Effects of oligomycins on adenosine triphosphatase activity of mitochondria isolated from the yeasts Saccharomyces cerevisiae and Schwanniomyces castellii.

Functional mitochondria with respiratory control were isolated from the yeasts Saccharomyces cerevisiae and Schwanniomyces castellii. The presence of site I in Schw. castellii was indicated by higher ADP/O ratio than in S. cerevisiae where this site is absent. The ATPase Vmax was higher in S. cerevisiae than in Schw. castellii mitochondria. The latter was increased by the DR12 nuclear mutation. Nevertheless, the stimulation by heat and the inhibition profile of oligomycins on mitochondrial F1-F0 ATPase activities were similar in all three tested strains. In S. cerevisiae and Schw. castelli wild type or mutant mitochondria, the well-known inhibition of F1-F0 ATPase activity by low concentrations of oligomycins is abolished at high inhibitor concentrations near 60microg/ml suggesting uncoupling of F1 activity. At still higher oligomycin concentration the ATPase activity of both species and mutant is again strongly inhibited, suggesting an inhibitory effect on yeast F1 activity not detected so far.

Mitochondrial ATP synthase subunit 9 is not required for viability of the petite-negative yeast Kluyveromyces lactis.

Specific mutations in nuclear MGI genes encoding the alpha, beta and gamma subunits of the mitochondrial inner membrane F1-ATPase complex allow mitochondrial DNA (mtDNA) to be lost from K. lactis. In the absence of a mutation in any of these three nuclear genes, loss of mtDNA is lethal. These results imply that mtDNA encodes a gene that is essential. Likely candidates for such an essential role are the ATP6, 8 and 9 genes coding for proteins of the ATP synthase-F0 component. The present study removes ATP9 from contention as a vital mitochondrial gene because in a respiratory deficient mutant, Gly- 3. 9, lacking a nuclear mgi mutation, we have found that a rearrangement in mtDNA has deleted 22 amino acids from the carboxy terminus of the 75 amino-acid subunit-9 protein. Rearrangement in mtDNA has occurred by recombination at a 23-bp repeated sequence in the introns of the ATP9 and large ribosomal RNA (LSU) subunit genes. These two introns, of 394 (ATP9) and 410 (LSU) nucleotides, both belong to group 1.

Characterization of alternative respiratory pathways in the yeast Schwanniomyces castellii by the study of mutants deficient in cytochromes a+a3 and/or b.

After a general review of the proposed mechanisms and physiological roles of the alternative respiratory pathways found in various organisms, the studies are focussed on the amylolytic yeast Schwaniomyces castellii. In addition to the cytochrome chain, the wild type presents two alternative pathways insensitive to antimycin A. One is salicylhydroxamic acid (SHAM)-sensitive and azide-insensitive; the other is SHAM-insensitive and sensitive to high azide concentration. Conditions for mutagenesis and screening are described, which allow isolation of mutants deficient in cytochromes a+a3 and/or b in this yeast previously classified as petite negative. The relative proportions of the alternative respiratory pathways are compared in the wild type and mutant strains following inhibition by SHAM and azide at optimal concentration as determined by iso-inhibition curves. The growth of the cytochrome deficient mutants on citrate, a non-fermentable carbon source, and the ability of the wild type to grow on citrate+antimycin A, after a lag of about 10 h, indicate an involvement of the alternative pathway(s) in energy production. Rotenone sensitivity of respiration and ATP level confirm the presence of a functional phosphorylation site 1. The role of each alternative respiratory pathway in energy production is discussed.

Mutations within an intron and its flanking sites: patterns of novel polypeptides generated by mutants in one segment of the cob-box region of yeast mitochondrial DNA.

We have undertaken a systematic examination of the polypeptides accumulating in thirteen (out of 23) mutants in the intron cluster box7 and its flanking clusters box2 and box9 of the cob-box (cytochrome b) region of the mitochondrial genome of Saccharomyces cerevisiae. We have subjected these polypeptides to fingerprint analysis, both sequential and in parallel, with two proteases in order to disclose sequence homologies and differences between the different novel polypeptides themselves, and between them and the wild type product of the gene, i.e. apocytochrome b. One of our aims has been to establish the existence of possible correlations between the nature of the novel polypeptides and the fine structure genetic map of that segment of the mitochondrial genome. Our results show that all box7 mutants accumulate the following set of polypeptides not seen in wild type cells: a) a characteristic set of "large" polypeptides consisting of three species: p56, p42 and p35 or p34.5; b) a polypeptides p23; c) a much shorter fragment (of which the apparent molecular weight varies from 12.5 to 13, according to the mutation) with the exception of two mutants; d) in addition, the majority accumulate in varying amounts a polypeptide p30 closely related to but not identical with apocytochrome b. Moreover only two box7 mutants accumulate a polypeptide in the range of mobilities corresponding to 25-27 Kd (referred to as class p26) while such a polypeptide is seen in all box9 and box2 mutants examined with one exception in box2.

Cytochrome c from Schizosaccharomyces pombe. 1. Purification, spectral properties, and amino-acid composition.

Cytochrome c from the fission yeast Schizosaccharomyces pombe has been purified. Its chromatographic and spectral properties are reported and compared to those of iso-1-cytochrome c from baker's yeast; the amino-acid composition is described. Schiz. pombe cytochrome c has a much lower affinity for Amberlite IRP64 than Sacch. cerevisiae iso-1-cytochrome c. Its alpha absorption band splits into three maxima (calpha1, calpha2, and calpha3) at -190 degrees C; this is unusual in yeasts, as shown by the low-temperature whole-cell absorption spectra which were examined in various yeast genera, species, and strains. A minor component can be separated by Amberlite chromatography. It exhibits the same low-temperature splitting of the alpha absorption band as the main fraction and it has a similar amino-acid composition with a notable exception: it is an unmethylated form of the cytochrome.

Energy requirements for the uptake of L-leucine by Saccharomyces cerevisiae.

(1) Substrates capable of activating mitochondrial electron transfer and oxidative phosphorylation, namely, pyruvate, acetate, propionaldehyde and butanol, stimulated the concentrative uptake (transport and accumulation) of L-[14-C]leucine by Saccharomyces cerevisiae (wild type strain 207, starved cells). Under adequate experimental conditions, the L-[14-C]leucine uptake versus the oxygen uptake ratio was almost the same with either pyruvate, acetate or D-glucose as energy sources. Substrate oxidation also increased L-[14-C]leucine incorporation into the cell protein. (2) With S. cerevisiae D261 and D247-2 and propionaldehyde as an energy source, or with strain 207 and glucose as energy source, 2,4-dinitrophenol (50 muM) inhibited L-[14-C]leucine uptake, the inhibition being accompanied by stimulation of respiration. With S. cerevisiae 207 and propionaldehyde as energy source, 2,4-dinitrophenol inhibited both respiration and L-[14-C]leucine uptake, but with respiration being less affected than uptake. Displacement of accumulated L-[14-C]leucine was also inhibited by 2,4-dinitrophenol. (3) In the presence of glucose, and for relatively brief incubation periods, anaerobically grown cells of S. cerevisiae 207 and of a p-minus "petite" mutant of this strain incorporated L-[14-C]leucine with less efficiency than the original wild type strain 207, grown aerobically. With D-glucose as energy source, 2,4-dinitrophenol and iodoacetate inhibited alike L-[14-C]leucine uptake by the respiration competent cells. (4) It is postulated that in respiration-competent yeasts, the mitochondrion contributes to 6-[14-C]leucine uptake by supplying high-energy compounds required for amino acid transport and accumulation. Conversely, the promitochondrion in the anaerobically grown yeast, or the modified mitochondrion in the respiratory deficient mutant, competes for high energy compounds generated by glycolysis in the cytosol.

[Low temperature spectral study on Euglena gracilis Z during synchronous culture on lactate medium: Variation of cytochrome 556 content]. / Etude spectrale à basse temperature chez Euglena gracilis Z en culture synchrone sur milieu lactate: Variation de teneur en cytochrome 556.

Low temperature spectra are described for whole Euglena cells. Euglena growing in synchronous culture with lactate medium show a cyclic variation of cytochrome 556 content during each cellular generation. The greatest quantity of cytochrome 556 seems to coincide with the non-dividing phase of the cells, the phase in which the mitochondrial network is observed. On the other hand after treatment of the Euglena with antimycin A, a correlation exists between the formation of giant mitochondria and an increase in the quantity of cytochrome 556.These results demonstrate the existence of a cyclic variation of cytochrome 556 synthesis in Euglena during synchronous growth on lactate medium.