The prevalence of nine genetic disorders in a dog population from Belgium, the Netherlands and Germany.

The objective of this study was to screen a dog population from Belgium, the Netherlands and Germany for the presence of mutant alleles associated with hip dysplasia (HD), degenerative myelopathy (DM), exercise-induced collapse (EIC), neuronal ceroid lipofuscinosis 4A (NCL), centronuclear myopathy (HMLR), mucopolysaccharidosis VII (MPS VII), myotonia congenita (MG), gangliosidosis (GM1) and muscular dystrophy (Duchenne type) (GRMD). Blood samples (K3EDTA) were collected for genotyping with Kompetitive Allele Specific PCR (n = 476). Allele and genotype frequencies were calculated in those breeds with at least 12 samples (n = 8). Hardy-Weinberg equilibrium was tested. Genetic variation was identified for 4 out of 9 disorders: mutant alleles were found in 49, 15, 3 and 2 breeds for HD, DM, EIC and NCL respectively. Additionally, mutant alleles were identified in crossbreeds for both HD and EIC. For HD, DM, EIC and NCL mutant alleles were newly discovered in 43, 13, 2 and 1 breed(s), respectively. In 9, 2 and 1 breed(s) for DM, EIC and NCL respectively, the mutant allele was detected, but the respective disorder has not been reported in those breeds. For 5 disorders (HMLR, MPS VII, MG, GM1, GRMD), the mutant allele could not be identified in our population. For the other 4 disorders (HD, DM, EIC, NCL), prevalence of associated mutant alleles seems strongly breed dependent. Surprisingly, mutant alleles were found in many breeds where the disorder has not been reported to date.

Recommendations for animal DNA forensic and identity testing.

Genetic analysis in animals has been used for many applications, such as kinship analysis, for determining the sire of an offspring when a female has been exposed to multiple males, determining parentage when an animal switches offspring with another dam, extended lineage reconstruction, estimating inbreeding, identification in breed registries, and speciation. It now also is being used increasingly to characterize animal materials in forensic cases. As such, it is important to operate under a set of minimum guidelines that assures that all service providers have a template to follow for quality practices. None have been delineated for animal genetic identity testing. Based on the model for human DNA forensic analyses, a basic discussion of the issues and guidelines is provided for animal testing to include analytical practices, data evaluation, nomenclature, allele designation, statistics, validation, proficiency testing, lineage markers, casework files, and reporting. These should provide a basis for professional societies and/or working groups to establish more formalized recommendations.

Application of AFLP markers for QTL mapping in the rabbit.

Two rabbit (Oryctolagus cuniculus) inbred strains (AX/JU and IIIVO/JU) have been used for genetic analysis of quantitative traits related to dietary cholesterol susceptibility. Application of the AFLP (amplified fragment length polymorphism) technique with 15 primer combinations revealed 226 polymorphisms between the 2 inbred strains. A total of 57 animals from a backcross progeny (IIIVO/JU x [IIIVO/JU x AX/JU]F1) were available for the genetic analysis. These backcross animals were fed a commercial pelleted diet fortified with 0.3% w/w cholesterol during a test period that lasted five weeks. A male genetic map could be constructed, consisting of 12 linkage groups and 103 AFLP markers. Linkage analysis between the cholesterol-related traits and marker loci revealed a significant LOD score for the relative weight of adrenal glands in males (LOD score = 3.83), whereas suggestive linkages were found for basal serum total cholesterol levels in females (LOD score = 2.69), for serum total cholesterol response (area under the curve) in males (LOD score = 2.21), and for hematocrit in males (LOD score = 3.24).