Oxygen dependence of promitochondrial and cytoplasmic protein synthesis in the formation of electron transfer complexes III and IV in adapting bakers' yeast

Abstract

When anaerobically grown Saccharomyces cerevisiae cells are aerated in the presence of cycloheximide, they accumulate precursor components of electron transfer complexes III and IV. The formation of these precursors is dependent upon promitochondrial protein synthesis and can occur in the absence of concomitant cytoplasmic protein synthesis. The levels to which these precursor components can accumulate during the cycloheximide incubation (phase I) are three to fourfold greater when the cells are grown anaerobically in galactose rather than in glucose. When such galactose-grown cells are sequentially aerated first in cycloheximide and then in chloramphenicol, adaptation responses are elicited with respect to cyanide-sensitive oxygen consumption (QO 2), coenzyme QH 2-cytochrome c reductase (complex III) and cytochrome oxidase (complex IV), all of which are exhibited during the chloramphenicol incubation (phase II). These phase II adaptation responses for QO 2 and for both enzyme activities were observed to be dependent upon the continued presence of oxygen during both phase I (period of mitochondrial translation) and phase II (period of cytoplasmic translation). If one makes the assumption that mRNA's are neither imported into nor exported from promitochondria during adaptation, then one may conclude that oxygen independently and coordinately derepresses synthetic activity in both the mitochondrial and nucleo-cytoplasmic genetic systems. Other regulatory schemes are discussed.