Literature DB >> 26186286

Reconsidering DNA Polymerases at the Replication Fork in Eukaryotes.

Bruce Stillman1.   

Abstract

The distribution of DNA polymerase activities at the eukaryotic DNA replication fork was "established," but recent genetic studies in this issue of Molecular Cell raise questions about which polymerases are copying the leading and lagging strand templates (Johnson et al, 2015).
Copyright © 2015 Elsevier Inc. All rights reserved.

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Year:  2015        PMID: 26186286      PMCID: PMC4636199          DOI: 10.1016/j.molcel.2015.07.004

Source DB:  PubMed          Journal:  Mol Cell        ISSN: 1097-2765            Impact factor:   17.970


  12 in total

Review 1.  Checking on the fork: the DNA-replication stress-response pathway.

Authors:  Alexander J Osborn; Stephen J Elledge; Lee Zou
Journal:  Trends Cell Biol       Date:  2002-11       Impact factor: 20.808

Review 2.  Replicative DNA polymerases.

Authors:  Erik Johansson; Nicholas Dixon
Journal:  Cold Spring Harb Perspect Biol       Date:  2013-06-01       Impact factor: 10.005

Review 3.  The DNA replication fork in eukaryotic cells.

Authors:  S Waga; B Stillman
Journal:  Annu Rev Biochem       Date:  1998       Impact factor: 23.643

4.  Ribonucleotides in DNA: hidden in plain sight.

Authors:  Sue Jinks-Robertson; Hannah L Klein
Journal:  Nat Struct Mol Biol       Date:  2015-03       Impact factor: 15.369

5.  A Major Role of DNA Polymerase δ in Replication of Both the Leading and Lagging DNA Strands.

Authors:  Robert E Johnson; Roland Klassen; Louise Prakash; Satya Prakash
Journal:  Mol Cell       Date:  2015-07-02       Impact factor: 17.970

6.  Analysis of the essential functions of the C-terminal protein/protein interaction domain of Saccharomyces cerevisiae pol epsilon and its unexpected ability to support growth in the absence of the DNA polymerase domain.

Authors:  R Dua; D L Levy; J L Campbell
Journal:  J Biol Chem       Date:  1999-08-06       Impact factor: 5.157

7.  Strand-specific analysis shows protein binding at replication forks and PCNA unloading from lagging strands when forks stall.

Authors:  Chuanhe Yu; Haiyun Gan; Junhong Han; Zhi-Xiong Zhou; Shaodong Jia; Andrei Chabes; Gianrico Farrugia; Tamas Ordog; Zhiguo Zhang
Journal:  Mol Cell       Date:  2014-10-23       Impact factor: 17.970

8.  Mechanism of asymmetric polymerase assembly at the eukaryotic replication fork.

Authors:  Roxana E Georgescu; Lance Langston; Nina Y Yao; Olga Yurieva; Dan Zhang; Jeff Finkelstein; Tani Agarwal; Mike E O'Donnell
Journal:  Nat Struct Mol Biol       Date:  2014-07-06       Impact factor: 15.369

9.  Reconstitution of a eukaryotic replisome reveals suppression mechanisms that define leading/lagging strand operation.

Authors:  Roxana E Georgescu; Grant D Schauer; Nina Y Yao; Lance D Langston; Olga Yurieva; Dan Zhang; Jeff Finkelstein; Mike E O'Donnell
Journal:  Elife       Date:  2015-04-14       Impact factor: 8.140

10.  Regulated eukaryotic DNA replication origin firing with purified proteins.

Authors:  Joseph T P Yeeles; Tom D Deegan; Agnieszka Janska; Anne Early; John F X Diffley
Journal:  Nature       Date:  2015-03-04       Impact factor: 49.962
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  28 in total

1.  Bacterial and Eukaryotic Replisome Machines.

Authors:  Nina Yao; Mike O'Donnell
Journal:  JSM Biochem Mol Biol       Date:  2016-05-30

Review 2.  The Eukaryotic CMG Helicase at the Replication Fork: Emerging Architecture Reveals an Unexpected Mechanism.

Authors:  Huilin Li; Michael E O'Donnell
Journal:  Bioessays       Date:  2018-02-06       Impact factor: 4.345

3.  CMG-Pol epsilon dynamics suggests a mechanism for the establishment of leading-strand synthesis in the eukaryotic replisome.

Authors:  Jin Chuan Zhou; Agnieszka Janska; Panchali Goswami; Ludovic Renault; Ferdos Abid Ali; Abhay Kotecha; John F X Diffley; Alessandro Costa
Journal:  Proc Natl Acad Sci U S A       Date:  2017-04-03       Impact factor: 11.205

4.  Divalent ions attenuate DNA synthesis by human DNA polymerase α by changing the structure of the template/primer or by perturbing the polymerase reaction.

Authors:  Yinbo Zhang; Andrey G Baranovskiy; Emin T Tahirov; Tahir H Tahirov; Youri I Pavlov
Journal:  DNA Repair (Amst)       Date:  2016-05-12

5.  Chromatin Constrains the Initiation and Elongation of DNA Replication.

Authors:  Sujan Devbhandari; Jieqing Jiang; Charanya Kumar; Iestyn Whitehouse; Dirk Remus
Journal:  Mol Cell       Date:  2016-12-15       Impact factor: 17.970

6.  Both DNA Polymerases δ and ε Contact Active and Stalled Replication Forks Differently.

Authors:  Chuanhe Yu; Haiyun Gan; Zhiguo Zhang
Journal:  Mol Cell Biol       Date:  2017-10-13       Impact factor: 4.272

7.  The absence of the catalytic domains of Saccharomyces cerevisiae DNA polymerase ϵ strongly reduces DNA replication fidelity.

Authors:  Marta A Garbacz; Phillip B Cox; Sushma Sharma; Scott A Lujan; Andrei Chabes; Thomas A Kunkel
Journal:  Nucleic Acids Res       Date:  2019-05-07       Impact factor: 16.971

Review 8.  Structure and function relationships in mammalian DNA polymerases.

Authors:  Nicole M Hoitsma; Amy M Whitaker; Matthew A Schaich; Mallory R Smith; Max S Fairlamb; Bret D Freudenthal
Journal:  Cell Mol Life Sci       Date:  2019-11-13       Impact factor: 9.261

9.  A simple but profound mutation in mouse DNA polymerase ε drives tumorigenesis.

Authors:  Thomas A Kunkel
Journal:  J Clin Invest       Date:  2018-08-20       Impact factor: 14.808

10.  Mutational Strand Asymmetries in Cancer Genomes Reveal Mechanisms of DNA Damage and Repair.

Authors:  Nicholas J Haradhvala; Paz Polak; Petar Stojanov; Kyle R Covington; Eve Shinbrot; Julian M Hess; Esther Rheinbay; Jaegil Kim; Yosef E Maruvka; Lior Z Braunstein; Atanas Kamburov; Philip C Hanawalt; David A Wheeler; Amnon Koren; Michael S Lawrence; Gad Getz
Journal:  Cell       Date:  2016-01-21       Impact factor: 41.582
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