Barry J. Cooper

Canine X-linked muscular dystrophy: An animal model of Duchenne muscular dystrophy: Clinical studies

The progression of clinical disease and serum creatine kinase (CK) levels in canine X-linked muscular dystrophy (CXMD) was studied in 7 dogs from birth to 12-14 months and in 18 dogs at varying intervals from birth to 8 weeks. One affected male was studied from age 3.5 to 6 years, and all pups were descendants of this dog. A lethal neonatal form was recognized in some pups. In the more typical form, clinical signs of stunting, weakness and gait abnormalities were evident by 6-9 weeks and were progressive, leading to marked muscle atrophy, fibrosis and contractures by 6 months. Serum CK levels were markedly elevated, such that affected pups could be identified by 1 week. CK values increased until 6-8 weeks, then plateaued at approx. 100 times normal. Affected females and beagle-cross dogs were less severely affected than large breed-cross dogs. In the 2 adult dogs with cardiac insufficiency CK levels had decreased to 5-15 times normal. These studies show that CXMD and Duchenne muscular dystrophy have striking phenotypic as well as genotypic similarities. In addition, these studies of CXMD suggest that in females and in smaller dogs the same genetic defect results in a less severe clinical disease.

Canine X-linked muscular dystrophy : morphologic lesions

Gross pathologic lesions and light microscopic and ultrastructural features of skeletal muscle lesions in canine X-linked muscular dystrophy (CXMD) were studied in dogs from 3 months to 6 years of age. Necrosis and regeneration were present at all ages, but were most prominent in the youngest dogs studied. Increased intracytoplasmic calcium, as evidenced by positive alizarin red S staining, was associated with fiber necrosis, but was also seen in small numbers of otherwise normal fibers. Progressive changes included development of severe fiber size variation, endomysial and perimysial fibrosis, prominent cytoplasmic disorganization, internalization of myonuclei, mitochondrial proliferation, mild fat infiltration, and alterations in the fiber-type pattern. The most consistent early ultrastructural changes were dilatation of the sarcoplasmic reticulum and focal subsarcolemmal areas of degeneration. Convincing sarcolemmal defects were not found. Z-band streaming was present at all ages, and Z-band duplication and nemaline rods were seen in older dogs. Evidence for abnormal regeneration was found in the oldest dog, and was associated with extensive fibrosis. These findings document the progression of lesions in CXMD, and illustrate the profound alterations in fiber organization and fiber type that may occur in late stages of dystrophin-deficient muscular dystrophy.

Deletion of the dystrophin muscle promoter in feline muscular dystrophy

We have characterized the mutation in a feline model of DMD that selectively eliminates expression of the muscle and Purkinje neuronal dystrophin isoforms. The cortical neuronal isoform was expressed at a detectable level in skeletal muscle in the absence of the muscle promoter and levels of PCR products representing cortical neuronal-type transcripts in dystrophic muscle were comparable to those of normal feline skeletal muscle. Although localized at the sarcolemma, cortical neuronal dystrophin apparently failed to protect skeletal muscle. Neuronal transcripts could not be amplified from feline heart, indicating that these promoters are not active in this tissue in the cat.

Progressive muscular dystrophy in a golden retriever dog: light microscope and ultrastructural features at 4 and 8 months.

SummaryThe clinical and morphological features of a congenital myopathy in a young male golden retriever dog were studied. Muscle biopsies at 4 and 8 months of age were examined with light and electron microscopy. Clinical features included early onset of generalized muscle weakness with selective muscle atrophy and hypertrophy, splaying of the limbs, stiff gait, and marked elevation of serum creatine kinase (CK). An electromyograph revealed spontaneous electrical activity characterized by sustained high-frequency activity, which was not abolished by neuromuscular blockade.Morphologically there was marked hypercontraction and segmental necrosis of muscle fibers with phagocytosis and regeneration. Ultrastructurally, dilatation of sarcoplasmic reticulum was the most consistent feature associated with early fiber degeneration. No abnormalities were noted in the central or peripheral nervous system. Progression of the disease was evident at 8 months. It was concluded that the findings are consistent with a dystrophic process of primary muscle origin. The probable genetics and comparison to other animal models of muscular dystrophy and to Duchenne dystrophy are discussed.

Canine X-linked muscular dystrophy: Selective involvement of muscles in neonatal dogs

The development of lesions in dogs with canine X-linked muscular dystrophy (CXMD) was studied in dogs from birth to 8 weeks of age. Selective involvement of muscles was noted in dogs up to 4 weeks of age, after which lesions were noted in all muscles examined. Marked fiber hypertrophy was a consequence of the dystrophic process. Severe degenerative lesions were first detected in the tongue, diaphragm, trapezius, deltoideus, extensor carpi radialis, sartorius, and cranial tibial muscles, with relative sparing of the triceps, biceps femoris, and quadriceps muscles. Fiber necrosis and regeneration were present in the tongue muscle at birth, indicating onset of degeneration in utero. The propensity for early development of lesions in certain muscles could not be attributed to larger fiber diameter or to fiber maturity. It is suggested that early development of lesions in these muscles may be related to the activity of these muscles in neonatal dogs.

Hereditary polioencephalomyelopathy of the Australian Cattle Dog

Abstract A vacuolar degeneration affecting primarily the gray matter in the central nervous system (CNS) of young Australian Cattle Dogs is described. An initial presentation of seizures was followed by a progressive spastic tetraparesis. Grossly evident bilateral and symmetrical foci of malacia were in the nuclei of the cerebellum and brain stem and the gray matter of the spinal cord. Microscopically, vacuolation of glial cells, dilation of the myelin sheaths and reactive astrocytosis characterized mild CNS changes. More advanced lesions displayed progressive dissolution of the neuropil, prominent vacuolation of reactive astrocytes, numerous glial fibrillary acidic protein-positive coiled astrocytic processes, neuronal vacuolation and loss with relative sparing of large neurons. Ultrastructurally, marked mitochondrial accumulation and swelling were seen in astrocytes. In the appendicular muscles, changes interpreted as long-term denervation atrophy accompanied by widespread expression of the neonatal isoform of myosin were observed. The character of the neurological signs, the nature and the distribution of the lesions within the neuroaxis have not been reported in domestic animals. An inherited biochemical defect, possibly mitochondrial, is proposed as the cause. Selected conditions with a bilateral and symmetrical distribution affecting the gray matter of domestic animals are summarized.

Expression of utrophin (dystrophin–related protein) during regeneration and maturation of skeletal muscle in canine X–linked muscular dystrophy

The regulation of utrophin, the autosomal homologue of dystrophin, has been studied in the canine X–linked model of Duchenne muscular dystrophy. Dystrophic muscle has been shown to exhibit abnormal sarcolemmal expression of utrophin, in addition to the normal expression at the neuromuscular junction, in peripheral nerves, vascular tissues and regenerating fibres. To establish whether this abnormal presence of utrophin in dystrophic muscle is a consequence of continued expression following regeneration, or is attributable to a disease related up–regulation, the expression of utrophin was compared immunocytochemically with that of dystrophin, β–spectrin and neonatal myosin in regenerating normal and dystrophic canine muscle, following necrosis induced by the injection of venom from the snake Notechis scutatis. In normal regenerating muscle, sarcolemmal utrophin and dystrophin were detected concomitantly from 2–3 d post–injection, prior to the expression of β–spectrin. Down–regulation of utrophin was apparent in some fibres from 7 d, and it was no longer present on the extra–junctional sarcolemma by 14 d. Neonatal myosin was still present in all fibres at this stage, but dystrophin and β–spectrin had been fully restored. In dystrophic regenerating muscle, downregulation of utrophin occurred from 7 d, although it persisted on some fibres until 28 d, longer than in normal muscle. At 42 d, however, utrophin in dystrophic muscle was only detected in a population of small fibres thought to represent a second cycle of regeneration, with no immunolabelling of mature fibres. The results show that most utrophin is down–regulated in regenerating dystrophic fibres, prior to neonatal myosin, thus abnormal sarcolemmal expression of utrophin in dystrophic muscle is unlikely to be a continuation of the maturational process. Persistence of both utrophin and neonatal myosin, however, suggest a delay in the maturation of dystrophic muscle. In addition, a second cycle of degeneration and regeneration in dystrophic muscle does not occur whilst utrophin is still present, suggesting it may have a protective role against fibre damage and necrosis.

Canine inherited hypertrophic neuropathy.

SummaryA recessively inherited hypertrophic neuropathy was discovered in Tibetan Mastiff dogs. Affected pups developed a generalized weakness with hyporeflexia shortly after weaning. Diagnostic findings in 10–18-week-old pups included: moderate to severe reduction in nerve conduction velocities, infrequent denervation potentials, and inconstant elevation in CSF protein. Light- and electron-microscopic studies of peripheral nerves and roots revealed widespread demyelination and primitive onion bulb formation with relatively little degeneration of axons. Myelin changes often were most striking in the cytoplasmic regions of the sheaths and consisted of separations at the major dense lines, anomalous incisure patterns, and marked filamentous accumulations in the inner spirals and adaxonal cytoplasm. The results of these initial studies suggest an inborn defect in the Schwann cells ability to form or maintain a stable myelin sheath.

Intracellular calcium in canine muscle biopsies

Intracellular staining for calcium was studied in muscle biopsies from 15 dogs by the alizarin red S (ARS) stain. Rare positive fibres were present in normal muscle and in denervation atrophy. The percentage of positive fibres was slightly increased in polymyositis, dermatomyositis and canine temporal/masseter myositis and markedly increased in progressive muscular dystrophy. Calcium-positive fibres were usually so-called large-dark (hypercontracted) fibres or necrotic fibres, although there was occasional staining of normal and atrophied fibres. These results indicate the probable involvement of calcium in muscle injury in canine inflammatory myopathies and in canine muscular dystrophy. In addition, use of the ARS stain appears to be useful for detecting the earliest lesions of acute muscle fibre injury.

Defective Schwann cell function in canine inheritedHypertrophic Neuropathy

SummarySegments of peripheral nerve from dogs with canine inherited hypertrophic neuropathy (CIHN) were transplanted to the transected sciatic nerve of immuno incompetent mice. Regenerating mouse axons penetrated the grafts and were myelimated by dog Schwann cells. In grafts collected 3 or more months after transplantation, filamentous or granular material, identical to that occurring in nerves of affected dogs, accumulated in myelinating Schwann cells. Demyelinated fibers were only rarely found in grafted segments of affected nerve. Neither filamentous accumulations nor demyelination were observed in grafts of control canine nerve.These results indicate that CIHN is associated with a defect in Schwann cell function, and the abnormal accumulations of filaments suggest that the defect may be in the cytoskeleton. The rarity of demyelination in grafts suggests that some factor in addition to the Schwann cell defect is required to precipitate myelin destruction.