A novel locus for dilated cardiomyopathy maps to canine chromosome 8.

Dilated cardiomyopathy (DCM), the most common form of cardiomyopathy, often leads to heart failure and sudden death. While a substantial proportion of DCMs are inherited, mutations responsible for the majority of DCMs remain unidentified. A genome-wide linkage study was performed to identify the locus responsible for an autosomal recessive inherited form of juvenile DCM (JDCM) in Portuguese water dogs using 16 families segregating the disease. Results link the JDCM locus to canine chromosome 8 with two-point and multipoint lod scores of 10.8 and 14, respectively. The locus maps to a 3.9-Mb region, with complete syntenic homology to human chromosome 14, that contains no genes or loci known to be involved in the development of any type of cardiomyopathy. This discovery of a DCM locus with a previously unknown etiology will provide a new gene to examine in human DCM patients and a model for testing therapeutic approaches for heart failure.

Bone marrow transplantation for feline mucopolysaccharidosis I.

Severe mucopolysaccharidosis type I (MPS I) is a fatal neuropathic lysosomal storage disorder with significant skeletal involvement. Treatment involves bone marrow transplantation (BMT), and although effective, is suboptimal, due to treatment sequelae and residual disease. Improved approaches will need to be tested in animal models and compared to BMT. Herein we report on bone marrow transplantation to treat feline mucopolysaccharidosis I (MPS I). Five MPS I stably engrafted kittens, transplanted with unfractionated bone marrow (6.3x10(7)-1.1x10(9) nucleated bone marrow cells per kilogram) were monitored for 13-37 months post-engraftment. The tissue total glycosaminoglycan (GAG) content was reduced to normal levels in liver, spleen, kidney, heart muscle, lung, and thyroid. Aorta GAG content was between normal and affected levels. Treated cats had a significant decrease in the brain GAG levels relative to untreated MPS I cats and a paradoxical decrease relative to normal cats. The alpha-l-iduronidase (IDUA) activity in the livers and spleens of transplanted MPS I cats approached heterozygote levels. In kidney cortex, aorta, heart muscle, and cerebrum, there were decreases in GAG without significant increases in detectable IDUA activity. Treated animals had improved mobility and decreased radiographic signs of disease. However, significant pathology remained, especially in the cervical spine. Corneal clouding appeared improved in some animals. Immunohistochemical and biochemical analysis documented decreased central nervous system ganglioside storage. This large animal MPS I study will serve as a benchmark of future therapies designed to improve on BMT.

The keeshond defect in cardiac conotruncal development is oligogenic.

Earlier studies in the keeshond breed of dogs established that isolated conotruncal defects (CTDs) are a group of genetically and embryologically related cardiac malformations, including sub-clinical defects of the conal septum, conal ventricular septal defects, tetralogy of Fallot, and persistent truncus arteriosus. The same spectrum occurs in some human families. In both species, inheritance of non-syndromic CTDs is usually complex and multifactorial inheritance has been assumed. Previous studies in the keeshond suggested that susceptibility to CTD is an autosomal recessive trait, with alleles at modifying loci affecting severity. Here we report results of a genome-wide scan for CTD linked loci in a keeshond x beagle F1 backcross pedigree in which 46 of 101 offspring had CTDs. Two-point linkage analysis identified regions of suggestive linkage on each of three chromosomes CFA2, CFA9, and CFA15. No single locus accounted for segregation of CTDs in the pedigree, ruling out a single autosomal susceptibility locus. Multipoint analysis with Genehunter resulted in a corrected LOD score of 3.7 at the locus on CFA9 and supported linkage to the loci on CFA2 and CFA15 (LOD scores of 2.71 and 3.03). Genehunter Twolocus analysis suggested that CTD-predisposing alleles of these three loci are necessary, at least in pairs, to produce CTD. The canine CTD-linked chromosome regions are orthologous to human regions HSA5q11-13, HSA5q31, HSA17q11-24, and HSA4q31. We excluded from the linked regions in the dog, a number of genes known to have a role in the etiology of CTDs and predict that continuing studies will identify CTD-predisposing genes not previously recognized.