Derepression of mitochondria and their enzymes in yeast: Regulatory aspects

Abstract

We have performed a detailed analysis of the properties of glucose-repressed cells of a commercial strain of Saccharomyces cerevisiae. They contain measurable amounts of the respiratory enzymes NADH oxidase, cytochrome c oxidase, succinate dehydrogenase, succinate:cytochrome c reductase and NADH:cytochrome c reductase (antimycin A-sensitive) as well as the dehydrogenases for l-malate, l-glutamate, and l 8-isocitrate. Cytochromes b, c 1, and aa 3 are present in amounts that may be in excess of those required for cytochrome-linked enzyme activities. Enzymes and cytochromes are localized in large, presumably mitochondrial organelles among which no compositional or functional heterogeneity could be detected. We have also analyzed the kinetics of synthesis of respiratory enzymes and cytochromes during the release from catabolite(glucose) repression. All activities assayed except for cytochrome c oxidase begin their derepression before the external glucose concentration falls below 0.4%; derepression of cytochrome oxidase occurs only after the glucose concentration falls below 0.1%. The earlier events comprise the “fermentative” phase of derepression while the later events comprise the “oxidative” phase. The two phases can be distinguished operationally by their sensitivity to antimycin A. Only the oxidative phase is blocked by the inhibitor. Respiratory enzymes and cytochromes appear to fall into two classes distinguishable by their increase during derepression. An apparently constitutive one consists of cytochrome c oxidase, ATPase, and cytochromes aa 3, b, and c 1; these entities increase in amount per cell but not in amount per unit of mitochondrial mass and are of the order of 5-fold or less. The second class consists of those activities that increase by more than 6-fold and may be considered derepressible in the strict sense. Thus, proliferation and differentiation of mitochondria both contribute to the cellular changes associated with derepression. The fermentative phase of derepression does not require mitochondrial function, mitochondrial protein, or RNA synthesis, or the gradual accumulation of regulatory elements for either its initiation or persistence. This phase of derepression also occurs in cytoplasmic petites. In contrast, the oxidative phase of derepression requires mitochondrial function. Mitochondrial gene expression is required for the biogenesis of fully functional mitochondria but, except for cytochrome c, it plays little or no role in regulating the expression of nuclear genes the products of which are localized in mitochondria.