Mapping of trypsin cleavage and antibody-binding sites and delineation of a dispensable domain in the beta subunit of Escherichia coli RNA polymerase.

We have mapped principal sites in the Escherichia coli RNA polymerase molecule that are exposed to attack by trypsin under limited proteolysis conditions. The 1342-amino acid-long beta subunit is alternatively cleaved at Arg903 or Lys909. The cleavage occurs adjacent to a dispensable domain (residues 940-1040) that is absent in the homologous RNA polymerase subunits from chloroplasts, eukaryotes, and archaebacteria. In E. coli, this region can be disrupted with genetic deletions and insertions without the loss of RNA polymerase function. Insertion of 127 amino acids into this region introduces a new highly labile site for trypsin proteolysis. The dispensable domain carries the epitope for monoclonal antibody PYN-6 (near residue 1000), which can be used for anchoring the catalytically active enzyme on a solid support. We also report the identification of a secondary trypsin cleavage at Arg81 of the beta' subunit within a putative zinc-binding domain that is conserved in prokaryotes and chloroplasts.     

Characterization and epitope mapping of monoclonal antibodies directed against the beta' subunit of the Escherichia coli RNA polymerase.

Monoclonal antibodies (mAbs) raised against the beta' subunit of the Escherichia coli RNA polymerase were used to probe the structure and function of this subunit. Of the five anti-beta' monoclonal antibodies studied, only mAb 311G2 is a strong inhibitor of RNA polymerase activity. This antibody binds to an epitope which is exposed in both the assembled holoenzyme and isolated beta' subunit. In contrast, the null antibodies bind to the free beta' subunit but very weakly to native RNA polymerase. It would appear that the beta' domain in which their epitopes reside is either conformationally altered or blocked due to interaction with other subunits in native RNA polymerase. In order to locate the positions of the epitopes for these five monoclonal antibodies, a series of overlapping deletion mutants have been constructed by partial restriction and religation of the beta' gene present in pT7 beta' (Zalenskaya, K., Lee, J., Gujuluva, C. N., Shin, Y. K., Slutsky, M., nd Goldfarb, A. (1990) Gene 89, 7-12). The presence of the epitopes for each of the anti-beta' monoclonal antibodies was assessed by Western blotting. The results indicate that the epitopes for mAb 340F11, mAb 370F3, mAb 371D6, and mAb 372B2 are located between amino acids 817-876. This region may be important in enzyme assembly or subunit-subunit interaction. The epitope for the inhibitory antibody, mAb 311G2, is located between amino acids 1047-1093. This region may be involved in the catalytic function of RNA polymerase.     

The nature of the catalytic domain of 2'-5'-oligoadenylate synthetases.

2'-5'-Oligoadenylate (2-5(A)) synthetases are a family of interferon-induced enzymes that are activated by double-stranded RNA. To understand why, unlike other DNA and RNA polymerases, they catalyze 2'-5' instead of 3'-5' phosphodiester bond formation, we used molecular modeling to compare the structure of the catalytic domain of DNA polymerase beta (pol beta) to that of a region of the P69 isozyme of 2-5(A) synthetase. Although the primary sequence identity is low, like pol beta, P69 can assume an alphabetabetaalphabetabetabeta structure in this region. Moreover, mutation of the three Asp residues of P69, which correspond to the three catalytic site Asp residues of pol beta, inactivated the enzyme without affecting its substrate and activator binding capacity, providing further credence to the concept that this region is the catalytic domain of P69. This domain is highly conserved among all 2-5(A) synthetase isozymes. Biochemical and mutational studies demonstrated that dimerization of the P69 protein is required for its enzyme activity. However, a dimer containing a wild type subunit and an inactive catalytic domain mutant subunit was also active. The rate of catalysis of the heterodimer was half of that of the wild type homodimer, although the two proteins bound double-stranded RNA and ATP equally well.     

Mapping protein-protein interactions with a library of tethered cutting reagents: the binding site of sigma 70 on Escherichia coli RNA polymerase

Surface-exposed lysine amino groups and other reactive nucleophiles of the sigma 70 protein were conjugated with the cutting reagent iron (S)-1-[p-(bromoacetamido)benzyl]ethylenediaminetetraacetate (FeBABE) via 2-iminothiolane (2IT) with low efficiency. The result is a library of sigma 70 conjugates, with an average of 1-2 cutting reagents tethered to any of a variety of sites (lysine, cysteine, etc.) on the surface of the protein. Model calculations indicate that the conjugates in this library should be capable of cutting nearby sites on the backbone of almost any protein or nucleic acid to which sigma 70 binds. Since cutting occurs only when the protein is bound, the cleaved sites indicate proximity; since only proximal sites are cleaved, interpretation of the results is straightforward. We used this library to map the periphery of the binding site on the core enzyme (alpha 2 beta beta') of Escherichia coli RNA polymerase. The beta subunit was cut primarily within its conserved regions C, D, Rif I, and G; additional sites were also cut between A and B and near conserved regions E and H. The cut sites within the beta' subunit were intensely clustered between residues 250-450, which include its conserved regions C and D, along with two additional cut sites in conserved regions A and G. No cut sites on the alpha subunit were observed. These results recapitulate and extend those obtained using FeBABE conjugates of seven strategically placed single-Cys sigma 70 mutants [Owens, J. T., Miyake, R., Murakami, K., Chmura, A. J., Fujita, N., Ishihama, A., and Meares, C. F. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 6021-6026]. This technique provides a straightforward, general approach to mapping protein interactions without mutagenesis.     

The structure of the zinc sites of Escherichia coli DNA-dependent RNA polymerase.

X-ray absorption spectroscopy is ideally suited for the investigation of the electronic structure and the local environment (approximately 5 A) of specific atoms in biomolecules. While the edge region provides information about the valence state of the absorbing atom, the chemical identity of neighboring atoms, and the coordination geometry, the extended x-ray absorption fine structure region contains information about the number and average distance of neighboring atoms and their relative disorder. The development of sensitive detection methods has allowed studies using near physiological concentrations (as low as approximately 100 microM). RNA polymerase from Escherichia coli contains two zinc atoms: one tightly bound in the beta' subunit, the subunit that participates in template binding, and the other loosely bound in the beta subunit, the subunit that participates in substrate binding. X-ray absorption studies of these zinc sites in the native protein and of the zinc site in the beta' subunit after removal of the zinc in the beta subunit site by p-(hydroxymercuri)benzenesulfonate (Giedroc, D. P., and Coleman, J. E. (1986) Biochemistry 25, 4969-4978) indicate that both zinc sites have octahedral coordination. The zinc in the beta' subunit site has four sulfur ligands at an average distance of 2.36 +/- 0.02 A and two oxygen (or nitrogen) ligands at an average distance of 2.23 +/- 0.02 A. The beta subunit zinc site has five sulfur ligands at an average distance of 2.38 +/- 0.01 A and one histidine nitrogen ligand at 2.14 +/- 0.02 A. These results are in general agreement with earlier biochemical and spectroscopic studies.     

The beta subunit of the Escherichia coli DNA polymerase III holoenzyme interacts functionally with the catalytic core in the absence of other subunits

We have previously demonstrated that the addition of a stoichiometric excess of the beta subunit of Escherichia coli DNA polymerase III holoenzyme to DNA polymerase III or holoenzyme itself can lead to an ATP-independent increase in the processivity of these enzyme forms (Crute, J. J., LaDuca, R. J., Johanson, K. O., McHenry, C. S., and Bambara, R. A. (1983) J. Biol. Chem. 258, 11344-11349). Here, we show that the beta subunit can interact directly with the catalytic core of the holoenzyme, DNA polymerase III, generating a new form of the enzyme with enhanced catalytic and processive capabilities. The addition of saturating levels of the beta subunit to the core DNA polymerase III enzyme results in as much as a 7-fold stimulation of synthetic activity. Two populations of DNA products were generated by the DNA polymerase III X beta enzyme complex. Short products resulting from the addition of 5-10 nucleotides/primer fragment were generated by DNA polymerase III in the presence and absence of added beta subunit. A second population of much longer products was generated only in beta-supplemented DNA polymerase III reactions. The DNA polymerase III-beta reaction was inhibited by single-stranded DNA binding protein and was unaffected by ATP, distinguishing it from the holoenzyme-catalyzed reaction. Complex formation of the DNA polymerase III core enzyme with beta increased the residence time of the enzyme on synthetic DNA templates. Our results demonstrate that the beta stimulation of DNA polymerase III can be attributed to a more efficient and highly processive elongation capability of the DNA polymerase III X beta complex. They also prove that at least part of beta's normal contribution to the DNA polymerase III holoenzyme reaction takes place through interaction with DNA polymerase III core enzyme components to produce the essential complex necessary for efficient elongation in vivo.     

Studies of the functional topography of Escherichia coli RNA polymerase. Affinity labelling of RNA polymerase in a promoter complex by phosphorylating derivatives of primer oligonucleotides

Amidation of the 5'-phosphate group of the heptanucleotide pdApdApdApdTpdCpdGprC and of its derivatives of the general formula (pdN)npdGprC (n = 0-5) with imidazole, N-methylimidazole, and 4-dimethylaminopyridine afforded a series of phosphorylating affinity reagents. The parent oligonucleotides of this series complementary to promoter A2 of T7 phage over the region (-5 to +2) are known to be efficient primers of the synthesis of RNA by Escherichia coli RNA polymerase with promoter A2 as template. Treatment of the complex RNA-polymerase X promoter-A2 with affinity reagents followed by addition of [alpha-32P]UTP resulted in labelling of RNA polymerase by the residues -(pdN)npdGprCprU (p = radioactive phosphate). This affinity labelling was highly selective because elongation of the covalently bound residues (pdN)npdGprC by prU residues was catalyzed by the active center of RNA polymerase. The most efficient reagents were N-methylimidazolides. A dramatic change of the pattern of labelling of the subunits beta, beta', and sigma took place with changing n. Maximum labelling of the beta subunit occurred at n = 1 and of the sigma subunit at n = 5. The targets in both the subunits were His residues. The alpha subunit was not specifically labelled.     

Autogenous regulation of RNA polymerase beta subunit synthesis in vitro.

The effects of Escherichia coli RNA polymerase and its subassemblies and subunits on the in vitro synthesis of beta subunit directed by DNA from a lambda transducing phage lambdadrif+-6 were investigated. This phage carries the structural gene (rpoB) for beta subunit as well as the genes for EF (translation elongation factor)-Tu, some ribosomal proteins, and stable RNAs of the E. coli chromosome. Among the RNA polymerase proteins examined, the two oligomers, holoenzyme and alpha2beta complex, repressed the synthesis of only the beta subunit but not of other proteins encoded by the phage DNA. The results indicate that the expression of at least the betabeta' (rpoBC) operon is under autogenous regulation, in which both holoenzyme and alpha2beta complex function as regulatory molecules with repressor activity.     

Subunit interaction and regulation of activity through terminal domains of the family D DNA polymerase from Pyrococcus horikoshii

Functions of the terminal domains of the family D DNA polymerase from Pyrococcus horikoshii (PolDPho) were analyzed by making and characterizing various truncated proteins. Based on a co-expression vector developed previously (Shen, Y., Musti, K., Hiramoto, M., Kikuchi, H., Kawabayashi, Y., and Matsui, I. (2001) J. Biol. Chem. 276, 27376-27383), 25 vectors for terminal truncated proteins were constructed. The expressed proteins were characterized in terms of thermostability, subunit interaction, and polymerization and 3'-5' exonuclease activities. The carboxyl-terminal (1255-1332) of the large subunit (DP2Pho) and two regions, the 201-260 and 599-622, of the small subunit (DP1Pho) were found to be critical for the complex formation, and probable subunit interaction of PolDPho. The amino-terminal (1-300) of DP2Pho is essential for the folding of PolDPho and is likely the oligomerization domain of PolDPho. A short region at the extreme C-terminal of DP2Pho (from 1385 to 1434) and the N-terminal of DP1Pho(1-200), which forms a stable protein, are not absolutely necessary for either polymerization or the 3'-5' exonuclease activity. We identified a possible regulatory role of DP1Pho(1-200) for the 3'-5' exonuclease. Deletion of DP1Pho(1-200) increased the exonuclease and DNA binding activities of PolDPho. Adding DP1Pho(1-200) to the truncated protein suppressed the elevated exonuclease activity. We also constructed and analyzed three internal deletion mutants and two site-directed mutants in the region of the putative zinc finger motif (cysteine cluster II) of DP2Pho at the COOH-terminal. We found that the internal region of the zinc finger motif is critical for the 3'-5' exonuclease, but is dispensable for the DNA polymerization.