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Literature DB >> 15702419

Chromosome size and origin as determinants of the level of CENP-A incorporation into human centromeres.

Danielle V Irvine¹, David J Amor, Jo Perry, Nicolas Sirvent, Florence Pedeutour, K H Andy Choo, Richard Saffery.

Abstract

We have expressed an EGFP-CENP-A fusion protein in human cells in order to quantitate the level of CENP-A incorporated into normal and variant human centromeres. The results revealed a 3.2-fold difference in the level of CENP-A incorporation into alpha-satellite repeat DNA-based centromeres, with the Y centromere showing the lowest level of all normal human chromosomes. Identification of individual chromosomes revealed a statistically significant, though not absolute, correlation between chromosome size and CENP-A incorporation. Analysis of three independent neocentromeres revealed a significantly reduced level of CENP-A compared to normal centromeres. Truncation of a neocentric marker chromosome to produce a minichromosome further reduced CENP-A levels, indicating a remodelling of centromeric chromatin. These results suggest a role for increased CENP-A incorporation in the faithful segregation of larger chromosomes and support a model of centromere evolution in which neocentromeres represent ancestral centromeres that, through adaptive evolution, acquire satellite repeats to facilitate the incorporation of higher numbers of CENP-A containing nucleosomes, thereby facilitating the assembly of larger kinetochore structures.

Entities: Gene Species

Mesh：

Substances：

Year: 2004 PMID： 15702419 DOI： 10.1007/s10577-005-5377-4

Source DB: PubMed Journal: Chromosome Res ISSN： 0967-3849 Impact factor: 5.239

43 in total

1. Co-localization of centromere activity, proteins and topoisomerase II within a subdomain of the major human X alpha-satellite array.

Authors: Jennifer M Spence; Ricky Critcher; Thomas A Ebersole; Manuel M Valdivia; William C Earnshaw; Tatsuo Fukagawa; Christine J Farr
Journal: EMBO J Date: 2002-10-01 Impact factor: 11.598

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. Size variation in kinetochores of human chromosomes.

Authors: L M Cherry; D A Johnston
Journal: Hum Genet Date: 1987-02 Impact factor: 4.132

4. Indirect immunofluorescence of inactive centromeres as indicator of centromeric function.

Authors: D Peretti; P Maraschio; S Lambiase; F Lo Curto; O Zuffardi
Journal: Hum Genet Date: 1986-05 Impact factor: 4.132

5. 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

6. Centromere/kinetochore localization of human centromere protein A (CENP-A) exogenously expressed as a fusion to green fluorescent protein.

Authors: K Sugimoto; R Fukuda; M Himeno
Journal: Cell Struct Funct Date: 2000-08 Impact factor: 2.212

7. Human centromeres and neocentromeres show identical distribution patterns of >20 functionally important kinetochore-associated proteins.

Authors: R Saffery; D V Irvine; B Griffiths; P Kalitsis; L Wordeman; K H Choo
Journal: Hum Mol Genet Date: 2000-01-22 Impact factor: 6.150

8. Genomic microarray analysis reveals distinct locations for the CENP-A binding domains in three human chromosome 13q32 neocentromeres.

Authors: Alicia Alonso; Radma Mahmood; Shulan Li; Fanny Cheung; Kinya Yoda; Peter E Warburton
Journal: Hum Mol Genet Date: 2003-08-19 Impact factor: 6.150

9. CENP-B interacts with CENP-C domains containing Mif2 regions responsible for centromere localization.

Authors: Nobutaka Suzuki; Megumi Nakano; Naohito Nozaki; Shin-ichiro Egashira; Tuneko Okazaki; Hiroshi Masumoto
Journal: J Biol Chem Date: 2003-11-10 Impact factor: 5.157

10. The centromere-kinetochore complex: a repeat subunit model.

Authors: R P Zinkowski; J Meyne; B R Brinkley
Journal: J Cell Biol Date: 1991-06 Impact factor: 10.539

33 in total

Review 1. Neocentromeres and epigenetically inherited features of centromeres.

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

2. A minimal CENP-A core is required for nucleation and maintenance of a functional human centromere.

Authors: Yasuhide Okamoto; Megumi Nakano; Jun-ichirou Ohzeki; Vladimir Larionov; Hiroshi Masumoto
Journal: EMBO J Date: 2007-02-22 Impact factor: 11.598

Review 3. Neocentromeres: new insights into centromere structure, disease development, and karyotype evolution.

Authors: Owen J Marshall; Anderly C Chueh; Lee H Wong; K H Andy Choo
Journal: Am J Hum Genet Date: 2008-02 Impact factor: 11.025

4. Centromere inactivation and epigenetic modifications of a plant chromosome with three functional centromeres.

Authors: Wenli Zhang; Bernd Friebe; Bikram S Gill; Jiming Jiang
Journal: Chromosoma Date: 2010-05-25 Impact factor: 4.316

5. Identification of a maize neocentromere in an oat-maize addition line.

Authors: C N Topp; R J Okagaki; J R Melo; R G Kynast; R L Phillips; R K Dawe
Journal: Cytogenet Genome Res Date: 2009-06-25 Impact factor: 1.636

6. Genomic and genetic characterization of rice Cen3 reveals extensive transcription and evolutionary implications of a complex centromere.

Authors: Huihuang Yan; Hidetaka Ito; Kan Nobuta; Shu Ouyang; Weiwei Jin; Shulan Tian; Cheng Lu; R C Venu; Guo-Liang Wang; Pamela J Green; Rod A Wing; C Robin Buell; Blake C Meyers; Jiming Jiang
Journal: Plant Cell Date: 2006-07-28 Impact factor: 11.277