Canine neuronal ceroid lipofuscinoses: Promising models for preclinical testing of therapeutic interventions.

The neuronal ceroid lipofuscinoses (NCLs) are devastating inherited progressive neurodegenerative diseases, with most forms having a childhood onset of clinical signs. The NCLs are characterized by progressive cognitive and motor decline, vision loss, seizures, respiratory and swallowing impairment, and ultimately premature death. Different forms of NCL result from mutations in at least 13 genes. The clinical signs of some forms overlap significantly, so genetic testing is the only way to definitively determine which form an individual patient suffers from. At present, an effective treatment is available for only one form of NCL. Evidence of NCL has been documented in over 20 canine breeds and in mixed-breed dogs. To date, 12 mutations in 8 different genes orthologous to the human NCL genes have been found to underlie NCL in a variety of dog breeds. A Dachshund model with a null mutation in one of these genes is being utilized to investigate potential therapeutic interventions, including enzyme replacement and gene therapies. Demonstration of the efficacy of enzyme replacement therapy in this model led to successful completion of human clinical trials of this treatment. Further research into the other canine NCLs, with in-depth characterization and understanding of the disease processes, will likely lead to the development of successful therapeutic interventions for additional forms of NCL, for both human patients and animals with these disorders.

Cervical spinal cord and motor unit pathology in a canine model of SOD1-associated amyotrophic lateral sclerosis.

Development of effective treatments for amyotrophic lateral sclerosis (ALS) would be facilitated by identification of early events in the pathological cascade of disease progression. Degenerative myelopathy (DM), a naturally occurring disease in dogs, is quite similar to forms of ALS associated with SOD1 mutations and is likely to be a good model for these forms of the human disease. The sequence of histopathological changes that occur in DM was characterized by analyzing tissue samples obtained from affected dogs euthanized at various stages of disease progression. Cervical spinal cord and the associated spinal nerve roots, ulnar nerve, and the extensor carpi radialis (ECR) muscle were obtained from Pembroke Welsh Corgi dogs (PWCs) with early and late stage DM and from age-matched unaffected PWCs. In early stage disease there was a substantial change in the ratio of the two main muscle fiber types and an increase in mean muscle fiber area in the ECR. DM, even in late stage disease, was not accompanied by changes in the number of motor neuron cell bodies, in the number of axons in the motor or sensory nerve roots, or in the ulnar nerve. In addition, no disease-related denervation of the acetylcholine receptors of the ECR was observed at any stage of the disease. On the other hand, axon densities in both motor and sensory nerve tracts in the cervical cord were reduced in affected dogs. SOD1-immunoreactive aggregates were observed in spinal cord motor neuron cell bodies only in late stage disease. These findings suggest that some of the earliest pathological changes in DM occur in the muscle fibers and upper motor and sensory neuron tracts in the spinal cord. Targeting therapeutic interventions to these early events in the disease are most likely to be effective in slowing disease progression for DM and may translate to therapy of SOD1-related forms of ALS.