Chromosomal assignment of six genes (EIF4G3, HSP90, RBBP6, IL8, TERT, and TERC) in four species of the genus Equus.

We mapped six genes (EIF4G3, HSP90, RBBP6, IL8, TERT, and TERC) on the chromosomes of Equus caballus, Equus asinus, Equus grevyi, and Equus burchelli by fluorescence in situ hybridization. Our results add six type I markers to the cytogenetic map of these species and provide new information on the comparative genomics of the genus Equus.

Uncoupling of satellite DNA and centromeric function in the genus Equus.

In a previous study, we showed that centromere repositioning, that is the shift along the chromosome of the centromeric function without DNA sequence rearrangement, has occurred frequently during the evolution of the genus Equus. In this work, the analysis of the chromosomal distribution of satellite tandem repeats in Equus caballus, E. asinus, E. grevyi, and E. burchelli highlighted two atypical features: 1) several centromeres, including the previously described evolutionary new centromeres (ENCs), seem to be devoid of satellite DNA, and 2) satellite repeats are often present at non-centromeric termini, probably corresponding to relics of ancestral now inactive centromeres. Immuno-FISH experiments using satellite DNA and antibodies against the kinetochore protein CENP-A demonstrated that satellite-less primary constrictions are actually endowed with centromeric function. The phylogenetic reconstruction of centromere repositioning events demonstrates that the acquisition of satellite DNA occurs after the formation of the centromere during evolution and that centromeres can function over millions of years and many generations without detectable satellite DNA. The rapidly evolving Equus species gave us the opportunity to identify different intermediate steps along the full maturation of ENCs.

Evolutionary movement of centromeres in horse, donkey, and zebra.

Centromere repositioning (CR) is a recently discovered biological phenomenon consisting of the emergence of a new centromere along a chromosome and the inactivation of the old one. After a CR, the primary constriction and the centromeric function are localized in a new position while the order of physical markers on the chromosome remains unchanged. These events profoundly affect chromosomal architecture. Since horses, asses, and zebras, whose evolutionary divergence is relatively recent, show remarkable morphological similarity and capacity to interbreed despite their chromosomes differing considerably, we investigated the role of CR in the karyotype evolution of the genus Equus. Using appropriate panels of BAC clones in FISH experiments, we compared the centromere position and marker order arrangement among orthologous chromosomes of Burchelli's zebra (Equus burchelli), donkey (Equus asinus), and horse (Equus caballus). Surprisingly, at least eight CRs took place during the evolution of this genus. Even more surprisingly, five cases of CR have occurred in the donkey after its divergence from zebra, that is, in a very short evolutionary time (approximately 1 million years). These findings suggest that in some species the CR phenomenon could have played an important role in karyotype shaping, with potential consequences on population dynamics and speciation.

Amplification of the pericentromeric region of chromosome 1 in a newly established colon carcinoma cell line.

The LRWZ cell line was established from an ascitic effusion of a colon adenocarcinoma. We studied the karyotype of LRWZ cells using G-banding and chromosome painting. The cell line is near triploid and is characterized by several chromosome rearrangements and pronounced intermetaphase variation. Chromosome painting probes revealed numerous labeled regions on different chromosomes, indicating that several translocations occurred during the evolution of the cell population. The 10 recurrent marker chromosomes identified (M1-M10) were derived from complex rearrangements involving up to three different chromosomes. M2 is a particularly interesting marker that originated from the amplification of the pericentromeric region of chromosome 1 and has a peculiar organization comprising five copies of the region included between 1p21 and 1q21 and is surprisingly stable: it is present in all the metaphases analyzed, has telomeric DNA at both termini, and contains one active and four inactivated centromeres. To provide insights into the molecular mechanisms that generated M2, we performed fluorescence in situ hybridization experiments using a panel of probes mapping near the centromere of chromosome 1 and three probes for different satellite sequences; the formation of chromosome M2 required the intervention of several rearrangements including unequal exchange, chromatid breakage followed by fusion of the sister chromatids, and loss of centromeric heterochromatin.

Molecular organization of internal telomeric sequences in Chinese hamster chromosomes.

In Chinese hamster extended blocks of telomeric-like repeats were previously detected by in situ hybridization at the pericentromeric region of most chromosomes and short arrays were localized at several interstitial sites. In this work, we analyzed the molecular organization of internal telomeric sequences (ITs) in the Chinese hamster genome. In genomic transfers hybridized with a telomeric probe, multiple Bal31 insensitive fragments were detected. Most of the fragments ranged in size between less than 1 kb and more than 100 kb and some were polymorphic. Fluorescence in situ hybridization experiments on DNA fibers and on elongated chromosomes showed that the pericentromeric ITs are composed of extensive and essentially continuous arrays of telomeric-like sequences. We then isolated three genomic regions which contain short ITs. These ITs are localized at interstitial sites (3q13-15, 3q21-26, 1p26) and are composed of 29-126 bp of (TTAGGG)(n) repeats. A peculiar feature of all the three ITs is the AT richness of the flanking sequences. Since AT-rich DNA is known to be unstable and characteristic of several mammalian fragile sites, we propose that the three ITs were inserted at these sites during the repair of double strand breaks.