Increased platelet activation in sleep apnea subjects with intermittent hypoxemia.

PURPOSE: Obstructive sleep apnea (OSA) is independently associated with increased risk for stroke and other cardiovascular diseases. Since activated platelets play an important role in cardiovascular disease, the objective of this study was to determine whether platelet reactivity was altered in OSA subjects with intermittent nocturnal hypoxemia. METHODS: Thirty-one subjects, without hypertension or cardiovascular disease and not taking medication, participated in the study. Subjects were stratified based on OSA-related oxygen desaturation index (ODI) recorded during overnight polysomnography. Platelet reactivity to a broad panel of agonists (collagen, thrombin, protease-activated receptor1 hexapeptide, epinephrine, ADP) was measured by monitoring platelet aggregation and ATP secretion. Expression of platelet activation markers CD154 (CD40L) and CD62P (P-selectin) and platelet-monocyte aggregates (PMA) was quantified by flow cytometry. RESULTS: Epinephrine-induced platelet aggregation was substantially decreased in OSA subjects with significant intermittent hypoxemia (ODI ≥ 15) compared with subjects with milder hypoxemia levels (ODI < 15) (area under curve, p = 0.01). In addition, OSA subjects with ODI ≥ 15 exhibited decreased thrombin-induced platelet aggregation (p = 0.02) and CD40L platelet surface expression (p = 0.05). Platelet responses to the other agonists, CD62P platelet surface expression, and PMA levels were not significantly different between groups. Reduction in platelet responses to epinephrine and thrombin, and decreased CD40L surface marker expression in significant hypoxemic OSA individuals, is consistent with their platelets being in an activated state. CONCLUSIONS: Increased platelet activation was present in otherwise healthy subjects with intermittent nocturnal hypoxemia due to underlying OSA. This prothrombotic milieu in the vasculature is likely a key contributing factor toward development of thrombosis and cardiovascular disease. TRIAL REGISTRATION: NCT00859950.

The m.3243A>G mtDNA mutation is pathogenic in an in vitro model of the human blood brain barrier.

MELAS is a common mitochondrial disease frequently associated with the m.3243A>G point mutation in the tRNA(Leu(UUR)) of mitochondrial DNA and characterized by stroke-like episodes with vasogenic edema and lactic acidosis. The pathogenic mechanism of stroke and brain edema is not known. Alterations in the blood brain barrier (BBB) caused by respiratory chain defects in the cortical microvessels could explain the pathogenesis. To test this hypothesis we developed a tissue culture model of the human BBB. The MELAS mutation was introduced into immortalized brain capillary endothelial cells and astrocytes. Respiratory chain activity and transendothelial electrical resistance, TEER was measured. Severe defects of respiratory chain complex I and IV activities, and a moderate deficiency of complex II activity in cells harboring the MELAS mutation were associated with low TEER, indicating that the integrity of the BBB was compromised. These data support our hypothesis that respiratory chain defects in the components of the BBB cause changes in permeability.

Evidence for nuclear modifier gene in mitochondrial cardiomyopathy.

Mitochondrial DNA (mtDNA) inheritance and maintenance and function of the respiratory chain are the result of a synergistic action of the nuclear and the mitochondrial genomes. Mutations in either or both genomes can result in a wide range of multisystemic disorders. We have studied a homoplasmic mtDNA mutation in the tRNA(Ile) gene that segregates exclusively with cardiomyopathy in two unrelated families. Cytochrome c oxidase (COX) deficiency was selectively observed only in the heart tissue and in patient's cardiomyocyte cultures and not in any other cell type, indicating that the defect is tissue specific. To understand the pathogenic mechanism of cardiomyopathy associated with a homoplasmic, tissue specific mtDNA mutation, we constructed transnuclear cardiomyocyte cell lines with normal or patient's nucleus and containing wild type or mutant mtDNA. Of the four cell lines analyzed, COX activity was low only in patient's cardiomyocytes illustrating that both the patient's nucleus and mitochondria are essential for expression of the phenotype. In cells with either wild type nucleus or wild type mtDNA, COX activity was normal. From these results it is evident that a tissue specific nuclear modifier gene may interact synergistically with the mtDNA mutation to cause COX deficiency.

A functionally dominant mitochondrial DNA mutation.

Mutations in mitochondrial DNA (mtDNA) tRNA genes can be considered functionally recessive because they result in a clinical or biochemical phenotype only when the percentage of mutant molecules exceeds a critical threshold value, in the range of 70-90%. We report a novel mtDNA mutation that contradicts this rule, since it caused a severe multisystem disorder and respiratory chain (RC) deficiency even at low levels of heteroplasmy. We studied a 13-year-old boy with clinical, radiological and biochemical evidence of a mitochondrial disorder. We detected a novel heteroplasmic C>T mutation at nucleotide 5545 of mtDNA, which was present at unusually low levels (<25%) in affected tissues. The pathogenic threshold for the mutation in cybrids was between 4 and 8%, implying a dominant mechanism of action. The mutation affects the central base of the anticodon triplet of tRNA(Trp) and it may alter the codon specificity of the affected tRNA. These findings introduce the concept of dominance in mitochondrial genetics and pose new diagnostic challenges, because such mutations may easily escape detection. Moreover, similar mutations arising stochastically and accumulating in a minority of mtDNA molecules during the aging process may severely impair RC function in cells.

Arsenic induced mitochondrial DNA damage and altered mitochondrial oxidative function: implications for genotoxic mechanisms in mammalian cells.

Arsenic is a well-established human carcinogen that is chronically consumed in drinking water by millions of people worldwide. Recent evidence has suggested that arsenic is a genotoxic carcinogen. Furthermore, we have shown that mitochondria mediate the mutagenic effects of arsenic in mammalian cells, as arsenic did not induce nuclear mutations in mitochondrial DNA (mtDNA)-depleted cells. Using the human-hamster hybrid A(L) cells, we show here that arsenic alters mitochondrial function by decreasing cytochrome c oxidase function and oxygen consumption but increasing citrate synthase function. These alterations correlated with depletion in mtDNA copy number and increase in large heteroplasmic mtDNA deletions. In addition, mtDNA isolated periodically from cultures treated continuously with arsenic did not consistently display the same deletion pattern, indicating that the mitochondrial genome was subjected to repeated and continuous damage. These data support the theory that the mitochondria, and particularly mtDNA, are important targets of the mutagenic effects of arsenic in mammalian cells.

Biochemical analysis of respiratory function in cybrid cell lines harbouring mitochondrial DNA mutations.

We analysed key biochemical features that reflect the balance between glycolysis and glucose oxidation in cybrids (cytoplasmic hybrids) harbouring a representative sample of mitochondrial DNA point mutations and deletions. The cybrids analysed had the same 143B cell nuclear background and were isogenic for the mitochondrial background. The 143B cell line and its rho(0) counterpart were used as controls. All cells analysed were in a dynamic state, and cell number, time of plating, culture medium, extracellular volume and time of harvest and assay were strictly controlled. Intra- and extra-cellular lactate and pyruvate levels were measured in homoplasmic wild-type and mutant cells, and correlated with rates of ATP synthesis and O2 consumption. In all mutant cell lines, except those with the T8993C mutation in the ATPase 6 gene, glycolysis was increased even under conditions of low glucose, as demonstrated by increased levels of extracellular lactate and pyruvate. Extracellular lactate levels were strictly and inversely correlated with rates of ATP synthesis and O2 consumption. These results show increased glycolysis and defective oxidative phosphorylation, irrespective of the type or site of the point mutation or deletion in the mitochondrial genome. The different biochemical consequences of the T8993C mutation suggest a uniquely different pathogenic mechanism for this mutation. However, the distinct clinical features associated with some of these mutations still remain to be elucidated.

Copper supplementation restores cytochrome c oxidase activity in cultured cells from patients with SCO2 mutations.

Human SCO2 is a nuclear-encoded Cu-binding protein, presumed to be responsible for the insertion of Cu into the mitochondrial cytochrome c oxidase (COX) holoenzyme. Mutations in SCO2 are associated with cardioencephalomyopathy and COX deficiency. Studies in yeast and bacteria have shown that Cu supplementation can restore COX activity in cells harbouring mutations in genes involving Cu transport. Therefore we investigated whether Cu supplementation could restore COX activity in cultured cells from patients with SCO2 mutations. Our data demonstrate that the COX deficiency observed in fibroblasts, myoblasts and myotubes from patients with SCO2 mutations can be restored to almost normal levels by the addition of CuCl(2) to the growth medium.