Determinants for Escherichia coli RNA polymerase assembly within the beta subunit

Novel layers of RNA polymerase III control affecting tRNA gene transcription in eukaryotes

RNA polymerase III (Pol III) transcribes a limited set of short genes in eukaryotes producing abundant small RNAs, mostly tRNA. The originally defined yeast Pol III transcriptome appears to be expanding owing to the application of new methods. Also, several factors required for assembly and nuclear import of Pol III complex have been identified recently. Models of Pol III based on cryo-electron microscopy reconstructions of distinct Pol III conformations reveal unique features distinguishing Pol III from other polymerases. Novel concepts concerning Pol III functioning involve recruitment of general Pol III-specific transcription factors and distinctive mechanisms of transcription initiation, elongation and termination. Despite the short length of Pol III transcription units, mapping of transcriptionally active Pol III with nucleotide resolution has revealed strikingly uneven polymerase distribution along all genes. This may be related, at least in part, to the transcription factors bound at the internal promoter regions. Pol III uses also a specific negative regulator, Maf1, which binds to polymerase under stress conditions; however, a subset of Pol III genes is not controlled by Maf1. Among other RNA polymerases, Pol III machinery represents unique features related to a short transcript length and high transcription efficiency.

Optimization of recombinant Mycobacterium tuberculosis RNA polymerase expression and purification

Mycobacterium tuberculosis, the human pathogen that causes tuberculosis, warrants enormous attention due to the emergence of multi drug resistant and extremely drug resistant strains. RNA polymerase (RNAP), the key enzyme in gene regulation, is an attractive target for anti-TB drugs. Understanding the structure-function relationship of M. tuberculosis RNAP and the mechanism of gene regulation by RNAP in conjunction with different σ factors and transcriptional regulators would provide significant information for anti-tuberculosis drug development targeting RNAP. Studies with M. tuberculosis RNAP remain tedious because of the extremely slow-growing nature of the bacteria and requirement of special laboratory facility. Here, we have developed and optimized recombinant methods to prepare M. tuberculosis RNAP core and RNAP holo enzymes assembled in vivo in Escherichia coli. These methods yield high amounts of transcriptionally active enzymes, free of E. coli RNAP contamination. The recombinant M. tuberculosis RNAP is used to develop a highly sensitive fluorescence based in vitro transcription assay that could be easily adopted in a high-throughput format to screen RNAP inhibitors. These recombinant methods would be useful to set a platform for M. tuberculosis RNAP targeted anti TB drug development, to analyse the structure/function of M. tuberculosis RNAP and to analyse the interactions among promoter DNA, RNAP, σ factors, and transcription regulators of M. tuberculosis in vitro, avoiding the hazard of handling of pathogenic bacteria.

Molecular evolution of multisubunit RNA polymerases: structural analysis

Comprehensive multiple sequence alignments of the multisubunit DNA-dependent RNA polymerase (RNAP) large subunits, including the bacterial beta and beta' subunits and their homologs from archaebacterial RNAPs, eukaryotic RNAPs I-III, nuclear-cytoplasmic large double-stranded DNA virus RNAPs, and plant plastid RNAPs, were created [Lane, W. J. and Darst, S. A. (2009). Molecular evolution of multisubunit RNA polymerases: sequence analysis. In press]. The alignments were used to delineate sequence regions shared among all classes of multisubunit RNAPs, defining common, fundamental RNAP features as well as identifying highly conserved positions. Here, we present a systematic, detailed structural analysis of these shared regions and highly conserved positions in terms of the RNAP structure, as well as the RNAP structure/function relationship, when known.

Identifying protein interactions by hydroxyl-radical protein footprinting

Hydroxyl-radical protein footprinting is a straightforward and direct method to map protein sites involved in macromolecular interactions. The first step is to radioactively end-label the protein. Using hydroxyl radicals as a peptide backbone cleavage reagent, the protein is then cleaved in the absence and presence of ligand. Cleavage products are separated by high resolution gel electrophoresis. The digital image of the footprinting gel can be subjected to quantitative analysis to identify changes in the sensitivity of the protein to hydroxyl-radical cleavage. Molecular weight markers are electrophoresed on the same gel and hydroxyl-radical cleavage sites assigned by interpolation between the known cleavage sites of the markers. The results are presented in the form of a difference plot that shows regions of the protein that change their susceptibility to cleavage while bound to a ligand.

The bacteriophage T4 late-transcription coactivator gp33 binds the flap domain of Escherichia coli RNA polymerase

Transcription of bacteriophage T4 late genes requires concomitant DNA replication. T4 late promoters, which consist of a single 8-bp -10 motif, are recognized by a holoenzyme containing Escherichia coli RNA polymerase core and the T4-encoded promoter specificity subunit, gp55. Initiation of transcription at these promoters by gp55-holoenzyme is inefficient, but is greatly activated by the DNA-loaded DNA polymerase sliding clamp, gp45, and the coactivator, gp33. We report that gp33 attaches to the flap domain of the Escherichia coli RNA polymerase beta-subunit and that this interaction is essential for activation. The beta-flap also mediates recognition of -35 promoter motifs by binding to sigma(70) domain 4. The results suggest that gp33 is an analogue of sigma(70) domain 4 and that gp55 and gp33 together constitute two parts of the T4 late sigma. We propose a model for the role of the gp45 sliding clamp in activation of T4 late-gene transcription.

Transcript cleavage factors GreA and GreB act as transient catalytic components of RNA polymerase

Prokaryotic transcription elongation factors GreA and GreB stimulate intrinsic nucleolytic activity of RNA polymerase (RNAP). The proposed biological role of Gre-induced RNA hydrolysis includes transcription proofreading, suppression of transcriptional pausing and arrest, and facilitation of RNAP transition from transcription initiation to transcription elongation. Using an array of biochemical and molecular genetic methods, we mapped the interaction interface between Gre and RNAP and identified the key residues in Gre responsible for induction of nucleolytic activity in RNAP. We propose a structural model in which the C-terminal globular domain of Gre binds near the opening of the RNAP secondary channel, the N-terminal coiled-coil domain (NTD) protrudes inside the RNAP channel, and the tip of the NTD is brought to the immediate vicinity of RNAP catalytic center. Two conserved acidic residues D41 and E44 located at the tip of the NTD assist RNAP by coordinating the Mg2+ ion and water molecule required for catalysis of RNA hydrolysis. If so, Gre would be the first transcription factor known to directly participate in the catalytic act of RNAP.

Role of second-largest RNA polymerase I subunit Zn-binding domain in enzyme assembly

The second-largest subunits of eukaryal RNA polymerases are similar to the beta subunits of prokaryal RNA polymerases throughout much of their lengths. The second-largest subunits from eukaryal RNA polymerases contain a four-cysteine Zn-binding domain at their C termini. The domain is also present in archaeal homologs but is absent from prokaryal homologs. Here, we investigated the role of the C-terminal Zn-binding domain of Rpa135, the second-largest subunit of yeast RNA polymerase I. Analysis of nonfunctional Rpa135 mutants indicated that the Zn-binding domain is required for recruitment of the largest subunit, Rpa190, into the RNA polymerase I complex. Curiously, the essential function of the Rpa135 Zn-binding domain is not related to Zn(2+) binding per se, since replacement of only one of the four cysteine residues with alanine led to the loss of Rpa135 function. Even more strikingly, replacement of all four cysteines with alanines resulted in functional Rpa135.

Escherichia coli RNA polymerase core and holoenzyme structures

Multisubunit RNA polymerase is an essential enzyme for regulated gene expression. Here we report two Escherichia coli RNA polymerase structures: an 11.0 A structure of the core RNA polymerase and a 9.5 A structure of the sigma(70) holoenzyme. Both structures were obtained by cryo-electron microscopy and angular reconstitution. Core RNA polymerase exists in an open conformation. Extensive conformational changes occur between the core and the holoenzyme forms of the RNA polymerase, which are largely associated with movements in ss'. All common RNA polymerase subunits (alpha(2), ss, ss') could be localized in both structures, thus suggesting the position of sigma(70) in the holoenzyme.

Suppression of temperature-sensitive sporulation mutation in the Bacillus subtilis sigA gene by rpoB mutation

We isolated a temperature-sensitive sporulation defective mutant of the sigA gene, encoding a major sigma factor, sigma(A) protein, in Bacillus subtilis, and designated it as sigA21. The sigA21 mutation caused a single-amino acid substitution, E314K, in region 4 of the sigma(A) protein. In this mutant, expression of the spoIIG gene, whose transcription depends on both sigma(A) and the phosphorylated Spo0A protein, Spo0A approximately P, a major transcription factor during early stages of sporulation, was greatly reduced at 43 degrees C. To obtain further information on the mechanism of sigma(A) function during the early spore development, we isolated a spontaneous sporulation-proficient suppressor mutant at 43 degrees C. This extragenic suppressor mutation was mapped within the rpoB gene, encoding the beta subunit of RNA polymerase, and was found to have a single-amino acid substitution, A863G. In this mutant, the expression of the spoIIG is partially restored at 43 degrees C.

Inter- and intrasubunit interactions during the formation of RNA polymerase assembly intermediate

We used yeast two-hybrid and in vitro co-immobilization assays to study the interaction between the Escherichia coli RNA polymerase (RNAP) alpha and beta subunits during the formation of alpha(2)beta, a physiological RNAP assembly intermediate. We show that a 430-amino acid-long fragment containing beta conserved segments F, G, H, and a short part of segment I forms a minimal domain capable of specific interaction with alpha. The alpha-interacting domain is held together by protein-protein interactions between beta segments F and I. Residues in catalytically important beta segments H and I directly participate in alpha binding; substitutions of strictly conserved segment H Asp(1084) and segment I Gly(1215) abolish alpha(2)beta formation in vitro and are lethal in vivo. The importance of these beta amino acids in alpha binding is fully supported by the structural model of the Thermus aquaticus RNAP core enzyme. We also demonstrate that determinants of RNAP assembly are conserved, and that a homologue of beta Asp(1084) in A135, the beta-like subunit of yeast RNAP I, is responsible for interaction with AC40, the largest alpha-like subunit. However, the A135-AC40 interaction is weak compared with the E. coli alpha-beta interaction, and A135 mutation that abolishes the interaction is phenotypically silent. The results suggest that in eukaryotes additional RNAP subunits orchestrate the enzyme assembly by stabilizing weak, but specific interactions of core subunits.

Electrospray ionization and matrix-assisted laser desorption ionization mass spectrometry. Emerging technologies in biomedical sciences

Tremendous progress in biomedical sciences has been made possible in part by recent advances in bioanalytical methods, in particular biological mass spectrometry. Since the introduction of electrospray ionization mass spectrometry (ESI-MS) in 1984 and matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) in 1988, the field of bioanalytical mass spectrometry has seen rapid growth. In concert with separation techniques such as capillary electrophoresis and high performance liquid chromatography, mass spectrometry allows characterization of a large array of small organic molecules, peptides, proteins, oligonucleotides, and RNA fragments. Thus, substantially more expedient and definitive determination of molecular weight is now possible by mass spectrometric analysis. In this commentary, general descriptions of ESI- and MALDI-MS are presented. Furthermore, several recent developments and applications in addressing difficult biological problems are discussed.

Mapping of subunit-subunit contact surfaces on the beta' subunit of Escherichia coli RNA polymerase

The RNA polymerase core enzyme of Escherichia coli with the catalytic activity of RNA polymerization is assembled sequentially under the order: 2alpha --> alpha(2) --> alpha(2)beta --> alpha(2)betabeta'. The core enzyme gains the activities of promoter recognition and transcription initiation after binding the sigma subunit. The subunit-subunit contact surfaces of beta' subunit (1407 residues) were analyzed by testing complex formation between various beta' fragments and either the alpha(2)beta complex or the sigma(70) subunit. Results indicate that two regions, one central region between residues 515 and 842 and the other COOH-terminal proximal region downstream from residue 1141, are involved in binding the alpha(2)beta complex; and the NH(2)-terminal proximal region between residues 201 and 345 plays a major role in binding the sigma(70) subunit. However, both alpha(2)beta binding sites have weak activity of the sigma(70) subunit; likewise, the sigma(70) subunit-contact surface has weak binding activity of the alpha(2)beta complex. The sites involved in the catalytic function of RNA polymerization are all located within two spacer regions sandwiched between these three subunit-subunit contact surfaces.

Crystal structure of Thermus aquaticus core RNA polymerase at 3.3 A resolution

The X-ray crystal structure of Thermus aquaticus core RNA polymerase reveals a "crab claw"-shaped molecule with a 27 A wide internal channel. Located on the back wall of the channel is a Mg2+ ion required for catalytic activity, which is chelated by an absolutely conserved motif from all bacterial and eukaryotic cellular RNA polymerases. The structure places key functional sites, defined by mutational and cross-linking analysis, on the inner walls of the channel in close proximity to the active center Mg2+. Further out from the catalytic center, structural features are found that may be involved in maintaining the melted transcription bubble, clamping onto the RNA product and/or DNA template to assure processivity, and delivering nucleotide substrates to the active center.

A zinc-binding site in the largest subunit of DNA-dependent RNA polymerase is involved in enzyme assembly

All multisubunit DNA-dependent RNA polymerases (RNAP) are zinc metalloenzymes, and at least two zinc atoms are present per enzyme molecule. RNAP residues involved in zinc binding and the functional role of zinc ions in the transcription mechanism or RNAP structure are unknown. Here, we locate four cysteine residues in the Escherichia coli RNAP largest subunit, beta', that coordinate one of the two zinc ions tightly associated with the enzyme. In the absence of zinc, or when zinc binding is prevented by mutation, the in vitro-assembled RNAP retains the proper subunit stoichiometry but is not functional. We demonstrate that zinc acts as a molecular chaperone, converting denatured beta' into a compact conformation that productively associates with other RNAP subunits. The beta' residues coordinating zinc are conserved throughout eubacteria and chloroplasts, but are absent from homologs from eukaryotes and archaea. Thus, the involvement of zinc in the RNAP assembly may be a unique feature of eubacterial-type enzymes.

Intragenic suppression of trans-dominant lethal substitutions in the conserved GEME motif of the beta subunit of RNA polymerase: evidence for functional cooperativity within the C-terminus

BACKGROUND

The ubiquitous multimeric RNA polymerases contain two large, conserved subunits, of which the beta subunit has been implicated in all three stages of transcription. We have previously described a genetic system involving random, PCR-mediated mutagenesis of the region of rpoB encoding the C-terminal 116 amino acids of the beta subunit of Escherichia coli RNA polymerase and the characterization of dominant-negative mutations. This study identified the invariant motif GEME (residues 1271-->1274; Cromie et al. 1999). Starting with three of these GEME-motif lethal mutations (G1271E, G1271V, M1273V), we have selected for intragenic suppressors, located within the same 3'-region, that prevent expression of the trans-dominant phenotype.

RESULTS

We isolated a total of 24 missense mutants and a further 14 frameshift alleles (the latter generating a nested set of C-terminal deletions of the beta subunit) and studied the effect of the missense suppressors in vivo and in vitro. The majority of the second-site substitutions pinpoint highly conserved residues and were allele-specific. In contrast, one particular missense substitution (S1332P) acted on all three primary site mutations whilst not appreciably affecting assembly proficiency, suggesting motif-specific suppression. Two missense substitutions were found to perturb assembly of the beta subunit (M1232T and L1233P) and define a small conserved region (1228-->1233) adjacent to one of the active-site residues identified by affinity-labelling, H1237. The majority of primary mutations were located in three main clusters within the 116 amino acid region.

CONCLUSIONS

The importance and functional co-operativity of the three main clusters pinpointed is supported by the present isolation of suppressors of three different GEME primary mutations in the same three regions (whereas the suppressors of G1271V and M1273V are located in all three clusters, those for G1271E are all C-terminal of this residue). Moreover, the location of the suppressors suggests that the GEME and HLVDDK regions are present as alpha-helices in holoenzyme, and that functional co-operativity is through one particular face of each helix.

Mapping interactions of Escherichia coli GreB with RNA polymerase and ternary elongation complexes

Escherichia coli GreA and GreB modulate transcription elongation by interacting with the ternary elongation complex (containing RNA polymerase, DNA template, and RNA transcript) to induce hydrolytic cleavage of the transcript and release of the 3'-terminal fragment. Hydroxyl radical protein footprinting and alanine-scanning mutagenesis were used to investigate the interactions of GreB with RNA polymerase alone and in a ternary elongation complex. A major determinant for binding GreB to both RNA polymerase and the ternary elongation complex was identified. In addition, the hydroxyl radical footprinting indicated major conformational changes of GreB, in terms of reorientations of the N- and C-terminal domains with respect to each other, particularly upon interactions with the ternary elongation complex.

Thermo-labile stability of sigmaH (Spo0H) in temperature-sensitive spo0H mutants of Bacillus subtilis can be suppressed by mutations in RNA polymerase beta subunit

We isolated novel temperature-sensitive mutants of spo0H, spo0H1 and spo0H5, having E61K and G30E amino-acid substitutions within the sigmaH protein, respectively, and located in the highly conserved region, "2", among prokaryotic sigma factors that participates in binding to core enzyme of RNA polymerase. These mutants showed a sporulation-deficient phenotype at 43 degrees C. Moreover, we successfully isolated suppressor mutants that were spontaneously generated from the spo0H mutants. Our genetic analysis of these suppressor mutations revealed that the suppressor mutations are within the rpoB gene coding for the beta subunit of RNA polymerase. The mutations caused single amino-acid substitutions, E857A and P1055S, in rpoB18 and rpoB532 mutants that were generated from spo0H1 and spo0H5, respectively. Whereas the sigmaH-dependent expression of a spo0A-bgaB fusion was greatly reduced in both spo0H mutants, their expression was partially restored in the suppressor mutants at 43 degrees C. Western blot analysis showed that the level of sigmaH protein in the wild type increased between T0 and T2 and decreased after T3, while the level of sigmaH protein in spo0H mutants was greatly reduced throughout growth, indicating that the mutant sigmaH proteins were rapidly degraded by some unknown proteolytic enzyme(s). The analysis of the half-life of sigmaH protein showed that the short life of sigmaH in spo0H mutants is prolonged in the suppressor mutants. These findings suggest that, at least to some extent, the process of E-sigmaH formation may be involved in stabilization of sigmaH at the onset of sporulation.

Trans-dominant mutations in the 3'-terminal region of the rpoB gene define highly conserved, essential residues in the beta subunit of RNA polymerase: the GEME motif

BACKGROUND

The multimeric DNA-dependent RNA polymerases are widespread throughout nature. The RNA polymerase of Escherichia coli, which is the most well characterized, consists of a holoenzyme with subunit stoichiometry of alpha2betabeta'sigma. The beta subunit is conserved and has been implicated in all stages of transcription. The extreme C-terminus of the beta subunit, which includes two well-conserved sequence segments, contributes to the active centre and has been proposed to act in transcriptional termination. We describe a genetic system for further characterizing the role of the extreme C-terminus of the beta subunit of E. coli RNA polymerase. This involves random, PCR (Polymerase Chain Reaction)-mediated mutagenesis of the 3' region of rpoB encoding the C-terminal 116 amino acids of beta, followed by the isolation and characterization of trans-dominant-negative mutations.

RESULTS

Substitutions of conserved residues in this region were obtained that exhibited different degrees of growth inhibition in a host expressing the chromosomal-encoded wild-type form of the beta subunit. A number of different substitutions were isolated within the highly conserved sequence motif GEME (residues 1271-->1274 of the E. coli beta subunit). In addition, substitutions were obtained in the extreme C-terminal (surface-exposed) region of beta and at two residues previously proposed to be in the active site (H1237, K1242). The properties of the purified mutant holoenzymes, assessed by transcription assays in vitro, suggested a promoter blockading action.

CONCLUSIONS

We have identified an important, highly conserved motif in the beta subunit, GEME (residues 1271-->1274). The nature and effect of the amino acid substitutions at the Gly residue in GEME emphasize the importance of a small, uncharged residue at this position. The in vitro properties of the most extreme trans dominant-negative mutants altered in the GEME motif (and the mutant characteristics in vivo) were similar to those of certain previously identified active-site mutants, suggesting that the altered RNA polymerases were capable of promoter binding and RNA chain initiation but were deficient in the subsequent transcriptional stage.

Functional organization of two large subunits of the fission yeast Schizosaccharomyces pombe RNA polymerase II. Location of the catalytic sites

The catalytically competent transcription complex of RNA polymerase II from the fission yeast Schizosaccharomyces pombe was affinity labeled with photoreactive nucleotide analogues incorporated at 3' termini of nascent RNA chains. To locate the catalytic site for RNA polymerization, the labeled subunits were separated by SDS-polyacrylamide gel electrophoresis and subjected to partial proteolysis. After microsequencing of proteolytic fragments, a complex multidomain organization was indicated for both of the two large subunits, Rpb1 and Rpb2, with the most available sites of proteolysis in junctions between the conserved sequences among RNA polymerase from both prokaryotes and eukaryotes. The cross-linking studies indicate the following: (i) the 3' termini of growing RNA chains are most extensively cross-linked to the second largest subunit Rpb2 between amino acids 825 and 994; (ii) the regions 298-535 of Rpb2 and 614-917 of Rpb1 are cross-linked to less extents, suggesting that these regions are situated in the vicinity of the catalytic site. All these regions include the conserved sequences of RNA polymerases, and the catalytic site of Rpb2 belongs to an NH2-terminal part of its conserved sequence H.

Mapping of subunit-subunit contact surfaces on the beta subunit of Escherichia coli RNA polymerase

The RNA polymerase core enzyme of Escherichia coli is composed of 2alpha, 1beta, and 1beta' subunits. Previously we mapped the alpha-alpha, alpha-beta, and alpha-beta' contact sites on the alpha subunit. Here we analyzed the alpha subunit contact sites on the beta subunit by using various experimental approaches: (i) comparison of the proteolytic cleavage map between the unassembled free beta subunit and the alpha2 beta complex; (ii) analysis of the binary complex formation between His6-tagged intact alpha subunit and various truncated beta fragments; and (iii) analysis of the complex formation between the alpha subunit and various His6-tagged beta fragments. The results altogether indicate that two regions of the beta subunit are involved in the full activity of alpha binding, that is, the primary contact site between residues 737 and 904 and the secondary region with assembly control activity downstream from residue 1138. All of the alpha subunit-beta fragment binary complexes identified in this study were found to bind beta' subunit and form pseudo-core complexes, indicating that the regions of beta involved in alpha subunit contact also participate in interaction with the beta' subunit.

Insights into Escherichia coli RNA polymerase structure from a combination of x-ray and electron crystallography

Our goal is to understand the mechanism of transcription and its regulation. Determining structures of RNA polymerase and transcription complexes is an essential step. Because of their large size and complexity, determination of these structures will require a combination of electron microscopy, biophysical methods, and biochemical methods to identify functionally and structurally relevant subassemblies and domains and x-ray crystallography to determine high-resolution structures of RNA polymerase components and accessory factors. We recently solved the 2.5-A crystal structure of the Escherichia coli RNA polymerase alpha subunit N-terminal domain, which is the first high-resolution structure of a core component required for RNA polymerase assembly and basal transcription. This structure, combined with a new 19-A resolution structure determined by cryo-electron microscopy of helical crystals of E. coli core RNAP embedded in vitreous ice, leads to a model for the organization of the RNAP subunits.

Localization of a sigma70 binding site on the N terminus of the Escherichia coli RNA polymerase beta' subunit

The Escherichia coli genome encodes genes for seven different sigma subunit species while only having single genes for the alpha, beta, and beta' subunits that make up the RNA polymerase core enzyme. The various sigma factors compete for binding to the core enzyme, upon which they confer promoter DNA-specific transcription initiation to the polymerase. We have mapped a major interaction site between one of the sigma species, sigma70, and beta'. Using far-Western blotting analysis of chemically cleaved and genetically engineered protein fragments, we have identified a N-terminal fragment of beta' (residues 60-309) that could bind sigma70. We were able to more precisely map the interaction domain to amino acid residues 260-309 of beta' using nickel nitrilotriacetic acid co-immobilization assays.

Structure of the Escherichia coli RNA polymerase alpha subunit amino-terminal domain

The 2.5 angstrom resolution x-ray crystal structure of the Escherichia coli RNA polymerase (RNAP) alpha subunit amino-terminal domain (alphaNTD), which is necessary and sufficient to dimerize and assemble the other RNAP subunits into a transcriptionally active enzyme and contains all of the sequence elements conserved among eukaryotic alpha homologs, has been determined. The alphaNTD monomer comprises two distinct, flexibly linked domains, only one of which participates in the dimer interface. In the alphaNTD dimer, a pair of helices from one monomer interact with the cognate helices of the other to form an extensive hydrophobic core. All of the determinants for interactions with the other RNAP subunits lie on one face of the alphaNTD dimer. Sequence alignments, combined with secondary-structure predictions, support proposals that a heterodimer of the eukaryotic RNAP subunits related to Saccharomyces cerevisiae Rpb3 and Rpb11 plays the role of the alphaNTD dimer in prokaryotic RNAP.

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).

Structure of the guanine nucleotide exchange factor Sec7 domain of human arno and analysis of the interaction with ARF GTPase

Sec7-related guanine nucleotide exchange factors (GEFs) initiate vesicle budding from the Golgi membrane surface by converting the GTPase ARF to a GTP-bound, membrane-associated form. Here we report the crystal structure of the catalytic Sec7 homology domain of Arno, a human GEF for ARF1, determined at 2.2 angstroms resolution. The Sec7 domain is an elongated, all-helical protein with a distinctive hydrophobic groove that is phylogenetically conserved. Structure-based mutagenesis identifies the groove and an adjacent conserved loop as the ARF-interacting surface. The sites of Sec7 domain interaction on ARF1 have subsequently been mapped, by protein footprinting experiments, to the switch 1 and switch 2 GTPase regions, leading to a model for the interaction between ARF GTPases and Sec7 domain exchange factors.

The use of bioreactive probes in protein characterization

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF) has in the past decade found routine use in the biological sciences. With this use has evolved several mass spectrometric-based methods directed at the intricate investigation of biomolecular structure and function. One such methodology involves the enzymatic modification of a protein prior to the mass spectrometric readout of the resulting products. The enzyme-modification/mass spectrometric approach has a definite use in a number of applications, including: the verification/identification of protein sequence, elucidation of post-translational modifications, the investigation of protein higher-order structure, and even the characterization of the modifying enzyme. To avoid the potentials of sample loss and autolytic interferences in the mass spectrum, mass spectrometer targets can be covalently derivatized with enzymes for use in the characterization procedures. The enzymatically active, or bioreactive, probes are used by application of the analyte to the activated surface, followed by application of a suitable MALDI matrix and mass analysis from the surface of the probe. Limited transfer and handling steps eliminate sample losses, and surface-tethered enzymes (and autolytic fragments) are prohibited from interfering with analytical signals in the mass spectra. In addition, the probes are rapid and easy to use. Reviewed here are issues of concern during the manufacture and use of the bioreactive probes, and application of the probes to investigate protein structure and function.

Tethering of the large subunits of Escherichia coli RNA polymerase

The rpoB and rpoC genes of eubacteria and archaea, coding, respectively, for the beta and beta'-like subunits of DNA-dependent RNA polymerase, are organized in an operon with rpoB always preceding rpoC. Here, we show that in Escherichia coli the two genes can be fused and that the resulting 2751-amino acid beta::beta' fusion polypeptide assembles into functional RNA polymerase in vivo and in vitro. The results establish that the C terminus of the beta subunit and the N terminus of the beta' subunit are in close proximity to each other on the surface of the assembled RNA polymerase during all phases of the transcription cycle and also suggest that RNA polymerase assembly in vivo may occur co-translationally.