Structural properties of Escherichia coli RNA polymerase Subunits

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.

Monoclonal antibodies as probes of the topological arrangement of the alpha subunits of Escherichia coli RNA polymerase

Three monoclonal anti-alpha antibodies were used to study the properties of the alpha subunit of Escherichia coli RNA polymerase. None of the monoclonal antibodies inhibited the d(A-T)n-directed synthesis of r(A-U)n. Reassembly of the RNA polymerase core was blocked by mAb 129C4 or mAb 126C6 while no effect was observed with mAb 124D1. The conversion of premature to mature core was partially inhibited by mAb 129C4 and almost totally inhibited by mAb 126C6. The data suggest that during the course of core assembly at least one of the alpha subunits undergoes conformational changes. The increase in affinity of mAb 126C6 for assembled alpha compared with free alpha also implies that alpha undergoes conformational changes during RNA polymerase assembly. Double antibody binding studies showed that the epitopes for mAb 124D1 and mAb 129C4 are available on only one of the alpha subunits in RNA polymerase. It would appear that the relevant domain on one of the alpha subunits in RNA polymerase is well exposed whereas this domain on the second alpha subunit is shielded by interaction with regions of the large beta and beta' subunits. The alpha domain in which the epitope for mAb 126C6 resides is not impeded by subunit interactions in the RNA polymerase. The data obtained also suggest that in the holoenzyme the sigma subunit may be positioned close to one of the alpha subunits, probably to the more exposed alpha. The alpha beta complex is the minimal stable subassembly since one of the alpha subunits dissociates from the alpha 2 beta complex following binding of any of the monoclonal antibodies studied.(ABSTRACT TRUNCATED AT 250 WORDS)

Functionally important site in the vicinity of the amino-terminus of the Escherichia coli RNA polymerase beta subunit

We have analyzed the interaction of monoclonal antibodies against Escherichia coli RNA polymerase with products of its limited proteolysis. Two major proteolytic fragments of molecular masses 107 and 43 kDa originate as a result of a single cleavage in the vicinity of the 980th amino acid residue. Anti-beta subunit monoclonal antibody PYN-2 inhibiting RNA polymerase activity at the stage of RNA elongation reacts with an epitope located between the amino-terminus and the 50th amino acid residue of the beta subunit. DNA sequencing has shown that the RNA polymerase mutation rpoB22 converts the Gln(1111) codon of the beta subunit gene into the amber codon. An epitope for the monoclonal antibody PYN-6 was located between the major site of proteolytic cleavage and Gln(1111) of the beta subunit.

Purification of RNA polymerase and transcription-termination factor Rho from Erwinia carotovora

Erwinia carotovora RNA polymerase consists of the holoenzyme structure sigma 2 beta beta' sigma as found in Escherichia coli and other bacteria. E. carotovora RNA polymerase can synthesize RNA using lambda, T7 of T4 DNA as templates; however, it is two times less active on these templates and is more temperature-sensitive than the E. coli enzyme. The alpha subunit of the E.. carotovora enzyme is lower in molecular mass than its E. coli counterpart. The sigma factors from E. coli and E. carotovora are similar in size and in their ability to stimulate RNA synthesis by core enzyme on DNA templates such as T7 DNA. An additional protein of 115 000 Da molecular mass, termed gamma, is found associated with E. carotovora RNA polymerase. The gamma protein is tightly associated with the polymerase subunits as it is not dissociated by gel filtration in buffer containing 0.5 M NaCl. It can be purified by passing the Agarose 1.5 m enzyme through coupled Bio-Rex 70 and DEAE-cellulose columns. The gamma-protein, when present in excess over the sigma subunit, inhibits holoenzyme activity on T7 DNA but not on poly[d(A-T)]and may thus interfere with sigma activity. The gamma protein by itself cannot transcribe T7 DNA or poly[d(A-T)], nor does it stimulate core enzyme activity on T7 DNA. E. carotovora rho has a subunit molecular mass of 48 000 Da and exhibits RNA-dependent phosphohydrolysis of adenosine ribonucleoside triphosphate. E. coli and E. carotovora rho are indistinguishable immunologically, as total fusion of precipitin bands is observed. E. carotovora rho elutes from a phosphocellulose column at a salt concentration of about 0.21 M KCl, compared to that of 0.29 M KCl for E. coli rho. The poly(C)-dependent ATPase activity of E. carotovora rho is more-temperature sensitive and is six to ten times less active than that of E. coli rho. E. carotovora rho is capable of terminating RNA transcripts, as indicated by a decrease in RNA synthesis using lambda or T7 DNA as template and E. carotovora or E. coli polymerase as the transcribing-enzyme.

The quaternary structure of Escherichia coli RNA polymerase studied with (scanning) transmission (immuno)electron microscopy

A model for the quaternary structure of Escherichia coli RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) is presented. It is based on results from classification of profiles of enzyme molecules, and from application of immuno electron microscopy. Classification of molecules, prepared with the single carbon layer technique, was first achieved for images recorded in dark field with the scanning transmission electron microscope and later on for images recorded in bright-field transmission electron microscopy. It results in five approximately equally sized groups, containing about 80% of the core enzyme profiles. Holoenzyme profiles can be grouped into the same classes, and have approximately the same dimensions (9 nm X 16 nm). Based on the shapes and sizes of the classified profiles, a tentative model for core enzyme has been constructed. Correlation of shadow projections of this model, with the distributions of attachment sites of antibodies against alpha, beta, beta' and sigma over the profiles, has led to models for core and holoenzyme in which the subunits are localized. The model is compared with literature data on the quaternary structure of RNA polymerase.

Topography of transcription: path of the leading end of nascent RNA through the Escherichia coli transcription complex

A cleavable dinucleotide photoaffinity reagent was prepared and used to map the path of the leading end of the RNA transcript across the surface of Escherichia coli RNA polymerase/T7 DNA transcription complexes. By using 5'-(4-azidophenacylthio)phosphoryladenylyl(3'-5')uridine, transcription was specifically initiated at the A1 promoter of bacteriophage T7 D111 or D123 DNA. Transcription complexes containing radiolabeled RNA chains of various lengths (4-116 nucleotides) were prepared, and the 5' end of the RNA transcript was then covalently attached to the nearby polymerase subunits or DNA by irradiation with UV light. The photoaffinity-labeled enzyme subunits and DNA were separated, the radiolabeled RNAs were cleaved from each, and the lengths and sequences of RNA attached to each component were determined. The leading end of RNA chains up to 12 bases long was found to label the DNA and the beta and beta' subunits of RNA polymerase, with more than 90% of the label going to the DNA. When the RNA transcript reached 12 bases in length, the 5' end diverged from the DNA and only the beta and beta' enzyme subunits were labeled thereafter. These two subunits were heavily labeled by RNA chains 12 to as many as 94 bases long. No significant labeling of the alpha subunit occurred. The sigma subunit was not labeled by RNAs longer than the trinucleotide.

RNA polymerase: interaction of RNA and rifampicin with the subassembly alpha 2 beta

We studied the inhibition of tryptic digestion of the subassembly alpha 2 beta of Escherichia coli DNA-dependent RNA polymerase to investigate its interaction with RNA and rifampicin. Both agents decreased distinctly the cleavage of subunit beta in the subassembly as well as the degradation of the transiently formed polypeptides (Mr greater than 80000). Short RNAs with a chain length of approximately 35 nucleotides were most protective at a concentration of 1 mg/ml while long RNAs were less effective at the same concentration. DNA did not exert any observable protective effects. The association of RNA with alpha 2 beta was shown by chromatography on phosphocellulose, which separates alpha 2 beta bound to RNA from free alpha 2 beta. The association of alpha 2 beta with RNA was inhibited by rifampicin.

beta-Galactosidase alpha-complementation. A model of protein-protein interaction

Studies on beta-galactosidase alpha-complementation are reviewed. The isolation and structure of two beta-galactosidase fragments that form an enzymically active complex are described. One of these is a cyanogen bromide peptide from whole beta-galactosidase; the other is a dimeric protein from a lacZ deletion mutant of Escherichia coli. The mechanism most likely involves an initial binding of two cyanogen bromide peptides to the dimer, followed by formation of a tetramer, and finally a slow conformational change of the complex to a native-like enzyme. The overall reaction is essentially irreversible. A region of the polypeptide chain involved in dimer-dimer contact must be supplied by the cyanogen bromide peptide. alpha-Complemented enzyme contains overlapping sequences. Proteolytic experiments were carried out to determine the origin of the functionally important segment. The effect on alpha-complementation of amino acid substitutions at four positions in the polypeptide chain was investigated. The implications of these results for beta-galactosidase structure and for proteins in general are discussed.

Antigenic variability of bacterial RNA polymerases

Radioimmunoassay analysis of enteric and some other Gram-negative bacteria has shown that the antigenic structure of the RNA polymerase alpha subunit is more conserved than that of the beta and beta' subunits. Since anti-alpha antibodies do not affect RNA polymerase activity, the constraints which determine the low variability of the antigenic structure of the alpha subunit are not directly related to its functional role. The antigenic determinants of the alpha subunit located on the surface of the RNA polymerase molecule are more conserved than those involved in contacts with other subunits; an opposite tendency characterizes the beta subunit. The range of variability of the antigenic determinants buried inside the RNA polymerase molecule suggests that the subunits are attached to each other rather loosely. Immunological comparison of RNA polymerases provides a simple method for reconstructing bacterial genealogies. The genealogy of the bacteria examined is essentially in agreement with phylogenetic trees based on 16S and 5S rRNA sequence characterization. This argues against extensive interspecific transfer of genes coding for components of the transcription and translation apparatus.

DNA strand specificity in promoter recognition by RNA polymerase

DNA strand and enzyme subunit specificities involved in the interaction between E. coli RNA polymerase and T7 DNA were studied by photo-crosslinking techniques. In non-specific enzyme-DNA complexes, subunits, sigma, beta, and beta' were crosslinked to both strands of the DNA. Under conditions leading to specific enzyme-promoter complexes, however, only sigma and beta subunits were crosslinked. The sigma subunit was crosslinked preferentially to the non-sense strand at promoter sites. No such strand specificity was observed for the beta subunit. These results provide insight into the molecular mechanism of promoter recognition and indicate that the interaction between RNA polymerase and DNA template is different at promoters and at non-specific sites.

Identification of a class of lysines within the non-specific DNA-binding site of RNA polymerase core enzyme from Escherichia coli

The imido ester, methyl acetimidate, which specifically amidinates lysine residues, modifies RNA polymerase core enzyme, leading to rapid loss of activity. Calf thymus DNA partially protects the enzyme against this inactivation, an effect which disappears at high salt concentration. DNA protects 17 +/- 6 lysines from amidination at low salt concentration. The dependence of amidination on methyl acetimidate concentration is examined in the presence of DNA at high and low salt concentration. Analysis of the data suggests a class of approximately 12 lysines which are protected by DNA, consistent with the above estimate. These lysines are approximately 5--10-fold more reactive than most other available lysine residues.

Purification and properties of the sigma subunit of Escherichia coli DNA-dependent RNA polymerase

An improved purification procedure is described for the sigma subunit of escherichia coli DNA-dependent RNA polymerase [ribonucleoside triphosphate:RNA nucleotidyl-transferase, EC 2.7.7.6]. The method involves chromatography of purified RNA polymerase on single-stranded DNA-agarose, Bio-Rex 70, and finally Ultragel AcA44. The sigma factor obtained is electrophoretically pure with a yield of about 40%. A number of the chemical--physical properties of sigma are presented. A molecular weight of 82,000 was determined by phosphate buffered sodium dodecyl sulfate--polyacrylamide gel electrophoresis. Ultraviolet absorption spectra were used to determine an E280nm 1% of 8.4. The amino acid composition and 12-residue N-terminal sequence (Met-Glx-Glx-Asx-Pro-Glx-(Ser or Cys)-Glx-Leu-Lys-Leu-Leu) of sigma have been determined. The isoelectric focusing properties of sigma are presented. Denaturation--renaturation studies indicate that sigma is capable of an unusually rapid and complete recovery of activity after being subjected to denaturing conditions. A stable, 40,000-dalton fragment is generated from sigma by mild trypsin treatment.

Rifampicin binding as a probe for subunit interactions in Escherchia coli RNA polymerase

The binding of the inhibitor rifampicin to RNA polymerase (alpha2betabeta') and its deficient subunit mixtures was investigated. The ability of beta to bind stoichiometric amounts of rifampicin was restored by formation of the alpha2beta subassembly. beta,beta' alpha, betabeta' and alpha2beta' were unable to bind rifampicin. RNA polymerase denatured with 6 M guanidine hydrochloride and dialysed against a renaturing buffer at 0degrees C ("renatured inactive enzyme") bound stoichiometric amounts of rifampicin but had lost the ability of bind dna. compared with native RNA polymerase "renatured inactive" enzyme possessed a markedly different tertiary structure as judged by limited proteolysis.

Conversion of Escherichia coli RNA polymerase to a template independent enzyme

Preparations of RNA polymerase (E.C.2.7.7.6) from uninfected Escherichia coli, T4 infected Escherichia coli, and Acinetobacter calcoaceticus when centrifuged in sucrose gradients in the absence of magnesium ions gave rise to five peaks, all of which were able to form polymers from ribonucleoside 5'-triphosphates in the absence of template or primer. All of the peaks obtained from the Escherichia coli enzyme appeared to contain the subunit alpha and beta and, in addition, polypeptides which appeared to be derived from the subunit beta.