Subunit topography of RNA polymerase from Escherichia coli. A cross-linking study with bifunctional reagents.

The quaternary structures of Escherichia coli DNA-dependent RNA polymerase holenzyme (alpha 2 beta beta' sigma) and core enzyme (alpha 2 beta beta') have been investigated by chemical cross-linking with a cleavable bifunctional reagent, methyl 4-mercaptobutyrimidate, and noncleavable reagents, dimethyl suberimidate and N,N'-(1,4-phenylene)bismaleimide. A model of the subunit organization deduced from cross-linked subunit neighbors identified by dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the large beta and beta' subunits constitute the backbone of both core and holoenzyme, while sigma and two alpha subunits interact with this structure along the contact domain of beta and beta' subunits. In holoenzyme, sigma subunit is in the vicinity of at least one alpha subunit. The two alpha subunits are close to each other in holoenzyme, core enzyme, and the isolated alpha 2 beta complex. Cross-linking of the "premature" core and holoenzyme intermediates in the in vitro reconstitution of active enzyme from isolated subunits suggests that these species are composed of subunit complexes of molecular weight lower than that of native core and holoenzyme, respectively. The structural information obtained for RNA polymerase and its subcomplexes has important implications for the enzyme-promoter recognition as well as the mechanism of subunit assembly of the enzyme.     

DNA-dependent RNA polymerases from Artemia salina. Subunit structure of polymerase II.

RNA polymerase II from larvae of the brine shrimp, Artemia salina, was highly purified by two cycles of DEAE-cellulose chromatography followed by centrifugation through discontinuous sucrose gradients. Gradient fractions were subjected to elctrophoresis is polyacrylamide gels containing sodium dodecyl sulfate. The subunit structure of RNA polymerase II was determined by quantitative comparison of the polypeptides and enzyme activity present in each gradient fraction. The enzyme contains one copy of each of four subunits with estimated molecular weights of 170,000, 130,000, 36,000 and 24,000. The total molecular weight agrees well with the molecular weight estimated for the native enzyme by density gradient centrifugation.     

Evidence that sigma factors are components of chloroplast RNA polymerase.

Plastid genes are transcribed by DNA-dependent RNA polymerase(s), which have been incompletely characterized and have been examined in a limited number of species. Plastid genomes contain rpoA, rpoB, rpoC1, and rpoC2 coding for alpha, beta, beta', and beta" RNA polymerase subunits that are homologous to the alpha, beta, and beta' subunits that constitute the core moiety of RNA polymerase in bacteria. However, genes with homology to sigma subunits in bacteria have not been found in plastid genomes. An antibody directed against the principal sigma subunit of RNA polymerase from the cyanobacterium Anabaena sp. PCC 7120 was used to probe western blots of purified chloroplast RNA polymerase from maize, rice, Chlamydomonas reinhardtii, and Cyanidium caldarium. Chloroplast RNA polymerase from maize and rice contained an immunoreactive 64-kD protein. Chloroplast RNA polymerase from C. reinhardtii contained immunoreactive 100- and 82-kD proteins, and chloroplast RNA polymerase from C. caldarium contained an immunoreactive 32-kD protein. The elution profile of enzyme activity of both algal chloroplast RNA polymerases coeluted from DEAE with the respective immunoreactive proteins, indicating that they are components of the enzyme. These results provide immunological evidence for sigma-like factors in chloroplast RNA polymerase in higher plants and algae.     

Escherichia coli RNA polymerase subunit omega and its N-terminal domain bind full-length beta' to facilitate incorporation into the alpha2beta subassembly.

The omega subunit of Escherichia coli RNA polymerase, consisting of 90 amino acids, is present in stoichiometric amounts per molecule of core RNA polymerase (alpha2betabeta'). The presence of omega is necessary to restore denatured RNA polymerase in vitro to its fully functional form, and, in an omega-less strain of E. coli, GroEL appears to substitute for omega in the maturation of RNA polymerase. The X-ray structure of Thermus aquaticus core RNA polymerase suggests that two regions of omega latch on to beta' at its N-terminus and C-terminus. We show here that omega binds only the intact beta' subunit and not the beta' N-terminal domain or beta' C-terminal domain, implying that omega binding requires both these regions of beta'. We further show that omega can prevent the aggregation of beta' during its renaturation in vitro and that a V8-protease-resistant 52-amino-acid-long N-terminal domain of omega is sufficient for binding and renaturation of beta'. CD and functional assays show that this N-terminal fragment retains the structure of native omega and is able to enhance the reconstitution of core RNA polymerase. Reconstitution of core RNA polymerase from its individual subunits proceeds according to the steps alpha + alpha --> alpha2 + beta --> alpha2beta + beta' --> alpha2betabeta'. It is shown here that omega participates during the last stage of enzyme assembly when beta' associates with the alpha2beta subassembly.     

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)     

Biosynthesis of RNA polymerase in Escherichia coli VI. Distribution of RNA polymerase subunits between nucleoid and cytoplasm.

The distribution of DNA-dependent RNA polymerase in Escherichia coli was analysed by measuring enzyme subunits in nucleoid (folded chromosome) and cytoplasm. Two independent methods, two-dimensional polyacrylamide gel electrophoresis of total proteins and sodium dodecyl sulphate/polyacrylamide gel electrophoresis of antibody precipitates, gave essentially the same results; with wild-type cells growing at a doubling time of 70 minutes, about two-thirds of the core enzyme but little σ subunit are present in the nucleoid. Pulse-chase experiments indicated that the distribution of the pulse-labelled proteins was at equilibrium within 1·5 minutes for β′, 5 minutes for β, and 15 minutes for α subunit. This order of appearance of the newly synthesized core subunits into the nueleoid is in good agreement with that into complete enzyme structure. This finding, together with the known sequence of subunit assembly (2α → α₂ → α₂β → α₂ββ′ → E), indicates that the assembly of RNA polymerase takes place in the cytoplasm. In concert with the conclusion, the amounts of pulse-labelled subunits in the cytoplasm of temperature-sensitive assembly defective mutants coincide well with those of intermediate subassemblies accumulated in the mutant cells. However, it is not known if the premature core is activated in cytoplasm prior to binding to the nucleoid or shortly after association with the nucleoid.     

RNA polymerase II subunit composition, stoichiometry, and phosphorylation.

RNA polymerase II subunit composition, stoichiometry, and phosphorylation were investigated in Saccharomyces cerevisiae by attaching an epitope coding sequence to a well-characterized RNA polymerase II subunit gene (RPB3) and by immunoprecipitating the product of this gene with its associated polypeptides. The immunopurified enzyme catalyzed alpha-amanitin-sensitive RNA synthesis in vitro. The 10 polypeptides that immunoprecipitated were identical in size and number to those previously described for RNA polymerase II purified by conventional column chromatography. The relative stoichiometry of the subunits was deduced from knowledge of the sequence of the subunits and from the extent of labeling with [35S]methionine. Immunoprecipitation from 32P-labeled cell extracts revealed that three of the subunits, RPB1, RPB2, and RPB6, are phosphorylated in vivo. Phosphorylated and unphosphorylated forms of RPB1 could be distinguished; approximately half of the RNA polymerase II molecules contained a phosphorylated RPB1 subunit. These results more precisely define the subunit composition and phosphorylation of a eucaryotic RNA polymerase II enzyme.     

Localization of yeast RNA polymerase I core subunits by immunoelectron microscopy.

Immunoelectron microscopy was used to determine the spatial organization of the yeast RNA polymerase I core subunits on a three-dimensional model of the enzyme. Images of antibody-labeled enzymes were compared with the native enzyme to determine the localization of the antibody binding site on the surface of the model. Monoclonal antibodies were used as probes to identify the two largest subunits homologous to the bacterial beta and beta' subunits. The epitopes for the two monoclonal antibodies were mapped using subunit-specific phage display libraries, thus allowing a direct correlation of the structural data with functional information on conserved sequence elements. An epitope close to conserved region C of the beta-like subunit is located at the base of the finger-like domain, whereas a sequence between conserved regions C and D of the beta'-like subunit is located in the apical region of the enzyme. Polyclonal antibodies outlined the alpha-like subunit AC40 and subunit AC19 which were found co-localized also in the apical region of the enzyme. The spatial location of the subunits is correlated with their biological activity and the inhibitory effect of the antibodies.     

Subunits of RNA polymerase in function and structure: VI. Sequence of the assembly in vitro of Escherichia coli RNA polymerase

Detailed analysis of the assembly in vitro of Escherichia coli RNA polymerase reveals that core enzyme subunits are assembled in the following sequence: $\text{2 α → α}{}_2\text{→}\text{β}\text{α}{}_2\text{β}\text{→}\text{β′}\text{α}{}_2\text{ββ′}$(premature core) → E (active core). Activation of the premature core enzyme, the rate-limiting step in this sequence, can be achieved in three different ways: self-reactivation, sigma subunit (σ or σ′)-promoted reactivation, and DNA-promoted reactivation.Although there has been disagreement on the enhancement of core enzyme maturation by sigma subunit or DNA, the discrepancy is resolved by the present finding that the premature core alone can be activated in the presence of high concentrations of salt or glycerol, whereas at a salt concentration as low as that in vivo, sigma subunit or DNA is required for maximum activation. However, the question remains unsolved as to which of the three ways operates in the in vivo process of RNA polymerase formation.     

Subunit assembly and metabolic stability of E. coli RNA polymerase

Immunological cross-reaction was employed for identification of proteolytic fragments of E. coli RNA polymerase generated both in vitro and in vivo. Several species of partially denatured but assembled RNA polymerase were isolated, which were composed of fragments of the two large subunits, beta and beta', and the two small and intact subunits, alpha and sigma. Comparison of the rate and pathway of proteolytic cleavage in vitro of unassembled subunits, subassemblies, and intact enzymes indicated that the susceptibility of RNA polymerase subunits to proteolytic degradation was dependent on the assembly state. Using this method, degradation in vivo was found for some, but not all, of the amber fragments of beta subunit in merodiploid cells carrying both wild-type and mutant rpoB genes. Although the RNA polymerase is a metabolically stable component in exponentially growing cells of E. coli, degradation of the full-sized subunits was found in two cases, i.e., several temperature-sensitive E. coli mutants with a defect in the assembly of RNA polymerase and the stationary-phase cells of a wild-type E. coli. The in vivo degradation of RNA polymerase was indicated to be initiated by alteration of the enzyme structure.