Genetic diversity of Swiss sheep breeds in the focus of conservation research.

There is constant pressure to improve evaluation of animal genetic resources in order to prevent their erosion. Maintaining the integrity of livestock species as well as their genetic diversity is of paramount interest for long-term agricultural policies. One major use of DNA techniques in conservation is to reveal genetic diversity within and between populations. Forty-one microsatellites were analysed to assess genetic diversity in nine Swiss sheep breeds and to measure the loss of the overall diversity when one breed would become extinct. The expected heterozygosities varied from 0.65 to 0.74 and 10.8% of the total genetic diversity can be explained by the variation among breeds. Based on the proportion of shared alleles, each of the nine breeds were clearly defined in their own cluster in the neighbour-joining tree describing the relationships among the breeds. Bayesian clustering methods assign individuals to groups based on their genetic similarity and infer the number of populations. In STRUCTURE, this approach pooled the Valais Blacknose and the Valais Red. With BAPS method the two Valais sheep breeds could be separated. Caballero & Toro approach (2002) was used to calculate the loss or gain of genetic diversity when each of the breeds would be removed from the set. The changes in diversity based on between-breed variation ranged from -12.2% (Valais Blacknose) to 0% (Swiss Black Brown Mountain and Mirror Sheep); based on within-breed diversity the removal of a breed could also produce an increase in diversity (-0.6% to + 0.6%). Allelic richness ranged from 4.9 (Valais Red) to 6.7 (Brown Headed Meat sheep and Red Engadine Sheep). Breed conservation decisions cannot be limited to genetic diversity alone. In Switzerland, conservation goals are embedded in the desire to carry the cultural legacy over to future generations.

Analysis of pedigree and conformation data to explain genetic variability of the horse breed Franches-Montagnes.

Franches-Montagnes is the only native horse breed in Switzerland, therefore special efforts should be made for ensuring its survival. The objectives of this study were to characterize the structure of this population as well as genetic variability with pedigree data, conformation traits and molecular markers. Studies were focused to clarify if this population is composed of a heavy- and a light-type subpopulation. Extended pedigree records of 3-year-old stallions (n = 68) and mares (n = 108) were available. Evaluations of body conformation traits as well as pedigree data and molecular markers did not support the two-subpopulation hypothesis. The generation interval ranged from 7.8 to 9.3 years. The complete generation equivalent was high (>12). The number of effective ancestors varied between 18.9 and 20.1, whereof 50% of the genetic variability was attributed to seven of them. Genetic contribution of Warmblood horses ranged from 36% to 42% and that of Coldblood horses from 4% to 6%. The average inbreeding coefficient reached 6%. Inbreeding effective population size was 114.5 when the average increase of the inbreeding coefficient per year since 1910 was taken. Our results suggest that bottleneck situations occurred because of selection of a small number of sire lines. Promotion of planned matings between parents that are less related is recommended in order to avoid a reduction of the genetic diversity.

Genetic diversity among horse populations with a special focus on the Franches-Montagnes breed.

Genetic characterization helps to assure breed integrity and to assign individuals to defined populations. The objective of this study was to characterize genetic diversity in six horse breeds and to analyse the population structure of the Franches-Montagnes breed, especially with regard to the degree of introgression with Warmblood. A total of 402 alleles from 50 microsatellite loci were used. The average number of alleles per locus was significantly lower in Thoroughbreds and Arabians. Average heterozygosities between breeds ranged from 0.61 to 0.72. The overall average of the coefficient of gene differentiation because of breed differences was 0.100, with a range of 0.036-0.263. No significant correlation was found between this parameter and the number of alleles per locus. An increase in the number of homozygous loci with increasing inbreeding could not be shown for the Franches-Montagnes horses. The proportion of shared alleles, combined with the neighbour-joining method, defined clusters for Icelandic Horse, Comtois, Arabians and Franches-Montagnes. A more disparate clustering could be seen for European Warmbloods and Thoroughbreds, presumably from frequent grading-up of Warmbloods with Thoroughbreds. Grading-up effects were also observed when Bayesian and Monte Carlo resampling approaches were used for individual assignment to a given population. Individual breed assignments to defined reference populations will be very difficult when introgression has occurred. The Bayesian approach within the Franches-Montagnes breed differentiated individuals with varied proportions of Warmblood.

Bovine spinal muscular atrophy: AFG3L2 is not a positional candidate gene.

Bovine spinal muscular atrophy (BSMA) is a neurodegenerative disorder, which is widespread in Brown Swiss cattle. Main symptoms of the disease are muscular atrophy and recumbency. Affected calves die within few days or weeks. BSMA seems to be inherited as a recessive trait and the disease allele appears to have a common origin. In this study, a pedigree with 30 affected BSMA calves was used to genetically localize the BSMA locus. Linkage analysis was performed between microsatellite markers of seven chromosomes, where the homologous genes of human neurodegenerative disorders are located according to comparative mapping data, and the disease genotype. BSMA was mapped to chromosome 24 confirming the recently published localization (Medugorac et al. 2003). The candidate gene AFG3L2 was physically mapped to chromosome 24q24 using fluorescence in situ hybridization. Due to their different localizations AFG3L2 is not a positional candidate for BSMA. An informative marker localized on the telomeric side of the BSMA locus would be beneficial for marker-assisted selection as well as searching for the causative gene. However, finding a marker distal to BSMA locus is difficult because of its position at the end of the chromosome.

Phylogenetic analysis of the tribe Bovini using microsatellites.

The objective of the present study was to determine if the generally accepted phylogenetic relationships in the tribe Bovini correspond to a phylogenetic scheme derived from polymorphisms at 20 bovine microsatellite loci. This study comprises 17 representative populations: eight Bos taurus, two Bos indicus, one Poëphagus, one Bibos, one Bison, three Bubalus and one Syncerus. Phylogenetic analyses using (delta mu)2 and chord (DC) distances revealed substantial divergence among species. Neighbor-joining trees with both distance measures showed only minor differences. Bos taurus and Bos indicus grouped first, followed by Bos frontalis (Mithan) and Bos grunniens (Yak), Bison bison branched off next and Bubalus bubalis and Syncerus caffer emerged as the two most divergent species from the Bos clade. These findings would suggest that Bos, Poëphagus, and Bibos should be integrated into the Bos genus with each group classified as a subgenus. On the other hand, Bison, Bubalus and Syncerus should each be considered a separate genus. Direct estimates of the divergence times were calculated using the (delta mu)2 genetic distance. Bos taurus and Bos indicus were estimated to have diverged 0.31-0.82 MYA, Bos and Poëphagus: 0.57-1.53 MYA, Bos and Bibos: 0.57-1.52 MYA, Bos and Bison: 0.46-1.23 MYA, Bos and Bubalus: 1.85-4.93 MYA and Bos and Syncerus: 0.98-2.61 MYA.

[PCR--the step to conclusive paternity in parentage control cases in cattle]. / PCR--der Griff nach der IST-Vaterschaft in der Abstammungskontrolle beim Rind.

PCR-based technology used for genotyping microsatellites is going to add new dimensions to parentage control in cattle. In the very near future the determination of microsatellite polymorphisms is expected to replace the former parentage control of conventional blood typing. Parentage control by microsatellite analysis is even more reliable than by the routine haemogenetic procedures. The potential of microsatellite polymorphisms to clarify family relationships is illustrated by 100 cases which could not be solved by conventional blood typing.

Microsatellite-based parentage control in cattle.

As a new approach to parentage control we developed two multiplex coamplification polymerase chain reaction (PCR) systems containing a total of six different short tandem repeat (STR) loci; the microsatellite polymorphisms were visualized by automated fluorescence detection on the Applied Biosystems 373 DNA Sequencer with 672 Genescan Analysis software. Allele frequency data were determined from 238 animals. Thirty-five bovine parentage control cases not solvable by conventional blood typing could be solved.