Comparative map between the domestic pig and dog

Cross-species chromosome painting with probes derived from flow-sorted dog and human chromosomes was used to construct a high-resolution comparative map for the pig. In total 98 conserved autosomal segments between pig and dog were detected by probes specific for the 38 autosomes and X Chromosome of the dog. Further integration of our results with the published human--dog and cat--dog comparative maps, and with data from comparative gene mapping, increases the resolution of the current pig--human comparative map. It allows for the conserved syntenies detected in the pig, human, and cat to be aligned against the putative ancestral karyotype of eutherian mammals and for the history of karyotype evolution of the pig lineage to be reconstructed. Fifteen fusions, 17 fissions, and 23 inversions are required to convert the ancestral mammalian karyotype into the extant karyotype of the pig.     

Reciprocal chromosome painting between three laboratory rodent species

The laboratory mouse (Mus musculus, 2n = 40), the Chinese hamster (Cricetulus griseus, 2n = 22), and the golden (Syrian) hamster (Mesocricetus auratus, 2n = 44) are common laboratory animals, extensively used in biomedical research. In contrast with the mouse genome, which was sequenced and well characterized, the hamster species has been set aside. We constructed a chromosome paint set for the golden hamster, which for the first time allowed us to perform multidirectional chromosome painting between the golden hamster and the mouse and between the two species of hamster. From these data we constructed a detailed comparative chromosome map of the laboratory mouse and the two hamster species. The golden hamster painting probes revealed 25 autosomal segments in the Chinese hamster and 43 in the mouse. Using the Chinese hamster probes, 23 conserved segments were found in the golden hamster karyotype. The mouse probes revealed 42 conserved autosomal segments in the golden hamster karyotype. The two largest chromosomes of the Chinese hamster (1 and 2) are homologous to seven and five chromosomes of the golden hamster, respectively. The golden hamster karyotype can be transformed into the Chinese hamster karyotype by 15 fusions and 3 fissions. Previous reconstructions of the ancestral murid karyotype proposed diploid numbers from 2n = 52 to 2n = 54. By integrating the new multidirectional chromosome painting data presented here with previous comparative genomics data, we can propose that syntenies to mouse Chrs 6 and 16 were both present and to hypothesize a diploid number of 2n = 48 for the ancestral Murinae/Cricetinae karyotype.     

Unusually extensive karyotype reorganization in four congeneric Gerbillus species (Muridae: Gerbillinae)

Comparative analysis of the G- and C-banding patterns in four morphologically poorly differentiated Gerbillus species (G. pyramidum, G. perpallidus, G. tarabuli and G. occiduus) was carried out. These gerbils have similar karyotype morphology with 2n and NF equal to 38/76, 40/76, 40/78 and 40/80, respectively. Our study revealed that possibly 70 Robertsonian (Rb) fusions, two pericentric inversions, one tandem translocation and at least 13 non-identified rearrangements have occurred during the karyotypic evolution of these species. The number of chromosomal changes by which any of these species differ from each other ranges from 33 to 49. One Rb fusion was common to two of the species, with only a single autosome-gonosome translocation shared by all four, suggesting a monophyletic origin of these karyotypically highly divergent species. Based on the chromosomal data obtained here, the systematic and geographic implications for these North African species are also discussed.     

Chromosome evolution in eulipotyphla

We integrated chromosome painting information on 5 core-insectivora species available in the literature with new Zoo-FISH data for Iberian shrew (Sorex granarius) and Altai mole (Talpa altaica). Our analysis of these 7 species allowed us to determine the chromosomal features of Eulipotyphla genomes and to update the previously proposed ancestral karyotype for 2 main groups of the Sorex genus. The chromosome painting evidence with human painting probes (HSA) reveals the presence of the 2 unique associations HSA4/5 and 1/10p/12/22b, which support Eulipotyphla. There are a series of synapomorphies both for Erinaceidae (HSA3/1/5, 3/17, 11/15 and 10/20) and for Soricinae (HSA5/9, 6/7/16, 8/3/21 and 11/12/22). We found associations that link Talpidae/Erinaceidae (HSA7/8, 1/5 and 1/19p), Talpidae/Soricidae (HSA1/8/4) and Erinaceidae/Soricidae (HSA4/20 and 2/13). Genome conservation in Eulipotyphla was estimated on the basis of the number of evolutionary breaks in the ancestral mammalian chromosomes. In total, 7 chromosomes of the boreo-eutherian ancestor (BEA8 or 10, 9, 17, 18, 20-22) were retained in all eulipotyphlans studied; among them moles show the highest level of chromosome conservation. The integration of sequence data into the chromosome painting information allowed us to further examine the chromosomal syntenies within a phylogenetic perspective. Based on our analysis we offer the most parsimonious reconstruction of phylogenetic relationships in Eulipotyphla. The cytogenetic reconstructions based on these data do not conflict with molecular phylogenies supporting basal position of Talpidae in the order.     

Comparative cytogenetics of main Laurasiatheria taxa

This short communication is a review of key trends in the karyotypic evolution of mammalian taxa Laurasiatheria, inferred from comparative chromosome painting.     

Comparative molecular cytogenetic studies in the order Carnivora: mapping chromosomal rearrangements onto the phylogenetic tree

We have made a set of chromosome-specific painting probes for the American mink by degenerate oligonucleotide primed-PCR (DOP-PCR) amplification of flow-sorted chromosomes. The painting probes were used to delimit homologous chromosomal segments among human, red fox, dog, cat and eight species of the family Mustelidae, including the European mink, steppe and forest polecats, least weasel, mountain weasel, Japanese sable, striped polecat, and badger. Based on the results of chromosome painting and G-banding, comparative maps between these species have been established. The integrated map demonstrates a high level of karyotype conservation among mustelid species. Comparative analysis of the conserved chromosomal segments among mustelids and outgroup species revealed 18 putative ancestral autosomal segments that probably represent the ancestral chromosomes, or chromosome arms, in the karyotype of the most recent ancestor of the family Mustelidae. The proposed 2n = 38 ancestral Mustelidae karyotype appears to have been retained in some modern mustelids, e.g., Martes, Lutra, Ictonyx, and Vormela. The derivation of the mustelid karyotypes from the putative ancestral state resulted from centric fusions, fissions, the addition of heterochromatic arms, and occasional pericentric inversions. Our results confirm many of the evolutionary conclusions suggested by other data and strengthen the topology of the carnivore phylogenetic tree through the inclusion of genome-wide chromosome rearrangements.     

Chromosomal phylogeny of certain shrews of the genera Crocidura and Suncus (Insectivora)

High-resolution chromosome analysis of eight Palaearctic and Oriental species of white-toothed shrews reveals almost complete chromosomal homology between the karyotypes studied, and extensive G-band homology is demonstrated even between species of the genera Crocidura and Suncus . Robertsonian translocations, tandem fusions, fissions, whole-arm reciprocal translocations, centromeric shifts, heterochromatin additions, and inversions are identified as the main mechanisms of chromosomal evolution. The evolutionary relationships of the Eurasian crocidurines under study are reconstructed and a hypothetical ancestral karyotype with 44 chromosomes is proposed.     

Homology of G-banded mammalian chromosomes

Linkage relationships of homologous loci and high resolution G-banding patterns of man, mouse, rat, chinese hamster, rabbit, cat, mink, pig, ox and sheep were used for identification of 11 evolutionary conservative autosomal regions. The distributions and inversions of these regions in the ancestor genomes of some phylums have been shown. For example, the regions homologous to human Ip region were detected in cat, mink and rabbit genomes. In the genomes of rodents studied the intraregion inversion was detected. In the ox and sheep genomes the distal end deletions were detected within these regions. In the pig genome these regions were represented solely by disruptions. We supposed that the rapid "catastrophic" chromosomal evolution took place during short time periods of some orders and families separation.     

Interstitial telomeric repeats as markers of evolutionary changes in the mammalian karyotype: Human chromosome 2

The presence of conserved telomeric repeats represented by the hexamer (TTAGGG)_n at the chromosomal termini is necessary for the correct functioning and stability of chromosomes. A number of the genomes of mammals, including human, are known to contain interstitial telomeric sequences located far from the chromosomal termini. It is assumed that these repeats mark the regions of fusions or other rear-rangements of ancestral chromosomes. Exact localization of all interstitial telomeric sequences in the genome could significantly advance the understanding of the mechanisms of karyotype evolution and speciation. In this context, software was developed to search for degenerate interstitial telomeric repeats in complete sequences of mammalian chromosomes. The evolutionary significance of such repeats was demonstrated by the example of human chromosome 2. The results are available at http://www.bionet.nsc.ru/labs/theorylabmain/orlov/telomere/.