Dimeric Association of Escherichia coli RNA Polymerase α Subunits, Studied by Cleavage of Single-Cysteine α Subunits Conjugated to Iron−(S)-1-[p-(Bromoacetamido)benzyl]ethylenediaminetetraacetate

Miyake, Reiko; Murakami, Katsuhiko; Owens, Jeffrey T.; Greiner, Douglas P.; Ozoline, Olga N.; Ishihama, A; Meares, Claude F.

doi:10.1021/bi9723313

Cited by 29 publications

(28 citation statements)

References 35 publications

(51 reference statements)

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“…Important biochemical and biophysical approaches for analysis of RNA polymerase (RNAP) structure and function--including affinity cleaving (1,2), photocrosslinking (3,4), and ensemble and single-molecule fluorescence resonance energy transfer (5–16)--require the ability to incorporate probes at specific sites within RNAP.…”

Section: Introductionmentioning

confidence: 99%

“…One approach to introduce a probe at a specific site within a protein is to perform site-directed mutagenesis to introduce a unique Cys residue at the site of interest followed by Cys-specific chemical modification to introduce the probe at the site of interest (1–17). This approach can be used to incorporate probes at any non-essential, solvent-accessible residue of Escherichia coli RNAP ω subunit (11), E. coli RNAP α subunit (after use of site-directed mutagenesis to substitute the pre-existing Cys residues at positions 54, 131, 176, and 269; 1), and E. coli transcription initiation factor σ 70 (after use of site-directed mutagenesis to substitute the pre-existing Cys residues at positions 132, 291, and 295; 2, 5–16).…”

Section: Introductionmentioning

confidence: 99%

“…This approach can be used to incorporate probes at any non-essential, solvent-accessible residue of Escherichia coli RNAP ω subunit (11), E. coli RNAP α subunit (after use of site-directed mutagenesis to substitute the pre-existing Cys residues at positions 54, 131, 176, and 269; 1), and E. coli transcription initiation factor σ 70 (after use of site-directed mutagenesis to substitute the pre-existing Cys residues at positions 132, 291, and 295; 2, 5–16). The resulting probe-containing ω and α derivatives enable preparation of probe-containing RNAP derivatives by in vitro reconstitution of RNAP (1,11; see 19–23), and the resulting probe-containing σ 70 derivatives enable preparation of probe-containing RNAP holoenzyme derivatives by addition to RNAP core (2, 5–16). However, this approach cannot be used to incorporate probes into the second-largest and largest RNAP subunits, β and β', since these very large polypeptides (1342 residues for E. coli β; 1407 residues for E. coli β') contain multiple pre-existing Cys residues that are essential and that therefore cannot be substituted without loss of function.…”

Section: Introductionmentioning

confidence: 99%

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Site-Specific Incorporation of Probes into RNA Polymerase by Unnatural-Amino-Acid Mutagenesis and Staudinger–Bertozzi Ligation

Chakraborty

Mazumder

Lin

et al. 2015

Methods in Molecular Biology

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Summary A three-step procedure comprising (i) unnatural-amino-acid mutagenesis with 4-azido-phenylalanine, (ii) Staudinger-Bertozzi ligation with a probe-phosphine derivative, and (iii) in vitro reconstitution of RNA polymerase (RNAP) enables the efficient site-specific incorporation of a fluorescent probe, a spin label, a crosslinking agent, a cleaving agent, an affinity tag, or any other biochemical or biophysical probe, at any site of interest in RNAP. Straightforward extensions of the procedure enable the efficient site-specific incorporation of two or more different probes in two or more different subunits of RNAP. We present protocols for synthesis of probe-phosphine derivatives, preparation of RNAP subunits and the transcription initiation factor σ, unnatural amino acid mutagenesis of RNAP subunits and σ, Staudinger ligation with unnatural-amino-acid-containing RNAP subunits and σ, quantitation of labelling efficiency and labelling specificity, and reconstitution of RNAP.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Site-Specific Incorporation of Probes into RNA Polymerase by Unnatural-Amino-Acid Mutagenesis and Staudinger–Bertozzi Ligation

Chakraborty

Mazumder

Lin

et al. 2015

Methods in Molecular Biology

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“…It is quite conceivable that long-range secondary interaction, in addition to primary contacts, in¯uences subunit assembly signi®cantly. In order to probe the primary contact sites between interacting proteins, many approaches, including crosslinking (Hillel and Wu 1977;Chen et al 1994;McMahan and Burgess 1994;Lee and Hoover 1995), protein footprinting (Heyduk and Heyduk 1994;Nagai and Shimamoto 1997), complex formation between subunits or subunit fragments Ishihama 1995a, 1995b;Nomura et al 1998) and chemical proteolysis (Greiner et al 1996;Owens et al 1998;Miyake et al 1998) have been used. On the other hand, protein-protein contact domains can also be studied by means of genetic suppression (reviewed by Hartman and Roth 1973;Perlich 1999).The rationale for this approach is that a mutant derivative which has lost its original function can regain the wildtype phenotype as the result of a second mutation.…”

Section: Introductionmentioning

confidence: 99%

Functional complementation between mutations at two distant positions in Escherichia coli RNA polymerase as revealed by second-site suppression

2001

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Subunit-subunit interactions are critical for the assembly of the core of Escherichia coli RNA polymerase. The mutant a-subunit C131A is unable to complement the temperature-sensitive a-R45C mutant strain, which is defective for binding of the b-subunit. In vitro reconstitution experiments, however, indicate that the a-C131A variant is able to form the intermediate a 2 b, but is defective in contacting the b¢-subunit. We used this a-C131A mutant to isolate a suppressor mutation in the b¢-subunit. Genetic and biochemical characterization of the b¢ suppressor indicates the allelespeci®c nature of its eect. Sequence analysis of the suppressor revealed a single substitution of Gly at position 333, an evolutionarily conserved position in the conserved region C of the b¢-subunit, by Asp. However, the crystal structure of the bacterial RNA polymerase indicates that the primary mutation (a-C131A) and its suppressor lie far apart. Thus, we propose that longrange interactions, as in this case, may play an important role in the functional assembly of E. coli RNA polymerase.

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“…The NMR structure has been determined for the ␣ COOH-terminal domain (8); the structure of the ␣ NH 2 -terminal domain was determined by x-ray crystallography (9), and the two domains are connected by a long flexible linker (10). Detailed mapping of the ␣-␣, ␣-␤, and ␣-␤Ј contact sites on the ␣ subunit have been carried out by making a number of contact-defective ␣ mutants with deletion, insertion, and Ala substitution mutations (11)(12)(13)(14) or by mapping the cleavage sites in ␣ by a chemical protease conjugated at various positions of the ␣ subunit (15).…”

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confidence: 99%

Mapping of Subunit-Subunit Contact Surfaces on the β′ Subunit of Escherichia coli RNA Polymerase

Katayama

Fujita

Ishihama

2000

Journal of Biological Chemistry

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The RNA polymerase core enzyme of Escherichia coli with the catalytic activity of RNA polymerization is assembled sequentially under the order: 2␣ 3 ␣ 2 3 ␣ 2 ␤ 3 ␣ 2 ␤␤. The core enzyme gains the activities of promoter recognition and transcription initiation after binding the subunit. The subunit-subunit contact surfaces of ␤ subunit (1407 residues) were analyzed by testing complex formation between various ␤ fragments and either the ␣ 2 ␤ complex or the 70 The RNA polymerase holoenzyme of Escherichia coli is composed of the core enzyme with the subunit composition of ␣ 2 ␤␤Ј and one of seven different species of the subunit (for review, see Ref. 1). The core enzyme carries the catalytic activities for RNA polymerization, but the subunit is required for promoter recognition and transcription initiation from the promoters. The core enzyme is assembled sequentially both in vitro and in vivo under the order: 2␣ 3 ␣ 2 3 ␣ 2 ␤ 3 ␣ 2 ␤␤Ј (premature core) 3 E (active core) (for review, see Ref. 2).Genetic and biochemical studies indicated that the subunitsubunit contact sites on ␣ including the sites for ␣ dimerization and the contact sites with the ␤ and ␤Ј subunits are all located within the amino (NH 2 )-terminal domain down to residue 235 (3-5), whereas the carboxyl (COOH)-terminal domain is involved in transcription regulation through direct interactions with class I (or ␣ contact) transcription factors and DNA UP elements (1, 5-7). The NMR structure has been determined for the ␣ COOH-terminal domain (8); the structure of the ␣ NH 2 -terminal domain was determined by x-ray crystallography (9), and the two domains are connected by a long flexible linker (10). Detailed mapping of the ␣-␣, ␣-␤, and ␣-␤Ј contact sites on the ␣ subunit have been carried out by making a number of contact-defective ␣ mutants with deletion, insertion, and Ala substitution mutations (11)(12)(13)(14) or by mapping the cleavage sites in ␣ by a chemical protease conjugated at various positions of the ␣ subunit (15).On the contrary, relatively little is known on the subunitsubunit contact sites on the two large subunits, ␤ and ␤Ј. The mapping of ␣ subunit contact sites on the ␤ subunit was carried out using two approaches: analysis of the proteolytic cleavage pattern of the unassembled free ␤ subunit and the intermediate subassembly ␣ 2 ␤ complex (16, 17), and analysis of complex formation between various ␤ fragments and the hexahistidine (His 6 )-tagged ␣ subunit or between various His 6 -tagged ␤ fragments and the intact ␣ subunit (17). The results altogether indicate that the primary and tight contact site of the ␣ subunit is located in the central portion of the ␤ polypeptide (16, 17); but in addition, the COOH-terminal proximal region is needed as the secondary and probable regulatory site for either efficient binding of the ␣ subunit or stabilization of ␣-␤ contact (17). All of the ␤ fragment-␣ binary complexes isolated were able to bind the ␤Ј subunit, leading to formation of pseudo-core complexes, suggesting that the ␤Ј subunit con...

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Dimeric Association of Escherichia coli RNA Polymerase α Subunits, Studied by Cleavage of Single-Cysteine α Subunits Conjugated to Iron−(S)-1-[p-(Bromoacetamido)benzyl]ethylenediaminetetraacetate

Cited by 29 publications

References 35 publications

Site-Specific Incorporation of Probes into RNA Polymerase by Unnatural-Amino-Acid Mutagenesis and Staudinger–Bertozzi Ligation

Site-Specific Incorporation of Probes into RNA Polymerase by Unnatural-Amino-Acid Mutagenesis and Staudinger–Bertozzi Ligation

Functional complementation between mutations at two distant positions in Escherichia coli RNA polymerase as revealed by second-site suppression

Mapping of Subunit-Subunit Contact Surfaces on the β′ Subunit of Escherichia coli RNA Polymerase

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