Literature DB >> 21857106

Analysis of phage Mu DNA transposition by whole-genome Escherichia coli tiling arrays reveals a complex relationship to distribution of target selection protein B, transcription and chromosome architectural elements.

Jun Ge1, Zheng Lou, Hong Cui, Lei Shang, Rasika M Harshey.   

Abstract

Of all known transposable elements, phage Mu exhibits the highest transposition efficiency and the lowest target specificity. In vitro, MuB protein is responsible for target choice. In this work, we provide a comprehensive assessment of the genome-wide distribution of MuB and its relationship to Mu target selection using high-resolution Escherichia coli tiling DNA arrays. We have also assessed how MuB binding and Mu transposition are influenced by chromosome-organizing elements such as AT-rich DNA signatures, or the binding of the nucleoid-associated protein Fis, or processes such as transcription. The results confirm and extend previous biochemical and lower resolution in vivo data. Despite the generally random nature of Mu transposition and MuB binding, there were hot and cold insertion sites and MuB binding sites in the genome, and differences between the hottest and coldest sites were large. The new data also suggest that MuB distribution and subsequent Mu integration is responsive to DNA sequences that contribute to the structural organization of the chromosome.

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Year:  2011        PMID: 21857106      PMCID: PMC3712764          DOI: 10.1007/s12038-011-9108-z

Source DB:  PubMed          Journal:  J Biosci        ISSN: 0250-5991            Impact factor:   1.826


  52 in total

1.  Genome-wide location and function of DNA binding proteins.

Authors:  B Ren; F Robert; J J Wyrick; O Aparicio; E G Jennings; I Simon; J Zeitlinger; J Schreiber; N Hannett; E Kanin; T L Volkert; C J Wilson; S P Bell; R A Young
Journal:  Science       Date:  2000-12-22       Impact factor: 47.728

Review 2.  Mechanisms of separation of the complementary strands of DNA during replication.

Authors:  A I Alexandrov; N R Cozzarelli; V F Holmes; A B Khodursky; B J Peter; L Postow; V Rybenkov; A V Vologodskii
Journal:  Genetica       Date:  1999       Impact factor: 1.082

3.  DNA transposition of bacteriophage Mu. A quantitative analysis of target site selection in vitro.

Authors:  Saija Haapa-Paananen; Hannu Rita; Harri Savilahti
Journal:  J Biol Chem       Date:  2001-11-07       Impact factor: 5.157

Review 4.  Regulation of gene expression by histone-like proteins in bacteria.

Authors:  Charles J Dorman; Padraig Deighan
Journal:  Curr Opin Genet Dev       Date:  2003-04       Impact factor: 5.578

5.  Influence of insertions on packaging of host sequences covalently linked to bacteriophage Mu DNA.

Authors:  A I Bukhari; A L Taylor
Journal:  Proc Natl Acad Sci U S A       Date:  1975-11       Impact factor: 11.205

Review 6.  Target site selection in transposition.

Authors:  N L Craig
Journal:  Annu Rev Biochem       Date:  1997       Impact factor: 23.643

7.  Curved helix segments can uniquely orient the topology of supertwisted DNA.

Authors:  C H Laundon; J D Griffith
Journal:  Cell       Date:  1988-02-26       Impact factor: 41.582

Review 8.  Integration target site selection for retroviruses and transposable elements.

Authors:  X Wu; S M Burgess
Journal:  Cell Mol Life Sci       Date:  2004-10       Impact factor: 9.261

9.  DNA dynamics vary according to macrodomain topography in the E. coli chromosome.

Authors:  Olivier Espeli; Romain Mercier; Frédéric Boccard
Journal:  Mol Microbiol       Date:  2008-04-11       Impact factor: 3.501

10.  Selection of target sites for mobile DNA integration in the human genome.

Authors:  Charles Berry; Sridhar Hannenhalli; Jeremy Leipzig; Frederic D Bushman
Journal:  PLoS Comput Biol       Date:  2006-11-24       Impact factor: 4.475
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  9 in total

1.  Unlocking Tn3-family transposase activity in vitro unveils an asymetric pathway for transposome assembly.

Authors:  Emilien Nicolas; Cédric A Oger; Nathan Nguyen; Michaël Lambin; Amandine Draime; Sébastien C Leterme; Michael Chandler; Bernard F J Hallet
Journal:  Proc Natl Acad Sci U S A       Date:  2017-01-17       Impact factor: 11.205

Review 2.  Transposable Phage Mu.

Authors:  Rasika M Harshey
Journal:  Microbiol Spectr       Date:  2014-10

3.  Repair of transposable phage Mu DNA insertions begins only when the E. coli replisome collides with the transpososome.

Authors:  Sooin Jang; Rasika M Harshey
Journal:  Mol Microbiol       Date:  2015-06-06       Impact factor: 3.501

4.  Deep sequencing reveals new roles for MuB in transposition immunity and target-capture, and redefines the insular Ter region of E. coli.

Authors:  David M Walker; Rasika M Harshey
Journal:  Mob DNA       Date:  2020-07-09

5.  Mu insertions are repaired by the double-strand break repair pathway of Escherichia coli.

Authors:  Sooin Jang; Steven J Sandler; Rasika M Harshey
Journal:  PLoS Genet       Date:  2012-04-12       Impact factor: 5.917

6.  Target DNA bending by the Mu transpososome promotes careful transposition and prevents its reversal.

Authors:  James R Fuller; Phoebe A Rice
Journal:  Elife       Date:  2017-02-13       Impact factor: 8.140

7.  Transposition Behavior Revealed by High-Resolution Description of Pseudomonas Aeruginosa Saltovirus Integration Sites.

Authors:  Gilles Vergnaud; Cédric Midoux; Yann Blouin; Maria Bourkaltseva; Victor Krylov; Christine Pourcel
Journal:  Viruses       Date:  2018-05-07       Impact factor: 5.048

Review 8.  Endogenous and Foreign Nucleoid-Associated Proteins of Bacteria: Occurrence, Interactions and Effects on Mobile Genetic Elements and Host's Biology.

Authors:  Rodrigo Flores-Ríos; Raquel Quatrini; Alejandra Loyola
Journal:  Comput Struct Biotechnol J       Date:  2019-06-14       Impact factor: 7.271

9.  Transposable prophage Mu is organized as a stable chromosomal domain of E. coli.

Authors:  Rudra P Saha; Zheng Lou; Luke Meng; Rasika M Harshey
Journal:  PLoS Genet       Date:  2013-11-07       Impact factor: 5.917
  9 in total

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