Evolutionary Formation of New Centromeres in Macaque

Ventura, Mario; Antonacci, Francesca; Cardone, Maria Francesca; Stanyon, Roscoe; D’Addabbo, Pietro; Cellamare, Angelo; Sprague, Leslee; Eichler, Evan E.; Archidiacono, Nicoletta; Rocchi, Mariano

doi:10.1126/science.1140615

Cited by 137 publications

(151 citation statements)

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“…Segmental duplication is a prominent feature associated with the pericentromeric regions of most human chromosomes (33). However, there has been limited evidence indicating that centromere re-seeding may trigger formation of such segmental duplications (14). Similar segmental duplications were not found in the pericentromeric regions of several well sequenced model plant species, including rice and Arabidopsis thaliana.…”

Section: Discussionmentioning

confidence: 84%

“…Although CRs occurred frequently in the evolution of mammalian species and was implicated to play an important role in mammalian genome evolution (14), very little is known about the genomic consequences of re-seeding a centromere in an eukaryotic chromosome. Segmental duplication is a prominent feature associated with the pericentromeric regions of most human chromosomes (33).…”

Section: Discussionmentioning

confidence: 99%

“…Thus, neocentromeres do not seem to have any evolutionary advantage over existing native centromeres. However, comparative mapping among closely related mammalian species has revealed position changes of some centromeres during evolution, most likely via neocentromere formation (5,(10)(11)(12)(13)(14)(15). Centromere repositioning (CR) events have occurred frequently in some mammalian lineages.…”

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confidence: 99%

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Centromere repositioning in cucurbit species: Implication of the genomic impact from centromere activation and inactivation

Han

Zhang

Liu

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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The centromere of an eukaryotic chromosome can move to a new position during evolution, which may result in a major alteration of the chromosome morphology and karyotype. This centromere repositioning phenomenon has been extensively documented in mammalian species and was implicated to play an important role in mammalian genome evolution. Here we report a centromere repositioning event in plant species. Comparative fluorescence in situ hybridization mapping using common sets of fosmid clones between two pairs of cucumber (Cucumis sativus L.) and melon (Cucumis melo L.) chromosomes revealed changes in centromere positions during evolution. Pachytene chromosome analysis revealed that the current centromeres of all four cucumber and melon chromosomes are associated with distinct pericentromeric heterochromatin. Interestingly, inactivation of a centromere in the original centromeric region was associated with a loss or erosion of its affixed pericentromeric heterochromatin. Thus, both centromere activation and inactivation in cucurbit species were associated with a gain/loss of a large amount of pericentromeric heterochromatin.cucumber ͉ melon ͉ pericentromeric heterochromatin

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Section: Discussionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Centromere repositioning in cucurbit species: Implication of the genomic impact from centromere activation and inactivation

Han

Zhang

Liu

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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“…Rapid centromere evolution has also been observed in some plants and animals (Haaf and Willard 1997;Henikoff et al 2001;Lee et al 2005;Ma et al 2007;Ventura et al 2007). In these taxa centromeres are extremely long and complex stretches of highly repetitive AT-rich satellite DNA, usually surrounded by or embedded in heterochromatin (Clarke 1998;Henikoff et al 2001;Sullivan et al 2001).…”

Section: Discussionmentioning

confidence: 99%

Rapid Evolution of Yeast Centromeres in the Absence of Drive

Bensasson¹,

Zarowiecki²,

Burt

et al. 2008

Genetics

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To find the most rapidly evolving regions in the yeast genome we compared most of chromosome III from three closely related lineages of the wild yeast Saccharomyces paradoxus. Unexpectedly, the centromere appears to be the fastest-evolving part of the chromosome, evolving even faster than DNA sequences unlikely to be under selective constraint (i.e., synonymous sites after correcting for codon usage bias and remnant transposable elements). Centromeres on other chromosomes also show an elevated rate of nucleotide substitution. Rapid centromere evolution has also been reported for some plants and animals and has been attributed to selection for inclusion in the egg or the ovule at female meiosis. But Saccharomyces yeasts have symmetrical meioses with all four products surviving, thus providing no opportunity for meiotic drive. In addition, yeast centromeres show the high levels of polymorphism expected under a neutral model of molecular evolution. We suggest that yeast centromeres suffer an elevated rate of mutation relative to other chromosomal regions and they change through a process of ''centromere drift,'' not drive.

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“…The centromere inactivation will ensure regular meiotic segregation of the fusion chromosome and can result in evolutionary fixed reduction of chromosome number. Several cases of inactivated ancestral centromeres as well as the emergence of neocentromeres (centromere repositioning) were reported in mammalian species (e.g., Ferreri et al, 2005;Ventura et al, 2007), but only a few examples of centromere inactivation (and reactivation; F. ) in plants, including dicentric chromosomes of Trititiceae (Sears and Camara, 1952;Luo et al, 2009), maize (Zea mays) B chromosomes (F. Han et al, 2006, and potentially also chromosomes of two cucurbit species (Y. . Except for the heterochromatic knob on chromosome SN3 corresponding to the AK5 centromere, no heterochromatin was observed at sites of the other 17 presumably inactivated centromeres.…”

Section: Species-specific Dysploidy Following the Wgdmentioning

confidence: 99%

Fast Diploidization in Close Mesopolyploid Relatives ofArabidopsis

et al. 2010

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Mesopolyploid whole-genome duplication (WGD) was revealed in the ancestry of Australian Brassicaceae species with diploid-like chromosome numbers (n = 4 to 6). Multicolor comparative chromosome painting was used to reconstruct complete cytogenetic maps of the cryptic ancient polyploids. Cytogenetic analysis showed that the karyotype of the Australian Camelineae species descended from the eight ancestral chromosomes (n = 8) through allopolyploid WGD followed by the extensive reduction of chromosome number. Nuclear and maternal gene phylogenies corroborated the hybrid origin of the mesotetraploid ancestor and suggest that the hybridization event occurred ;6 to 9 million years ago.The four, five, and six fusion chromosome pairs of the analyzed close relatives of Arabidopsis thaliana represent complex mosaics of duplicated ancestral genomic blocks reshuffled by numerous chromosome rearrangements. Unequal reciprocal translocations with or without preceeding pericentric inversions and purported end-to-end chromosome fusions accompanied by inactivation and/or loss of centromeres are hypothesized to be the main pathways for the observed chromosome number reduction. Our results underline the significance of multiple rounds of WGD in the angiosperm genome evolution and demonstrate that chromosome number per se is not a reliable indicator of ploidy level.

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Evolutionary Formation of New Centromeres in Macaque

Cited by 137 publications

References 31 publications

Centromere repositioning in cucurbit species: Implication of the genomic impact from centromere activation and inactivation

Centromere repositioning in cucurbit species: Implication of the genomic impact from centromere activation and inactivation

Rapid Evolution of Yeast Centromeres in the Absence of Drive

Fast Diploidization in Close Mesopolyploid Relatives ofArabidopsis

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