DNA-dependent RNA polymerases isolated from yeast mitochondria

Purified preparations of yeast mitochondria yield three species of DNA-dependent RNA polymerases. These enzymes have been separated and purified to homogeneity for analysis of their properties and for comparison with the properties of nuclear preparations of yeast RNA polymerases. Three enzymes have been separated by DEAE-Sephadex chromatography of each fraction. Both nuclear and mitochondrial preparations yield three components with nearly identical elution properties. The distributions of enzyme activity on DEAE-Sephadex chromatography differ with the three nuclear peaks, being found in ratios (uncorrected for the effect of increasing salt concentration) of 8:85:7 and the mitochondrial peaks in ratios of 8:32:60 at late log phase of growth under optimized conditions in which protease inhibitors and an antioxidant were included. The type of mitochondrial enzymes in 3-day-old cells differed from those grown to late logarithmic phase. It has been established that the enzymes of the mitochondrial preparation are associated with the membrane fraction. While extraction with 0.5 m KCl solubilizes considerable enzyme activity, greatly enhanced yields of enzyme MIII are obtained by addition of the antioxidant 2,6-di-t-butyl-4-hydroxymethyl phenol during enzyme extraction. Inhibition of protease activity has also been shown to have a major effect on the yield and distribution of enzymes obtained from mitochondrial preparations. The mitochondrial preparations of yeast polymerases are generally similar but not identical to corresponding nuclear polymerases in subunit molecular weights, inhibitor sensitivities, and in DNA template dependence. Comparative studies of nuclear and mitochondrial polymerases clearly establish that differences do exist among the isolated enzymes of these classes. It has not been ruled out to date that these enzymes may be derived in part or in total from the same cytoplasmic subunit pool, nor has it been established that any of these enzymes function in mitochondria in vivo.     

Nuclear origin of specific yeast mitochondrial aminoacyl-tRNA synthetases.

Hydroxylapatite chromatographies of mitochondrial and total enzymes from a rho+ yeast, or from the related rho degrees mitochondrial DNA-less mutant, show the occurrence in the mitochondrial enzyme of one Phe-, one Met-, one Leu-tRNA synthetase peak which elutes distinctly from the cytoplasmic counterpart and charges well mitochondrial tRNA, whereas the cytoplasmic enzyme does not. The measurement of the mitochondrial synthetases activities in various enzymatic extracts shows that they are not repressed in rho+ cells grown on 10% glucose and that they are concentrated in the mitochondria (Phe- and Met- tRNA synthetases) but are also present outside the mitochondria. It is concluded that yeast mitochondrial protein biosynthesis involves the nuclear coded mitochondrial specific Phe-, Met- and Leu-tRNA synthetases and that the entrance of the synthetases into the mitochondria needs no factor depending on the mitochondrial DNA.     

Purification of the yeast mitochondrial methionyl-tRNA synthetase. Common and distinctive features of the cytoplasmic and mitochondrial isoenzymes

Yeast-mitochondrial methionyl-tRNA synthetase was purified 1060-fold from mitochondrial matrix proteins of Saccharomyces cerevisiae using a four-step procedure based on affinity chromatography (heparin-Ultrogel, tRNA(Met)-Sepharose, Agarose-hexyl-AMP) to yield to a single polypeptide of high specific activity (1800 U/mg). Like the cytoplasmic methionyl-tRNA synthetase (Mr 85,000), the mitochondrial isoenzyme is a monomer, but of significantly smaller polypeptide size (Mr 65,000). In contrast, the corresponding enzyme of Escherichia coli is a dimer (Mr 152,000) made up of identical subunits. The measured affinity constants of the purified mitochondrial enzyme for methionine and tRNA(Met) are similar to those of the cytoplasmic isoenzyme. However, the two yeast enzymes exhibit clearly different patterns of aminoacylation of heterologous yeast and E. coli tRNA(Met). Furthermore, polyclonal antibodies raised against the two proteins did not show any cross-reactivity by inhibition of enzymatic activity and by the highly sensitive immunoblotting technique, indicating that the two enzymes share little, if any, common antigenic determinants. Taken together, our results further support the belief that the yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases are different proteins coded for by two distinct nuclear genes. Like the yeast cytoplasmic aminoacyl-tRNA synthetases, the mitochondrial enzymes displayed affinity for immobilized heparin. This distinguishes them from the corresponding enzymes of E. coli. Such an unexpected property of the mitochondrial enzymes suggests that they have acquired during evolution a domain for binding to negatively charged cellular components.     

Biochemical,cellular and molecular identification of DNA polymerase α in yeast mitochondria

DNA replication occurs in various compartments of eukaryotic cells such as the nuclei, mitochondria and chloroplasts, the latter of which is used in plants and algae. Replication appears to be simpler in the mitochondria than in the nucleus where multiple DNA polymerases, which are key enzymes for DNA synthesis, have been characterized. In mammals, only one mitochondrial DNA polymerase (pol γ) has been described to date. However, in the mitochondria of the yeast Saccharomyces cerevisiae, we have found and characterized a second DNA polymerase. To identify this enzyme, several biochemical approaches such as proteinase K treatment of sucrose gradient purified mitochondria, analysis of mitoplasts, electron microscopy and the use of mitochondrial and cytoplasmic markers for immunoblotting demonstrated that this second DNA polymerase is neither a nuclear or cytoplasmic contaminant nor a proteolytic product of pol γ. An improved purification procedure and the use of mass spectrometry allowed us to identify this enzyme as DNA polymerase α. Moreover, tagging DNA polymerase α with a fluorescent probe demonstrated that this enzyme is localized both in the nucleus and in the organelles of intact yeast cells. The presence of two replicative DNA polymerases may shed new light on the mtDNA replication process in S. cerevisiae.     

Distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.

Total methionine-tRNA synthetases from wild type $\text{Saccharomyces}\text{cerevisiae}$ can be fractionated on hydroxylapatite into two peaks: Peak I is the mitochondrial, peak II the cytoplasmic isoenzyme. The specificity towards various tRNAs and the antigenic determinants are not identical. A mutant strain, known for its altered cytoplasmic enzyme, contains a mitochondrial species with the same properties as the wild type mitochondrial enzyme, as well as a cytoplasmic isoenzyme with a K_M for methionine about 300 times higher than the corresponding wild type enzyme. Another strain, obtained by back-crossing the mutant with a wild type strain, retains the enzyme pattern found in the mutant. The results are in favor of two distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.     

Heterologous expression, purification, and kinetic comparison of the cytoplasmic and mitochondrial glyoxalase II enzymes, Glo2p and Glo4p, from Saccharomyces cerevisiae

The aims of the present study are (i) to purify a mitochondrial glyoxalase II to homogeneity for the first time from any organism and (ii) to compare its kinetic properties with those of the cytoplasmic enzyme. Both the cytoplasmic and the mitochondrial glyoxalases II from Saccharomyces cerevisiae, which are the products of two distinct genes, GLO2 and GLO4, were purified from yeast and in recombinant form from Escherichia coli. To obtain a higher protein yield (compared to wild-type expression) in yeast, the genes were placed under the control of the strong GAL1 promoter on a multicopy plasmid. Amino-terminal sequencing and molecular mass determination by MALDI-TOF mass spectrometry of the mitochondrial Glo4 protein revealed Met-11 of the primary translation product of the gene as the N-terminal amino acid. Judged by enzyme kinetic properties the recombinant and natural proteins were equivalent. The cytoplasmic and the mitochondrial enzyme differed in the pH dependence of the kinetic parameters for the main substrate, S-d-lactoylglutathione. Whereas the cytoplasmic protein showed a pronounced peak of enzyme activity between pH 7-8 and a continuous up to fivefold increase of the K(M) value with increasing pH (from 5. 5-9.0), the mitochondrial protein had a nearly constant K(M) value and an activity maximum over a broad pH range (6.5-9.0). The kinetic parameters (at pH 7.5) of both the cytoplasmic and the mitochondrial enzyme for S-D-lactoylglutathione were of the same order of magnitude as reported recently for the human and Arabidopsis thaliana enzymes which are presumably of cytoplasmic origin. However, both yeast enzymes showed a severalfold lower preference for the more hydrophobic substrate, S-d-mandeloylglutathione.     

Mitochondrial one-carbon metabolism is adapted to the specific needs of yeast, plants and mammals

In eukaryotes, folate metabolism is compartmentalized between the cytoplasm and organelles. The folate pathways of mitochondria are adapted to serve the metabolism of the organism. In yeast, mitochondria support cytoplasmic purine synthesis through the generation of formate. This pathway is important but not essential for survival, consistent with the flexibility of yeast metabolism. In plants, the mitochondrial pathways support photorespiration by generating serine from glycine. This pathway is essential under photosynthetic conditions and the enzyme expression varies with photosynthetic activity. In mammals, the expression of the mitochondrial enzymes varies in tissues and during development. In embryos, mitochondria supply formate and glycine for purine synthesis, a process essential for survival; in adult tissues, flux through mitochondria can favor serine production. The differences in the folate pathways of mitochondria depending on species, tissues and developmental stages, profoundly alter the nature of their metabolic contribution.     

Different forms of rat liver aldehyde dehydrogenase and their subcellular distribution.

1. The properties and distribution of the NAD-linked unspecific aldehyde dehydrogenase activity (aldehyde: NAD+ oxidoreductase EC 1.2.1.3) has been studied in isolated cytoplasmic, mitochondrial and microsomal fractions of rat liver. The various types of aldehyde dehydrogenase were separated by ion exchange chromatography and isoelectric focusing. 2. The cytoplasmic fraction contained 10-15, the mitochondrial fraction 45-50 and the microsomal fraction 35-40% of the total aldehyde dehydrogenase activity, when assayed with 6.0 mM propionaldehyde as substrate. 3. The cytoplasmic fraction contained two separable unspecific aldehyde dehydrogenases, one with high Km for aldehydes (in the millimolar range) and the other with low Km for aldehydes (in the micromolar range). The latter can, however, be due to leakage from mitochondria. The high-Km enzyme fraction contained also all D-glucuronolactone dehydrogenase activity of the cytoplasmic fraction. The specific formaldehyde and betaine aldehyde dehydrogenases present in the cytoplasmic fraction could be separated from the unspecific activities. 4. In the mitochondrial fraction there was one enzyme with a low Km for aldehydes and another with high Km for aldehydes, which was different from the cytoplasmic enzyme. 5. The microsomal aldehyde dehydrogenase had a high Km for aldehydes and had similar properties as the mitochondrial high-Km enzyme. Both enzymes have very little activity with formaldehyde and glycolaldehyde in contrast to the other aldehyde dehydrogenases. They are apparently membranebound.     

Computer modeling of two inorganic pyrophosphatases.

The yeast Saccharomyces cerevisiae has two inorganic pyrophosphatases that are structurally related. One, PPA1, is a cytoplasmic enzyme. The other, PPA2, is located in the mitochondria and appears to be energy-linked. The sequence similarity of PPA1 and PPA2 is about 66% and the identity is about 50%. All amino acids known to be important for catalysis are conserved, except one glutamate which is substituted by an aspartate in PPA2. The structures of PPA2 and the cytoplasmic PPase from Schizosaccharomyces pombe were modeled based on the three dimensional structure of PPA1. Two cysteines in PPA2 and one in the S. pombe enzyme are located at the catalytic cleft. Four residues form an unique insertion near the entrance of the catalytic cleft in the mitochondrial enzyme.     

The synthesis of yeast matrix mitochondrial enzymes is regulated by different levels of mitochondrial function

The role of mitochondria in the oxygen induction of a number of catabolic and mitochondrial enzymes (citrate synthase, NAD- and NADP-isocitrate dehydrogenases, oxoglutarate dehydrogenase, NAD-glutamate dehydrogenase) has been investigated in anaerobic yeast grown under different conditions. The patterns of variation of enzyme activity with oxygen and lipid content of the mitochondria and with antibiotics suggest that more than one control is operating. The inhibition produced by cycloheximide, which blocks protein translation, suggests that induction involves de novo protein synthesis, except for an initial 2-h induction of citrate synthase, which is insensitive to all antibiotics tested. Ethidium bromide prevents enzyme induction in lipid-depleted anaerobic yeast. Induction follows normal kinetics in lipid-supplemented cultures despite the ethidium bromide block in the development of respiratory ability. Enzyme induction is inhibited by chloramphenicol in both lipid-depleted and lipid-supplemented anaerobic yeast. On the basis of four results it can be postulated that the mitochondrial genome is involved in controlling the induction of enzymes synthesized on cytoplasmic ribosomes. This control might be exerted by a specific, mitochondrial product or might be the result of modulation by a secondary product of mitochondrial function.     

The Saccharomyces cerevisiae Pus2 protein encoded by YGL063w ORF is a mitochondrial tRNA:Psi27/28-synthase

The RNA:pseudouridine (Psi)-synthase family is one of the most complex families of RNA modification enzymes. Ten genes encoding putative RNA:Psi-synthases have been identified in S. cerevisiae. Most of the encoded enzymes have been characterized experimentally. Only the putative RNA:Psi-synthase Pus2p (encoded by the YGL063w ORF) had no identified substrate. Here, we analyzed Psi residues in cytoplasmic and mitochondrial tRNAs extracted from S. cerevisiae strains, carrying disruptions in the PUS1 and/or PUS2 ORFs. Our results demonstrate that Pus2p is a mitochondrial-specific tRNA:Psi-synthase acting at positions 27 and 28 in tRNAs. The importance of the Asp56 residue in the conserved ARTD motif of the Pus2p catalytic site is demonstrated in vivo. Interestingly, in spite of the absence of a characteristic N-terminal targeting signal, our data strongly suggest an efficient and rapid targeting of Pus2p in yeast mitochondria. In contradiction with the commonly held idea that a unique nuclear gene encodes the enzyme required for both cytoplasmic and mitochondrial tRNA modifications, here we show the existence of an enzyme specifically dedicated to mitochondrial tRNA modification (Pus2p), the corresponding modification in cytoplasmic tRNAs being catalyzed by another protein (Pus1p).     

Biochemical comparison of the Neurospora crassa wild type and the temperature-sensitive and leucine-auxotroph mutant leu-5. Purification of the cytoplasmic and mitochondrial leucyl-tRNA synthetases and comparison of the enzymatic activities and the degradation patterns

The cytoplasmic leucyl-tRNA synthetases of Neurospora crassa wild type (grown at 37 degrees C) and mutant (grown at 28 degrees C) were purified approximately 1770-fold and 1440-fold respectively. Additional enzyme preparations were carried out with mutant cells grown for 24 h at 28 degrees C and transferred then to 37 degrees C for 10-70 h of growth. The mitochondrial leucyl-tRNA synthetase of the wild type was purified approximately 722-fold. The mitochondrial mutant enzyme was found only in traces. The cytoplasmic leucyl-tRNA synthetase from the mutant (grown at 37 degrees C) in vivo is subject of a proteolytic degradation. This leads to an increased pyrophosphate exchange, without altering aminoacylation. Proteolysis in vitro by trypsin or subtilisin of isolated cytoplasmic wild-type and mutant leucyl-tRNA synthetases, however, did not establish and difference in the degradation products and in their catalytic properties. Comparing the cytoplasmic wild-type and mutant enzymes (grown at 28 degrees C) via steady-state kinetics did not show significant differences between these synthetases either. The rate-determining step appears to be after the transfer of the aminoacyl group to the tRNA, e.g. a conformational change or the release of the product. Besides leucine only isoleucine is activated by the enzymes with a discrimination of approximately 1:600; however, no Ile-tRNALeu is released. Similarly these enzymes, when tested with eight ATP analogs, cannot be distinguished. For both enzymes six ATP analogs are neither substrates nor inhibitors. Two analogs are substrates with identical kinetic parameters. The mitochondrial wild-type leucyl-tRNA synthetase is different from the cytoplasmic enzyme, as particularly exhibited by aminoacylating Escherichia coli tRNALeu but not N. crassa cytoplasmic tRNALeu. The presence of traces of the analogous mitochondrial mutant enzyme could be demonstrated. Therefore, the difference between wild-type and mutant leu-5 does not rest in the catalytic properties of the cytoplasmic leucyl-tRNA synthetases. Differences in other properties of these enzymes are not excluded. In contrast the activity of the mitochondrial leucyl-tRNA synthetase of the mutant is approximately 1% of that of the wild-type enzyme.     

Structure and evolution of a group of related aminoacyl-tRNA synthetases

A yeast nuclear gene, designated MSK1, has been selected from a yeast genomic library by transformation of a respiratory deficient mutant impaired in acylation of mitochondrial lysine tRNA. This gene confers a respiratory competent phenotype and restores the mutant's ability to acylate the mitochondrial lysine tRNA. The amino acid sequence of the protein encoded by MSK1 is homologous to yeast cytoplasmic lysyl-tRNA synthetase and to the product of the herC gene, which has recently been suggested to code for the Escherichia coli enzyme. These observations indicate that MSK1 codes for the lysyl-tRNA synthetase of yeast mitochondria. Several regions of high primary sequence conservation have been identified in the bacterial and yeast lysyl-tRNA synthetases. These domains are also present in the aspartyl- and asparaginyl-tRNA synthetases, further confirming the notion that all three present-day enzymes originated from a common ancestral gene. The most conserved domain, located near the carboxyl terminal ends of this group of synthetases is characterized by a cluster of glycines and is also highly homologous to the carboxyl-terminal region of the E. coli ammonia-dependent asparagine synthetase. A catalytic function of the carboxyl terminal domain is indicated by in vitro mutagenesis of the yeast mitochondrial lysyl-tRNA synthetase. Replacement of any one of three glycine residues by alanine and in one case by aspartic acid completely suppresses the activity of the enzymes, as evidenced by the inability of the mutant genes to complement an msk1 mutant, even when present in high copy. Other mutations result in partial loss of activity. Only one glycine replacement affects the stability of the protein in vivo. The observed presence of a homologous domain in asparagine synthetase, which, like the aminoacyl-tRNA synthetases, catalyzes the formation of an aminoacyladenylate, suggests that the glycine-rich sequence is part of a catalytic site involved in binding of ATP and of the aminoacyladenylate intermediate.     

Intracellular localization of the 3-hydroxy-3-methylglutaryl coenzme A cycle enzymes in liver. Separate cytoplasmic and mitochondrial 3-hydroxy-3-methylglutaryl coenzyme A generating systems for cholesterogenesis and ketogenesis.

Acetoacetyl-CoA thiolase and 3-hydroxy-3-methylglutaryl coenzyme synthase which comprise the 3-hydroxy-3-methylglutaryl-CoA-generating system(s) for hepatic cholesterogenesis and ketogenesis exhibit dual mitochondrial and cytoplasmic localization. Twenty to forty per cent of the thiolase and synthase of avian and rat liver are localized in the cytoplasmic compartment, the remainder residing in the mitochondria. In contrast, 3-hydroxy-3 methylglutaryl-CoA lyase, an enzyme unique to the "3-hydroxy-3-methylglutaryl-CoA cycle" of ketogenesis, appears to be localized in the mitochondrion. The small proportion, 4 to 8 percent, of this enzyme found in the cytoplasmic fraction appears to arise via leakage from the mitochondria during cell fractionation in that its properties, pI and stability, are identical to those of the mitochondrial lyase. These results are consistent with the view that ketogenesis which involves all three enzymes, acetoacetyl-CoA thiolase, 3-hydroxy-3-methylglutaryl-CoA synthase and 3-hydroxy-3-methylglutaryl-CoA lyase, occurs exclusively in the mitochondrion, whereas cholesterogenesis, a pathway which involves only the 3-hydroxy-3-methylglutaryl-CoA synthesizing enzymes, is restricted to the cytoplasm. Further fractionation of isolated mitochondria from chicken and rat liver showed that all three of the 3-hydroxy-3-methylglutaryl-CoA cycle enzymes are soluble and are localized within the matrix compartment of the mitochondrion. Likewise, cytoplasmic acetoacetyl-CoA thiolase and 3-hydroxy-3-methylglutaryl-CoA synthase are soluble cytosolic enzymes, no thiolase or synthase activity being detectable in the microsomal fraction. Chicken liver mitochondrial 3-hydroxy-3methylglutaryl-CoA synthase activity consists of a single enzymic species with a pI of 7.2, whereas the cytoplasmic activity is composed of at least two species with pI values of 4.8 and 6.7. Thus it is evident that the mitochondrial and cytoplasmic species are molecularly distinct as has been shown to be the case for the mitochondrial and cytoplasmic acetoacetyl-CoA thiolases from avian liver (Clinkenbeard, K. D., Sugiyama, T., Moss, J., Reed, W. D., and Lane, M. D. (1973) J. Biol. Chem. 248, 2275). Substantial mitochondrial 3-hydroxy-3-methylglutaryl-CoA lyase activity is present in all tissues surveyed, while only liver and kidney possess significant mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase activity. Therefore, it is proposed that tissues other than liver and kidney are unable to generate acetoacetate because they lack the mitochondrial synthase.     

The Identity of Hexokinase Activities from Mitochondrial and Cytoplasmic Fractions of Rat Brain Homogenates

Cytoplasmic hexokinase (ATP: D-hexose 6-phosphotransferase, EC 2.7.1.1) was purified from the soluble fraction of a rat brain homogenate by a procedure that included a unique affinity elution of the enzyme from Blue Dextran-Sepharose. The purified enzyme was examined with respect to properties in which the impure cytoplasmic enzyme has been reported to differ from the solubilized mitochondrial enzyme. These included the ability to bind to mitochondria, inhibition by quercetin, effect of pH on activity, and kinetics. In all regards the purified mitochondrial and cytoplasmic enzymes appeared identical. In addition, comparative peptide maps after partial proteolysis showed no detectable differences. These results do not support the view that there exist distinct mitochondrial and cytoplasmic forms of hexokinase, the latter being permanently relegated to a cytoplasmic location and unable to participate in a dynamic equilibrium with the mitochondrially-bound enzyme. Alternatives are proposed to explain previous results that had been interpreted as indirect evidence for the existence of a distinct cytoplasmic hexokinase.     

Baculovirus expression reconstitutes Drosophila mitochondrial DNA polymerase.

Drosophila mitochondrial DNA polymerase has been reconstituted and purified from baculovirus-infected insect cells. Baculoviruses encoding full-length and mature forms of the catalytic and accessory subunits were generated and used in single and co-infection studies. Recombinant heterodimeric holoenzyme was reconstituted in both the mitochondria and cytoplasm of Sf9 cells and required the mitochondrial presequences in both subunits. The recombinant holoenzyme contains DNA polymerase and 3'-5' exonuclease that are stimulated substantially by both salt and mitochondrial single-stranded DNA-binding protein. Thus, the recombinant enzyme exhibits biochemical properties indistinguishable from those of the native enzyme from Drosophila embryos. Production of the catalytic subunit alone yielded soluble protein with the chromatographic properties of the heterodimeric holoenzyme. However, the purified catalytic core has a 50-fold lower specific activity. This provides evidence of a critical role for the accessory subunit in the catalytic efficiency of Drosophila mitochondrial DNA polymerase.     

Comparison of yeast mitochondrial Phe-tRNA synthetase subunits to their cytoplasmic counterparts: Isolation and determination of amino acid compositions

The α and β subunits of yeast mitochondrial Phe-tRNA synthetase are separated and isolated by means of chromatography on DEAE-cellulose, after enzyme alkylation with iodoacetate. The comparison of amino acid compositions of yeast mitochondrial and cytoplasmic native Phe-tRNA synthetases and their components shows significant differences. Results indicate that the two enzymes are coded for by different nuclear genes.     

Mammalian mitochondrial endonuclease activities specific for ultraviolet-irradiated DNA.

Mitochondrial forms of uracil DNA glycosylase and UV endonuclease have been purified and characterized from the mouse plasmacytoma cell line, MPC-11. As in other cell types, the mitochondrial uracil DNA glycosylase has properties very similar to those of the nuclear enzyme, although in this case the mitochondrial activity was also distinguishable by extreme sensitivity to dilution. Three mitochondrial UV endonuclease activities are also similar to nuclear enzymes; however, the relative amounts of these enzyme activities in the mitochondria is significantly different from that in the nucleus. In particular, mitochondria contain a much higher proportion of an activity analogous to UV endonuclease III. Nuclear UV endonuclease III activity is absent from XP group D fibroblasts and XP group D lymphoblasts have reduced, but detectable levels of the mitochondrial form of this enzyme. This residual activity differs in its properties from the normal mitochondrial form of UV endonuclease III, however. The presence of these enzyme activities which function in base excision repair suggests that such DNA repair occurs in mitochondria. Alternatively, these enzymes might act to mark damaged mitochondrial genomes for subsequent degradation.     

Identity of mitochondrial and cytosolic glycerate kinases in rat liver and regulation of their intracellular localization by dietary protein

Glycerate kinase (ATP : D-glycerate 2-phosphotransferase EC 2.7.1.31) is a key enzyme of gluconeogenesis from serine via hydroxypyruvate. A differential centrifugation of rat liver homogenate and an analysis of the particle fraction by sucrose density gradient centrifugation indicated that 72% and 26% of glycerate kinase are present in mitochondria and cytosol, respectively. A study on the intramitochondrial localization of the enzyme suggested that the mitochondrial glycerate kinase was present in inner membrane and/or matrix. It was found that dietary protein selectively induced mitochondrial glycerate kinase. This result suggested that mitochondrial glycerate kinase had a physiological function for gluconeogenesis from serine. However, the metabolic significance of the cytoplasmic enzyme was still unclear. The properties of solubilized-mitochondrial and cytosolic glycerate kinases were compared. However, no difference between the two enzymes could be found in the kinetic properties, thermal stability, molecular size or electrochemical properties. These results suggested that both enzymes originate from common genetic information. In order to elucidate the regulatory mechanism of the intracellular distribution of glycerate kinase in rat liver, the responses of mitochondrial and cytosolic glycerate kinases to an alteration of dietary protein were studied. The result suggested that an alteration of dietary protein content may regulate the distribution and the translocation of glycerate kinase to mitochondria and cytosol as well as the total amount of glycerate kinase.     

Identity of mitochondrial and cytosolic glycerate kinases in rat liver and regulation of their intracellular localization by dietary protein.

Glycerate kinase (ATP: D-glycerate 2-phosphotransferase EC 2.7.1.31) is a key enzyme of glyconeogenesis from serine via hydroxypyruvate. A differential centrifugation of rat liver homogenate and an analysis of the particle fraction by sucrose density gradient centrifugation indicated that 72% and 26% of glycerate kinase are present in mitochondria and cytosol, respectively. A study on the intramitochondrial localization of the enzyme suggested that the mitochondrial glycerate kinase was present in inner membrane and/or matrix. It was found that dietary protein selectively induced mitochondrial glycerate kinase. This result suggested that mitochondrial glycerate kinase had a physiological function for gluconeogenesis from serin. However, the metabolic significance of the cytoplasmic enzyme was still unclear. The properties of solubilized-mitochondrial and cytosolic glycerate kinases were compared. However, no difference between the two enzymes could be found in the kinetic properties, thermal stability, molecular size or electrochemical properties. These results suggested that both enzymes originate from common genetic information. In order to elucidate the regulatory mechanism of the intracellular distribution of glycerate kinase in rat liver, the responses of mitochondrial and cytosolic glycerate kinases to an alteration of dietary protein were studied. The result suggested that an alteration of dietary protein content may regulate the distribution and the translocation of glycerate kinase to mitochondria and cytosol as well as the total amount of glycerate kinase.