The structural basis for terminator recognition by the Rho transcription termination factor

Cynthia E. Bogden; Deborah Fass; Nick Bergman; Matthew D. Nichols; James M. Berger

doi:10.1016/S1097-2765(00)80476-1

The structural basis for terminator recognition by the Rho transcription termination factor

Cynthia E. Bogden, Deborah Fass, Nick Bergman, Matthew D. Nichols, James M. Berger

Research output: Contribution to journal › Article › peer-review

100 Scopus citations

Abstract

The E. coli Rho protein disengages newly transcribed RNA from its DNA template, helping terminate certain transcripts. We have determined the X- ray crystal structure of the RNA-binding domain of Rho complexed to an RNA ligand. Filters that screen both ligand size and chemical functionality line the primary nucleic acid-binding site, imparting sequence specificity to a generic single-stranded nucleic acid-binding fold and explaining the preference of Rho for cytosine-rich RNA. The crystal packing reveals two Rho domain protomers bound to a single RNA with a single base spacer, suggesting that the strong RNA-binding sites of Rho may arise from pairing of RNA- binding modules. Dimerization of symmetric subunits on an asymmetric ligand is developed as a model for allosteric control in the action of the intact Rho hexamer.

Original language	English (US)
Pages (from-to)	487-493
Number of pages	7
Journal	Molecular cell
Volume	3
Issue number	4
DOIs	https://doi.org/10.1016/S1097-2765(00)80476-1
State	Published - Apr 1999
Externally published	Yes

ASJC Scopus subject areas

Molecular Biology
Cell Biology

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10.1016/S1097-2765(00)80476-1

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title = "The structural basis for terminator recognition by the Rho transcription termination factor",

abstract = "The E. coli Rho protein disengages newly transcribed RNA from its DNA template, helping terminate certain transcripts. We have determined the X- ray crystal structure of the RNA-binding domain of Rho complexed to an RNA ligand. Filters that screen both ligand size and chemical functionality line the primary nucleic acid-binding site, imparting sequence specificity to a generic single-stranded nucleic acid-binding fold and explaining the preference of Rho for cytosine-rich RNA. The crystal packing reveals two Rho domain protomers bound to a single RNA with a single base spacer, suggesting that the strong RNA-binding sites of Rho may arise from pairing of RNA- binding modules. Dimerization of symmetric subunits on an asymmetric ligand is developed as a model for allosteric control in the action of the intact Rho hexamer.",

author = "Bogden, {Cynthia E.} and Deborah Fass and Nick Bergman and Nichols, {Matthew D.} and Berger, {James M.}",

note = "Funding Information: The authors would like to thank David Bartel and members of his lab for technical assistance with RNA preparation, Richard Calendar for critical reading of the manuscript, Craig Ogata and the Brookhaven X4A beamline staff for assistance collecting data from the Rho13N:rC 9 complex, and the Harold Y. and Leila G. Mathers Charitable Foundation, Whitehead Institute, and Berkeley MCB department for financial support. ",

year = "1999",

month = apr,

doi = "10.1016/S1097-2765(00)80476-1",

language = "English (US)",

volume = "3",

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journal = "Molecular cell",

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publisher = "Cell Press",

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T1 - The structural basis for terminator recognition by the Rho transcription termination factor

AU - Bogden, Cynthia E.

AU - Fass, Deborah

AU - Bergman, Nick

AU - Nichols, Matthew D.

AU - Berger, James M.

N1 - Funding Information: The authors would like to thank David Bartel and members of his lab for technical assistance with RNA preparation, Richard Calendar for critical reading of the manuscript, Craig Ogata and the Brookhaven X4A beamline staff for assistance collecting data from the Rho13N:rC 9 complex, and the Harold Y. and Leila G. Mathers Charitable Foundation, Whitehead Institute, and Berkeley MCB department for financial support.

PY - 1999/4

Y1 - 1999/4

N2 - The E. coli Rho protein disengages newly transcribed RNA from its DNA template, helping terminate certain transcripts. We have determined the X- ray crystal structure of the RNA-binding domain of Rho complexed to an RNA ligand. Filters that screen both ligand size and chemical functionality line the primary nucleic acid-binding site, imparting sequence specificity to a generic single-stranded nucleic acid-binding fold and explaining the preference of Rho for cytosine-rich RNA. The crystal packing reveals two Rho domain protomers bound to a single RNA with a single base spacer, suggesting that the strong RNA-binding sites of Rho may arise from pairing of RNA- binding modules. Dimerization of symmetric subunits on an asymmetric ligand is developed as a model for allosteric control in the action of the intact Rho hexamer.

AB - The E. coli Rho protein disengages newly transcribed RNA from its DNA template, helping terminate certain transcripts. We have determined the X- ray crystal structure of the RNA-binding domain of Rho complexed to an RNA ligand. Filters that screen both ligand size and chemical functionality line the primary nucleic acid-binding site, imparting sequence specificity to a generic single-stranded nucleic acid-binding fold and explaining the preference of Rho for cytosine-rich RNA. The crystal packing reveals two Rho domain protomers bound to a single RNA with a single base spacer, suggesting that the strong RNA-binding sites of Rho may arise from pairing of RNA- binding modules. Dimerization of symmetric subunits on an asymmetric ligand is developed as a model for allosteric control in the action of the intact Rho hexamer.

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DO - 10.1016/S1097-2765(00)80476-1

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VL - 3

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JO - Molecular cell

JF - Molecular cell

IS - 4

ER -

The structural basis for terminator recognition by the Rho transcription termination factor

Abstract

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