role in DNA recognition, which is accomplished solely through RNA polymerase core interaction with DNA downstream of the transcription start point. However, sigma is required for full-sized transcript synthesis by allowing RNA polymerase core to escape into productive elongation. RNA polymerase sigma may play a similar role during replication primer synthesis in other bacterial mobile elements whose life cycle involves a single-stranded DNA stage.

Mechanism of stimulation of ribosomal promoters by binding of the +1 and +2 nucleotides

The rate of transcription of Escherichia coli ribosomal RNA promoters is central to adjusting the cellular growth rate to nutritional conditions. The +1 initiating nucleotide and ppGpp are regulatory effectors of these promoters. The data herein show that in vitro transcription is also regulated by the +2 nucleotide. Both the +1 and +2 nucleotides act by driving polymerase into an altered conformation rather than by increasing the lifetime of transcription complexes. The unique design of the ribosomal promoters may stabilize a distorted state of polymerase that is relieved by the binding of the two nucleotides required for transcription initiation.

Transcription factor B contacts promoter DNA near the transcription start site of the archaeal transcription initiation complex

Transcription initiation in all three domains of life requires the assembly of large multiprotein complexes at DNA promoters before RNA polymerase (RNAP)-catalyzed transcript synthesis. Core RNAP subunits show homology among the three domains of life, and recent structural information supports this homology. General transcription factors are required for productive transcription initiation complex formation. The archaeal general transcription factors TATA-element-binding protein (TBP), which mediates promoter recognition, and transcription factor B (TFB), which mediates recruitment of RNAP, show extensive homology to eukaryal TBP and TFIIB. Crystallographic information is becoming available for fragments of transcription initiation complexes (e.g. RNAP, TBP-TFB-DNA, TBP-TFIIB-DNA), but understanding the molecular topography of complete initiation complexes still requires biochemical and biophysical characterization of protein-protein and protein-DNA interactions. In published work, systematic site-specific protein-DNA photocrosslinking has been used to define positions of RNAP subunits and general transcription factors in bacterial and eukaryal initiation complexes. In this work, we have used systematic site-specific protein-DNA photocrosslinking to define positions of RNAP subunits and general transcription factors in an archaeal initiation complex. Employing a set of 41 derivatized DNA fragments, each having a phenyl azide photoactivable crosslinking agent incorporated at a single, defined site within positions -40 to +1 of the gdh promoter of the hyperthermophilic marine archaea, Pyrococcus furiosus (Pf), we have determined the locations of PfRNAP subunits PfTBP and PfTFB relative to promoter DNA. The resulting topographical information supports the striking homology with the eukaryal initiation complex and permits one major new conclusion, which is that PfTFB interacts with promoter DNA not only in the TATA-element region but also in the transcription-bubble region, near the transcription start site. Comparison with crystallographic information implicates the PfTFB N-terminal domain in the interaction with the transcription-bubble region. The results are discussed in relation to the known effects of substitutions in the TFB and TFIIB N-terminal domains on transcription initiation and transcription start-site selection.

Superselective labelling of proteins: approaches and techniques

Affinity labelling is a popular method used for the study of macromolecules and their interactions with ligands. The method is based on the targeted delivery of a chemically cross-linkable group, attached to a reactive molecule with affinity for a particular site in the biopolymer of interest. In complex multicomponent systems, the applications of affinity labelling are restricted by the tendency of the reagents to randomly label nontargetted molecules. This review highlights techniques developed to minimize non-specific cross-linking and to achieve high selectivity for the labelling of target protein. Such techniques might be termed 'superselective labelling', as opposed to traditional, less selective approaches.

RNA polymerase holoenzyme: structure, function and biological implications

The past three years have marked the breakthrough in our understanding of the structural and functional organization of RNA polymerase. The latest major advance was the high-resolution structures of bacterial RNA polymerase holoenzyme and the holoenzyme in complex with promoter DNA. Together with an array of genetic, biochemical and biophysical data accumulated to date, the structures provide a comprehensive view of dynamic interactions between the major components of transcription machinery during the early stages of the transcription cycle. They include the binding of sigma factor to the core enzyme, and the recognition of promoter sequences and DNA melting by holoenzyme, transcription initiation and promoter clearance.

Role of the RNA polymerase sigma subunit in transcription initiation

In bacteria, sigma subunits direct the catalytically competent RNA polymerase core enzyme to promoters. Recent advances in our understanding of bacterial RNA polymerase reveal that sigma subunits are intimately involved in all aspects of transcription initiation including promoter location, promoter melting, initiation of RNA synthesis, abortive initiation and promoter escape.

Structural basis of transcription initiation: RNA polymerase holoenzyme at 4 A resolution

The crystal structure of the initiating form of Thermus aquaticus RNA polymerase, containing core RNA polymerase (alpha2betabeta'omega) and the promoter specificity sigma subunit, has been determined at 4 angstrom resolution. Important structural features of the RNA polymerase and their roles in positioning sigma within the initiation complex are delineated, as well as the role played by sigma in modulating the opening of the RNA polymerase active-site channel. The two carboxyl-terminal domains of sigma are separated by 45 angstroms on the surface of the RNA polymerase, but are linked by an extended loop. The loop winds near the RNA polymerase active site, where it may play a role in initiating nucleotide substrate binding, and out through the RNA exit channel. The advancing RNA transcript must displace the loop, leading to abortive initiation and ultimately to sigma release.

Structure of the bacterial RNA polymerase promoter specificity sigma subunit

The sigma subunit is the key regulator of bacterial transcription. Proteolysis of Thermus aquaticus sigma(A), which occurred in situ during crystallization, reveals three domains, sigma(2), sigma(3), and sigma(4), connected by flexible linkers. Crystal structures of each domain were determined, as well as of sigma(4) complexed with -35 element DNA. Exposed surfaces of each domain are important for RNA polymerase binding. Universally conserved residues important for -10 element recognition and melting lie on one face of sigma(2), while residues important for extended -10 recognition lie on sigma(3). Genetic studies correctly predicted that a helix-turn-helix motif in sigma(4) recognizes the -35 element but not the details of the protein-DNA interactions. Positive control mutants in sigma(4) cluster in two regions, positioned to interact with activators bound just upstream or downstream of the -35 element.

The anti-initial transcribed sequence, a portable sequence that impedes promoter escape, requires sigma70 for function

The anti-sequence, a portable element extending from +1 to +15 of the transcript, is sufficient to prevent promoter escape from a variety of strong final sigma70 promoters. We show here that this sequence does not function with even the strongest final sigma32 promoter. Moreover, a particular class of substitutions in final sigma70 that disrupt interaction between Region 2.2 of final sigma70 and a coiled-coiled motif in the beta'-subunit of RNA polymerase antagonizes the function of the anti-element. This same group of mutants prevents lambdaQ-mediated anti-termination at the lambdaP(R') promoter. At this promoter, interaction of final sigma70 with the non-template strand of the initial transcribed sequence (ITS) is required to promote the pause prerequisite for anti-termination. These mutants prevent pausing because they are defective in this recognition event. By analogy, we suggest that interaction of final sigma70 with the non-template strand of the anti-ITS is required for function of this portable element, thus explaining why neither final sigma32 nor the Region 2.2 final sigma70 mutants mediate anti-function. Support for the analogy with the lambdaP(R') promoter comes from preliminary experiments suggesting that the anti-ITS, like the lambdaP(R') ITS, is bipartite.

Restructuring of an RNA polymerase holoenzyme elongation complex by lambdoid phage Q proteins

The structure of an intermediate in the initiation to elongation transition of Escherichia coli RNA polymerase has been visualized through region-specific DNA cleavage by the hydroxyl radical reagent FeBABE. FeBABE was tethered to specific sites of the final sigma(70) subunit and incorporated into two specialized paused elongation complexes that obligatorily retain the final sigma(70) initiation subunit and are targets for modification by lambdoid phage late gene antiterminators. The FeBABE cleavage pattern reveals structures similar to open complex, except for notable changes to region 3 of final sigma(70) that might reflect the presence of stably bound transcript. Binding of the antiterminator protein Q displaces the reactivity of FeBABE conjugated to region 4 of final sigma(70), suggesting that final sigma(70) subunit rearrangement is a step in conversion of RNAP to the antiterminating form.

Binding of the initiation factor sigma(70) to core RNA polymerase is a multistep process

The interaction of RNA polymerase and its initiation factors is central to the process of transcription initiation. To dissect the role of this interface, we undertook the identification of the contact sites between RNA polymerase and sigma(70), the Escherichia coli initiation factor. We identified nine mutationally verified interaction sites between sigma(70) and specific domains of RNA polymerase and provide evidence that sigma(70) and RNA polymerase interact in at least a two-step process. We propose that a cycle of changes in the interface of sigma(70) with core RNA polymerase is associated with progression through the process of transcription initiation.

A multipartite interaction between Salmonella transcription factor sigma28 and its anti-sigma factor FlgM: implications for sigma28 holoenzyme destabilization through stepwise binding

Transcription of the late (Class 3) flagellar promoters in Salmonella typhimurium is dependent upon the flagellar specific sigma factor, sigma28, encoded by the fliA gene. sigma28-dependent transcription is inhibited by an anti-sigma factor, FlgM, through a direct interaction. FlgM can bind both to free sigma28 to prevent it from forming a complex with core RNA polymerase, and to sigma28 holoenzyme to destabilize the complex. A collection of fliA mutants defective for negative regulation by FlgM (fliA* mutants) were isolated. This collection included 27 substitution mutations that conferred insensitivity to FlgM in vivo. The distribution of mutations defined three potential FlgM binding domains in conserved sigma factor regions 2.1, 3.1 and 4 of sigma28. A subset of mutants from each region was assayed for FlgM binding and transcriptional activity in vitro. The results strongly support a multipartite interaction between sigma28 and FlgM. Region 4 mutations, but not region 2.1 or 3.1 mutations, interfered with the ability of FlgM to destabilize sigma28 from core RNA polymerase. We present refined models for FlgM inhibition of sigma28, and for FlgM destabilization of sigma28 holoenzyme.

Complementary expression of two plastid-localized sigma-like factors in maize

The eubacterial-like RNA polymerase of plastids is composed of organelle-encoded core subunits and nuclear-encoded sigma-factors. Families of sigma-like factors (SLFs) have been identified in several plants, including maize (Zea mays) and Arabidopsis. In vitro import assays determined that at least two of the maize sigma-like proteins have functional chloroplast transit peptides and thus are likely candidates for chloroplast transcriptional regulators. However, the roles of individual SLFs in chloroplast transcription remain to be determined. We have raised antibodies against the unique amino-terminal domains of two maize SLFs, ZmSig1 and ZmSig3, and have used these specific probes to examine the accumulation of each protein in different maize tissues and during chloroplast development. The expression of ZmSig1 is tissue specific and parallels the light-activated chloroplast development program in maize seedling leaves. Its accumulation in mature chloroplasts however, is not affected by subsequent changes in the light regime. It is interesting that the expression profile of ZmSig3 is complementary to that of ZmSig1. It accumulates in non-green tissues, including roots, etiolated seedling leaves, and the basal region of greening seedling leaves. The nonoverlapping expression patterns of these two plastid-localized SLFs suggest that they may direct differential expression of plastid genes during chloroplast development.

Polymerase arrest at the lambdaP(R) promoter during transcription initiation

During transcription initiation by Escherichia coli RNA polymerase, a fraction of the homogeneous enzyme population has been kinetically shown to form two types of nonproductive complexes at some promoters: moribund complexes, which produce only abortive transcripts, and fully inactive ternary complexes (Kubori, T., and Shimamoto, N. (1996) J. Mol. Biol. 256, 449-457). Here we report biochemical isolation of the complexes arrested at the lambdaP(R) promoter and an analysis of their structure by DNA and protein footprintings. We found that the isolated promoter-arrested complexes retain a stoichiometric amount of sigma(70) subunit. Exonuclease III footprints of the arrested complexes are backtracked compared with that of the binary complex, and KMnO(4) footprinting reveals a decrease in the melting of DNA in the promoter region. Protein footprints of the retained sigma(70) have shown a more exposed conformation in region 3, compared with binary complexes. This feature is similar to that of the complexes arrested in inactive state during transcription elongation, indicating the existence of a common inactivating mechanism during transcription initiation and elongation. The possible involvement of the promoter arrest in transcriptional regulation is discussed.

DNA bending and wrapping around RNA polymerase: a "revolutionary" model describing transcriptional mechanisms

A model is proposed in which bending and wrapping of DNA around RNA polymerase causes untwisting of the DNA helix at the RNA polymerase catalytic center to stimulate strand separation prior to initiation. During elongation, DNA bending through the RNA polymerase active site is proposed to lower the energetic barrier to the advance of the transcription bubble. Recent experiments with mammalian RNA polymerase II along with accumulating evidence from studies of Escherichia coli RNA polymerase indicate the importance of DNA bending and wrapping in transcriptional mechanisms. The DNA-wrapping model describes specific roles for general RNA polymerase II transcription factors (TATA-binding protein [TBP], TFIIB, TFIIF, TFIIE, and TFIIH), provides a plausible explanation for preinitiation complex isomerization, suggests mechanisms underlying the synergy between transcriptional activators, and suggests an unforseen role for TBP-associating factors in transcription.

Mapping the sigma70 subunit contact sites on Escherichia coli RNA polymerase with a sigma70-conjugated chemical protease

The core enzyme of Escherichia coli RNA polymerase acquires essential promoter recognition and transcription initiation activities by binding one of several sigma subunits. To characterize the proximity between sigma70, the major sigma for transcription of the growth-related genes, and the core enzyme subunits (alpha2 beta beta'), we analyzed the protein-cutting patterns produced by a set of covalently tethered FeEDTA probes [FeBABE: Fe (S)-1-(p-bromoacetamidobenzyl)EDTA]. The probes were positioned in or near conserved regions of sigma70 by using seven mutants, each carrying a single cysteine residue at position 132, 376, 396, 422, 496, 517, or 581. Each FeBABE-conjugated sigma70 was bound to the core enzyme, which led to cleavage of nearby sites on the beta and beta' subunits (but not alpha). Unlike the results of random cleavage [Greiner, D. P., Hughes, K. A., Gunasekera, A. H. & Meares, C. F. (1996) Proc. Natl. Acad. Sci. USA 93, 71-75], the cut sites from different probe-modified sigma70 proteins are clustered in distinct regions of the subunits. On the beta subunit, cleavage is observed in two regions, one between residues 383 and 554, including the conserved C and Rif regions; and the other between 854 and 1022, including conserved region G, regions of ppGpp sensitivity, and one of the segments forming the catalytic center of RNA polymerase. On the beta' subunit, the cleavage was identified within the sequence 228-461, including beta' conserved regions C and D (which comprise part of the catalytic center).

Reduction in abortive transcription from the lambdaPR promoter by mutations in region 3 of the sigma70 subunit of Escherichia coli RNA polymerase

Transcription initiation by Escherichia coli RNA polymerase at most promoters is associated with a reiterative synthesis and release of short abortive RNA products. We have investigated the mechanism of abortive RNA synthesis by using holoenzymes containing mutant sigma70 subunits with changes in region 3 (S506F and P504L), which reduce the ratio of abortive to full-length products. Binary complexes formed by these mutant enzymes at a modified lambdaPR promoter contained a smaller fraction of open complexes than for normal polymerase, suggesting an involvement of region 3 in melting duplex DNA or in maintenance of the open complex. The half-lives of the majority of binary complexes formed by the mutant enzymes were less than 1 min, in contrast to 30 min for the wild-type complexes. The time courses of transcription and pulse-labeling assays showed that moribund complexes, which generate only abortive products (Kubori, T., and Shimamoto, N. (1996) J. Mol. Biol. 256, 449-457), were formed by the mutant enzymes. However, they accumulated to a lesser extent than for the wild-type enzyme, due both to faster dissociation and conversion into inactive complexes. This is the main cause of the low degree of abortive transcription displayed by the mutant enzymes on this promoter.

Principal transcription sigma factors of Pseudomonas putida strains mt-2 and G1 are significantly different

The rpoD gene coding for the primary transcription sigma factor, sigma70, and its entire operon were cloned from strain mt-2 of the purple soil bacterium Pseudomonas putida. Comparison of the deduced amino acid sequence of Ppmt-2 sigma70 with that of sigma70 from P. putida strain G1 shows that the two proteins differ in their primary structure, molecular weight, and isoelectric point. The significance of this difference is discussed in terms of bacterial taxonomy and transcription regulation.

Identification of a prime suspect

Recent findings help to define the multiple functions of the sigma subunit of bacterial RNA polymerase, from promoter recognition to the release of pausing during initial RNA elongation; these functions can now be confronted with a crystal structure of an essential domain of the sigma subunit.

Sigma domain structure: one down, one to go

The recent publication of the 2.6 A crystal structure of a portion of sigma70 provides insight into the role of sigma during transcription initiation. This high resolution picture unveils novel questions.

Conserved region 3 of Escherichia coli final sigma70 is implicated in the process of abortive transcription

Multiple-round in vitro transcription assays were performed using purified Escherichia coli RNA polymerase reconstituted with either wild-type or mutant final sigma70 proteins. These mutants, final sigma70(P504L) and final sigma70(S506F), bear single amino acid changes in conserved protein region 3. Behavior of the mutant enzymes on three test templates, bearing either the T7 A1, T5 N25, or T5 N25antiDSR promoter, were characterized. Transcription of all three promoter templates produced a pattern of specific abortive RNA species, which was qualitatively different for the mutants compared to the wild-type final sigma70 enzyme. Short abortive RNAs were produced at similar levels for mutant and wild-type enzymes. The production of longer abortive species was either reduced or increased by the mutant enzymes in a systematic manner that appears promoter-specific, and could be RNA length- or promoter distance-dependent. The process of abortive RNA transcription is thought to be tightly associated with that of promoter clearance. However, promoter clearance from these templates appears only slightly affected by the mutant enzymes. These mutants implicated region 3 of final sigma70 in the process of abortive transcription and suggest that the sequence of enzymatic events leading to the production of abortive or full-length RNA may be separable.

The beta subunit Rif-cluster I is only angstroms away from the active center of Escherichia coli RNA polymerase

Ribonucleotide analogs bound in the initiating site of Escherichia coli RNA polymerase-promoter complex were cross-linked to the beta subunit. Using limited proteolysis and chemical degradation, the cross-link was mapped to a segment of beta between amino acids Val516 and Arg540. This region (Rif-cluster I) is known to harbor many rifampicin-resistant (RifR) mutations. The results demonstrate that Rif-culster I is part of the "5'-face" of the active center and provide structural basis for the long-known effects of RifR mutations on transcription initiation, elongation, and termination.

Active site mapping of the catalytic mouse primase subunit by alanine scanning mutagenesis

In the eukaryotic cell, DNA synthesis is initiated by DNA primase associated with DNA polymerase alpha. The eukaryotic primase is composed of two subunits, p49 and p58, where the p49 subunit contains the catalytic active site. Mutagenesis of the cDNA for the p49 subunit was initiated to demonstrate a functional correlation of conserved residues among the eukaryotic primases and DNA polymerases. Fourteen invariant charged residues in the smaller catalytic mouse primase subunit, p49, were changed to alanine. These mutant proteins were expressed, purified, and enzymatically characterized for primer synthesis. Analyses of the mutant proteins indicate that residues 104-111 are most critical for primer synthesis and form part of the active site. Alanine substitution in residues Glu105, Asp109, and Asp111 produced protein with no detectable activity in direct primase assays, indicating that these residues may form part of a conserved carboxylic triad also observed in the active sites of DNA polymerases and reverse transcriptases. All other mutant proteins showed a dramatic decrease in catalysis, while mutation of two residues, Arg162 and Arg163, caused an increase in Km(NTP). Analysis of these mutant proteins in specific assays designed to separately investigate dinucleotide formation (initiation) and elongation of primer indicates that these two activities utilize the same active site within the p49 subunit. Finally, mutations in three active site codons produced protein with reduced affinity with the p58 subunit, suggesting that p58 may interact directly with active site residues.