Organization and concerted evolution of the ampliconic Y-chromosomal TSPY genes from cattle.

The Y-chromosomal gene TSPY (testis-specific protein Y-encoded) is probably involved in early spermatogenesis and has a variable copy number in different mammalian species. Analysis of bovine BAC clones leads to an estimate of 90 TSPY loci on the bovine Y chromosome. Half of these loci (TSPY-M1 and TSPY-M2) contain a single copy, while the other loci (TSPY-C) contain a cluster of three, possibly four, truncated pseudogenes. Fluorescence in situ hybridization indicated that the TSPY loci are located mainly on the short arm (Yp). The TSPY genes appear to account for about 2.5% of the Y chromosome and contain several published bovine Y-chromosomal microsatellites. The homology of TSPY and the major Y-chromosomal repetitive elements BRY.2 from cattle and OY.1 from sheep (80-85% similarity) further illustrates how the Y chromosome is shaped by rearrangements and horizontal spreading of the most abundant sequences. A comparison of TSPY-M1 sequences from different BAC clones and from related bovine species suggests concerted evolution as one of the mechanisms of the rapid evolution of the mammalian Y chromosome.

Real-time PCR detection of ruminant DNA.

To control the spread of bovine spongiform encephalopathy, several DNA methods have been described for the detection of the species origin of meat and bone meal. Most of these methods are based on the amplification of a mitochondrial DNA segment. We have developed a semiquantitative method based on real-time PCR for detection of ruminant DNA, targeting an 88-bp segment of the ruminant short interspersed nuclear element Bov-A2. This method is specific for ruminants and is able to detect as little as 10 fg of bovine DNA. Autoclaving decreased the amount of detectable DNA, but positive signals were observed in feeding stuff containing 10% bovine material if this had not been rendered in accordance with the regulations, i.e., heated at 134 degrees C for 3 instead of 20 min.

Maternal and paternal lineages in cross-breeding bovine species. Has wisent a hybrid origin?

The tribe Bovini comprises cattle and cattle-like species. Reconstructions of their phylogeny have so far been incomplete and have yielded conflicting conclusions about the relationship of American bison and wisent (European bison). We have compared the sequences of three mitochondrial and two Y-chromosomal DNA segments. Mitochondrial DNA indicates that four distinct maternal lineages diverged after an early split-off of the buffalo species, leading to (1) taurine cattle and zebu, (2) wisent, (3) American bison and yak, and (4) banteng, gaur, and gayal, respectively. At a higher level, lineages (1) and (2) and lineages (3) and (4) are probably associated. In contrast, Y-chromosomal sequences indicate a close association of American and European bison, which is in agreement with their morphological similarity, complete fertility of hybrid offspring, and amplified fragment length polymorphism (AFLP) fingerprints of nuclear DNA. One explanation for the anomalous divergence of the mitochondrial DNA from the two bison species is lineage sorting, which implies that two distinct mitochondrial lineages coexisted in the bison-yak branch until the recent divergence of American bison and wisent. Alternatively, the wisent may have emerged by species hybridization initiated by introgression of bison bulls in another ancestral species. This "transpatric" mode of species formation would be consistent with the recent appearance of the wisent in the fossil record without clearly identifiable ancestors.