Antioxidant function of cytosolic sources of NADPH in yeast.

The relative antioxidant functions of thiol-dependent mechanisms and of direct catalytic inactivation of H2O2 were examined using a collection of yeast mutants containing disruptions in single or multiple genes encoding two major enzymatic sources of NADPH [glucose-6-phosphate dehydrogenase (ZWF1) and cytosolic NADP+-specific isocitrate dehydrogenase (IDP2)] and in genes encoding two major cellular peroxidases [mitochondrial cytochrome c peroxidase (CCP1) and cytosolic catalase (CTT1)]. Both types of mechanisms were found to be important for growth in the presence of exogenous H2O2. In the absence of exogenous oxidants, however, loss of ZWF1 and IDP2, but not loss of CTT1 and CCP1, was found to be detrimental not only to growth but also to viability of cells shifted to rich medium containing oleate or acetate. The loss in viability correlates with increased levels of intracellular oxidants apparently produced during normal metabolism of these carbon sources. Acute effects in DeltaZWF1DeltaIDP2 mutants following shifts to these nonpermissive media include an increase in the number of cells demonstrating a transient decrease in growth rate and in cells containing apparent nuclear DNA strand breaks. Cumulative effects are reflected in phenotypes, including sensitivity to acetate medium and a reduction in mating efficiency, that become more pronounced with time following disruption of the ZWF1 and IDP2 genes. These results suggest that cellular mechanisms dependent on NADPH are crucial metabolic antioxidants.

Allosteric inhibition of NAD+-specific isocitrate dehydrogenase by a mitochondrial mRNA.

NAD+-specific isocitrate dehydrogenase (IDH) has been reported to bind sequences in 5'-untranslated regions of yeast mitochondrial mRNAs. In the current study, an RNA transcript containing the 5'-untranslated region of the mRNA from the yeast mitochondrial COX2 gene is shown to be an allosteric inhibitor of the affinity-purified yeast enzyme. At 0.1 microM concentrations of the transcript, velocity of the IDH reaction is reduced to 20% of the value obtained in the absence of the RNA transcript. This inhibition is due to a 2. 5-fold increase in the S0.5 value for isocitrate. Significant inhibition of IDH activity is also obtained with a transcript containing a portion of the 5'-untranslated region of the yeast mitochondrial ATP9 gene and with an antisense form of the COX2 transcript, both of which contain potential stem-loop secondary structures implicated in binding of IDH. In contrast, much higher concentrations of yeast tRNA or poly(A)mRNA, respectively, 33- and 60-fold greater than that required for the COX2 transcript, are required to produce a 50% decrease in velocity. These results suggest that inhibition of activity is relatively specific for the 5'-untranslated regions of mitochondrial mRNAs. All measurable inhibition of IDH activity by RNA is eliminated by addition of 100 microM concentrations of the allosteric activator AMP. At equivalent concentrations, dAMP is less efficient than AMP as an allosteric activator of IDH and is proportionally less effective in protecting against inhibition of activity by the COX2 transcript. Other nucleotides that are not allosteric activators fail to protect IDH activity from inhibitory effects of RNA. Thus, alleviation of catalytic inhibition of IDH by mitochondrial mRNA correlates with the property of allosteric activation.

Dependence of peroxisomal beta-oxidation on cytosolic sources of NADPH.

Growth of Saccharomyces cerevisiae with a fatty acid as carbon source was shown previously to require function of either glucose-6-phosphate dehydrogenase (ZWF1) or cytosolic NADP+-specific isocitrate dehydrogenase (IDP2), suggesting dependence of beta-oxidation on a cytosolic source of NADPH. In this study, we find that DeltaIDP2DeltaZWF1 strains containing disruptions in genes encoding both enzymes exhibit a rapid loss of viability when transferred to medium containing oleate as the carbon source. This loss of viability is not observed following transfer of a DeltaIDP3 strain lacking peroxisomal isocitrate dehydrogenase to medium with docosahexaenoate, a nonpermissive carbon source that requires function of IDP3 for beta-oxidation. This suggests that the fatty acid- phenotype of DeltaIDP2DeltaZWF1 strains is not a simple defect in utilization. Instead, we propose that the common function shared by IDP2 and ZWF1 is maintenance of significant levels of NADPH for enzymatic removal of the hydrogen peroxide generated in the first step of peroxisomal beta-oxidation in yeast and that inadequate levels of the reduced form of the cofactor can produce lethality. This proposal is supported by the finding that the sensitivity to exogenous hydrogen peroxide previously reported for DeltaZWF1 mutant strains is less pronounced when analyses are conducted with a nonfermentable carbon source, a condition associated with elevated expression of IDP2. Under those conditions, similar slow growth phenotypes are observed for DeltaZWF1 and DeltaIDP2 strains, and co-disruption of both genes dramatically exacerbates the H2O2s phenotype. Collectively, these results suggest that IDP2, when expressed, and ZWF1 have critical overlapping functions in provision of reducing equivalents for defense against endogenous or exogenous sources of H2O2.

Sources of NADPH and expression of mammalian NADP+-specific isocitrate dehydrogenases in Saccharomyces cerevisiae.

To compare roles of specific enzymes in supply of NADPH for cellular biosynthesis, collections of yeast mutants were constructed by gene disruptions and matings. These mutants include haploid strains containing all possible combinations of deletions in yeast genes encoding three differentially compartmentalized isozymes of NADP+-specific isocitrate dehydrogenase and in the gene encoding glucose-6-phosphate dehydrogenase (Zwf1p). Growth phenotype analyses of the mutants indicate that either cytosolic NADP+-specific isocitrate dehydrogenase (Idp2p) or the hexose monophosphate shunt is essential for growth with fatty acids as carbon sources and for sporulation of diploid strains, a condition associated with high levels of fatty acid synthesis. No new biosynthetic roles were identified for mitochondrial (Idp1p) or peroxisomal (Idp3p) NADP+-specific isocitrate dehydrogenase isozymes. These and other results suggest that several major presumed sources of biosynthetic reducing equivalents are non-essential in yeast cells grown under many cultivation conditions. To develop an in vivo system for analysis of metabolic function, mammalian mitochondrial and cytosolic isozymes of NADP+-specific isocitrate dehydrogenase were expressed in yeast using promoters from the cognate yeast genes. The mammalian mitochondrial isozyme was found to be imported efficiently into yeast mitochondria when fused to the Idp1p targeting sequence and to substitute functionally for Idp1p for production of alpha-ketoglutarate. The mammalian cytosolic isozyme was found to partition between cytosolic and organellar compartments and to replace functionally Idp2p for production of alpha-ketoglutarate or for growth on fatty acids in a mutant lacking Zwf1p. The mammalian cytosolic isozyme also functionally substitutes for Idp3p allowing growth on petroselinic acid as a carbon source, suggesting partial localization to peroxisomes and provision of NADPH for beta-oxidation of that fatty acid.

Expression and mutagenesis of mammalian cytosolic NADP+-specific isocitrate dehydrogenase.

Rat liver cytosolic NADP+-specific isocitrate dehydrogenase (IDP2) was expressed in bacteria as a fusion protein with maltose binding protein (MBP). High levels of expression were obtained. The fusion protein was purified from bacterial lysates by affinity chromatography with an amylose resin and found to be catalytically active. IDP2 was separated from MBP by cleavage with protease Xa and purified to homogeneity by FPLC anion-exchange chromatography. A specific activity of 56.3 units/mg and respective apparent Km values for dl-isocitrate and NADP+ of 9.7 +/- 2.9 microM and 11.5 +/- 0.2 microM were obtained for the purified enzyme. These values are similar to those previously reported for cytosolic isocitrate dehydrogenase isolated from a variety of tissues. Evolutionarily conserved arginine residues implicated in substrate binding were changed to glutamate residues using PCR based site-directed mutagenesis of the bacterial fusion plasmid. Mutant enzymes containing residue changes of R100E, R109E, R119E, or R132E were expressed, purified, and characterized by initial rate kinetic analyses. The R119E and R109E mutant enzymes exhibited respective 15- and 31-fold increases in Km values for dl-isocitrate relative to the wild-type enzyme. In contrast, Km values for NADP+ were, respectively, unchanged and increased 9-fold. The most significant reductions in kcat/Km values were obtained for the R100E, R109E, and R132E enzymes. These results suggest that substrate binding residues are highly conserved between bacterial and mammalian enzymes despite low overall homology.

Expression and function of a mislocalized form of peroxisomal malate dehydrogenase (MDH3) in yeast.

The malate dehydrogenase isozyme MDH3 of Saccharomyces cerevisiae was found to be localized to peroxisomes by cellular fractionation and density gradient centrifugation. However, unlike other yeast peroxisomal enzymes that function in the glyoxylate pathway, MDH3 was found to be refractory to catabolite inactivation, i.e. to rapid inactivation and degradation following glucose addition. To examine the structural requirements for organellar localization, the Ser-Lys-Leu carboxyl-terminal tripeptide, a common motif for localization of peroxisomal proteins, was removed by mutagenesis of the MDH3 gene. This resulted in cytosolic localization of MDH3 in yeast transformants. To examine structural requirements for catabolite inactivation, a 12-residue amino-terminal extension from the yeast cytosolic MDH2 isozyme was added to the amino termini of the peroxisomal and mislocalized "cytosolic" forms of MDH3. This extension was previously shown to be essential for catabolite inactivation of MDH2 but failed to confer this property to MDH3. The mislocalized cytosolic forms of MDH3 were found to be catalytically active and competent for metabolic functions normally provided by MDH2.

Glucose-induced phosphorylation of the MDH2 isozyme of malate dehydrogenase in Saccharomyces cerevisiae.

The cytosolic isozyme of malate dehydrogenase, MDH2, was previously shown to be subject to rapid inactivation and proteolysis following the addition of glucose to yeast cultures growing on nonfermentable carbon sources. In this report, we show that MDH2 is phosphorylated during the process of glucose-induced degradation. A truncated active form of MDH2 lacking the first 12 residues of the amino terminus was previously found to be resistant to glucose-induced degradation and, as shown in this study, is not subject to phosphorylation. Site-directed mutagenesis was conducted to change Ser-12 in the authentic enzyme to Ala-12 and to Asp-12. The S12A substitution has little effect on glucose-induced phosphorylation and degradation, whereas the enzyme with the S12D substitution is subject to phosphorylation and inactivation but not to rapid degradation. This provides clear evidence that inactivation is not simply a result of degradation. Additional mutagenesis was conducted to change His-214, a critical active site residue, to Leu-214. Analysis of expression of full-length and truncated forms of the H214L enzyme demonstrated that catalytic inactivity is not a prerequisite for degradation and confirmed an essential role for the amino terminus of the authentic enzyme in this phenomenon.

Glucose-induced degradation of the MDH2 isozyme of malate dehydrogenase in yeast.

MDH2, the nonmitochondrial isozyme of malate dehydrogenase in Saccharomyces cerevisiae, was determined to be a target of glucose-induced proteolytic degradation. Shifting a yeast culture growing with acetate to medium containing glucose as a carbon source resulted in a 25-fold increase in turnover of MDH2. A truncated form of MDH2 lacking amino acid residues 1-12 was constructed by mutagenesis of the MDH2 gene and expressed in a haploid yeast strain containing a deletion disruption of the corresponding chromosomal gene. Measurements of malate dehydrogenase specific activity and determination of growth rates with diagnostic carbon sources indicated that the truncated form of MDH2 was expressed at authentic MDH2 levels and was fully active. However, the truncated enzyme proved to be less susceptible to glucose-induced proteolysis, exhibiting a 3.75-fold reduction in turnover rate following a shift to glucose medium. Rates of loss of activity for other cellular enzymes known to be subject to glucose inactivation were similarly reduced. An extended lag in attaining wild type rates of growth on glucose measured for strains expressing the truncated MDH2 enzyme represents the first evidence of a selective advantage for the phenomenon of glucose-induced proteolysis in yeast.

Expression and function of heterologous forms of malate dehydrogenase in yeast.

The structure of the tricarboxylic acid cycle enzyme malate dehydrogenase is highly conserved in various organisms. To test the extent of functional conservation, the rat mitochondrial enzyme and the enzyme from Escherichia coli were expressed in a strain of Saccharomyces cerevisiae containing a disruption of the chromosomal MDH1 gene encoding yeast mitochondrial malate dehydrogenase. The authentic precursor form of the rat enzyme, expressed using a yeast promoter and a multicopy plasmid, was found to be efficiently targeted to yeast mitochondria and processed to a mature active form in vivo. Mitochondrial levels of the polypeptide and malate dehydrogenase activity were found to be similar to those for MDH1 in wild-type yeast cells. Efficient expression of the E. coli mdh gene was obtained with multicopy plasmids carrying gene fusions encoding either a mature form of the procaryotic enzyme or a precursor form with the amino terminal mitochondrial targeting sequence from yeast MDH1. Very low levels of mitochondrial import and processing of the precursor form were obtained in vivo and activity could be demonstrated for only the expressed precursor fusion protein. Results of in vitro import experiments suggest that the percursor form of the E. coli protein associates with yeast mitochondria but is not efficiently internalized. Respiratory rates measured for isolated yeast mitochondria containing the mammalian or procaryotic enzyme were, respectively, 83 and 62% of normal, suggesting efficient delivery of NADH to the respiratory chain. However, expression of the heterologous enzymes did not result in full complementation of growth phenotypes associated with disruption of the yeast MDH1 gene.

Isolation, nucleotide sequence analysis, and disruption of the MDH2 gene from Saccharomyces cerevisiae: evidence for three isozymes of yeast malate dehydrogenase.

The major nonmitochondrial isozyme of malate dehydrogenase (MDH2) in Saccharomyces cerevisiae cells grown with acetate as a carbon source was purified and shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to have a subunit molecular weight of approximately 42,000. Enzyme assays and an antiserum prepared against the purified protein were used to screen a collection of acetate-nonutilizing (acetate-) yeast mutants, resulting in identification of mutants in one complementation group that lack active or immunoreactive MDH2. Transformation and complementation of the acetate- growth phenotype was used to isolate a plasmid carrying the MDH2 gene from a yeast genomic DNA library. The amino acid sequence derived from complete nucleotide sequence analysis of the isolated gene was found to be extremely similar (49% residue identity) to that of yeast mitochondrial malate dehydrogenase (molecular weight, 33,500) despite the difference in sizes of the two proteins. Disruption of the MDH2 gene in a haploid yeast strain produced a mutant unable to grow on minimal medium with acetate or ethanol as a carbon source. Disruption of the MDH2 gene in a haploid strain also containing a disruption in the chromosomal MDH1 gene encoding the mitochondrial isozyme produced a strain unable to grow with acetate but capable of growth on rich medium with glycerol as a carbon source. The detection of residual malate dehydrogenase activity in the latter strain confirmed the existence of at least three isozymes in yeast cells.