Using solutes and kinetics to probe large conformational changes in the steps of transcription initiation

Emily F. Ruff; Wayne S. Kontur; M. Thomas Record

doi:10.1007/978-1-4939-2392-2_14

Using solutes and kinetics to probe large conformational changes in the steps of transcription initiation

Emily F. Ruff, Wayne S. Kontur, M. Thomas Record

Pharmacology

Research output: Chapter in Book/Report/Conference proceeding › Chapter

4 Scopus citations

Abstract

Small solutes are useful probes of large conformational changes in RNA polymerase-promoter interactions and other biopolymer processes. In general, a large effect of a solute on an equilibrium constant (or rate constant) indicates a large change in water-accessible biopolymer surface area in the corresponding step (or transition state), resulting from conformational changes, interface formation, or both. Here, we describe nitrocellulose filter binding assays from series used to determine the urea dependence of open complex formation and dissociation with Escherichia coli RNA polymerase and phage λPR promoter DNA. Then, we describe the subsequent data analysis and interpretation of these solute effects.

Original language	English (US)
Title of host publication	Bacterial Transcriptional Control
Subtitle of host publication	Methods and Protocols
Publisher	Springer New York
Pages	241-261
Number of pages	21
ISBN (Electronic)	9781493923922
ISBN (Print)	9781493923915
DOIs	https://doi.org/10.1007/978-1-4939-2392-2_14
State	Published - Feb 9 2015

Keywords

Conformational changes
Kinetics
Mechanism
Open complex formation
RNA polymerase
Solute effects

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10.1007/978-1-4939-2392-2_14

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abstract = "Small solutes are useful probes of large conformational changes in RNA polymerase-promoter interactions and other biopolymer processes. In general, a large effect of a solute on an equilibrium constant (or rate constant) indicates a large change in water-accessible biopolymer surface area in the corresponding step (or transition state), resulting from conformational changes, interface formation, or both. Here, we describe nitrocellulose filter binding assays from series used to determine the urea dependence of open complex formation and dissociation with Escherichia coli RNA polymerase and phage λPR promoter DNA. Then, we describe the subsequent data analysis and interpretation of these solute effects.",

keywords = "Conformational changes, Kinetics, Mechanism, Open complex formation, RNA polymerase, Solute effects",

author = "Ruff, {Emily F.} and Kontur, {Wayne S.} and {Thomas Record}, M.",

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AU - Ruff, Emily F.

AU - Kontur, Wayne S.

AU - Thomas Record, M.

PY - 2015/2/9

Y1 - 2015/2/9

N2 - Small solutes are useful probes of large conformational changes in RNA polymerase-promoter interactions and other biopolymer processes. In general, a large effect of a solute on an equilibrium constant (or rate constant) indicates a large change in water-accessible biopolymer surface area in the corresponding step (or transition state), resulting from conformational changes, interface formation, or both. Here, we describe nitrocellulose filter binding assays from series used to determine the urea dependence of open complex formation and dissociation with Escherichia coli RNA polymerase and phage λPR promoter DNA. Then, we describe the subsequent data analysis and interpretation of these solute effects.

AB - Small solutes are useful probes of large conformational changes in RNA polymerase-promoter interactions and other biopolymer processes. In general, a large effect of a solute on an equilibrium constant (or rate constant) indicates a large change in water-accessible biopolymer surface area in the corresponding step (or transition state), resulting from conformational changes, interface formation, or both. Here, we describe nitrocellulose filter binding assays from series used to determine the urea dependence of open complex formation and dissociation with Escherichia coli RNA polymerase and phage λPR promoter DNA. Then, we describe the subsequent data analysis and interpretation of these solute effects.

KW - Conformational changes

KW - Kinetics

KW - Mechanism

KW - Open complex formation

KW - RNA polymerase

KW - Solute effects

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SN - 9781493923915

SP - 241

EP - 261

BT - Bacterial Transcriptional Control

PB - Springer New York

ER -

Using solutes and kinetics to probe large conformational changes in the steps of transcription initiation

Abstract

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