The species and chromosomal distribution of the centromeric α-satellite I sequence from sheep in the tribe Caprini and other Bovidae

Chaves, Raquel; Guedes-Pinto, Henrique; Heslop-Harrison, J.S.; Schwarzacher, Trude

doi:10.1159/000056820

Cited by 36 publications

(47 citation statements)

References 17 publications

(27 reference statements)

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“…For in situ hybridization on chromosomes and extended chromatin fibres, a satellite I sheep clone pOaKB9 (Chaves et al 2000a(Chaves et al , 2003b) and a satellite I cattle clone, (pBtKB5, GenBank AJ293510, Chaves et al 2000bChaves et al , 2003a labelled Table 1. In situ hybridization patterns with probes sheep satellite I DNA (pOaKB9) and cattle satellite I DNA (pBtKB5) in all chromosome preparations of the 15 Bovidae species analysed.…”

Section: Methodsmentioning

confidence: 99%

“…Both Modi et al (1993Modi et al ( , 1996 and Chaves et al (2000a) observed different satellite DNA in situ hybridization patterns within a small number of tribes in the Bovidae family, and we considered that the sequences had potential as phylogenetic markers to increase the resolution of the evolutionary tree at the base of the Artiodactyla (Chaves et al 2000a). Here we aimed to analyse the presence and distribution of satellites to address evolutionary and phylogenetic questions with respect to the X chromosome (and its primitive state), karyotype, species and tribal evolution.…”

Section: Introductionmentioning

confidence: 99%

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Phylogenetic relationships and the primitive X chromosome inferred from chromosomal and satellite DNA analysis in Bovidae

2005

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The early phylogeny of the 137 species in the Bovidae family is difficult to resolve; knowledge of the evolution and relationships of the tribes would facilitate comparative mapping, understanding chromosomal evolution patterns and perhaps assist breeding and domestication strategies. We found that the study of the presence and organization of two repetitive DNA satellite sequences (the clone pOaKB9 from sheep, a member of the 1.714 satellite I family and the pBtKB5, a 1.715 satellite I clone from cattle) on the X and autosomal chromosomes by in situ hybridization to chromosomes from 15 species of seven tribes, was informative. The results support a consistent phylogeny, suggesting that the primitive form of the X chromosome is acrocentric, and has satellite I sequences at its centromere. Because of the distribution of the ancient satellite I sequence, the X chromosome from the extant Tragelaphini (e.g. oryx), rather than Caprini (sheep), line is most primitive. The Bovini (cow) and Tragelaphini tribes lack the 1.714 satellite present in the other tribes, and this satellite is evolutionarily younger than the 1.715 sequence, with absence of the 1.714 sequence being a marker for the Bovini and Tragelaphini tribes (the Bovinae subfamily). In the other tribes, three (Reduncini, Hippotragini and Aepycerotini) have both 1.714 and 1.715 satellite sequences present on both autosomes and the X chromosome. We suggest a parallel event in two lineages, leading to X chromosomes with the loss of 1.715 satellite from the Bovini, and the loss of both 1.714 and 1.715 satellites in a monophyletic Caprini and Alcelaphini lineage. The presence and X chromosome distribution of these satellite sequences allow the seven tribes to be distributed to four groups, which are consistent with current diversity estimates, and support one model to resolve points of separation of the tribes.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Phylogenetic relationships and the primitive X chromosome inferred from chromosomal and satellite DNA analysis in Bovidae

2005

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“…The ubiquity and persis-tence of heterochromatin in these genomes suggest that this distinctive genomic component has an adaptive value, be-sides being considered a genomic compartment carrying out important functions with an unconventional structural and functional basis (Dimitri et al 2004). Among other repetitive sequences, this genomic fraction comprises satellite DNAs that usually reside in the centromeric regions of chromo-somes (Chaves et al 2000). Identification of CH and its size differences is made feasible by the simple but extremely useful C-banding technique.…”

Section: Introductionmentioning

confidence: 99%

Chromosomal evolution and phylogenetic analyses in Tayassu pecari and Pecari tajacu (Tayassuidae): tales from constitutive heterochromatin

Adega

Chaves

Guedes-Pinto

2007

J Genet

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The mammalian family Tayassuidae (peccaries) is confined to the New World and comprises three recognized extant species, white-lipped (Tayassu pecari), collared (Pecari tajacu) and chacoan (Catagonus wagneri) peccaries, which exhibit distinct morphological and chromosomal features. The phylogenetic relationships among the tayassuids are unclear and have instigated debate over the palaeontological, cytogenetic and molecular aspects. Constitutive heterochromatin analysis can be used in understanding the phylogenetic relationships between related species. Here we describe, for the first time, the constitutive heterochromatin (C-positive heterochromatin) of two tayassuid species, Tayassu pecari and Pecari tajacu. We demonstrate that in situ restriction endonuclease digestion with sequential C-banding could be a complementary tool in the study of constitutive heterochromatin heterogeneity in chromosomes of the Tayassuidae. Our characterization of peccary chromosomes suggests that the Pecari tajacu autosomal karyotype is more primitive and has accumulated great diversity in its constitutive heterochromatin. This idea is supported by several other studies that analysed nuclear and mitochondrial sequences of the living peccary species. Finally, the tayassuid X chromosome primitive form seems to be the one of Tayassu pecari.

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“…1). The sheep satellite I DNA (the 1.714 family) has a repeat unit of 820 bp and, as the bovine satellites, constitutes the centromeric heterochromatin of all autosomes, but not of the sex chromosomes (Buckland, 1983;Burkin et al, 1996;Chaves et al, 2000;Chaves et al, 2005). However, the amount and organization of satellite I DNA differ among the autosomes, with a lower amount at the centromeres of the biarmed chromosomes 1, 2, and 3, particularly of chromosome 1 (Burkin et al, 1996;D'Aiuto et al, 1997).…”

Section: Cetartiodactylamentioning

confidence: 99%

Centromere Evolution: Digging into Mammalian Primary Constriction

Giannuzzi¹,

Catacchio²,

Ventura³

2012

Current Frontiers and Perspectives in Cell Biology

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The species and chromosomal distribution of the centromeric α-satellite I sequence from sheep in the tribe Caprini and other Bovidae

Cited by 36 publications

References 17 publications

Phylogenetic relationships and the primitive X chromosome inferred from chromosomal and satellite DNA analysis in Bovidae

Phylogenetic relationships and the primitive X chromosome inferred from chromosomal and satellite DNA analysis in Bovidae

Chromosomal evolution and phylogenetic analyses in Tayassu pecari and Pecari tajacu (Tayassuidae): tales from constitutive heterochromatin

Centromere Evolution: Digging into Mammalian Primary Constriction

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