Proactivator-dependent activation of procollagenase induced by treatment with EGTA.

Operation of the branched-chain 2-hydroxy acid/2-oxo acid shuttle for the transfer of reducing equivalents in mitochondria of mouse spermatozoa was studied in vitro in reconstituted systems. Results show that the branched-chain 2-oxo acids within the mitochondria are offered several metabolic pathways. (a) Decarboxylation: mouse sperm mitochondria possess high branched-chain 2-oxo acid decarboxylase activity. (b) Recycling to the cytosol by using a transport system which can be inhibited by alpha-cyano-3-hydroxycinnamate and pH 6.8. (c) Transamination to the corresponding amino acids: experiments presented indicate that leucine formed from 4-methyl-2-oxopentanoate may pass to the external phase, re-initiating the cycle. These two last possibilities would allow autocatalytic operation of the shuttle. The branched-chain 2-hydroxy acids apparently do not utilize the monocarboxylate carrier to penetrate the mitochondria.     

A shuttle system for the transfer of reducing equivalents in mouse sperm mitochondria.

Studies have been carried out on an $\text{in vitro}$ reconstituted system composed of mouse lactate dehydrogenase isozyme X or C4, branched chain amino acid aminotransferase, NAD, alpha-hydroxy isocaproate, glutamate and mouse sperm mitochondria. This system demonstrated capacity for the oxidation of extramitochondrial NADH. It is proposed that a branched chain alpha-hydroxyacid / amino acid shuttle for the transfer of reducing equivalents from cytosol to mitochondria may be functional in mouse spermatozoa.     

Thyroid hormone and dehydroepiandrosterone permit gluconeogenic hormone responses in hepatocytes

The importance of the sn-glycerol- 3-phosphate (G-3-P) electron transfer shuttle in hormonal regulation of gluconeogenesis was examined in hepatocytes from rats with decreased mitochondrial G-3-P dehydrogenase activity (thyroidectomized) or increased G-3-P dehydrogenase activity [triiodothyronine (T(3)) or dehydroepiandrosterone (DHEA) treated]. Rates of glucose formation from 10 mM lactate, 10 mM pyruvate, or 2.5 mM dihydroxyacetone were somewhat less in hypothyroid cells than in cells from normal rats but gluconeogenic responses to calcium addition and to norepinephrine (NE), glucagon (G), or vasopressin (VP) were similar to the responses observed in cells from normal rats. However, with 2. 5 mM glycerol or 2.5 mM sorbitol, substrates that must be oxidized in the cytosol before conversion to glucose, basal gluconeogenesis was not appreciably altered by hypothyroidism but responses to calcium and to the calcium-mobilizing hormones were abolished. Injecting thyroidectomized rats with T(3) 2 days before preparing the hepatocytes greatly enhanced gluconeogenesis from glyc erol and restored the response to Ca(2+) and gluconeogenic hormones. Feeding dehydroepiandrosterone for 6 days depressed gluconeogenesis from lactate or pyruvate but substantially increased glucose production from glycerol in euthyroid cells and restored responses to Ca(2+) in hypothyroid cells metabolizing glycerol. Euthyroid cells metabolizing glycerol or sorbitol use the G-3-P and malate/aspartate shuttles to oxidize excess NADH generated in the cytosol. The transaminase inhibitor aminooxyacetate (AOA) decreased gluconeogenesis from glycerol 40%, but had little effect on responses to Ca(2+) and NE. However, in hypothyroid cells, with minimal G-3-P dehydrogenase, AOA decreased gluconeogenesis from glycerol more than 90%. Thus, the basal rate of gluconeogenesis from glycerol in the euthyroid cells is only partly dependent on electron transport from cytosol to mitochondria via the malate/aspartate shuttle and almost completely dependent in the hypothyroid state, and the hormone enhancement of the rate in euthyroid cells involves primarily the G-3-P cycle. These data are consistent with Ca(2+) being mobilized by gluconeogenic hormones and G-3-P dehydrogenase being activated by Ca(2+) so as to permit it to transfer reducing equivalents from the cytosol to the mitochondria.     

In vivo analysis of the mechanisms for oxidation of cytosolic NADH by Saccharomyces cerevisiae mitochondria

During respiratory glucose dissimilation, eukaryotes produce cytosolic NADH via glycolysis. This NADH has to be reoxidized outside the mitochondria, because the mitochondrial inner membrane is impermeable to NADH. In Saccharomyces cerevisiae, this may involve external NADH dehydrogenases (Nde1p or Nde2p) and/or a glycerol-3-phosphate shuttle consisting of soluble (Gpd1p or Gpd2p) and membrane-bound (Gut2p) glycerol-3-phosphate dehydrogenases. This study addresses the physiological relevance of these mechanisms and the possible involvement of alternative routes for mitochondrial oxidation of cytosolic NADH. Aerobic, glucose-limited chemostat cultures of a gut2Delta mutant exhibited fully respiratory growth at low specific growth rates. Alcoholic fermentation set in at the same specific growth rate as in wild-type cultures (0.3 h(-1)). Apparently, the glycerol-3-phosphate shuttle is not essential for respiratory glucose dissimilation. An nde1Delta nde2Delta mutant already produced glycerol at specific growth rates of 0.10 h(-1) and above, indicating a requirement for external NADH dehydrogenase to sustain fully respiratory growth. An nde1Delta nde2Delta gut2Delta mutant produced even larger amounts of glycerol at specific growth rates ranging from 0.05 to 0.15 h(-1). Apparently, even at a low glycolytic flux, alternative mechanisms could not fully replace the external NADH dehydrogenases and glycerol-3-phosphate shuttle. However, at low dilution rates, the nde1Delta nde2Delta gut2Delta mutant did not produce ethanol. Since glycerol production could not account for all glycolytic NADH, another NADH-oxidizing system has to be present. Two alternative mechanisms for reoxidizing cytosolic NADH are discussed: (i) cytosolic production of ethanol followed by its intramitochondrial oxidation and (ii) a redox shuttle linking cytosolic NADH oxidation to the internal NADH dehydrogenase.     

Citrin/mitochondrial glycerol-3-phosphate dehydrogenase double knock-out mice recapitulate features of human citrin deficiency

Citrin is the liver-type mitochondrial aspartate-glutamate carrier that participates in urea, protein, and nucleotide biosynthetic pathways by supplying aspartate from mitochondria to the cytosol.Citrin also plays a role in transporting cytosolic NADH reducing equivalents into mitochondria as a component of the malate-aspartate shuttle. In humans, loss-of-function mutations in the SLC25A13 gene encoding citrin cause both adult-onset type II citrullinemia and neonatal intrahepatic cholestasis, collectively referred to as human citrin deficiency. Citrin knock-out mice fail to display features of human citrin deficiency. Based on the hypothesis that an enhanced glycerol phosphate shuttle activity may be compensating for the loss of citrin function in the mouse, we have generated mice with a combined disruption of the genes for citrin and mitochondrial glycerol 3-phosphate dehydrogenase. The resulting double knock-out mice demonstrated citrullinemia, hyperammonemia that was further elevated by oral sucrose administration, hypoglycemia, and a fatty liver, all features of human citrin deficiency. An increased hepatic lactate/pyruvate ratio in the double knock-out mice compared with controls was also further elevated by the oral sucrose administration, suggesting that an altered cytosolic NADH/NAD(+) ratio is closely associated with the hyperammonemia observed. Microarray analyses identified over 100 genes that were differentially expressed in the double knock-out mice compared with wild-type controls, revealing genes potentially involved in compensatory or downstream effects of the combined mutations. Together, our data indicate that the more severe phenotype present in the citrin/mitochondrial glycerol-3-phosphate dehydrogenase double knock-out mice represents a more accurate model of human citrin deficiency than citrin knock-out mice.     

Binding and function of mitochondrial glycerol kinase in comparison with those of mitochondrial hexokinase

Mitochondrial-bound glycerol kinase in rat brain was examined with reference to factors involved in the binding and significance of the binding in relation to ATP metabolism inside the mitochondria. The mitochondrial-bound glycerol kinase was solubilized with glycerol 3-phosphate or ADP, and the solubilized enzyme was rebound to mitochondria by addition of divalent cations. The rebinding was decreased by the presence of glycerol 3-phosphate, while was increased by glucose 6-phosphate. Positive correlation was found between the formation of glycerol 3-phosphate by mitochondrial-bound glycerol kinase and ATP content in mitochondria in experiments using various concentrations of succinate and ADP. On the other hand, glycerol 3-phosphate formation was inhibited by addition of inhibitors for mitochondria functions, such as oligomycin, dinitrophenol, cyanide, and atractyloside. Furthermore, formation of dihydroxyacetone phosphate from glycerol was proved, indicating the involvement of glycerol kinase in glycerol phosphate shuttle in combination with glycerol phosphate dehydrogenase. These findings are discussed in comparison with those of mitochondrial-bound hexokinase.     

High content of mitochondrial glycerol-3-phosphate dehydrogenase in pancreatic islets and its inhibition by diazoxide

Homogenates of isolated pancreatic islets contain 40-70 times as much flavin-linked glycerol-3-phosphate dehydrogenase (EC 1.1.99.5) as homogenates of whole pancreas, liver, heart, or skeletal muscle when the activity is assayed with either iodonitrotetrazolium or with dichloroindophenol as an electron acceptor. Intact mitochondria from islets release 3HOH from [2-3H]glycerol phosphate 7 times faster than do skeletal muscle mitochondria. The activity of the cytosolic, NAD-linked, glycerol phosphate dehydrogenase (EC 1.1.1.8) in pancreatic islets is comparable to that of the mitochondrial dehydrogenase so a glycerol phosphate shuttle is possible in pancreatic islets. Diazoxide, an inhibitor of insulin release in vivo and in vitro, inhibits the islet mitochondrial glycerol phosphate dehydrogenase in all three of the assays mentioned above at concentrations that inhibit insulin release and CO2 formation from glucose by isolated pancreatic islets. Diazoxide does not inhibit the dehydrogenase in mitochondria from skeletal muscle, liver, and heart. A slight inhibition in mitochondria from whole pancreas can be accounted for as inhibition of the islet dehydrogenase because no inhibition is observed in mitochondria from pancreas of rats treated with alloxan, an agent that causes diabetes by destroying pancreatic beta cells. The results of this study are compatible with the hypothesis that the mitochondrial glycerol phosphate dehydrogenase has a key role in stimulus-secretion coupling in the pancreatic beta cell during glucose-induced insulin release.     

Survey of normal appearing mouse strain which lacks enzyme and NAD+-linked glycerol phosphate dehydrogenase: Normal pancreatic beta cell function,but abnormal metabolite pattern in skeltal muscle

We studied a mouse doubly homozygous for mutations in the genes encoding malic enzyme (EC1.1.1.40) and cytosolic glycerol phosphate dehydrogenase (EC 1.1.1.8) (cGPD). This mouse, which we call the mmgg mouse and which is the product of intercrosses between the Mod-1 mouse and the BALB/cHeA mouse, lacks activity of both enzymes. Like both parental strains the mmgg mouse is completely normal in appearance. cGPD is one of the two enzymes that catalyze the reactions of the glycerol phosphate shuttle. The activity of the other enzyme of the glycerol phosphate shuttle, mitochondrial glycerol phosphate dehydrogenase (EC 1.1.99.5) (mGPD), is abundant in tissues, such as brain, skeletal muscle and the pancreatic islet, suggesting that the glycerol phosphate shuttle is important in these tissues which rapidly metabolize glucose. Cytosolic malic enzyme activity is important for shuttles which transport NADPH equivalents from mitochondria to the cytosol. The major finding of the study was a highly abnormal metabolite pattern in tissues of the mmgg mouse suggesting a block in the glycerol phosphate shuttle due to cGPD deficiency. The metabolite pattern did not suggest that malic enzyme deficiency caused an abnormality. Tissue levels of glycerol phosphate (low) and dihydroxyacetone phosphate (high) were only abnormal in skeletal muscle. Glycolytic intermediates, situated at or before the triose phosphates in the pathway, such as fructose bisphosphate and glyceraldehyde phosphate were increased depending on the tissue. Taken together with previous extensive data on the mouse deficient only in cGPD this suggests a block in glycolysis at the step catalyzed by glyceraldehyde phosphate dehydrogenase caused by an abnormally low NAD/NADH ratio resulting from a nonfunctional glycerol phosphate shuttle. Consistent with this idea the lactate/pyruvate ratio was high in skeletal muscle signifying a low cytosolic NAD/NADH ratio. The mmgg mouse was normal in all other factors studied including blood glucose and serum insulin levels, pancreatic islet mass, insulin release from isolated pancreatic islets, as well as the activities of five metabolic enzymes, including mGPD, in liver, kidney, skeletal muscle and pancreatic islets. cGPD enzyme activity was undetectable in pancreatic islets, 0.5% of normal in liver, and 2.1% of normal in kidney and skeletal muscle. Malic enzyme activity was undetectable in these same tissues.     

Branched-chain amino acid aminotransferase in mouse testicular tissue

Branched-chain amino acid aminotransferase (L-leucine:2-oxoglutarate aminotransferase, EC 2.6.1.6) activity was determined in several tissues of the mouse. Testis homogenates presented a specific activity very close to that of heart extracts which were the most active. Enzyme activity was detectable in testes from 5-day-old mice and increased steadily during development to reach a maximum at the 20th day of life. The transaminase was present in the cytosol of testicular homogenates and also associated, probably in the matrix, with a special type of mitochondria present in spermatozoa and gametogenic cells. The enzyme from testis is active against the three branched-chain amino acids and catalyses the reaction in both directions. Highest activity and lowest Km were obtained with L-leucine. Activity with L-valine was the lowest. The enzyme from the mitochondrial fraction showed identical properties to that from the soluble phase. The possible participation of this aminotransferase in a shuttle system transferring reducing equivalents from cytoplasm to mitochondria is postulated.     

Effect of glycerol on gluconeogenesis in isolated rabbit kidney cortex tubules

In renal tubules isolated from fed rabbits glycerol is not utilized as a glucose precursor, probably due to the rate-limiting transfer of reducing equivalents from cytosol to mitochondria. Pyruvate and glutamate stimulated an incorporation of [14C]glycerol to glucose by 50- and 10-fold, respectively, indicating that glycerol is utilized as a gluconeogenic substrate under these conditions. Glycerol at concentration of 1.5 mM resulted in an acceleration of both glucose formation and incorporation of [14C]pyruvate and [14C]glutamate into glucose by 2- and 9-fold, respectively, while it decreased the rates of these processes from lactate as a substrate. In the presence of fructose, glycerol decreased the ATP level, limiting the rate of fructose phosphorylation and glucose synthesis. As concluded from the 'cross-over' plots, the ratios of both 3-hydroxybutyrate/acetoacetate and glycerol 3-phosphate/dihydroxyacetone phosphate, as well as from experiments performed with methylene blue and acetoacetate, the stimulatory effect of glycerol on glucose formation from pyruvate and glutamate may result from an acceleration of fluxes through the first steps of gluconeogenesis as well as glyceraldehyde-3-phosphate dehydrogenase. As inhibition by glycerol of gluconeogenesis from lactate is probably due to a marked elevation of the cytosolic NADH/NAD+ ratio resulting in a decline of flux through lactate dehydrogenase.     

Differential rates of synthesis of glycerokinase and glycerophosphate dehydrogenase in Neurospora crassa during induction.

The synthesis of the enzymes of the glycerophosphate pathway in Neurospora has been examined during exponential growth of cells on acetate as the sole carbon source. After the addition of glycerol to the media, increases in the levels of both glycerokinase and a mitochondrial glycerol-3-phosphate dehydrogenase are observed within 1 h and fully induced levels are reached within one and a half mass doublings for glycerokinase and two and a half mass doublings for glycerol-3-phosphate dehydrogenase. The increase in glycerokinase activity represents de novo synthesis of enzyme as evidenced by the absence of immunologically related protein in uninduced cell extracts. The synthesis of both glycerokinase and glycerol-3-phosphate dehydrogenase can be totally inhibited by treatment of cells with 20 μg/ml cycloheximide. During incubation with 4 mg/ml chloramphenicol, there is normal synthesis of glycerokinase but a 30–50% inhibition of mitochondrial glycerol-3-phosphate dehydrogenase synthesis. However, under these conditions, in the cytosol fraction there is a significant increase in glycerol-3-phosphate dehydrogenase specific activity, suggesting that precursors are synthesized and accumulated in the cytosol prior to incorporation into mitochondria. Upon removal of chloramphenicol, the rate of appearance of glycerol-3-phosphate dehydrogenase into the mitochondria is up to four times greater than observed in untreated controls. It is concluded that both glycerokinase and glycerol-3-phosphate dehydrogenase are synthesized on cytoplasmic ribosomes, but that final assembly of glycerol-3-phosphate dehydrogenase into mitochondria is dependent on concomitant synthesis of mitochondrial inner membrane.     

Malate-aspartate shuttle and exogenous NADH/cytochrome c electron transport pathway as two independent cytosolic reducing equivalent transfer systems

In mammalian cells aerobic oxidation of glucose requires reducing equivalents produced in glycolytic phase to be channelled into the phosphorylating respiratory chain for the reduction of molecular oxygen. Data never presented before show that the oxidation rate of exogenous NADH supported by the malate-aspartate shuttle system (reconstituted in vitro with isolated liver mitochondria) is comparable to the rate obtained on activation of the cytosolic NADH/cytochrome c electron transport pathway. The activities of these two reducing equivalent transport systems are independent of each other and additive. NADH oxidation induced by the malate-aspartate shuttle is inhibited by aminooxyacetate and by rotenone and/or antimycin A, two inhibitors of the respiratory chain, while the NADH/cytochrome c system remains insensitive to all of them. The two systems may simultaneously or mutually operate in the transfer of reducing equivalents from the cytosol to inside the mitochondria. In previous reports we suggested that the NADH/cytochrome c system is expected to be functioning in apoptotic cells characterized by the presence of cytochrome c in the cytosol. As additional new finding the activity of reconstituted shuttle system is linked to the amount of α-ketoglutarate generated inside the mitochondria by glutamate dehydrogenase rather than by aspartate aminotransferase.     

Kinetic regulation of the mitochondrial glycerol-3-phosphate dehydrogenase by the external NADH dehydrogenase in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the two most important systems for conveying excess cytosolic NADH to the mitochondrial respiratory chain are external NADH dehydrogenase (Nde1p/Nde2p) and the glycerol-3-phosphate dehydrogenase shuttle. In the latter system, NADH is oxidized to NAD+ and dihydroxyacetone phosphate is reduced to glycerol 3-phosphate by the cytosolic Gpd1p; glycerol 3-phosphate gives two electrons to the respiratory chain via mitochondrial glycerol-3-phosphate dehydrogenase (Gut2p)-regenerating dihydroxyacetone phosphate. Both Nde1p/Nde2p and Gut2p are located in the inner mitochondrial membrane with catalytic sites facing the intermembranal space. In this study, we showed kinetic interactions between these two enzymes. First, deletion of either one of the external dehydrogenases caused an increase in the efficiency of the remaining enzyme. Second, the activation of NADH dehydrogenase inhibited the Gut2p in such a manner that, at a saturating concentration of NADH, glycerol 3-phosphate is not used as respiratory substrate. This effect was not a consequence of a direct action of NADH on Gut2p activity because both NADH dehydrogenase and its substrate were needed for Gut2p inhibition. This kinetic regulation of the activity of an enzyme as a function of the rate of another having a similar physiological function may be allowed by their association into the same supramolecular complex in the inner membrane. The physiological consequences of this regulation are discussed.     

Competition of electrons to enter the respiratory chain: a new regulatory mechanism of oxidative metabolism in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the most important systems for conveying excess cytosolic NADH to the mitochondrial respiratory chain are the external NADH dehydrogenases (Nde1p and Nde2p) and the glycerol-3-phosphate dehydrogenase shuttle. In the latter system, NADH is oxidized to NAD+ and dihydroxyacetone phosphate is reduced to glycerol 3-phosphate by the cytosolic Gpd1p. Subsequently, glycerol 3-phosphate donates electrons to the respiratory chain via mitochondrial glycerol-3-phosphate dehydrogenase (Gut2p). At saturating concentrations of NADH, the activation of external NADH dehydrogenases completely inhibits glycerol 3-phosphate oxidation. Studies on the functionally isolated enzymes demonstrated that neither Nde1p nor Nde2p directly inhibits Gut2p. Thus, the inhibition of glycerol 3-phosphate oxidation may be caused by competition for the entrance of electrons into the respiratory chain. Using single deletion mutants of Nde1p or Nde2p, we have shown that glycerol 3-phosphate oxidation via Gut2p is inhibited fully when NADH is oxidized via Nde1p, whereas only 50% of glycerol 3-phosphate oxidation is inhibited when Nde2p is functioning. By comparing respiratory rates with different respiratory substrates, we show that electrons from Nde1p are favored over electrons coming from Ndip (internal NADH dehydrogenase) and that when electrons come from either Nde1p or Nde2p and succinodehydrogenase, their use by the respiratory chain is shared to a comparable extent. This suggests a very specific competition for electron entrance into the respiratory chain, which may be caused by the supramolecular organization of the respiratory chain. The physiological consequences of such regulation are discussed.     

Activation of mitochondrial glycerol 3-phosphate dehydrogenase by cadmium ions

Mitochondrial glycerol 3-phosphate dehydrogenase (EC 1.1.2.1.) requires Ca2+ ions for its activity. Cadmium ions also have activatory effect on the enzyme. They activate the glycerol 3-phosphate dehydrogenase in a very narrow concentration range (1-2 mmol/l). As contrasted with calcium, strong inhibitory effect occurred at higher concentrations (3-4 mmol/l). The inhibition induced by cadmium ions was completely reversible by washing of the mitochondria.     

NADH shuttle system regulates K(ATP) channel-dependent pathway and steps distal to cytosolic Ca(2+) concentration elevation in glucose-induced insulin secretion.

The NADH shuttle system is composed of the glycerol phosphate and malate-aspartate shuttles. We generated mice that lack mitochondrial glycerol-3-phosphate dehydrogenase (mGPDH), a rate-limiting enzyme of the glycerol phosphate shuttle. Application of aminooxyacetate, an inhibitor of the malate-aspartate shuttle, to mGPDH-deficient islets demonstrated that the NADH shuttle system was essential for coupling glycolysis with activation of mitochondrial ATP generation to trigger glucose-induced insulin secretion. The present study revealed that blocking the NADH shuttle system severely suppressed closure of the ATP-sensitive potassium (K(ATP)) channel and depolarization of the plasma membrane in response to glucose in beta cells, although properties of the K(ATP) channel on the excised beta cell membrane were unaffected. In mGPDH-deficient islets treated with aminooxyacetate, Ca(2+) influx through the plasma membrane induced by a depolarizing concentration of KCl in the presence of the K(ATP) channel opener diazoxide restored insulin secretion. However, the level of the secretion was only approximately 40% of wild-type controls. Thus, glucose metabolism through the NADH shuttle system leading to efficient ATP generation is pivotal to activation of both the K(ATP) channel-dependent pathway and steps distal to an elevation of cytosolic Ca(2+) concentration in glucose-induced insulin secretion.     

Substrate specificity of human carnitine acetyltransferase: Implications for fatty acid and branched-chain amino acid metabolism

Carnitine acyltransferases catalyze the reversible conversion of acyl-CoAs into acylcarnitine esters. This family includes the mitochondrial enzymes carnitine palmitoyltransferase 2 (CPT2) and carnitine acetyltransferase (CrAT). CPT2 is part of the carnitine shuttle that is necessary to import fatty acids into mitochondria and catalyzes the conversion of acylcarnitines into acyl-CoAs. In addition, when mitochondrial fatty acid β-oxidation is impaired, CPT2 is able to catalyze the reverse reaction and converts accumulating long- and medium-chain acyl-CoAs into acylcarnitines for export from the matrix to the cytosol. However, CPT2 is inactive with short-chain acyl-CoAs and intermediates of the branched-chain amino acid oxidation pathway (BCAAO). In order to explore the origin of short-chain and branched-chain acylcarnitines that may accumulate in various organic acidemias, we performed substrate specificity studies using purified recombinant human CrAT. Various saturated, unsaturated and branched-chain acyl-CoA esters were tested and the synthesized acylcarnitines were quantified by ESI-MS/MS. We show that CrAT converts short- and medium-chain acyl-CoAs (C2 to C10-CoA), whereas no activity was observed with long-chain species. Trans-2-enoyl-CoA intermediates were found to be poor substrates for this enzyme. Furthermore, CrAT turned out to be active towards some but not all the BCAAO intermediates tested and no activity was found with dicarboxylic acyl-CoA esters. This suggests the existence of another enzyme able to handle the acyl-CoAs that are not substrates for CrAT and CPT2, but for which the corresponding acylcarnitines are well recognized as diagnostic markers in inborn errors of metabolism.     

Rapid hydrolysis of diacylglycerol formed during phosphatidate phosphatase assay by lipase activities in rat liver cytosol and microsomes

Side reactions which may affect the determination of phosphatidate phosphatase activity were investigated in rat liver cytosol and microsomes. Incubation of these subcellular fractions with either 14C-labeled phosphatidate bound to microsomal membranes (PAmb) or that coemulsified with microsomal lipids resulted in rapid formation of water-soluble products, most of which were identified as glycerol, in addition to diacylglycerol. Neither lysophosphatidate nor glycerol 3-phosphate accumulated under any of the conditions used and only a minute amount of activity catalyzing hydrolysis of glycerol 3-phosphate could be detected in cytosol and microsomes, suggesting that glycerol was not formed by the deacylation of phosphatidate to glycerol 3-phosphate and subsequent dephosphorylation. On the other hand, pretreatment of cytosol or microsomes with diisopropylfluorophosphate abolished the formation of water-soluble products, indicating that glycerol was formed from diacylglycerol, the product of the phosphatidate phosphatase reaction, by lipase-type activities. Rapid deacylation of diacylglycerol by these subcellular fractions was also observed with an emulsion of phosphatidate, which has been purified from the total lipid extract of PAmb as substrate. The rate of hydrolysis of diacylglycerol was maximum when the concentration of diacylglycerol was less than 20 microM with either cytosol or microsomes. The present results suggest that it is essential to characterize the reaction products before employing specific assay conditions for phosphatidate phosphatase. At least under the conditions we tested, reliable measurement of the enzyme activity in rat liver cytosol and microsomes can be achieved only by determining the release of Pi or that of water-soluble activity from 32P-labeled phosphatidate.     

The tritium isotope effect of sn-glycerol 3-phosphate oxidase and the effects of clofenapate and N-(2-benzoyloxyethyl)norfenfluramine on the esterification of glycerol phosphate and dihydroxyacetone phosphate by rat liver mitochondria

1. Owing to a (3)H isotope effect, the mitochondrial sn-glycerol 3-phosphate oxidase (EC 1.1.99.5) had a mean activity which was 8.4 times less with sn-[2-(3)H]-rather than with sn-[1-(14)C]glycerol 3-phosphate as a substrate. 2. A method for measuring the simultaneous synthesis of lipid from glycerol phosphate and dihydroxyacetone phosphate in rat liver mitochondria is described. 3. The lipid synthesized by rat liver mitochondria from sn-[1-(14)C]glycerol 3-phosphate was mainly phosphatidate and lysophosphatidate, whereas that synthesized from dihydroxy[1-(14)C]acetone phosphate was mainly acyldihydroxyacetone phosphate. 4. Additions of NADPH facilitated the conversion of acyldihydroxyacetone phosphate into lysophosphatidate and phosphatidate. 5. Hydrazine (1.4mm) or KCN (1.4mm) inhibited the synthesis of lipids from dihydroxyacetone phosphate but not from glycerol phosphate. 6. Clofenapate (1-2.5mm) inhibited the synthesis of lipids from dihydroxyacetone phosphate but slightly stimulated synthesis from glycerol phosphate. 7. The methanesulphonate of N-(2-benzoyloxyethyl)norfenfluramine, at 0.25-0.75mm, inhibited lipid synthesis from both glycerol phosphate and dihydroxyacetone phosphate.