Literature DB >> 18252209

Neocentromeres: new insights into centromere structure, disease development, and karyotype evolution.

Owen J Marshall1, Anderly C Chueh, Lee H Wong, K H Andy Choo.   

Abstract

Since the discovery of the first human neocentromere in 1993, these spontaneous, ectopic centromeres have been shown to be an astonishing example of epigenetic change within the genome. Recent research has focused on the role of neocentromeres in evolution and speciation, as well as in disease development and the understanding of the organization and epigenetic maintenance of the centromere. Here, we review recent progress in these areas of research and the significant insights gained.

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Year:  2008        PMID: 18252209      PMCID: PMC2427194          DOI: 10.1016/j.ajhg.2007.11.009

Source DB:  PubMed          Journal:  Am J Hum Genet        ISSN: 0002-9297            Impact factor:   11.025


  151 in total

1.  Analphoid 3qter markers.

Authors:  I Teshima; E V Bawle; R Weksberg; C Shuman; D L Van Dyke; S Schwartz
Journal:  Am J Med Genet       Date:  2000-09-11

2.  A novel chromatin immunoprecipitation and array (CIA) analysis identifies a 460-kb CENP-A-binding neocentromere DNA.

Authors:  A W Lo; D J Magliano; M C Sibson; P Kalitsis; J M Craig; K H Choo
Journal:  Genome Res       Date:  2001-03       Impact factor: 9.043

3.  Construction of neocentromere-based human minichromosomes for gene delivery and centromere studies.

Authors:  L H Wong; R Saffery; K H A Choo
Journal:  Gene Ther       Date:  2002-06       Impact factor: 5.250

4.  Tetrasomy 12pter-12p13.31 in a girl with partial Pallister-Killian syndrome phenotype.

Authors:  Joris Robert Vermeesch; Cindy Melotte; Ivo Salden; Mariluce Riegel; Vladimir Trifnov; Anna Polityko; Natalia Rumyantseva; Irina Naumchik; Heike Starke; Gert Matthijs; Albert Schinzel; Jean-Pierre Fryns; Thomas Liehr
Journal:  Eur J Med Genet       Date:  2005 Jul-Sep       Impact factor: 2.708

5.  Characterization of an analphoid supernumerary marker chromosome derived from 15q25-->qter using high-resolution CGH and multiplex FISH analyses.

Authors:  X-L Huang; M I de Michelena; H F L Mark; R Harston; P J Benke; S J Price; A Milunsky
Journal:  Clin Genet       Date:  2005-12       Impact factor: 4.438

6.  The activation of a neocentromere in Drosophila requires proximity to an endogenous centromere.

Authors:  K A Maggert; G H Karpen
Journal:  Genetics       Date:  2001-08       Impact factor: 4.562

7.  Variable and hierarchical size distribution of L1-retroelement-enriched CENP-A clusters within a functional human neocentromere.

Authors:  Anderly C Chueh; Lee H Wong; Nicholas Wong; K H Andy Choo
Journal:  Hum Mol Genet       Date:  2004-11-10       Impact factor: 6.150

8.  Terminal deletion with stable acentric fragment of 1q in a child with congenital malformations.

Authors:  M Kucerová; Z Polívková; S Dluholucký; M Kvasnicová
Journal:  Am J Hum Genet       Date:  1983-01       Impact factor: 11.025

9.  Characterization of an analphoid, neocentromere-positive inv dup 8p marker chromosome using multiplex whole chromosome and sub-telomere FISH analyses.

Authors:  M Velinov; H Gu; M Genovese; C Duncan; P Warburton; S Sklower Brooks; E C Jenkins
Journal:  Ann Genet       Date:  2004 Apr-Jun

Review 10.  Small supernumerary marker chromosomes (sSMC) in humans.

Authors:  T Liehr; U Claussen; H Starke
Journal:  Cytogenet Genome Res       Date:  2004       Impact factor: 1.636
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  187 in total

1.  Chickens possess centromeres with both extended tandem repeats and short non-tandem-repetitive sequences.

Authors:  Wei-Hao Shang; Tetsuya Hori; Atsushi Toyoda; Jun Kato; Kris Popendorf; Yasubumi Sakakibara; Asao Fujiyama; Tatsuo Fukagawa
Journal:  Genome Res       Date:  2010-06-09       Impact factor: 9.043

2.  Active transcription and essential role of RNA polymerase II at the centromere during mitosis.

Authors:  F Lyn Chan; Owen J Marshall; Richard Saffery; Bo Won Kim; Elizabeth Earle; K H Andy Choo; Lee H Wong
Journal:  Proc Natl Acad Sci U S A       Date:  2012-01-20       Impact factor: 11.205

Review 3.  Establishment of the vertebrate kinetochores.

Authors:  Tetsuya Hori; Tatsuo Fukagawa
Journal:  Chromosome Res       Date:  2012-07       Impact factor: 5.239

Review 4.  Regulatory mechanisms of kinetochore-microtubule interaction in mitosis.

Authors:  Kozo Tanaka
Journal:  Cell Mol Life Sci       Date:  2012-07-04       Impact factor: 9.261

Review 5.  The fate of metaphase kinetochores is weighed in the balance of SUMOylation during S phase.

Authors:  Debaditya Mukhopadhyay; Mary Dasso
Journal:  Cell Cycle       Date:  2010-08-09       Impact factor: 4.534

Review 6.  Centromere identity: a challenge to be faced.

Authors:  Gunjan D Mehta; Meenakshi P Agarwal; Santanu Kumar Ghosh
Journal:  Mol Genet Genomics       Date:  2010-06-29       Impact factor: 3.291

7.  Interstitial deletion of proximal 8q including part of the centromere from unbalanced segregation of a paternal deletion/marker karyotype with neocentromere formation at 8p22.

Authors:  R D Burnside; J Ibrahim; C Flora; S Schwartz; J H Tepperberg; P R Papenhausen; P E Warburton
Journal:  Cytogenet Genome Res       Date:  2011-01-06       Impact factor: 1.636

8.  Ancestral grass karyotype reconstruction unravels new mechanisms of genome shuffling as a source of plant evolution.

Authors:  Florent Murat; Jian-Hong Xu; Eric Tannier; Michael Abrouk; Nicolas Guilhot; Caroline Pont; Joachim Messing; Jérôme Salse
Journal:  Genome Res       Date:  2010-09-28       Impact factor: 9.043

Review 9.  Neocentromeres and epigenetically inherited features of centromeres.

Authors:  Laura S Burrack; Judith Berman
Journal:  Chromosome Res       Date:  2012-07       Impact factor: 5.239

Review 10.  Understanding eukaryotic chromosome segregation from a comparative biology perspective.

Authors:  Snezhana Oliferenko
Journal:  J Cell Sci       Date:  2018-07-20       Impact factor: 5.285
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