Martha Elisa Vázquez-Memije scite author profile

The authors identified a novel mtDNA mutation (T9176G) in the ATPase 6 gene in a family in which a 10-year-old girl had a severe neurodegenerative disorder, her elder sister had died of Leigh syndrome (LS), and a maternal uncle had a spinocerebellar disorder. Biochemical studies disclosed a reduced rate of ATP synthesis in skin fibroblast cultures from the proposita as the likely explanation of her severe illness. The findings expand the genetic variants associated with LS.

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ATP6 Homoplasmic Mutations Inhibit and Destabilize the Human F1F0-ATP Synthase without Preventing Enzyme Assembly and Oligomerization

Cortés-Hernández

Vázquez-Memije

Garcia

2007

Journal of Biological Chemistry

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The molecular pathogenic mechanism of the human mitochondrial diseases neurogenic ataxia and retinitis pigmentosa and maternally inherited Leigh syndrome was determined in cultured human cells harboring homoplasmic T8993G/T8993C point mutations in the mitochondrial ATP6 gene, which encodes subunit 6 of the F 1 F 0 -ATP synthase. Immunoprecipitation and blue native electrophoresis showed that F 1 F 0 -ATP synthase assembles correctly in homoplasmic mutant mitochondria. The mutants exhibited a tendency to have an increased sensitivity to subsaturating amounts of oligomycin; this provided further evidence for complete assembly and tight coupling between the F 1 and F 0 sectors. Furthermore, human ATP synthase dimers and higher homo-oligomers were observed for the first time, and it was demonstrated that the mutant enzymes retain enough structural integrity to oligomerize. A reproducible increase in the proportion of oligomeric-to-monomeric enzyme was found for the T8993G mutant suggesting that F 1 F 0 oligomerization is regulated in vivo and that it can be modified in pathological conditions. Despite correct assembly, the T8993G mutation produced a 60% inhibition in ATP synthesis turnover. In vitro denaturing conditions showed F 1 F 0 instability conferred by the mutations, although this instability did not produce enzyme disassembly in the conditions used for determination of ATP synthesis. Taken together, the data show that the primary molecular pathogenic mechanism of these deleterious human mitochondrial mutations is functional inhibition in a correctly assembled ATP synthase. Structural instability may play a role in the progression of the disease under potentially denaturing conditions, as discussed.

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Comparative biochemical studies of ATPases in cells from patients with the T8993G or T8993C mitochondrial DNA mutations

Vázquez-Memije

Shanske

Santorelli

et al. 1998

J of Inher Metab Disea

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We performed comparative biochemical studies in cultured fibroblast mitochondria from patients with the T8993G or the T8993C point mutations in the ATPase 6 gene of mitochondrial DNA. We found that ATP production was much more severely decreased in cells from patients with the T8993G mutation than in those from patients with the T8993C mutation. Kinetic studies suggest that both mutations affect only the F0 sector of the mitochondrial ATPase complex. We conclude that these two mutations, which result in the substitution of different amino acids at the same site of the ATPase, result in an enzyme with different biochemical characteristics.

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