Assembly of amber fragments of the beta subunit of Escherichia coli RNA polymerase

Immunoblotting of size-separated whole cell proteins permitted the study of protein-protein interaction. Briefly, proteins obtained from cleared cell lysates of Escherichia coli were separated by glycerol gradient centrifugation and analysed by blotting against a set of specific antibodies. We have applied this procedure to the assembly of 11 N-terminal amber fragments of the beta subunit of E. coli RNA polymerase ranging in size between 97% and 23% the length of the intact beta polypeptide (1342 amino acids). In this way, we have been able to define regions on the beta polypeptide involved in the assembly of RNA polymerase.     

Formation of a RNA polymerase sub-assembly composed of subunit alpha from Escherichia coli and of subunit beta from Micrococcus luteus.

Functionally equivalent subunits of RNA polymerase from Micrococcus luteus and Escherichia coli differ from each other in many molecular and antigenic properties. In spite of these differences, subunit alpha from E. coli and subunit beta from M. luteus form a complex alpha2beta, when incubated together. This complex binds rifampicin tightly, which the isolated subunits do not. The hybrid complex is very similar in its properties to the complex alpha2beta formed only from E. coli or M. luteus subunits. Since the sub-assembly alpha2beta from E. coli is reported to be an obligatory intermediate in the assembly process of complete RNA polymerase, the newly described hybrid sub-assembly may function similarly as an intermediate in the formation of the hybrid form of RNA polymerase described earlier.     

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.     

Molecular analysis of RNA polymerase alpha subunit gene from Streptomyces coelicolor A3(2).

The rpoA gene, encoding the alpha subunit of RNA polymerase, was cloned from Streptomyces coelicolor A3(2). It is preceded by rpsK and followed by rplQ, encoding ribosomal proteins S11 and L17, respectively, similar to the gene order in Bacillus subtilis. The rpoA gene specifies a protein of 339 amino acids with deduced molecular mass of 36,510 Da, exhibiting 64.3 and 70.7% similarity over its entire length to Escherichia coli and B. subtilis alpha subunits, respectively. Using T7 expression system, we overexpressed the S. coelicolor alpha protein in E. coli. A small fraction of this protein was found to be assembled into E. coli RNA polymerase. Antibody against S. coelicolor alpha protein crossreacted with that of B. subtilis more than with the E. coli alpha subunit. The ability of recombinant alpha protein to assemble beta and beta' subunits into core enzyme in vitro was examined by measuring the core enzyme activity. Maximal reconstitution was obtained at alpha2:beta+beta' ratio of 1:2.3, indicating that the recombinant alpha protein is fully functional for subunit assembly. Similar results were also obtained for natural alpha protein. Limited proteolysis with endoproteinase Glu-C revealed that S. coelicolor alpha contains a tightly folded N-terminal domain and the C-terminal region is more protease-sensitive than that of E. coli alpha.     

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.     

Cloning and characterization of RNA polymerase core subunits of Chlamydia trachomatis by using the polymerase chain reaction.

Taking advantage of sequence conservation of portions of the alpha, beta, and beta' subunits of RNA polymerase of bacteria and plant chloroplasts, we have designed degenerate oligonucleotides corresponding to these domains and used these synthetic DNA sequences as primers in a polymerase chain reaction to amplify DNA sequences from the chlamydial genome. The polymerase chain reaction products were used as a probe to recover the genomic fragments encoding the beta subunit and the 5' portion of the beta' subunit from a library of cloned murine Chlamydia trachomatis DNA. Similar attempts to recover the alpha subunit were unsuccessful. Sequence analysis demonstrated that the beta subunit of RNA polymerase was located between genes encoding the L7/L12 ribosomal protein and the beta' subunit of RNA polymerase; this organization is reminiscent of the rpoBC operon of Escherichia coli. The C. trachomatis beta subunit overproduced in E. coli was used as an antigen in rabbits to make a polyclonal antibody to this subunit. Although this polyclonal antibody specifically immunoprecipitated the beta subunit from Chlamydia-infected cells, it did not immunoprecipitate core or holoenzyme. Immunoblots with this antibody demonstrated that the beta subunit appeared early in infection.     

Mutation slowing down the degradation of the beta beta'-subunits of Escherichia coli RNA-polymerase

The rpoC1 ts mutation affecting the RNA polymerase beta' subunit accelerates synthesis of RNA polymerase beta beta' subunits at 42 degrees C, while the surplus amount of subunits degrades in an hour's time. In a Ts strain with two RNA polymerase mutations, rpoC1 and rpoB251, we obtained a ts+ reversion designated opr24 which slows down degradation of surplus beta beta' subunits. The slowing down of degradation and the resulting accumulation of beta beta' subunits does not affect the kinetics of beta beta' subunit synthesis after the transfer to 42 degrees C. The effects of the opr24 are allele non-specific. The mutation also slows down degradation of beta' subunit and the amber fragment of beta subunit in the strain with subunit amber mutation rpoB22. Besides, the opr24 mutation reduces proteolysis of anomalous proteins containing canavanine. The opr24 mutation has been mapped between 17 and 21 minutes on the Escherichia coli map.