Literature DB >> 14602898

A DNA translocation motif in the bacterial transcription--repair coupling factor, Mfd.

A L Chambers1, A J Smith, N J Savery.   

Abstract

The bacterial transcription-repair coupling factor, Mfd, is a superfamily II helicase that releases transcription elongation complexes stalled by DNA damage or other obstacles. Transcription complex displacement is an ATP-dependent reaction that is thought to involve DNA translocation without the strand separation associated with classical helicase activity. We have identified single amino acid substitutions within Mfd that disrupt the ability of Mfd to displace RNA polymerase but do not prevent ATP hydrolysis or binding to DNA. These substitutions, or deletion of the C-terminal 209 residues of Mfd, abrogate the ability of Mfd to increase the efficiency of roadblock repression in vivo. The substitutions fall in a region of Mfd that is homologous to the 'TRG' motif of RecG, a protein that catalyses ATP-dependent translocation of Holliday junctions. Our results define a translocation motif in Mfd and suggest that Mfd and RecG couple ATP hydrolysis to translocation of DNA in a similar manner.

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Year:  2003        PMID: 14602898      PMCID: PMC275562          DOI: 10.1093/nar/gkg868

Source DB:  PubMed          Journal:  Nucleic Acids Res        ISSN: 0305-1048            Impact factor:   16.971


  33 in total

1.  Repression of lac promoter as a function of distance, phase and quality of an auxiliary lac operator.

Authors:  J Müller; S Oehler; B Müller-Hill
Journal:  J Mol Biol       Date:  1996-03-22       Impact factor: 5.469

2.  High resolution mapping of E.coli transcription elongation complex in situ reveals protein interactions with the non-transcribed strand.

Authors:  M Guérin; M Leng; A R Rahmouni
Journal:  EMBO J       Date:  1996-10-01       Impact factor: 11.598

3.  Transcript cleavage factors from E. coli.

Authors:  S Borukhov; V Sagitov; A Goldfarb
Journal:  Cell       Date:  1993-02-12       Impact factor: 41.582

4.  Molecular mechanism of transcription-repair coupling.

Authors:  C P Selby; A Sancar
Journal:  Science       Date:  1993-04-02       Impact factor: 47.728

Review 5.  Transcription-repair coupling and mutation frequency decline.

Authors:  C P Selby; A Sancar
Journal:  J Bacteriol       Date:  1993-12       Impact factor: 3.490

6.  Thermal energy requirement for strand separation during transcription initiation: the effect of supercoiling and extended protein DNA contacts.

Authors:  H Burns; S Minchin
Journal:  Nucleic Acids Res       Date:  1994-09-25       Impact factor: 16.971

7.  Transcription-repair coupling factor is involved in carbon catabolite repression of the Bacillus subtilis hut and gnt operons.

Authors:  J M Zalieckas; L V Wray; A E Ferson; S H Fisher
Journal:  Mol Microbiol       Date:  1998-03       Impact factor: 3.501

8.  Structure and function of transcription-repair coupling factor. II. Catalytic properties.

Authors:  C P Selby; A Sancar
Journal:  J Biol Chem       Date:  1995-03-03       Impact factor: 5.157

9.  Structure and function of transcription-repair coupling factor. I. Structural domains and binding properties.

Authors:  C P Selby; A Sancar
Journal:  J Biol Chem       Date:  1995-03-03       Impact factor: 5.157

10.  Analysis of Bacillus subtilis hut operon expression indicates that histidine-dependent induction is mediated primarily by transcriptional antitermination and that amino acid repression is mediated by two mechanisms: regulation of transcription initiation and inhibition of histidine transport.

Authors:  L V Wray; S H Fisher
Journal:  J Bacteriol       Date:  1994-09       Impact factor: 3.490
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  35 in total

1.  Effects on growth by changes of the balance between GreA, GreB, and DksA suggest mutual competition and functional redundancy in Escherichia coli.

Authors:  Daniel Vinella; Katarzyna Potrykus; Helen Murphy; Michael Cashel
Journal:  J Bacteriol       Date:  2011-11-04       Impact factor: 3.490

2.  Importance of the tmRNA system for cell survival when transcription is blocked by DNA-protein cross-links.

Authors:  H Kenny Kuo; Rachel Krasich; Ashok S Bhagwat; Kenneth N Kreuzer
Journal:  Mol Microbiol       Date:  2010-09-16       Impact factor: 3.501

Review 3.  What happens when replication and transcription complexes collide?

Authors:  Richard T Pomerantz; Mike O'Donnell
Journal:  Cell Cycle       Date:  2010-07-01       Impact factor: 4.534

Review 4.  RNA polymerase between lesion bypass and DNA repair.

Authors:  Alexandra M Deaconescu
Journal:  Cell Mol Life Sci       Date:  2013-06-27       Impact factor: 9.261

5.  Derepression of bacterial transcription-repair coupling factor is associated with a profound conformational change.

Authors:  Devendra B Srivastava; Seth A Darst
Journal:  J Mol Biol       Date:  2010-12-23       Impact factor: 5.469

6.  Role of DNA bubble rewinding in enzymatic transcription termination.

Authors:  Joo-Seop Park; Jeffrey W Roberts
Journal:  Proc Natl Acad Sci U S A       Date:  2006-03-21       Impact factor: 11.205

Review 7.  RNA polymerase elongation factors.

Authors:  Jeffrey W Roberts; Smita Shankar; Joshua J Filter
Journal:  Annu Rev Microbiol       Date:  2008       Impact factor: 15.500

8.  Mfd is required for rapid recovery of transcription following UV-induced DNA damage but not oxidative DNA damage in Escherichia coli.

Authors:  Brandy J Schalow; Charmain T Courcelle; Justin Courcelle
Journal:  J Bacteriol       Date:  2012-03-16       Impact factor: 3.490

Review 9.  Transcription of Bacterial Chromatin.

Authors:  Beth A Shen; Robert Landick
Journal:  J Mol Biol       Date:  2019-05-31       Impact factor: 5.469

10.  An N-terminal clamp restrains the motor domains of the bacterial transcription-repair coupling factor Mfd.

Authors:  Michael N Murphy; Peng Gong; Kenneth Ralto; Laura Manelyte; Nigel J Savery; Karsten Theis
Journal:  Nucleic Acids Res       Date:  2009-08-21       Impact factor: 16.971
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