Literature DB >> 23230266

Sequences associated with centromere competency in the human genome.

Karen E Hayden1, Erin D Strome, Stephanie L Merrett, Hye-Ran Lee, M Katharine Rudd, Huntington F Willard.   

Abstract

Centromeres, the sites of spindle attachment during mitosis and meiosis, are located in specific positions in the human genome, normally coincident with diverse subsets of alpha satellite DNA. While there is strong evidence supporting the association of some subfamilies of alpha satellite with centromere function, the basis for establishing whether a given alpha satellite sequence is or is not designated a functional centromere is unknown, and attempts to understand the role of particular sequence features in establishing centromere identity have been limited by the near identity and repetitive nature of satellite sequences. Utilizing a broadly applicable experimental approach to test sequence competency for centromere specification, we have carried out a genomic and epigenetic functional analysis of endogenous human centromere sequences available in the current human genome assembly. The data support a model in which functionally competent sequences confer an opportunity for centromere specification, integrating genomic and epigenetic signals and promoting the concept of context-dependent centromere inheritance.

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Year:  2012        PMID: 23230266      PMCID: PMC3571344          DOI: 10.1128/MCB.01198-12

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


  49 in total

1.  Alpha-satellite DNA of primates: old and new families.

Authors:  I Alexandrov; A Kazakov; I Tumeneva; V Shepelev; Y Yurov
Journal:  Chromosoma       Date:  2001-08       Impact factor: 4.316

2.  Genome-wide characterization of centromeric satellites from multiple mammalian genomes.

Authors:  Can Alkan; Maria Francesca Cardone; Claudia Rita Catacchio; Francesca Antonacci; Stephen J O'Brien; Oliver A Ryder; Stefania Purgato; Monica Zoli; Giuliano Della Valle; Evan E Eichler; Mario Ventura
Journal:  Genome Res       Date:  2010-11-16       Impact factor: 9.043

3.  Topoisomerase II cleavage activity within the human D11Z1 and DXZ1 alpha-satellite arrays.

Authors:  Jennifer M Spence; R E Keith Fournier; Mitsuo Oshimura; Vinciane Regnier; Christine J Farr
Journal:  Chromosome Res       Date:  2005-09-21       Impact factor: 5.239

Review 4.  Centromere-competent DNA: structure and evolution.

Authors:  Durd Ica Ugarković
Journal:  Prog Mol Subcell Biol       Date:  2009

5.  Pulsed-field and two-dimensional gel electrophoresis of long arrays of tandemly repeated DNA : analysis of human centromeric alpha satellite.

Authors:  P E Warburton; R Wevrick; M M Mahtani; H F Willard
Journal:  Methods Mol Biol       Date:  1992

6.  Patterns of intra- and interarray sequence variation in alpha satellite from the human X chromosome: evidence for short-range homogenization of tandemly repeated DNA sequences.

Authors:  S J Durfy; H F Willard
Journal:  Genomics       Date:  1989-11       Impact factor: 5.736

7.  The phylogeny of human chromosome specific alpha satellites.

Authors:  I A Alexandrov; S P Mitkevich; Y B Yurov
Journal:  Chromosoma       Date:  1988       Impact factor: 4.316

8.  Physical map of the centromeric region of human chromosome 7: relationship between two distinct alpha satellite arrays.

Authors:  R Wevrick; H F Willard
Journal:  Nucleic Acids Res       Date:  1991-05-11       Impact factor: 16.971

Review 9.  The role of CENP-B and alpha-satellite DNA: de novo assembly and epigenetic maintenance of human centromeres.

Authors:  Hiroshi Masumoto; Megumi Nakano; Jun-Ichirou Ohzeki
Journal:  Chromosome Res       Date:  2004       Impact factor: 5.239

10.  The diploid genome sequence of an individual human.

Authors:  Samuel Levy; Granger Sutton; Pauline C Ng; Lars Feuk; Aaron L Halpern; Brian P Walenz; Nelson Axelrod; Jiaqi Huang; Ewen F Kirkness; Gennady Denisov; Yuan Lin; Jeffrey R MacDonald; Andy Wing Chun Pang; Mary Shago; Timothy B Stockwell; Alexia Tsiamouri; Vineet Bafna; Vikas Bansal; Saul A Kravitz; Dana A Busam; Karen Y Beeson; Tina C McIntosh; Karin A Remington; Josep F Abril; John Gill; Jon Borman; Yu-Hui Rogers; Marvin E Frazier; Stephen W Scherer; Robert L Strausberg; J Craig Venter
Journal:  PLoS Biol       Date:  2007-09-04       Impact factor: 8.029
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  53 in total

Review 1.  Completing the human genome: the progress and challenge of satellite DNA assembly.

Authors:  Karen H Miga
Journal:  Chromosome Res       Date:  2015-09       Impact factor: 5.239

2.  Clusters of alpha satellite on human chromosome 21 are dispersed far onto the short arm and lack ancient layers.

Authors:  William Ziccardi; Chongjian Zhao; Valery Shepelev; Lev Uralsky; Ivan Alexandrov; Tatyana Andreeva; Evgeny Rogaev; Christopher Bun; Emily Miller; Catherine Putonti; Jeffrey Doering
Journal:  Chromosome Res       Date:  2016-07-18       Impact factor: 5.239

Review 3.  Centromeric heterochromatin: the primordial segregation machine.

Authors:  Kerry S Bloom
Journal:  Annu Rev Genet       Date:  2014-09-18       Impact factor: 16.830

Review 4.  Centromere studies in the era of 'telomere-to-telomere' genomics.

Authors:  Karen H Miga
Journal:  Exp Cell Res       Date:  2020-06-03       Impact factor: 3.905

Review 5.  Genetic and epigenetic effects on centromere establishment.

Authors:  Yick Hin Ling; Zhongyang Lin; Karen Wing Yee Yuen
Journal:  Chromosoma       Date:  2019-11-28       Impact factor: 4.316

Review 6.  Genomic and functional variation of human centromeres.

Authors:  Lori L Sullivan; Beth A Sullivan
Journal:  Exp Cell Res       Date:  2020-02-06       Impact factor: 3.905

7.  DNA replication acts as an error correction mechanism to maintain centromere identity by restricting CENP-A to centromeres.

Authors:  Yael Nechemia-Arbely; Karen H Miga; Ofer Shoshani; Aaron Aslanian; Moira A McMahon; Ah Young Lee; Daniele Fachinetti; John R Yates; Bing Ren; Don W Cleveland
Journal:  Nat Cell Biol       Date:  2019-06-03       Impact factor: 28.824

Review 8.  Alpha satellite DNA biology: finding function in the recesses of the genome.

Authors:  Shannon M McNulty; Beth A Sullivan
Journal:  Chromosome Res       Date:  2018-07-05       Impact factor: 5.239

Review 9.  The unique kind of human artificial chromosome: Bypassing the requirement for repetitive centromere DNA.

Authors:  Craig W Gambogi; Jennine M Dawicki-McKenna; Glennis A Logsdon; Ben E Black
Journal:  Exp Cell Res       Date:  2020-04-01       Impact factor: 3.905

10.  Genome-wide alterations of uracil distribution patterns in human DNA upon chemotherapeutic treatments.

Authors:  Hajnalka L Pálinkás; Angéla Békési; Gergely Róna; Lőrinc Pongor; Gábor Papp; Gergely Tihanyi; Eszter Holub; Ádám Póti; Carolina Gemma; Simak Ali; Michael J Morten; Eli Rothenberg; Michele Pagano; Dávid Szűts; Balázs Győrffy; Beáta G Vértessy
Journal:  Elife       Date:  2020-09-21       Impact factor: 8.140
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