Multiple symmetric lipomatosis (MSL) is a rare disorder of middle life characterized by large nonencapsulated lipomas distributed around the neck, shoulders, and other axial regions. Neurologic involvement, particularly peripheral neuropathy, is frequent. The pathogenesis of the syndrome is still unknown, but ragged-red fibers are occasionally present in muscle of affected patients, suggesting a mitochondrial abnormality. We studied 11 unrelated patients with MSL by means of neurophysiology, muscle morphology, muscle biochemistry, Southern blot, and PCR analysis of mitochondrial DNA. All patients were men aged 41 to 63 years. Clinical or electrophysiologic signs of a sensorimotor polyneuropathy were present in nine patients, eight of whom had a history of alcoholism. In muscle biopsy specimens, the most prominent feature was pathologic subsarcolemmal aggregates of mitochondria. Biochemical analysis of respiratory chain enzymes revealed a moderate but significant decrease of cytochrome c oxidase activity as compared with age-matched controls. In one patient, Southern blot analysis showed multiple deletions of mitochondrial DNA. We conclude that mitochondrial dysfunction is common in MSL and may be based on identifiable defects in the mitochondrial genome.
There is good evidence that patients with Parkinson’s disease have respiratory chain dysfunction in their substantia nigra. Since mitochondrial cytopathies due to enzyme defects in the respiratory chain are predominantly manifested in tissues with a high oxidative metabolism we analyzed oxidative energy metabolism in skeletal muscle from 6 patients with Parkinson’s disease. Control muscles were from subjects of the same age group. Histological and histo-chemical analyses showed no morphological abnormalities found in mitochondrial myopathies. Biochemical analyses of the various complexes of the respiratory chain were normal. Since 13 subunits of complexes I, III, IV and V of the respiratory chain are encoded by the mitochondrial genome we performed Southern blot and PCR analyses in skeletal muscle from patients and controls and found no disease-specific increase in deletions or insertions of the mitochondrial genome. Therefore, we do not think that skeletal muscle reflects the mitochondrial disturbance in Parkinson’s disease found in the substantia nigra.
Point mutations of the mitochondrial genome are often considered to be the cause of certain neurodegenerative disorders and mitochondrial myopathies. Recently, there has been a report on Alzheimer’s disease (AD) point mutations at position 5460 of the mitochondrial genome located within the ND2 gene. Using allele-specific PCR with a sensitivity of detection of less than 1% mutated mtDNA, we investigated postmortem brain samples from 48 patients with AD and blood samples of 15 patients with clinically diagnosed AD. In addition, we investigated tissue samples of patients with different neuromuscular disorders and patients with Downs syndrome. Independent of the tissue analysed very few of all the tested samples of patients showed a point mutation at nt 5460 with a base substitution from G to A. Two out of 19 brain and 48 blood samples from controls carried this mutation. The G to T transversion was not found in any of the so far tested samples. Our results do not support the previously reported significant high frequency of these mutations in AD. A polymorphism seems more likely.
Mitochondrial DNA (mtDNA) deletions have been found in the majority of patients with chronic progressive external ophthalmoplegia and Kearns-Sayre syndrome. A large number of different mtDNA deletions have been identified. They generally spare the two origins of replication and are frequently flanked by direct or indirect repeats. We have found a 3.1-kb deletion of mtDNA in a patient with Kearns-Sayre syndrome that has some unusual features. First, it encompasses nucleotides 11259 to 14368, a localization that was not described before. Second, the deletion is not flanked by direct or indirect repeats, supporting the view that homologous recombination and slip-replication do not account for all mtDNA deletions.
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