A nonsense mutation in the NDUFS4 gene encoding the 18 kDa (AQDQ) subunit of complex I abolishes assembly and activity of the complex in a patient with Leigh-like syndrome.

Sequence analysis of mitochondrial and nuclear candidate genes of complex I in children with deficiency of this complex and exhibiting Leigh-like syndrome has revealed, in one of them, a novel mutation in the NDUFS4 gene encoding the 18 kDa subunit. Phosphorylation of this subunit by cAMP-dependent protein kinase has previously been found to activate the complex. The present mutation consists of a homozygous G-->A transition at nucleotide position +44 of the coding sequence of the gene, resulting in the change of a tryptophan codon to a stop codon. Such mutation causes premature termination of the protein after only 14 amino acids of the putative mitochondrial targeting peptide. Fibroblast cultures from the patient exhibited severe reduction of the rotenone-sensitive NADH-->UQ oxidoreductase activity of complex I, which was insensitive to cAMP stimulation. Two-dimensional electrophoresis showed the absence of detectable normally assembled complex I in the inner mitochondrial membrane. These findings show that the expression of the NDUFS4 gene is essential for the assembly of a functional complex I.

Fast-to-slow muscle conversion by chronic electrostimulation: effects on mitochondrial respiratory chain function with possible implications for the gracilis neosphincter procedure.

The effects of chronic, around the clock, low-frequency electrostimulation on the respiratory chain activity and cytochrome content of freshly isolated mitochondria were evaluated in rabbit skeletal muscle before and after 30 days of continuous or cyclical electrostimulation using a totally implantable system and a training programme now used in humans. The respiratory activity measured in state III increased strongly after electrostimulation. The efficiency of the respiratory chain increased significantly after electrostimulation but the activity of complex [(reduced nicotinamide adenine dinucleotide dehydrogenase) did not increase. The amount of cytochromes a and a3, b562, and c and c1 increased clearly after electrostimulation. The respiratory activity rate of mitochondria obtained after continuous electrostimulation was apparently higher than after cyclical electrostimulation. Chronic uninterrupted low-frequency electrostimulation, using a clinical training programme, induces an increase in mitochondrial respiratory chain activity in purified mitochondria of skeletal muscle. These changes are the basis of induced resistance to fatigue in fast-to-slow muscle conversion by chronic electrostimulation.