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Query: UMLS:C0162671 (
MELAS
)
587
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Decreased activity of complex I (
NAD
:ubiquinone oxidoreductase) is the most frequent biochemical finding associated with mutation at the base pair 3243 of the mitochondrial DNA. The mutation has been previously shown to lead to a defective translation. We hypothesized that due to an imperfect assembly of complex I subunits the substrate affinity of this enzyme may be lowered and this may be counteracted by increasing the mitochondrial NAD+NADH concentration. Therefore, we studied the effect and mechanism of action of nicotinamide treatment in a
MELAS
patient with the base pair 3243 mutation. Nicotinamide treatment was initiated after his first stroke-like episode. The blood
NAD
concentration (representing the intracellular concentration in erythrocytes) increased linearly being 24-fold at 6 weeks of treatment. Blood lactate and pyruvate concentration decreased by 50% within three days and 24 h urine lactate content within 2 weeks and we observed a clinical improvement together with a decrease in the lesion volume in magnetic resonance imaging within the first month. The cellular
NAD
increase upon nicotinamide administration was probably universal, because it occurred in a time and dose-dependent manner in cultured fibroblasts from both the patient and the controls. Alleviation of the lactate accumulation during the nicotinamide treatment suggests that an increase in the cellular NAD+NADH concentration leads to enhancement of the oxidation of reducing equivalents. However, the Km of complex I for NADH in skeletal muscle from the patient was similar to that of controls. This may indicate that physiologically mitochondrial complex I operates at non-saturating substrate concentration, and this may explain the effect of nicotinamide treatment.
...
PMID:Increase of blood NAD+ and attenuation of lactacidemia during nicotinamide treatment of a patient with the MELAS syndrome. 859 19
The mitochondrial DNA (mtDNA) codes for essential hydrophobic components of the system of oxidative phosphorylation. Diseases caused by mtDNA defects are manifested as variable clinical phenotypes and the symptoms represent the involvement of tissues with high energy demand. Various approaches have been taken to treat mitochondrial diseases by administration of redox compounds, enzyme activators, vitamins and coenzymes or dietary measures. The
MELAS
mutation at the base pair 3243 of mitochondrial DNA demolishes a transcription termination sequence located within the tRNA(Leu)[UUR] gene, resulting in synthesis of an abnormally large derivative of 16 S rRNA and defective translation. The activity of NADH:Q oxidoreductase (complex I) is often decreased and lactic acidosis is a typical clinical finding. We hypothesized that defective translation of the seven mitochondrially coded subunits (of the total 41) of complex I may alter its affinity to the NADH substrate in which case the activity decrease may be compensated for by increasing the NADH concentration. A
MELAS
patient was treated with oral nicotinamide for 5 months. The blood
NAD
content representing the
NAD
+ NADH pool of erythrocytes rose 24 fold and the blood lactate + pyrovate concentration fell by 50%. All these metabolic alterations suggested an improvement of the function of complex I or the whole mitochondrial respiratory chain. However, the kinetic properties of the patient's complex I were similar to the reference values. A tempting explanation is that the free NADH concentration in mitochondria is normally at the level of K(m), so that the decreased activity of the respiratory chain can be compensated for by increased mitochondrial [NADH]. Another possibility would be that the substrate shuttles for transport of reducing power of cytosolic NADH into mitochondria (the malate aspartate or glycerol-3-phosphate shuttles) may be enhanced by increased total
NAD
+ NADH. Because the malate-aspartate shuttle is actually a pump for reducing equivalents driven by the mitochondrial membrane energization, it is proposed that the exacerbations of the
MELAS syndrome
be partly due to a vicious circle initiated by a defect of complex I and affecting the active transport of the hydrogen from cytosolic NADH into the mitochondrion.
...
PMID:Metabolic interventions against complex I deficiency in MELAS syndrome. 930 2
The ratio of mtDNA and a nuclear reference gene was estimated by Southern blotting in the skeletal muscle DNA of a 3-year-old girl who suffered from congenital brain damage, focal epilepsy, hepatomegaly, malabsorption syndrome and severe myopathy. The signal ratio of mtDNA versus 18S rDNA was 22% of the mean value obtained from controls. No major deletions or insertions were found and the MERRF,
MELAS
and NARP mutations were ruled out. Mitochondrial DNA-encoded enzyme activities and mitochondrial respiration were reduced. The analysis of the
NAD
(P)H and flavoprotein redox states of intact fibres revealed the presence of mitochondrial dysfunction. In tissue sections a moderate elevation of type I and type II fibre diameter variation was detected, aberrant NADH- and succinate dehydrogenase staining and some ragged red fibres. This suggested that a mitochondrial disorder caused by a decrease in the amount of intact wild-type mtDNA was responsible for the severe myopathy.
...
PMID:mtDNA depletion and impairment of mitochondrial function in a case of a multisystem disorder including severe myopathy. 970 May 97
Ketogenic Diet used to treat refractory epilepsy for almost a century may represent a treatment option for mitochondrial disorders for which effective treatments are still lacking. Mitochondrial complex I deficiencies are involved in a broad spectrum of inherited diseases including Mitochondrial Encephalomyopathy, Lactic Acidosis and Stroke-like episodes syndrome leading to recurrent cerebral insults resembling strokes and associated with a severe complex I deficiency caused by mitochondrial DNA (mtDNA) mutations. The analysis of
MELAS
neuronal cybrid cells carrying the almost homoplasmic m.3243A>G mutation revealed a metabolic switch towards glycolysis with the production of lactic acid, severe defects in respiratory chain activity and complex I disassembly with an accumulation of assembly intermediates. Metabolites, NADH/
NAD
+
ratio, mitochondrial enzyme activities, oxygen consumption and BN-PAGE analysis were evaluated in mutant compared to control cells. A severe complex I enzymatic deficiency was identified associated with a major complex I disassembly with an accumulation of assembly intermediates of 400kDa. We showed that Ketone Bodies (KB) exposure for 4weeks associated with glucose deprivation significantly restored complex I stability and activity, increased ATP synthesis and reduced the NADH/NAD+ ratio, a key component of mitochondrial metabolism. In addition, without changing the mutant load, mtDNA copy number was significantly increased with KB, indicating that the absolute amount of wild type mtDNA copy number was higher in treated mutant cells. Therefore KB may constitute an alternative and promising therapy for
MELAS syndrome
, and could be beneficial for other mitochondrial diseases caused by complex I deficiency.
...
PMID:The addition of ketone bodies alleviates mitochondrial dysfunction by restoring complex I assembly in a MELAS cellular model. 2781 40
