Complex I deficiency is the most frequently encountered single mitochondrial single enzyme deficiency in patients with a mitochondrial disorder. Although specific genotype-phenotype correlations are very difficult to identify, the majority of patients present with symptoms caused by leukodystrophy. The poor genotype-phenotype correlations can make establishing a diagnosis a challenge. The classical way to establish a complex I deficiency in patients is by performing spectrophotometric measurements of the enzyme in a muscle biopsy or other patient-derived material (liver or heart biopsy, cultured skin fibroblasts). Complex I is encoded by both the mtDNA and nuclear DNA and pathogenic mutations have been identified in the majority of the 44 genes encoding the structural subunits of complex I. In recent years, the increasing possibilities for diagnostic molecular genetic tests of large gene panels, exomes, and even entire genomes has led to the identification of many novel genetic defects causing complex I deficiency. Complex I mutations not only result in a reduced enzyme activity but also induce secondary effects at the cellular level, such as elevated reactive oxygen species production, altered membrane potential and mitochondrial morphology. At this moment there is no cure for complex I deficiency and the treatment options for complex I patients are restricted to symptomatic treatment. Recent developments, amongst others based on the treatment of the secondary effects of complex I deficiency, have shown to be promising as new therapeutic strategies in vitro and have entered clinical trials. This article is part of a Special Issue entitled Respiratory complex I, edited by Volker Zickermann and Ulrich Brandt.
Keywords: Complex I; Enzyme measurement; Mitochondrial disease; Whole exome sequencing; mtDNA.
Copyright © 2016. Published by Elsevier B.V.