Oxidative phosphorylation differences between mitochondrial DNA haplogroups modify the risk of Leber's hereditary optic neuropathy.

Leber's hereditary optic neuropathy is a maternally inherited optic atrophy caused by mitochondrial DNA point mutations. Previous epidemiological studies have shown that individuals from mitochondrial genetic backgrounds (haplogroups) J/Uk and H have a higher and a lower risk, respectively, of suffering this disorder. To analyze the bases of these associations at cellular and molecular levels, functional studies with cybrids provide high quality evidence. Cybrids from haplogroup J contain less mitochondrial deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) and synthesize a smaller amount of mitochondrial DNA-encoded polypeptides than those from haplogroup H. Haplogroup J cybrids also display lower oxygen consumption, mitochondrial inner membrane potential and total adenosine-5'-triphosphate (ATP) levels. Moreover, mitochondrial DNA levels correlate with many parameters of the oxidative phosphorylation system. These results suggest that the mitochondrial DNA amount determines oxidative phosphorylation capacity and, along with other recently published observations, support the possibility that mitochondrial DNA levels may be responsible for the bias of the disorder toward males, for the incomplete penetrance of mutations causing Leber's hereditary optic neuropathy and for the association of the disease with particular mitochondrial DNA haplogroups.

Human mitochondrial variants influence on oxygen consumption.

This work investigates if human mitochondrial variants influence on maximal oxygen consumption (VO(2max)). With this purpose we recruited, as a uniform population in term of nutritional habits and life style, 114 healthy male Spanish subjects that practiced fitness exercises 3-4 times a week. Once mtDNA haplogroups were determined, we found that J presents with lower VO(2max) (P=0.02) than nonJ variants. J has been related with a lower efficiency of electron transport chain (ETC), diminished ATP and ROS production. Thus, the difficult to compensate the mitochondrial energetic deficiency could explain the accumulation of J haplogroup in LHON and multiple sclerosis. Furthermore, the lower ROS production associated to J could also account for the accrual of this variant in elderly people consequent to a decreased oxidative damage.

A new pathologic mitochondrial DNA mutation in the cytochrome oxidase subunit I (MT-CO1).

A disorder of mitochondrial energy metabolism may be missed in children with a very mild phenotype. Here, we described a patient with a moderate mental retardation and a mild exercise intolerance. This child harboured a mtDNA transition (m.6955G>A) in the subunit I of the cytochrome oxidase (MT-CO1) that fulfils most of the requirements to be pathologic. Despite this subunit is the second longest polypeptide encoded in the mtDNA, only one other missense mutation associated with a myopathy has been described. This suggests that we are missing other phenotypes and that the mitochondrial pathology field is broader that previously thought.

De Toni-Debré-Fanconi syndrome due to a palindrome-flanked deletion in mitochondrial DNA.

We report the molecular findings in a child presenting with sideroblastic anemia and proximal tubulopathy. Analysis of mitochondrial DNA (mtDNA) from fibroblasts showed the presence of a 3.3-kb single deletion in 50% of the genomes. This mutation is, unlike other previously reported deletions in tubulopathy patients, not flanked by direct repeat sequences but by palindrome sequences at the deletion breakpoints, suggesting an unusual mechanism for production of deletion. These findings further expand our knowledge of the syndrome of anemia and tubulopathy due to single deletions of mtDNA.

Bilateral striatal necrosis associated with a novel mutation in the mitochondrial ND6 gene.

We report the molecular findings in two independent patients presenting with progressive generalized dystonia and bilateral striatal necrosis in whom we have identified a mutation (T14487C) in the mitochondrial ND6 gene. The mutation is heteroplasmic in all samples analyzed, and it fulfills all accepted criteria of pathogenicity. Transmitochondrial cell lines harboring 100% mutant mitochondrial DNA showed a marked decrease in the activity of complex I of the respiratory chain supporting the pathogenic role of T14487C.

Isolation of biogenetically competent mitochondria from mammalian tissues and cultured cells.

This article describes a quick basic method adapted for the purification of mammalian mitochondria from different sources. The organelles obtained using this protocol are suitable for the investigation of biogenetic activities such as enzyme activity, mtDNA, mtRNA, mitochondrial protein synthesis, and mitochondrial tRNA aminoacylation. In addition, these mitochondria are capable of efficient protein import and the investigation of mtDNA/protein interactions by DNA footprinting is also possible.