Characterization of mitochondrial 2-enoyl thioester reductase involved in respiratory competence

Abstract

<div lang="en" class="abs"><p class="abs_header">Abstract</p><p>Maintenance of the mitochondrial respiratory chain complexes plays crucial role for the aerobic metabolism of the eukaryotes such as unicellular yeasts, for example, <em>Saccharomyces cerevisiae</em> as well as of human being.</p><p>Mitochondrial respiratory function has been studied using the yeast <em>S. cerevisiae</em> as a model organism. Since yeast cells are also able to grow without respiration by fermentation, identification of the nuclear genes linked to respiratory function is possible by generation of nuclear gene deletions and testing for respiration-deficient phenotype of the yeast deletion strains <em>id est</em> for yeast cells only poorly or not at all growing on the media containing non-fermentable carbon sources.</p><p>This study reports identification of a novel mitochondrial 2-enoyl thioester reductase from the yeasts <em>Candida tropicalis</em> and <em>S. cerevisiae</em>, Etr1p and Mrf1p, respectively. Examination of the function of these proteins in the respiration-deficient <em>mrf1</em>Δ strain from <em>S. cerevisiae</em> suggests that the reductase is involved in mitochondrial fatty acid synthesis (FAS type II) in the yeast. Site-directed mutagenesis of a conserved tyrosine in the catalytic site of the enzyme indicated that the 2-enoyl thioester reductase activity is critical for mitochondrial respiratory competence. In addition, subcellular localization to mitochondria was required for the complementation of the respiration-deficient phenotype of the yeast reductase deletion strain. The crystal structure for the Etr catalytic site mutant indicated the structural integrity of the mutant supporting the requirement of the tyrosine for the catalysis.</p><p>Characterization of Etr crystal structures both in apo- and holo-forms containing NADPH established Etr as a member of novel subfamily of enoyl thioester reductases in the superfamily of medium-chain dehydrogenases/reductases (MDR). Two isoforms of Etr with the difference in three amino acids only are encoded by two distinct genes in <em>C. tropicalis</em>, whereas only single gene encodes the reductase functioning in the mitochondria in <em>S. cerevisiae</em>. The presence of two genes in <em>C. tropicalis</em> was taken as an example of genetic redundancy in this yeast, the two genes also shown to be expressed in slightly different ways under various carbon sources available for growth.</p></div>