Growth defects in intramitochondrial energy depleted cells: role of mitochondrial biogenesis

Simultaneous inhibition of oxidative phosphorylation by rho- mutation and adenine nucleotide exchange by op1 mutation or bongkrekic acid results in intramitochondrial energy depletion and cessation of growth in yeast. Effect of energy depletion of mitochondria on mitochondrial biogenesis was studied in intact yeast cells. Immunoblot analysis revealed an overall decrease in cellular content of two mitochondrial proteins - ADP/ATP translocase and beta subunit of mitochondrial ATPase - together with their lower ability to reach the proper intramitochondrial compartment. Both effects indicate disturbed biogenesis of energy depleted mitochondria. Quantitative differences in growth abilities and mitochondrial damage observed in two studied systems - op1 rho- double mutants and rho- cells treated with bongkrekic acid - can be explained by different degree of intramitochondrial energy depletion due to leakiness of op1 mutation in op1 rho- cells.     

ATP synthase of yeast mitochondria. Characterization of subunit d and sequence analysis of the structural gene ATP7.

The subunit analogous to the d-subunit of ATP synthase from bovine heart mitochondria was isolated from the purified yeast enzyme. Partial protein sequences were determined by direct methods. From this information, two oligonucleotide probes were constructed and used for screening a DNA genomic bank of Saccharomyces cerevisiae. The sequence of yeast subunit d was deduced from the DNA sequence of ATP7 gene. Mature yeast subunit d is 173 amino acids long. Its NH2-terminal serine is blocked by an N-acetyl group, and the protein has no processed NH2-terminal sequence other than the removal of the initiator methionine. The protein is predominantly hydrophilic. The amino acid sequence is 22% identical and 44% homologous to bovine subunit d. A null mutant was constructed. The mutant strain was unable to grow on glycerol medium. The mutant mitochondria had no detectable oligomycin-sensitive ATPase activity, and the catalytic sector F1 was loosely bound to the membranous part. The mutant mitochondria did not contain subunit d, and the mitochondrially encoded hydrophobic subunit 6 was not present.     

Involvement of the ADP/ATP carrier in calcium-induced perturbations of the mitochondrial inner membrane permeability: importance of the orientation of the nucleotide binding site

Compounds which induce calcium efflux from calcium-loaded mitochondria generally provoke membrane leakiness. The involvement of the ADP/ATP carrier in modification of mitochondrial membrane properties was studied. The addition of impermeant inhibitors of the ADP/ATP carrier, namely carboxyatractylate, palmitoyl coenzyme A (in the absence of carnitine), and pyridoxal 5-phosphate, to calcium-loaded mitochondria triggered the release of accumulated calcium, the leakage of endogenous ADP, and the swelling of mitochondria. Permeant ligands, such as bongkrekic acid or ADP, showed no damaging effect on membrane permeability; in fact, they impeded the membrane perturbation which was induced by the three impermeant effectors. In addition, both bongkrekic acid and ADP were able to cancel the calcium loss and swelling resulting from the oxidation of intramitochondrial pyridine nucleotides by acetoacetate. In acetoacetate-treated mitochondria, the ADP/ATP carrier was shown to be mainly in a c-state conformation (i.e., the nucleotide binding site had an external orientation). It was concluded that induction of membrane leakiness by calcium ions depends on the conformational state of the adenine nucleotide carrier. The ability of intramitochondrial calcium ions to modify membrane properties is determined by the orientation of the nucleotide binding site. Only the c-state conformation allows membrane destabilization. Consequently, all compounds which stabilize the ADP/ATP carrier in the c-state conformation will have a deleterious effect on calcium-loaded mitochondria.     

Activation of ATP hydrolysis by an uncoupler in mutant mitochondria lacking an intrinsic ATPase inhibitor in yeast

An intrinsic ATPase inhibitor and 9-kDa protein are regulatory factors of mitochondrial ATP synthase in Saccharomyces cerevisiae. A gene encoding the ATPase inhibitor was isolated from a yeast genomic library with synthetic oligonucleotides as hybridization probes and was sequenced. The deduced amino acid sequence showed that the precursor protein contains an amino-terminal presequence of 22 amino acid residues. Mutant strains that did not contain the inhibitor and/or the 9-kDa protein were constructed by transformation of cells with their in vitro disrupted genes. The disruption of the chromosomal copy in recombinant cells was verified by Southern blot analysis, and the absence of the proteins in the mutant cells was confirmed by Western blot analysis. All the mutants could grow on a nonfermentable carbon source and the oxidative phosphorylation activities of their isolated mitochondria were the same as that of normal mitochondria. However, an uncoupler, carbonylcyanide-m-chlorophenylhydrazone, induced marked ATP hydrolysis in the inhibitor-deficient mitochondria, but not in normal mitochondria. These observations suggest that the ATPase inhibitor inhibits ATP hydrolysis by F1F0-ATPase only when the membrane potential is lost.     

Four mutations in transmembrane domains of the mitochondrial ADP/ATP carrier increase resistance to bongkrekic acid

Two distinct conformations of the mitochondrial ADP/ATP carrier involved in the adenine nucleotide transport are called BA and CATR conformations, as they were distinguished by binding of specific inhibitors bongkrekic acid (BA) and carboxyatractyloside (CATR), respectively. To find out which amino acids are implicated in the transition between these two conformations, which occurs during transport, mutants of the Saccharomyces cerevisiae ADP/ATP carrier Anc2p responsible for resistance of yeast cells to BA were identified and characterized after in vivo chemical or UV mutagenesis. Only four different mutations could be identified in spite of a large number of mutants analyzed. They are located in the Anc2p transmembrane segments I (G30S), II (Y97C), III (L142S), and VI (G298S), and are independently enabling growth of cells in the presence of BA. The variant and wild-type Anc2p were produced practically to the same level in mitochondria, as evidenced by immunochemical analysis and by atractyloside binding experiments. ADP/ATP exchange mediated by Anc2p variants in isolated mitochondria was more efficient than that of the wild-type Anc2p in the presence of BA, confirming that BA resistance of the mutant cells was linked to the functional properties of the modified ADP/ATP carrier. These results suggest that resistance to BA is caused by alternate conformation of Anc2p due to appearance of Ser or Cys at specific positions. Different interactions of these residues with other amino acids and/or BA could prevent formation of stable inactive Anc2p BA complex.     

Deletion of mitochondrial ATPase inhibitor in the yeast Saccharomyces cerevisiae decreased cellular and mitochondrial ATP levels under non-nutritional conditions and induced a respiration-deficient cell-type.

T(1), a mutant yeast lacking three regulatory proteins of F(1)F(o)ATPase, namely ATPase inhibitor, 9K protein and 15K protein, grew on non-fermentable carbon source at the same rate as normal cells but was less viable when incubated in water. During the incubation, the cellular ATP content decreased rapidly in the T(1) cells but not in normal cells, and respiration-deficient cells appeared among the T(1) cells. The same mutation was also induced in D26 cells lacking only the ATPase inhibitor. Overexpression of the ATPase inhibitor in YC63 cells, which were derived from the D26 strain harboring an expression vector containing the gene of the ATPase inhibitor, prevented the decrease of cellular ATP level and the mutation. Isolated T(1) mitochondria exhibited ATP hydrolysis for maintenance of membrane potential when antimycin A was added to the mitochondrial suspension, while normal and YC63 mitochondria continued to show low hydrolytic activity and low membrane potential. Thus, it is likely that deletion of the ATPase inhibitor induces ATPase activity of F(1)F(o)ATPase to create a dispensable membrane potential under the non-nutritional conditions and that this depletes mitochondrial and cellular ATP. The depletion of mitochondrial ATP in turn leads to occurrence of aberrant DNA in mitochondria.     

The effects of altered sterol composition on the mitochondrial adenine nucleotide transporter of Saccharomyces cerevisiae.

1. The membrane sterol composition of mitochondria of the ole-3 mutant of Saccharomyces cerevisiae was manipulated by growing the organism in the presence of Tween 80 (1%, W/V) plus defined supplements o- delta-aminolaevulinate. 2. Changes in mitochondrial sterol content induced considerable changes in the adenine nucleotide transporter. 3. As the sterol content was decreased, the affinity of the transporter for ATP did not alter significantly, but the rate of ATP uptake was greatly decreased, the total number of atractylate-sensitive binding sites diminished, and the proportion of high-affinity binding sites was decreased. 4. Since sterol depletion also uncouples oxidative phosphorylation [Astin & Haslam (1977) Biochem. J., 166, 287-298] and prevents the intramitochondrial generation of ATP, the decrease in the rate of ATP uptake by sterol-depleted mitochondria will cause a decrease in intramitochondrial ATP concentrations in vivo. This probably explains the inhibition of mitochondrial macromolecular synthesis that has previously been reported in lipid-depleted yeast mitochondria.     

Assembly of imported subunit 8 into the ATP synthase complex of isolated yeast mitochondria

This study concerns the assembly into a multisubunit enzyme complex of a small hydrophobic protein imported into isolated mitochondria. Subunit 8 of yeast mitochondrial ATPase (normally a mitochondrial gene product) was expressed in vitro as a chimaeric precursor N9L/Y8-1, which includes an N-terminal-cleavable transit peptide to direct its import into mitochondria. Assembly into the enzyme complex of the imported subunit 8 was monitored by immunoadsorption using an immobilized anti-F1-beta monoclonal antibody. Preliminary experiments showed that N9L/Y8-1 imported into normal rho+ mitochondria, with its complement of fully assembled ATPase, did not lead to an appreciable assembly of the exogenous subunit 8. With the expectation that mitochondria previously depleted of subunit 8 could allow such assembly in vitro, target mitochondria were prepared from genetically modified yeast cells in which synthesis of subunit 8 was specifically blocked. Initially, mitochondria were prepared from strain M31, a mit- mutant completely incapable of intramitochondrial biosynthesis of subunit 8. These mit- mitochondria however were unsuitable for assembly studies because they could not import protein in vitro. A controlled depletion strategy was then evolved. An artificial nuclear gene encoding N9L/Y8-1 was brought under the control of a inducible promoter GAL1. This regulated gene construct, in a low copy number yeast expression vector, was introduced into strain M31 to generate strain YGL-1. Galactose control of the expression of N9L/Y8-1 was demonstrated by the ability of strain YGL-1 to grow vigorously on galactose as a carbon source, and by the inability to utilize ethanol alone for prolonged periods of growth. The measurement of bioenergetic parameters in mitochondria from YGL-1 cells experimentally depleted of subunit 8, by transferring growing cells from galactose to ethanol, was consistent with the presence in mitochondria of a mosaic of ATPase, namely fully assembled functional ATPase complexes and partially assembled complexes with defective F0 sectors. These mitochondria demonstrated very efficient import of N9L/Y8-1 and readily incorporated the imported processed subunit 8 protein into ATPase. Comparison of the kinetics of import and assembly of subunit 8 showed that assembly was noticeably delayed with respect to import. These findings open the way to a new systematic analysis of the assembly of imported proteins into multisubunit mitochondrial enzyme complexes.     

The effects of unsaturated fatty acid depletion on the proton permeability and energetic functions of yeast mitochondria

1. The fatty acid composition of the ole-1 and ole-1 petite mutants of Saccharomyces cerevisiae was manipulated by growing the organism in the presence of defined supplements of Tween 80 or by allowing cells that had first been grown in the presence of Tween 80 to deplete their unsaturated fatty acids by sequent growth in the absence of Tween 80. 2. The transition temperature of Arrhenius plots of mitochondrial ATPase (adenosine triphosphatase) increases as the unsaturated fatty acid content is lowered. 3. Cells require larger amounts of unsaturated fatty acids to grow on ethanol at lower temperatures. 4. Cells that stop growing owing to unsaturated fatty acid depletion at low temperatures are induced to grow further by raising the temperature and this results in a further depletion of unsaturated acids. This is due to a higher rate, but not a greater efficiency, of mitochondrial ATP synthesis. 5. Arrhenius plots of the passive permeability of mitochondria to protons between 4 and 37 degrees C are linear. The rate and the Arrhenius activation energy of proton entry increase greatly as the unsaturated fatty acid content is lowered. 6. Unsaturated fatty acid depletion has the same effects on the proton permeability of ole-1 petite mitochondria, indicating that the mitochondrially synthesized subunits of the ATPase are not involved in the enhanced rates of proton entry. 7. The adenylate energy charge of depleted ole-1 cells is greatly decreased by growth on ethanol medium. 8. The adenylate energy charge of isolated mitochondria is also lowered by unsaturated fatty acid depletion. 9. The results confirm that unsaturated fatty acid depletion uncouples oxidative phosphorylation in yeast both in vivo and in vitro, and is a consequence of changes in the lipid part of the membrane.     

Biogenesis of mitochondria. The effects of altered membrane lipid composition on cation transport by mitochondria of Saccharomyces cerevisiae

1. The fatty acid composition of the membrane lipids of a fatty acid desaturase mutant of Saccharomyces cerevisiae was manipulated by growing the organism in a medium containing defined fatty acid supplements. 2. Mitochondria were obtained whose fatty acids contain between 20% and 80% unsaturated fatty acids. 3. Mitochondria with high proportions of unsaturated fatty acids in their lipids have coupled oxidative phosphorylation with normal P/O ratios, accumulate K(+) ions in the presence of valinomycin and an energy source, and eject protons in an energy-dependent fashion. 4. If the unsaturated fatty acid content of the mitochondrial fatty acids is lowered to 20%, the mitochondria simultaneously lose active cation transport and the ability to couple phosphorylation to respiration. 5. The loss of energy-linked reactions is accompanied by an increased passive permeability of the mitochondria to protons. 6. Free fatty acids uncouple oxidative phosphorylation in yeast mitochondria and the effect is reversed by bovine serum albumin. 7. The free fatty acid contents of yeast mitochondria are unaffected by depletion of unsaturated fatty acids, and free fatty acids are not responsible for the uncoupling of oxidative phosphorylation in organelles depleted in unsaturated fatty acids. 8. It is suggested that the loss of energy-linked reactions in yeast mitochondria that are depleted in unsaturated fatty acids is a consequence of the increased passive permeability to protons, and is caused by a change in the physical properties of the lipid phase of the inner mitochondrial membrane.     

Substrate-site interactions in the membrane-bound adenine-nucleotide carrier as disclosed by ADP and ATP analogs

The binding parameters of a number of ADP or ATP analogs to the adenine nucleotide carrier in mitochondria and inside-out submitochondrial particles have been explored by means of two specific inhibitors, carboxyatractyloside and bongkrekic acid. The nucleotides tested fell into two classes depending on the shape of the binding curve. Curvilinear Scatchard plots were obtained for the binding of ADP, ATP, adenosine 5'-triphospho-gamma-1-(5-sulfonic acid)naphthylamidate [gamma-AmNS)ATP) and adenylyl (beta,gamma)-methylenediphosphate (p[CH2]ppA); on the other hand, rectilinear Scatchard plots were obtained in the case of naphthoyl-ADP (N-ADP) and 8-bromo ADP (8Br-ADP) binding. The total number of binding sites for N-ADP and 8Br-ADP could be extrapolated with good accuracy to 1.3-1.5 nmol/mg protein; this value corresponds to the number of carboxyatractyloside-binding sites in heart mitochondria (Block, M.R., Pougeois, R. and Vignais, P.V. (1980) FEBS Lett. 117, 335-340). On the other hand, because of the curvilinearity of the Scatchard plots for the binding of ADP, ATP, (gamma-AmNS)ATP and p[CH2]ppA, the total number of binding sites for these nucleotides could only be approximated to a value higher than 1 nmol/mg protein, the exact value being probably equal to that found for N-ADP and 8Br-ADP binding, i.e. 1.3-1.5 nmol/mg protein. Curvilinearity of Scatchard plots was discussed in terms of negative interactions between nucleotide-binding sites located on the same face of the adenine nucleotide carrier. A possible relationship between the features of the binding plots and the transportable nature of the nucleotide is discussed. Contrary to the enhancing effect of bongkrekic acid on [14C]ADP uptake observed essentially in nucleotide-depleted heart mitochondria (Klingenberg, M., Appel, M., Babel, W. and Aquila, H. (1983) Eur. J. Biochem. 131, 647-654), binding of bongkrekic acid to nondepleted heart mitochondria was found to partially displace previously bound [14C]ADP. These opposite effects of bongkrekic acid may be explained by assuming that bongkrekic acid is able to abolish negative cooperativity between external (cytosolic) ADP-binding sites.     

Functionally important conserved length of C-terminal regions of yeast and bovine ADP/ATP carriers, identified by deletion mutants studies, and water accessibility of the amino acids at the C-terminal region of the yeast carrier

Comparison of the amino acid sequence of yeast type 2 ADP/ATP carrier (yAAC2) with that of bovine type 1 AAC (bAAC1) revealed that the N- and C-terminus of yAAC2 are 15- and 6-amino acids longer, respectively, than those of bAAC1. In the present study, we focused on the difference in the C-terminal region between yAAC2 and bAAC1. Deletion of first six residues of C-terminus of yAAC did not markedly affect the function of yAAC2; however, further deletion of 1 amino acid (7th amino acid from the C-terminus) destroyed its function. On the contrary, deletion of the first amino acid residue of the C-terminus of bAAC1 caused failure of its functional expression in yeast mitochondria. Based on these results, we concluded that the 6-amino acid residue extension of the C-terminus of yAAC2 was not necessary for the function of this carrier and that the remainder of the C-terminal region of yAAC2, having a length conserved with that of bAAC1, is important for the transport function of AACs. We next prepared various single-Cys mutants in which each of 32 residues in the C-terminus of yAAC2 was replaced by a Cys residue. Since all mutants were successfully expressed in yeast mitochondria, we examined the reactivity of these cysteine residues with the membrane-impermeable sulfhydryl reagent eosin 5-maleimide (EMA). As a result, all cysteine residues that replaced the 9 continuous amino acids in Met310-Lys318 showed high reactivity with EMA regardless of the presence of carboxyatractyloside or bongkrekic acid; and so this region was concluded to be exposed to the water-accessible environment. Furthermore, based on the reactivities of cysteine residues that replaced amino acids in the sixth transmembrane segment, the probable structural features of the C-terminal region of this carrier in the presence of bongkrekic acid were discussed.     

Increasing mitochondrial substrate-level phosphorylation can rescue respiratory growth of an ATP synthase-deficient yeast

In a previous study we have identified Fmc1p, a mitochondrial protein involved in the assembly/stability of the yeast F0F1-ATP synthase at elevated temperatures. The deltafmc1 mutant was shown to exhibit a severe phenotype of very slow growth on respiratory substrates at 37 degrees C. We have isolated ODC1 as a multicopy suppressor of the fmc1 deletion restoring a good respiratory growth. Odc1p expression level was estimated to be at least 10 times higher in mitochondria isolated from the deltafmc1/ODC1 transformant as compared with wild type mitochondria. Interestingly, ODC1 encodes an oxodicarboxylate carrier, which transports alpha-ketoglutarate and alpha-ketoadipate or any other transported tricarboxylic acid cycle intermediate in a counter-exchange through the inner mitochondrial membrane. We show that the suppression of the respiratory-growth-deficient fmc1 by the overexpressed Odc1p was not due to a restored stable ATP synthase. Instead, the rescuing mechanism involves an increase in the flux of tricarboxylic acid cycle intermediate from the cytosol into the mitochondria, leading to an increase in the alpha-ketoglutarate oxidative decarboxylation, resulting in an increase in mitochondrial substrate-level-dependent ATP synthesis. This mechanism of metabolic bypass of a defective ATP synthase unravels the physiological importance of intramitochondrial substrate-level phosphorylations. This unexpected result might be of interest for the development of therapeutic solutions in pathologies associated with defects in the oxidative phosphorylation system.     

Yeast killer factor: ATP leakage and coordinate inhibition of macromolecular synthesis in sensitive cells

The action of the yeast killer factor proteins on sensitive yeast cells has been examined. The killer factor caused a coordinate inhibition of protein synthesis, nucleic acid synthesis and d-[⁴C]glucose incorporation into macromolecules in growing sensitive cells. During the inhibition period ATP became detectable in the growth medium and the cellular ATP pool level fell to exhaustion. ATP synthesis continued over this period as extracellular ATP accumulated to levels 4–20-fold those found in the cellular pools of control cultures. Leakage studies on other cellular components over the ATP leakage period indicated little loss of macromolecules, but an increased efflux of pools of leucine and glucose. The results are consistent with a killer-induced alteration in the yeast cell membrane.     

Adenosine utilization in cordycepin-sensitive mutants of Saccharomyces cerevisiae.

A purine-requiring, wild-type yeast strain was cordycepin resistant and failed to grow in medium containing adenosine; in contrast, a cordycepin-sensitive mutant (also purine requiring) grew well in medium containing adenosine. The cordycepin-sensitive mutant incorporated [8-14C]adenosine at nine times the wild-type rate, and adenosine completely fulfilled the purine requirement of the cells. Exogenous adenosine rapidly entered the mutant cells, apparently as free nucleoside, and was phosphorylated; uptake displayed concentration-dependent saturation kinetics (Km, 6 mM). Within 10 min 14C radioactivity was being incorporated into nucleic acids.     

Bongkrekic acid sensitivity of respiration-deficient mutants and of petite-negative species of yeasts

1. Growth on glucose of cytoplasmic respiration-deficient (ρ⁻) mutants isolated from five strains of Saccharomyces cerevisiae and one strain of Saccharomyces carlsbergensis were arrested by the inhibitor of mitochondrial adenine nucleotide translocation, bongkrekic acid. This indicates that the mitochondrial adenine nucleotide translocation system is preserved and necessary for growth in a number of independent ρ⁻ mutants.

2. Growth of three “petite-negative” yeast species was arrested by a combined inhibition of respiration by antimycin A and of adenine nucleotide translocation by bongkrekic acid. Thus, the arrest of growth upon inhibition of adenine nucleotide translocation in non-respiring cells is not specific for ρ⁻ mutants and may be a general characteristic of eucaryotic cells.     

Transcomplementation between different types of respiration-deficient mitochondria with different pathogenic mutant mitochondrial DNAs

Two cell lines were used for determination of whether interaction occurred between different types of respiration-deficient mitochondria. One was a respiration-deficient rho- cell line having mutant mitochondrial DNA (mtDNA) with a 5,196-base pair deletion including five tRNA genes (tRNAGly, Arg, Ser(AGY), Leu(CUN), His), DeltamtDNA5196, causing Kearns-Sayre syndrome. The other was a respiration-deficient syn- cell line having mutant mtDNA with an A to G substitution at 4,269 in the tRNAIle gene, mtDNA4269, causing fatal cardiomyopathy. The occurrence of mitochondrial interaction was examined by determining whether cybrids constructed by fusion of enucleated rho- cells with syn- cells became respiration competent by exchanging their tRNAs. No cybrids were isolated in selection medium, where only respiration-competent cells could survive, suggesting that no interaction occurred, or that it occurred so slowly that sufficient recovery of mitochondrial respiratory function was not attained by the time of selection. The latter possibility was confirmed by the observations that heteroplasmic cybrids with both mutant mtDNA4269 and DeltamtDNA5196 isolated without selection showed restored mitochondrial respiration activity. This demonstration of transcomplementation between different respiration-deficient mitochondria will help in understanding the relationship between somatic mutant mtDNAs and the roles of such mutations in aging processes.     

Isobongkrekic acid, a new inhibitor of mitochondrial ADP-ATP transport: radioactive labeling and chemical and biological properties.

An isomer of bongkrekic acid, designated as isobongkrekic acid, has been isolated from ethereal extracts of Pseudomonas cocovenenans grown on defatted coconut. Isobongkrekic acid was also obtained by alkaline treatment of bongkrekic acid. Isobongkrekic acid possesses the same ultraviolet spectrum and the same molecular weight as bongkrekic acid; it has a similar infrared spectrum but not the same nuclear magnetic resonance (NMR) spectrum. The differences in NMR data were interpreted to mean that isobongkrekic acid differs from bongkrekic acid by the configuration of the dicarboxylic end; whereas the two carboxylic groups of the dicarboxylic end have the trans configuration in bongkrekic acid, they have the cis configuration in isobongkrekic acid. Differences between bongkrekic and isobongkrekic acids are lost after catalytic hydrogenation of the molecules. Isobongkrekic acid, like bongkrekic acid, is an uncompetitive inhibitor of ADP transport in mitochondria, provided the mitochondria are preincubated in the presence of the inhibitor and a minute concentration of ADP. The inhibitory and binding efficiency of isobongkrekic acid is considerably increased below pH 7. The number of high affinity sites for [3H] isobongkrekic acid is 0.13 to 0.20 nmol/mg protein in rat liver mitochondria and about 1 nmol/mg protein in rat heart mitochondria, i.e., similar to the number of high affinity sites for [3H] bongkrekic acid. Isobongkrekic and bongkrekic acids compete for the same site, but the affinity of isobongkrekic acid for mitochondria is one-half to one-fourth that of bongkrekic acid.     

Inhibition of citrulline synthesis by octanoate and its modulation by adenine nucleotides

Liver mitochondria from octanoate-treated rabbits showed an impaired ability to synthesize citrulline. Two methods were used to evaluate citrulline synthesis in rat liver mitochondria. Under these conditions octanoate inhibited citrulline synthesis by over 50%. When ATP was included in the assay medium the inhibitory effect of octanoate was prevented. In the absence of ATP in the suspending medium, octanoate did not significantly lower total adenine nucleotides in rat liver mitochondria. However, under these conditions octanoate caused a change in the adenine nucleotide profile such that ATP content was decreased and AMP content was increased. When ATP was present in the assay medium, octanoate caused a similar increase in AMP content. However, ATP decreased only slightly. The alterations in mitochondrial adenine nucleotide profile by octanoate and the reversal of the effect by exogenous ATP suggests that octanoate inhibits citrulline synthesis via reduced intramitochondrial ATP levels. The ability of octanoate to lower mitochondrial ATP and elevate mitochondrial AMP may be related to its intramitochondrial activation by the medium chain fatty acid activating enzyme.     

Phenotype of a Temperature-Sensitive, Respiration-Deficient (cyt) Mutant of Yeast

A temperature-sensitive respiration-deficient mutant of yeast lacks hemoproteins and accumulates coproporphyrin III when cultivated at elevated temperatures. Cells grown at 20 C respired normally and contained cytochromes a, b, and c. Cells grown at 35 C showed respiration-deficient mutant characters; they did not respire, lacked cytochromes, and accumulated coproporphyrin III. Addition of protoporphyrin IX or protohemin IX to the culture medium restored the respiratory activity of this mutant during growth at 35 C. The activities of various enzymes, including succinate-2,6-dichlorophenol indophenol (DCPIP), reduced nicotinamide adenine dinucleotide (NADH(2))-DCPIP, succinate-cytochrome c, and NADH(2)-cytochrome c oxidoreductase, and cytochrome oxidase, and the cytochrome c content of cells cultured in various conditions were determined. Changes in the number and structure of mitochondria were associated with changes in respiratory activity.