The glutathione-binding site in glutathione S-transferases. Investigation of the cysteinyl, glycyl and gamma-glutamyl domains.

In hamster heart, the majority of the phosphatidylcholine is synthesized via the CDP-choline pathway, and the rate-limiting step of this pathway is catalysed by CTP:phosphocholine cytidylyltransferase (EC 2.7.7.15). We have shown previously [Choy (1982) J. Biol. Chem. 257, 10928-10933] that, in the myopathic heart, the level of cardiac CTP was diminished during the development of the disease. In order to maintain the level of CDP-choline, and consequently the rate of phosphatidylcholine biosynthesis, cardiac cytidylyltransferase activity was increased. However, it was not clear if the same compensatory mechanism would occur when the cardiac CTP level was decreased rapidly. In this study, hypoxia of the hamster heart was produced by perfusion with buffer saturated with 95% N2. The heart was pulse-labelled with radioactive choline and then chased with non-radioactive choline for various periods under hypoxic conditions. There was a severe decrease in ATP and CTP levels within 60 min of hypoxic perfusion, with a corresponding fall in the rate of phosphatidylcholine biosynthesis. Analysis of the choline-containing metabolites revealed that the lowered ATP level did not affect the phosphorylation of choline to phosphocholine, but the lower CTP level resulted in the decreased conversion of phosphocholine to CDP-choline. Determination of enzyme activities revealed that hypoxic treatment resulted in the enhanced translocation of cytidylyltransferase from the cytosolic to the microsomal form. This enhanced translocation was probably caused by the accumulation of fatty acids in the heart during hypoxia. We postulate that the enhancement of translocation of the cytidylyltransferase to the microsomal form (a more active form) is a mechanism by which the heart can compensate for the decrease in CTP level during hypoxia in order to maintain phosphatidylcholine biosynthesis.     

Effect of cAMP on choline uptake and phosphatidylcholine biosynthesis in cultured chick heart cells

The effect of an analogue of cAMP on the uptake and metabolism of choline in the heart was studied in isolated cardiac cells. The cells were obtained from 7-day-old chick embryos and maintained in culture. The effects of cAMP were studied using the dibutyryl cAMP analogue and the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. After a 2-h incubation with [3H]choline, about 85% of the label was recovered in phosphocholine, with most of the rest in phospholipid. During a subsequent chase incubation, [3H]phosphocholine was transferred to phosphatidylcholine with little accumulation in CDP-choline. This suggests the rate-limiting step for the conversion of phosphocholine to phosphatidylcholine in these cells is the synthesis of CDP-choline. cAMP decreased the incorporation of choline into phosphatidylcholine, but did not change the flux of metabolites through the step catalyzed by CTP:phosphocholine cytidylyltransferase. cAMP had little effect on choline uptake at low (1-25 microM) extracellular choline concentrations, but significantly (p less than 0.05) decreased choline uptake at higher (37.5-50 microM) extracellular choline concentrations. Thus, cardiac cells take up and metabolize choline to phosphocholine, with CTP:phosphocholine cytidylyltransferase being the rate-limiting step in phosphatidylcholine biosynthesis. cAMP decreases [3H]choline uptake and its subsequent incorporation into phosphocholine and phospholipid. However, the metabolism of choline within the cell is unaffected.     

Effects of fatty acids on phosphatidylcholine biosynthesis in isolated hamster heart

The effects of stearic, oleic, and arachidonic acids on phosphatidylcholine biosynthesis in the hamster heart were investigated. When hamster hearts were perfused with labelled choline in the presence of fatty acids, biosynthesis of phosphatidylcholine was stimulated only by stearic acid. Stearic acid was found to accumulate in unesterified (free) form in the hamster heart after perfusion. The stimulation by stearic acid was mediated in vivo by an enhancement of CTP:phosphocholine cytidylyltransferase activity in the microsomal fraction of the hamster heart and the enzyme activity in the cytosolic fraction was not affected. In contrast with the observations in rat hepatocytes, cytidylyltransferase from the hamster heart was not stimulated directly by stearic acid. The selective activation of the microsomal enzyme when the heart was perfused with stearic acid suggests that activation of the enzyme was mediated via the modification of the membrane by stearic acid.     

Trifluoperazine and chlorpromazine inhibit phosphatidylcholine biosynthesis and CTP:phosphocholine cytidylyltransferase in HeLa cells

The influence of chlorpromazine and trifluoperazine on phosphatidylcholine biosynthesis in HeLa cells was investigated. HeLa cells were prelabeled with [Me-3H]choline for 1 h. The cells were subsequently incubated with various concentrations of drugs. Both compounds were potent inhibitors of phosphatidylcholine biosynthesis, with 50% inhibition by 5 micron of either drug. Analysis of the radioactivity in the soluble precursors indicated a block in the conversion of phosphocholine to CDPcholine catalyzed by CTP:phosphocholine cytidylyltransferase (CTP:cholinephosphate cytidylyltransferase, EC 2.7.7.15). Inhibition by these drugs was slowly reversed after incubation for more than 2 h, or was immediately abolished when 0.4 mM oleate was included in the cell medium or when the drug-containing medium was removed. The subcellular location of the cytidylyltransferase was unaffected by either drug, nor did the drugs alter the rate of release of cytidylyltransferase from HeLa cells by digitonin treatment. The drugs had a direct inhibitory effect on cytidylyltransferase activity in HeLa cell postmitochondrial supernatants. Half-maximal inhibition was achieved with 30 microM trifluoperazine and 50 microM chlorpromazine. These drugs did not change the apparent Km of the cytidylyltransferase for CTP or phosphocholine. Inhibition of cytidylyltransferase by these compounds was reversible with exogenous phospholipid or oleate in the enzyme assay. The data indicate that both drugs inhibit phosphatidylcholine synthesis by an effect on the cytidylyltransferase. The mechanism of action remains unknown at this time.     

Effect of sodium chloride concentration on fluid-phase assembly and stability of the C3 convertase of the classical pathway of the complement system.

The specificity of the phospholipid head-group for feedback regulation of CTP: phosphocholine cytidylyltransferase was examined in rat hepatocytes. In choline-deficient cells there is a 2-fold increase in binding of cytidylyltransferase to cellular membranes, compared with choline-supplemented cells. Supplementation of choline-deficient cells with choline, dimethylethanolamine, monomethylethanolamine or ethanolamine resulted in an increase in the concentration of the corresponding phospholipid. Release of cytidylyltransferase into cytosol was only observed in hepatocytes supplemented with choline or dimethylethanolamine. The apparent EC50 values (concn. giving half of maximal effect) for cytidylyltransferase translocation were similar for choline and dimethylethanolamine (25 and 27 microM respectively). The maximum amount of cytidylyltransferase released into cytosol with choline supplementation (1.13 m-units/mg membrane protein) was twice that (0.62) observed with dimethylethanolamine. Supplementation of choline-deficient hepatocytes with NN'-diethylethanolamine, N-ethylethanolamine or 3-aminopropanol also did not cause release of cytidylyltransferase from cellular membranes. The translocation of cytidylyltransferase appeared to be mediated by the concentration of phosphatidylcholine in the membranes and not the ratio of phosphatidylcholine to phosphatidylethanolamine. The results provide further evidence for feedback regulation of phosphatidylcholine biosynthesis by phosphatidylcholine.     

Effect of diethylstilboestrol on phosphatidylcholine biosynthesis and choline metabolism in the liver of roosters.

It has been known for 40 years that oestrogens stimulate phospholipid metabolism in roosters. We have investigated in vivo the mechanism for this effect. Young roosters were injected daily with 1 mg of diethylstilboestrol for 1--3 days. At 4 h after the last injection, 30 microCi of [Me-3H]choline was injected into the portal vein. At periods up to 3 min the livers were freeze-clamped and choline and its metabolites were extracted and resolved by t.l.c. Hormone treatment in the first 2 days resulted in a 2-fold increase in phosphorylation of [Me-3H]choline and a decrease in the oxidation of [Me-3H]choline to [3H]betaine. The concentrations of phosphocholine in liver were increased 2-fold during the first 2 days concomitant with a 2-fold increase in the rate of phosphatidylcholine biosynthesis. After 3 days of hormone treatment, many of the above effects were reversed and the rate of phosphatidylcholine biosynthesis decreased to approx. 60% of the control value. The results suggest that the initial hormone treatments activate choline kinase within 4 h and, thereby, divert choline form oxidation to betaine. The resulting increased phosphocholine concentrations cause an increase in the activity of CTP:phosphocholine cytidylyltransferase, which results in a doubling of the rate of phosphatidylcholine biosynthesis. After 3 days of hormone treatment, the biosynthesis of phosphatidylcholine is decreased, most likely by an effect on the cytidylyltransferase reaction.     

A CDP-choline pathway for phosphatidylcholine biosynthesis in Treponema denticola

The genomes of Treponema denticola and Treponema pallidum contain a gene, licCA, which is predicted to encode a fusion protein containing choline kinase and CTP:phosphocholine cytidylyltransferase activities. Because both organisms have been reported to contain phosphatidylcholine, this raises the possibility that they use a CDP-choline pathway for the biosynthesis of phosphatidylcholine. This report shows that phosphatidylcholine is a major phospholipid in T. denticola, accounting for 35-40% of total phospholipid. This organism readily incorporated [14C]choline into phosphatidylcholine, indicating the presence of a choline-dependent biosynthetic pathway. The licCA gene was cloned, and recombinant LicCA had choline kinase and CTP:phosphocholine cytidylyltransferase activity. The licCA gene was disrupted in T. denticola by erythromycin cassette mutagenesis, resulting in a viable mutant. This disruption completely blocked incorporation of either [14C]choline or 32Pi into phosphatidylcholine. The rate of production of another phospholipid in T. denticola, phosphatidylethanolamine, was elevated considerably in the licCA mutant, suggesting that the elevated level of this lipid compensated for the loss of phosphatidylcholine in the membranes. Thus it appears that T. denticola does contain a licCA-dependent CDP-choline pathway for phosphatidylcholine biosynthesis.     

c-Ha-ras oncogene expression increases choline uptake,CTP:prosphocholine cytidylyltransferase activity and phosphatidylcholine biosynthesis in the immortalized human keratinocyte cell line HaCaT

The effect of c-Ha-ras transfection on phosphatidylcholine biosynthesis of the keratinocyte cell line HaCaT was investigated. It was shown that ras-transfection caused a 3-fold increase of choline incorporation into phosphatidylcholine. By investigating the mechanisms underlying this phenomenon, two targets were obtained. First, the choline uptake was elevated by 2-fold in ras-transfected HaCaT cells as compared with untransfected HaCaT cells, and second, the activity of the rate-limiting enzyme of phosphatidylcholine biosynthesis, CTP:phosphocholine cytidylyltransferase, was increased by 43%. Stimulation of HaCaT cells and ras-transfected HaCaT cells with oleate revealed that the increased activity of cytidylyltransferase might be due to a higher level of enzyme. In these experiments, a 75% increase of the specific activity of fully stimulated, membrane-bound cytidylyltransferase was found in ras-transfected HaCaT cells. Choline kinase which has been previously descrived as a target of ras-transfection in fibroblasts was unaffected.     

The choline-depleted type II pneumonocyte. A model for investigating the synthesis of surfactant lipids.

When type II pneumonocytes from adult rats were maintained in a medium that lacked choline, the incorporation of [14C]glycerol into phosphatidylcholine was not greatly diminished during the period that the cells displayed characteristics of type II pneumonocytes. Cells that were maintained in choline-free medium that contained choline oxidase and catalase, however, became depleted of choline and subsequent synthesis of phosphatidylcholine by these cells was responsive to choline in the extracellular medium. Incorporation of [14C]glycerol into phosphatidylcholine by choline-depleted cells was stimulated maximally (approx. 6-fold) by extracellular choline at a concentration (0.05 mM) that also supported the greatest incorporation into phosphatidylglycerol. The incorporation of [14C]glycerol into other glycerophospholipids by choline-depleted cells was not increased by extracellular choline. When cells were incubated in the presence of [3H]cytidine, the choline-dependent stimulation of the synthesis of phosphatidylcholine and phosphatidylglycerol was accompanied by an increased recovery of [3H]CMP. This increased recovery of [3H]CMP reflected an increase in the intracellular amount of CMP from 48 +/- 9 to 76 +/- 16 pmol/10(6) cells. Choline-depleted cells that were exposed to [3H]choline contained [3H]CDP-choline as the principal water-soluble choline derivative. As the extracellular concentration of choline was increase, however, the amount of 3H in phosphocholine greatly exceeded that in all other water-soluble derivatives. Choline-depletion of cells resulted in an increase in the specific activity of CTP:phosphocholine cytidylyltransferase in cell homogenates (from 0.40 +/- 0.15 to 1.31 +/- 0.20 nmol X min-1 X mg of protein-1). These data are indicative that the biosynthesis of phosphatidylcholine is integrated with that of phosphatidylglycerol and are consistent with the proposed involvement of CMP in this integration. The choline-depleted type II pneumonocyte provides a new model for investigating the regulation of CTP:phosphocholine cytidylyltransferase activity.     

Regulation of CTP: phosphocholine cytidylyltransferase activity in type II pneumonocytes.

Phosphatidylcholine synthesis by rat type II pneumonocytes was altered either by depleting the cells of choline or by exposing the cells to extracellular lung surfactant. Effects of these experimental treatments on the activity of a regulatory enzyme, CTP:phosphocholine cytidylyltransferase, were investigated. Although choline depletion of type II pneumonocytes resulted in inhibition of phosphatidylcholine synthesis, cytidylyltransferase activity (measured in cell homogenates in either the absence or presence of added lipids) was greatly increased. Activation of cytidylyltransferase in choline-depleted cells was rapid and specific, and was quickly and completely reversed when choline-depleted cells were exposed to choline (but not ethanolamine). Choline-dependent changes in enzymic activity were apparently not a result of direct actions of choline on cytidylyltransferase and they were largely unaffected by cyclic AMP analogues, oleic acid, linoleic acid or cycloheximide. The Km value of cytidylyltransferase for CTP (but not phosphocholine) was lower in choline-depleted cells than in choline-repleted cells. Subcellular redistribution of cytidylyltransferase also was associated with activation of the enzyme in choline-depleted cells. When measured in the presence of added lipids, 66.5 +/- 5.0% of recovered cytidylyltransferase activity was particulate in choline-depleted cells but only 34.1 +/- 4.5% was particulate in choline-repleted cells. An increase in particulate cytidylyltransferase also occurred in type II pneumonocytes that were exposed to extracellular surfactant. This latter subcellular redistribution, however, was not accompanied by a change in cytidylyltransferase activity even though incorporation of [3H]choline into phosphatidylcholine was inhibited by approx. 50%. Subcellular redistribution of cytidylyltransferase, therefore, is associated with changes in enzymic activity under some conditions, but can also occur without a resultant alteration in enzymic activity.     

Altered phosphatidylcholine metabolism in C3H10T1/2 cells transfected with the Harvey-ras oncogene

The effect of expression of the Harvey-ras oncogene on phosphatidylcholine metabolism in C3H10T1/2 mouse fibroblast cells was examined. There were multiple changes in the CDP-choline pathway for phosphatidylcholine biosynthesis in the ras-expressing cells. The activity of the first enzyme in the pathway, choline kinase, was stimulated 1.9-fold, while the activity of the second enzyme, CTP:phosphocholine cytidylyltransferase, was decreased by one-half. High levels of intracellular phosphocholine measured in the ras cells were consistent with the altered activities of choline kinase and cytidylyltransferase. The overall rate of phosphatidylcholine synthesis appeared to be increased because the turnover rate of phosphocholine from the intracellular pool was higher in the ras-transfected cells. There also appeared to be an increased rate of phosphatidylcholine degradation in ras-expressing C3H10T1/2 cells. Very high levels of glycerophosphocholine (6-fold increased over control cells) suggested that phospholipase A was activated in these cells. These results indicate that the ras oncogene product directly or indirectly causes an increased turnover of phosphatidylcholine in C3H10T1/2 cells.     

Regulatory enzymes of phosphatidylcholine biosynthesis: a personal perspective

Phosphatidylcholine is a prominent constituent of eukaryotic and some prokaryotic membranes. This Perspective focuses on the two enzymes that regulate its biosynthesis, choline kinase and CTP:phosphocholine cytidylyltransferase. These enzymes are discussed with respect to their molecular properties, isoforms, enzymatic activities, and structures, and the possible molecular mechanisms by which they participate in regulation of phosphatidylcholine levels in the cell.     

Regulation of phosphatidylcholine biosynthesis in mammalian cells. II. Effects of phospholipase C treatment on the activity and subcellular distribution of CTP:phosphocholine cytidylyltransferase in Chinese hamster ovary and LM cell lines

CTP:phosphocholine cytidylyltransferase was located in both the cytosolic and particulate fractions from Chinese hamster ovary cells. The activity of the cytosolic form of the enzyme was greatly enhanced by incubation with sonicated preparations of several different lipids, although incubations with either phosphatidylcholine or 1,2-sn-diolein did not increase activity. The activation of the cytidylyltransferase in Chinese hamster ovary cells treated with phospholipase C from Clostridium perfringens occurred with a concomitant shift in the subcellular distribution of the enzyme from cytosolic to particulate fractions. This shift was rapid and did not require protein synthesis. Removal of phospholipase C from the cell cultures resulted in a return to basal levels of incorporation of [3H]choline into phosphatidylcholine, a decrease in the activity of cytidylyltransferase, and a loss of the membrane-bound form of the enzyme. Similar experiments with LM cells, which are resistant to exogenous phospholipase C, showed no change in subcellular distribution of cytidylyltransferase, suggesting that the activation of CTP:phosphocholine cytidylyltransferase required a change in membrane phospholipid composition. The results presented are discussed in terms of a mechanism of regulation of phosphatidylcholine production involving monitoring of membrane phospholipid composition.     

Hormonal regulation of phosphatidylcholine synthesis by reversible modulation of cytidylyltransferase.

The effect of both lipolytic and antilipolytic hormones on the turnover of phosphatidylcholine in freshly isolated rat adipocytes was investigated. Treatment of adipocytes with agonists such as glucagon or isoprenaline that stimulate lipolysis through a cyclic AMP-dependent mechanism caused an increase in the incorporation of [Me-3H]choline into phosphatidylcholine. Pulse-chase studies indicated that the stimulation was due to an increase in the conversion of choline into phosphatidylcholine, which was both time- and dose-dependent. The stimulatory effect of isoprenaline was inhibited in a dose-dependent manner by oxytocin or insulin. Oxytocin inhibited the incorporation of [Me-3H]choline into phosphatidylcholine in both the presence and the absence of isoprenaline, whereas in the absence of isoprenaline insulin increased the incorporation of [Me-3H]choline into phosphatidylcholine. The effects of isoprenaline, oxytocin and insulin on the incorporation of [3H]choline into phosphatidylcholine were paralleled by changes in the activity of CTP:phosphocholine cytidylyltransferase.     

Regulation of phosphatidylcholine biosynthesis in Chinese hamster ovary cells by reversible membrane association of CTP: phosphocholine cytidylyltransferase

Treatment of Chinese hamster ovary cells with phospholipase C was previously shown to stimulate the CDP-choline pathway for phosphatidylcholine biosynthesis, and to cause activation of the CTP:phosphocholine cytidylyltransferase with a concomitant change in subcellular location of the enzyme (Sleight, R., and Kent, C. (1983) J. Biol. Chem. 258, 831-835). This paper presents a detailed analysis of the early events in the phospholipase C treatment, and provides evidence that the increased cytidylyltransferase activity causes the increased flux through the pathway. The time courses for the increase in cytidylyltransferase activity, increase in amount of membrane-associated enzyme, decrease in phosphocholine levels, and increase in phosphatidylcholine synthesis were similar, with all changes occurring within 30 min after addition of phospholipase C. These events preceded a decrease in cellular choline levels which correlated with a decreased capacity for choline uptake. The rate at which radioactive label was lost from pulse-labeled phosphocholine was the same as the rate at which label was incorporated into phosphatidylcholine, and these rates were stimulated 2.2-fold by phospholipase C treatment. We have also shown that the association of cytidylyltransferase with membranes was rapidly reversible when phospholipase C was removed from the cultures, and that the rate of decrease in phosphatidylcholine synthesis paralleled the rate of decrease in cytidylyltransferase activity. Cytidylyltransferase became reassociated with membranes when phospholipase C was added back to cultures from which it was previously removed. These results represent the first detailed account of the time frame involved in regulating phosphatidylcholine synthesis by the reversible association of cytidylyltransferase with cellular membranes.     

胆碱摄取及磷脂酰胆碱合成的调节研究

木文研究了多种氨基酸、乙醇胺和甲基乙醇胺对细胞摄取胆碱和合成磷脂酰胆碱（ＰＣ）的影响,发现多种氨基酸非竞争性地抑制细胞摄取胆碱。含胆碱代谢物的分析显示胆碱转变成ＣＤＰ－胆碱,随之形成ＰＣ均不受氨基酸影响。乙醇胺竞争性地抑制胆碱摄取,且存在剂量依赖关系。乙醇胺能明显抑制胆碱激酶活性,但细胞内胆碱和磷酸胆碱的代谢池并不改变,提示乙醇胺不影响胆碱转变成磷酸胆碱。根据ＣＤＰ－胆碱和ＰＣ的比放射性分布,乙醇胺也不影响ＰＣ的生物合成。甲基乙醇胺抑制胆碱摄入的程度强于乙醇胺,并抑制胆碱激酶和ＣＴＰ：磷酸胆碱胞苷转移酶活性,含胆碱代谢物以ＣＤＰ－胆碱下降最显著;提示甲基乙醇胺不仅抑制胆碱摄入而且还干扰了ＣＤＰ－胆碱通路。     

Effect of exogenous CDP-choline on choline metabolism in isolated adult rat ventricular myocytes under normoxic and hypoxic conditions

The purpose of this study was to examine the effect of exogenous CDP-choline on choline metabolism and phosphatidylcholine biosynthesis in adult rat ventricular myocytes. Choline uptake and metabolism were examined, using [methyl³ H] choline. CDP-choline in the medium produced a concentration dependent reduction in the amount of radio-label in phosphocholine and phospholipid but it did not alter choline uptake into the myocytes. CDP-choline also did not antagonize the effect of hypoxia on phosphatidylcholine synthesis; rather it accentuated the hypoxia-induced reductions in cellular phosphocholine and phosphatidylcholine biosynthesis. These results indicate that the exogenous administration of CDP-choline alters choline metabolism in the heart by reducing the formation of phosphocholine and phosphatidylcholine without altering choline uptake and suggest an effect of a CDP-choline metabolite on choline metabolism which is not effective in opposing the effect of hypoxia on phosphatidylcholine biosynthesis.     

Stimulation of hepatic phosphatidylcholine biosynthesis in rats fed a high cholesterol and cholate diet correlates with translocation of CTP: phosphocholine cytidylyltransferase from cytosol to microsomes

A new model system for the study of phosphatidylcholine biosynthesis is presented. Young rats were fed a diet that contained 5% cholesterol and 2% cholate. After 6 days there was a 2-fold increase in the concentration of plasma phospholipid (243 mg/dl compared to 132 mg/dl for control animals) and a 3-fold increase in the concentration of plasma phosphatidylcholine. The rate of phosphatidylcholine biosynthesis was measured after injection of [Me-3H]choline into the portal veins. The incorporation of tritium into choline, phosphocholine and betaine by liver was similar for experimental and control animals, whereas there was a 3-fold increased incorporation into phosphatidylcholine of the cholesterol/cholate-fed rats. The activities of the enzymes of phosphatidylcholine biosynthesis in cytosol and microsomes were assayed. The only change detected was in the cytosolic and microsomal activities of CTP: phosphocholine cytidylyltransferase which were increased more than 2-fold in specific activity. When total cytidylyltransferase activity per liver was determined, a dramatic translocation of the enzyme to microsomes was observed. The control livers had 24% of the cytidylyltransferase activity associated with microsomes, whereas this value was 61% in the livers from cholesterol/cholate-fed rats. When the cytosolic cytidylyltransferase was assayed in the presence of phospholipid, the enzyme was stimulated several-fold and the difference in specific activity between control and cholesterol/cholate-fed rats was abolished. The increased activity in cytosol appears to be the result of a 2-fold increase in the amount of phospholipid in the cytosol from cholesterol/cholate-fed rats. The data strongly support the hypothesis that the special diet stimulates phosphatidylcholine biosynthesis by causing a translocation of the cytidylyltransferase from cytosol to microsomes where it is activated.     

Regulation of phosphatidylcholine metabolism in mammalian hearts

Phosphatidylcholine is the major phospholipid in the mammalian heart. Over 90% of the cardiac phosphatidylcholine is synthesized via the CDP-choline pathway. The rate-limiting step of this pathway is catalyzed by CTP:phosphocholine cytidylyltransferase. Current evidence suggests that phosphatidylcholine biosynthesis in the heart is regulated by the availability of CTP and the modulation of cytidylyltransferase activity. Phosphatidylcholine is degraded mainly by the actions of phospholipase A1 and A2, with the formation of lysophosphatidylcholine. Lysophosphatidylcholine may be further deacylated by lysophospholipase or reacylated back into the parent phospholipid by the action of acyltransferase. The accumulation of lysophosphatidylcholine in the heart may be one of the biochemical factors for the production of cardiac arrhythmias.     

Characterization of cytidylyltransferase enzyme activity through high performance liquid chromatography

The cytidylyltransferases are a family of enzymes that utilize cytidine 5′-triphosphate (CTP) to synthesize molecules that are typically precursors to membrane phospholipids. The most extensively studied cytidylyltransferase is CTP:phosphocholine cytidylyltransferase (CCT), which catalyzes conversion of phosphocholine and CTP to cytidine diphosphocholine (CDP-choline), a step critical for synthesis of the membrane phospholipid phosphatidylcholine (PC). The current method used to determine catalytic activity of CCT measures production of radiolabeled CDP-choline from ¹⁴C-labeled phosphocholine. The goal of this research was to develop a CCT enzyme assay that employed separation of non-radioactive CDP-choline from CTP. A C18 reverse phase column with a mobile phase of 0.1 M ammonium bicarbonate (98%) and acetonitrile (2%) (pH 7.4) resulted in separation of solutions of the substrate CTP from the product CDP-choline. A previously characterized truncated version of rat CCTα (denoted CCTα236) was used to test the HPLC enzyme assay by measuring CDP-choline product formation. The V_max for CCTα236 was 3850 nmol/min/mg and K_0.5 values for CTP and phosphocholine were 4.07 mM and 2.49 mM, respectively. The HPLC method was applied to glycerol 3-phosphate cytidylyltransferase (GCT) and CTP:2-C-methyl-D-erythritol-4-phosphate cytidylyltransferase synthetase (CMS), members of the cytidylyltransferase family that produce CDP-glycerol and CDP-methylerythritol, respectively.