Myoblasts isolated from hypertrophy-responsive callipyge muscles show altered growth rates and increased resistance to serum deprivation-induced apoptosis.

Back and hind limb muscles of sheep paternally heterozygous for the callipyge single nucleotide polymorphism undergo extensive hypertrophy shortly after birth. We have established cell cultures from foetal semitendinosus and longissimus dorsi muscles of normal and callipyge animals. Cultures were assessed for rates of proliferation, cell death, myogenicity and DLK1 expression. Myoblasts from callipyge semitendinosus, but not longissimus dorsi muscles, proliferated faster than myoblasts isolated from normal semitendinosus muscle, and cells isolated from either callipyge muscle were more resistant to serum deprivation-induced apoptosis than equivalent cells isolated from normal individuals. These observations indicate that there are intrinsic differences in the behaviour of isolated myoblasts, which are associated with their muscle and genotype of origin. As myoblasts are the cells responsible for hypertrophy of muscle fibres, the observed differences in cell growth may play a role in the hypertrophy of certain muscles in callipyge animals.

Evaluation of haplotypes associated with copper toxicosis in Bedlington Terriers in Australia.

OBJECTIVE: To evaluate the haplotype distribution associated with the copper toxicosis gene and the segregation of the mutated allele in a Bedlington Terrier population in Australia. ANIMALS: 131 Bedlington Terriers. PROCEDURE: Samples of DNA and RNA were obtained from each dog. Genetic status of each dog was evaluated by use of the DNA markers C04107; single nucleotide polymorphism (SNP), which was adjacent to exon 2 of Murr1; and a deletion marker for exon 2. A subgroup of the study population was evaluated by use of biochemical and histologic techniques to elucidate the correlation between genotype and phenotype. RESULTS: We identified a recombination between the C04107 marker and Murr1 and a variation in a nucleotide in the splice site of exon 2 in our Bedlington Terrier cohort. Furthermore, we identified a novel haplotype associated with copper toxicosis in this cohort. CONCLUSIONS AND CLINICAL RELEVANCE: Our findings indicate that the deletion of exon 2 was not the sole cause of copper toxicosis, although only exon 2 deletion of Murr1 has been responsible for copper toxicosis in Bedlington Terriers. Although we failed to find a novel mutation in our cohort, we identified an affected dog family with an intact exon 2. Furthermore, we found that an SNP in the 5' splicing site of exon 2 may or may not be associated with a novel mutation of the Murr1 gene or other genes. Loss of linkage between the C04107 marker and the Murr1 gene was also identified in a certain family of dogs.

Functional consequences of the G235R mutation in liver arginase leading to hyperargininemia.

Hyperargininemia is a rare autosomal disorder that results from a deficiency in hepatic type I arginase. This deficiency is the consequence of random point mutations that occur throughout the gene. The G235R patient mutation has been proposed to affect the catalytic activity and structural integrity of the protein [D. E. Ash, L. R. Scolnick, Z. F. Kanyo, J. G. Vockley, S. D. Cederbaum, and D. W. Christianson (1998) Mol. Genet. Metab. 64, 243-249]. The G235R (patient) and G235A (control) arginase mutants of rat liver arginase have been generated to probe the effects of these point mutations on the structure and function of hepatic type I arginase. Both mutant arginases were trimeric by gel filtration, but the control G235A mutant had 56% of wild-type activity and the G235R mutant had less than 0.03% activity compared to the wild-type enzyme. The G235R mutant contained undetectable levels of tightly bound manganese as determined by electron paramagnetic resonance, while the G235A mutant had a Mn(II) stoichiometry of 2 Mn/subunit. Molecular modeling indicates that the introduction of an arginine residue at position 235 results in a major rearrangement of the metal ligands that compromise Mn(II) binding.