Literature DB >> 1847499

Relationship of avian retrovirus DNA synthesis to integration in vitro.

Y M Lee1, J M Coffin.   

Abstract

An in vitro integration system derived from avian leukosis virus-infected cells supports both intra- and intermolecular integration of the viral DNA. In the absence of polyethylene glycol, intramolecular integration of viral DNA molecules into themselves (autointegration) was preferred. In the presence of polyethylene glycol, integration into an exogenously supplied DNA target was greatly promoted. Analysis of integration intermediates revealed that the strand transfer mechanisms of both reactions were identical to those of retroviruses and some transposons: each 3' end of the donor molecule is joined to a 5' end of the cleaved target DNA. The immediate integration precursor appears to be linear viral DNA with the 3' ends shortened by 2 nucleotides. Finally, in the avian system, most cytoplasmic viral DNA appears to be incomplete and further DNA synthesis is required for integration in vitro.

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Year:  1991        PMID: 1847499      PMCID: PMC369417          DOI: 10.1128/mcb.11.3.1419-1430.1991

Source DB:  PubMed          Journal:  Mol Cell Biol        ISSN: 0270-7306            Impact factor:   4.272


  32 in total

1.  Intramolecular transposition by Tn10.

Authors:  H W Benjamin; N Kleckner
Journal:  Cell       Date:  1989-10-20       Impact factor: 41.582

2.  Sequences in the gag-pol-5'env region of avian leukosis viruses confer the ability to induce osteopetrosis.

Authors:  P R Shank; P J Schatz; L M Jensen; P N Tsichlis; J M Coffin; H L Robinson
Journal:  Virology       Date:  1985-08       Impact factor: 3.616

3.  Structure of the termini of DNA intermediates in the integration of retroviral DNA: dependence on IN function and terminal DNA sequence.

Authors:  M J Roth; P L Schwartzberg; S P Goff
Journal:  Cell       Date:  1989-07-14       Impact factor: 41.582

4.  Retroviral integration: structure of the initial covalent product and its precursor, and a role for the viral IN protein.

Authors:  P O Brown; B Bowerman; H E Varmus; J M Bishop
Journal:  Proc Natl Acad Sci U S A       Date:  1989-04       Impact factor: 11.205

5.  Correct integration of retroviral DNA in vitro.

Authors:  P O Brown; B Bowerman; H E Varmus; J M Bishop
Journal:  Cell       Date:  1987-05-08       Impact factor: 41.582

6.  Ordered interstrand and intrastrand DNA transfer during reverse transcription.

Authors:  A T Panganiban; D Fiore
Journal:  Science       Date:  1988-08-26       Impact factor: 47.728

7.  Highly preferred targets for retrovirus integration.

Authors:  C C Shih; J P Stoye; J M Coffin
Journal:  Cell       Date:  1988-05-20       Impact factor: 41.582

8.  The avian retroviral integration protein cleaves the terminal sequences of linear viral DNA at the in vivo sites of integration.

Authors:  M Katzman; R A Katz; A M Skalka; J Leis
Journal:  J Virol       Date:  1989-12       Impact factor: 5.103

9.  Retroviral DNA integration: structure of an integration intermediate.

Authors:  T Fujiwara; K Mizuuchi
Journal:  Cell       Date:  1988-08-12       Impact factor: 41.582

10.  Integration of mini-retroviral DNA: a cell-free reaction for biochemical analysis of retroviral integration.

Authors:  T Fujiwara; R Craigie
Journal:  Proc Natl Acad Sci U S A       Date:  1989-05       Impact factor: 11.205
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  36 in total

Review 1.  Retroviral DNA integration.

Authors:  P Hindmarsh; J Leis
Journal:  Microbiol Mol Biol Rev       Date:  1999-12       Impact factor: 11.056

2.  DNase protection analysis of retrovirus integrase at the viral DNA ends for full-site integration in vitro.

Authors:  A Vora; D P Grandgenett
Journal:  J Virol       Date:  2001-04       Impact factor: 5.103

3.  Characterization of a replication-defective human immunodeficiency virus type 1 att site mutant that is blocked after the 3' processing step of retroviral integration.

Authors:  H Chen; A Engelman
Journal:  J Virol       Date:  2000-09       Impact factor: 5.103

4.  Nonrandom integration of retroviral DNA in vitro: effect of CpG methylation.

Authors:  Y Kitamura; Y M Lee; J M Coffin
Journal:  Proc Natl Acad Sci U S A       Date:  1992-06-15       Impact factor: 11.205

5.  Effects on DNA synthesis and translocation caused by mutations in the RNase H domain of Moloney murine leukemia virus reverse transcriptase.

Authors:  S W Blain; S P Goff
Journal:  J Virol       Date:  1995-07       Impact factor: 5.103

6.  Effects of alterations of primer-binding site sequences on human immunodeficiency virus type 1 replication.

Authors:  X Li; J Mak; E J Arts; Z Gu; L Kleiman; M A Wainberg; M A Parniak
Journal:  J Virol       Date:  1994-10       Impact factor: 5.103

7.  Quantitative analysis of HIV-1 preintegration complexes.

Authors:  Alan Engelman; Ilker Oztop; Nick Vandegraaff; Nidhanapati K Raghavendra
Journal:  Methods       Date:  2009-02-20       Impact factor: 3.608

8.  Footprints on the viral DNA ends in moloney murine leukemia virus preintegration complexes reflect a specific association with integrase.

Authors:  S Q Wei; K Mizuuchi; R Craigie
Journal:  Proc Natl Acad Sci U S A       Date:  1998-09-01       Impact factor: 11.205

9.  Association of integrase, matrix, and reverse transcriptase antigens of human immunodeficiency virus type 1 with viral nucleic acids following acute infection.

Authors:  M I Bukrinsky; N Sharova; T L McDonald; T Pushkarskaya; W G Tarpley; M Stevenson
Journal:  Proc Natl Acad Sci U S A       Date:  1993-07-01       Impact factor: 11.205

10.  Rous sarcoma virus (RSV) integration in vivo: a CA dinucleotide is not required in U3, and RSV linear DNA does not autointegrate.

Authors:  Jangsuk Oh; Kevin W Chang; Rafal Wierzchoslawski; W Gregory Alvord; Stephen H Hughes
Journal:  J Virol       Date:  2007-10-24       Impact factor: 5.103
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