oligomycins and Leigh-Disease

To verify whether enhanced substrate-level phosphorylation increases viability and adenosine 5'-triphosphate (ATP) content of cells with neuropathy, ataxia, and retinitis pigmentosa/maternally inherited Leigh syndrome (NARP/MILS) mitochondrial DNA mutations and ATP synthase dysfunction.. We used cell lines "poisoned" with oligomycin, the specific inhibitor of ATP synthase, and "natural" models, including transmitochondrial human cell lines (cybrids) harboring 2 different pathogenic mutations associated with the NARP/MILS phenotypes.. Cell survival, morphology, and ATP content.. When normal human fibroblasts cultured in glucose-free medium were forced to increase energy consumption by exposure to the ionophore gramicidin or were energy challenged by oligomycin inhibition, their survival at 72 hours was 5%, but this increased to 70% when the medium was supplemented with alpha-ketoglutarate/aspartate to boost mitochondrial substrate-level phosphorylation. Homoplasmic cybrids harboring the 8993T-->G NARP mutation were also protected from death (75% vs 15% survival at 72 hours) by the supplemented medium and their ATP content was similar to controls.. These results show that ATP synthase-deficient cells can be rescued by increasing mitochondrial substrate-level phosphorylation and suggest potential dietary or pharmacological therapeutic approaches based on the supplementation of alpha-ketoglutarate/aspartate to patients with impaired ATP synthase activity.

Topics: Adenosine Triphosphate; Anti-Infective Agents, Local; Aspartic Acid; C-Reactive Protein; Cell Line; Cell Survival; DNA, Mitochondrial; Energy Metabolism; Gramicidin; Humans; Ketoglutaric Acids; Leigh Disease; Mitochondria; Mitochondrial Proton-Translocating ATPases; Mutation; Nerve Tissue Proteins; Oligomycins; Oxidative Phosphorylation; Retinitis Pigmentosa; Spinocerebellar Degenerations

Point and deletion mutations and a general depletion of mammalian mitochondrial DNA (mtDNA) give rise to a wide variety of medical syndromes that are refractory to treatment, possibly including aging itself. While gene therapy directed at correcting such deficits in the mitochondrial genome may offer some therapeutic benefits, there are inherent problems associated with a direct approach. These problems are primarily due to the high mitochondrial genome copy number in each cell and the mitochondrial genome being "protected" inside the double-membrane mitochondrial organelle. In an alternative approach there is evidence that genes normally present in the mitochondrial genome can be incorporated into the nuclear genome. To extend such studies, we modified the Chinese Hamster Ovary (CHO) mtDNA-located ATPase6 gene (possessing a mutation which confers oligomycin resistance- oli(r)) by altering the mtDNA code to the universal code (U-code) to permit the correct translation of its mRNA in the cytoplasm. The U-code construct was inserted into the nuclear genome (nucDNA) of a wild type CHO cell. The expressed transgene products enabled the transformed CHO cell lines to grow in up to 1000 ng mL(-1) oligomycin, while untransformed sensitive CHO cells were eliminated in 1 ng mL(-1) oligomycin. This approach, termed allotopic expression, provides a model that may make possible the transfer of all 13 mtDNA mammalian protein-encoding genes to the nucDNA, for treatments of mtDNA disorders. The CHO mtATPase6 protein is 85% identical to both the mouse and human mtATPase6 protein; these proteins are highly conserved in the region of the oligomycin resistance mutation. They are also well conserved in the regions of the oligomycin resistance mutation of the mouse, and in the region of a mutation found in Leigh's syndrome (T8993G), also called NARP (neurogenic weakness, ataxia, retinitis pigmentosum). It is likely that the CHO oli(r) mtATPase6 Ucode construct could impart oligomycin-resistance in human and mouse cells, as well as function in place of the mutant ATPase subunit in a NARP cell line. Preliminary experiments on human cybrids homoplasmic for the NARP mutation (kindly supplied by D.C. Wallace), transformed with our construct, display an increased oligomycin resistance that supports these suppositions.

Topics: Animals; CHO Cells; Cricetinae; DNA, Mitochondrial; Gene Transfer Techniques; Genetic Therapy; Leigh Disease; Mitochondrial Proton-Translocating ATPases; Oligomycins; Plasmids; Protein Biosynthesis; Transgenes

The mutation in the mitochondrial ATP synthase subunit 6 gene (ATP6 T8993G) was identified in a male infant who died at age 15 months of Leigh syndrome. He had 94% mutated mitochondrial DNA (mtDNA) in muscle and 92% in lymphocytes. His mother was healthy but had 37% mutated mtDNA in muscle and 38% in lymphocytes. The proband's brother, who was also healthy, had 44% mutated mtDNA in lymphocytes. No mutated mtDNA was detected in muscle and lymphocytes from the maternal grandmother of the proband or in lymphocytes from 15 other maternal relatives, showing that the first carrier of the ATP6 T8993G mutation in this family was the mother of the proband. This study shows that this point mutation may occur at substantial levels in a carrier of a de novo mutation and rapid segregation with high levels of mutated mtDNA causing neurodegenerative disease may occur in the second generation.

Topics: 2,4-Dinitrophenol; Ca(2+) Mg(2+)-ATPase; Dinitrophenols; DNA, Mitochondrial; Heterozygote; Humans; Infant; Leigh Disease; Male; Mitochondria, Muscle; Muscle, Skeletal; Oligomycins; Pedigree; Point Mutation; Proton-Translocating ATPases; Uncoupling Agents