Formation of deoxycytidine diphosphate-diglyceride by nuclei isolated from HeLa cells.

Isolated nuclei from HeLa cells synthesize dCDP-diglyceride from dCTP at the rapid rate of 5–10 nmol/20 min/10⁸ nuclei. The incorporation of dCTP into this phospholipid precursor is thus 10 to 20 times faster than the incorporation of dCTP into DNA, in vitro, under the same conditions. ATP, phosphatidic acid, and MgCl₂ are required for optimal synthesis of dCDP-diglyceride. The reaction is completely inhibited by the presence of 0.04% Triton N-101. Liponucleotide formation occurs equally well with dCTP or CTP in this system and competition studies suggest that a single enzyme catalyzes the formation of dCDP- and CDP-diglyceride.     

The enzymes of phospholipid synthesis in Clostridium butyricum

We have examined extracts of Clostridium butyricum for several enzymes of phospholipid synthesis. Membrane particles were shown to catalyze the formation of CDP-diglyceride from [3H]CTP and phosphatidic acid. The reaction was dependent on Mg2+ and stimulated by monovalent cations. CDP-diglyceride formed in vitro was found to be a substrate for both phosphatidylglycerophosphate synthetase and phosphatidylserine synthetase. The formation of phosphatidylglycerophosphate from added CDP-diglyceride and [U-14C]sn-glycerol-3-phosphate was dependent on Mg2+ and Triton X-100. The dephosphorylation of endogenously-generated phosphatidylglycerophosphate to yield phosphatidylglycerol was observed to be pH-dependent. The formation of phosphatidylserine from CDP-diglyceride and L-[3-14C]serine was stimulated by Mg2+ and Triton X-100. dCDP-diglyceride was a suitable substrate for both phosphatidylglycerophosphate synthetase and phosphatidylserine synthetase. Phosphatidylserine decarboxylase activity was barely detectable in membrane particles from C. butyricum. The addition of E. coli membrane particles provided efficient phosphatidylserine decarboxylase activity in this system. Although plasmalogens are the principal lipids of C. butyricum, none of the products of phospholipid synthesis formed in vitro contained measurable amounts of plasmalogens. The subcellular distribution of both phosphatidylglycerophosphate synthetase and phosphatidylserine synthetase in C. butyricum was also studied. Both were found to be membrane-associated.     

Ribosomal-associated phosphatidylserine synthetase from Escherichia coli: purification by substrate-specific elution from phosphocellulose using cytidine 5'-diphospho-1,2-diacyl-sn-glycerol.

Cytidine 5'-diphospho-1,2-diacyl-sn-glycerol (CDPdiglyceride):L-serine O-phosphatidyltransferase (EC 2.7.8.8, phosphatidylserine synthetase) is bound tightly to the ribosomes in crude extracts of Escherichia coli. After separation of the enzyme from the ribosomes by the method of Raetz and Kennedy (Raetz, C.R.H., and Kennedy, E.P. (1974), J. Biol. Chem. 249, 5038), we have purified the enzyme to 97% of homogenekty. The major portion of the overall 5500-fold purification was attained by substrate-specific elution from phosphocellulose using CDP-diglyceride in the presence of detergent. The purified enzyme migrated as a single band with an apparent minimum molecular weight of 54 000 when subjected to electrophoresis on polyacrylamide disc gels containing sodium dodecyl sulfate. The purified enzyme catalyzed exchange reactions between cytidine 5'- monophosphate (CMP) and CDP-diglyceride and between serine and phosphatidylserine. The enzyme also catalyzed the hydrolysis of CDP-diglyceride to form CMP and phosphatidic acid. dCDP-diglyceride was equivalent to CDP-diglyceride in all reactions catalyzed by the enzyme. In addition, the purified enzyme catalyzed the formation of phosphatidylglycerol or phosphatidylglycerophosphate at a very slow rate when serine was replaced as substrate by glycerol or sn-glycero-3-phosphate, respectively. These results suggest catalysis occurs via a ping-pong mechanism through the formation of a phosphatidyl-enzyme intermediate.     

Partial purification and characterization of cytidine 5''-diphosphate-diglyceride hydrolase from membranes of Escherichia coli.

Cytidine 5'-diphosphate (CDP)-diglyceride is hydrolyzed to phosphatidic acid and cytidine 5'-monophosphate by a specific membrane-bound enzyme in cell-free extracts of Escherichia coli. The hydrolase can be extracted from the particulate fraction with Triton X-100 and purified 1,000-fold in the presence of this detergent. Several nucleoside disphosphate diglycerides were synthesized to determine the substrate specificity of the hydrolase. CDP-diglyceride was hydrolyzed preferentially, although uridine 5'-diphosphate-diglyceride, guanosine 5'-diphosphate-diglyceride, and adenosine 5'-diphosphate (ADP)-diglyceride were also slowly hydrolyzed. Surprisingly, the purified enzyme did not catalyze detectable cleavage of deoxy-CDP (dCDP)-diglyceride. The liponucleotide pool of E. coli contains dCDP-diglyceride and CDP-diglyceride in approximately equal amounts (Raetz and Kennedy, 1973). Water-soluble nucleoside pyrophosphates, such as CDP-choline, nicotinamide adenine dinucleotide, or adenosine 5'-triphosphate are not attacked by this specific hydrolase. Hydrolysis of CDP-diglyceride is strongly inhibited by adenosine 5'-monophosphate and by ADP-diglyceride.     

CTP-phosphatidic acid cytidyltransferase from Saccharomyces cerevisiae. Partial purification, characterization, and kinetic behavior.

CTP-phosphatidic acid cytidyltransferase catalyzes the formation of CDP-diglyceride from CTP and phosphatidic acid. The enzyme was solubilized from crude mitochondrial membrane by treatment with digitonin and was further purified by chromatography on DEAE-Sephadex, quaternary aminoethyl (QAE) Sephadex, and Sepharose 6B columns. At this stage the enzyme, enriched 550-fold over crude cell homogenate, still remains associated with phospholipid and has an estimated approximate molecular weight of 400,000 on the basis of gel filtration chromatography. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of the 550-fold enriched enzyme yielded two major protein bands having molecular weights of 45,000 and 19,000. The enzyme exhibits an absolute dependence on Triton X-100, a sharp Mg2+ dependence with an optimum at 20 mM, and a pH optimum of 6.5 for activity. The product of the CTP-phosphatidic acid cytidyl-transferase reaction has been isolated and identified as CDP-diglyceride, both for the crude enzyme preparation as well as for the 550-fold enriched enzyme. CTP-phosphatidic acid cytidyltransferase is capable of catalyzing the reverse reaction in the presence of pyrophosphate, utilizing CDP-diglyceride as substrate. The product of the reverse reaction was identified as CTP. Kinetic analysis of the behavior of CTP-phosphatidic acid cytidyltransferase was performed at three different stages of its purification. Initial analysis of the data yielded biphasic behavior in double reciprocal plots with respect to both substrates. Hill plots of the data indicated the presence of negative cooperativity. A detailed analysis of the kinetic behavior was performed on the enzyme purified 550-fold. The data suggest a mechanism involving two distinct cycles of catalysis, responsive to homotropic modification, with different affinities for both substrates. Further analysis of the kinetic behavior in the presence of inhibitors (dCTP and PPi) yielded a reaction order for the entrance of substrates and departure of products from the reaction cycles. The high affinity site catalyzes the reaction via a double displacement mechanism and is the predominant form at low concentrations of substrates. At high concentrations of substrates the low affinity site starts contributing significantly to the reaction velocity with an ordered single displacement mechanism. In each case CTP is the first substrate to attach and PPi is the first product released.     

Steady-state kinetics of the glutaminase reaction of CTP synthase from Lactococcus lactis. The role of the allosteric activator GTP incoupling between glutamine hydrolysis and CTP synthesis.

CTP synthase catalyzes the reaction glutamine + UTP + ATP --> glutamate + CTP + ADP + Pi. The rate of the reaction is greatly enhanced by the allosteric activator GTP. We have studied the glutaminase half-reaction of CTP synthase from Lactococcus lactis and its response to the allosteric activator GTP and nucleotides that bind to the active site. In contrast to what has been found for the Escherichia coli enzyme, GTP activation of the L. lactis enzyme did not result in similar kcat values for the glutaminase activity and glutamine hydrolysis coupled to CTP synthesis. GTP activation of the glutaminase reaction never reached the levels of GTP-activated CTP synthesis, not even when the active site was saturated with UTP and the nonhydrolyzeable ATP-binding analog adenosine 5'-[gamma-thio]triphosphate. Furthermore, under conditions where the rate of glutamine hydrolysis exceeded that of CTP synthesis, GTP would stimulate CTP synthesis. These results indicate that the L. lactis enzyme differs significantly from the E. coli enzyme. For the E. coli enzyme, activation by GTP was found to stimulate glutamine hydrolysis and CTP synthesis to the same extent, suggesting that the major function of GTP binding is to activate the chemical steps of glutamine hydrolysis. An alternative mechanism for the action of GTP on L. lactis CTP synthase is suggested. Here the binding of GTP to the allosteric site promotes coordination of the phosphorylation of UTP and hydrolysis of glutamine for optimal efficiency in CTP synthesis rather than just acting to increase the rate of glutamine hydrolysis itself.     

Properties of brain dolichol kinase activity solubilized with a zwitterionic detergent

Dolichol kinase activity is effectively solubilized by extracting calf brain microsomes with 2% 3-[(3-cholamidopropyl) dimethylammonio]-1-propanesulfonate (CHAPS), a zwitterionic detergent. The solubilized kinase catalyzes the enzymatic phosphorylation of dolichols with either CTP or dCTP serving as phosphoryl donor in the presence of Ca2+. Similar Km values were calculated for CTP (7.7 microM) and dCTP (9.1 microM). Dolichol phosphorylation was inhibited by CDP and dCDP, but not CMP, ADP, GDP, or UDP. A kinetic analysis of the inhibitory effect of CDP revealed a pattern characteristic of competitive inhibition. Dolichol kinase activity was markedly stimulated by the addition of R-dolichol (C95) or S-dolichol(C95). The apparent Km value for R-dolichol(C95) and S-dolichol(C95) was 9 microM, but the Vmax for the phosphorylation reaction was 40% higher with S-dolichol(C95). Incubation of the CHAPS extract with [gamma-32P]CTP and exogenous undecaprenol(C55) resulted in the enzymatic synthesis of a radiolabeled product that was mild acid-labile and chromatographically identical to undecaprenyl monophosphate. An enzymatic comparison with a variety of polyprenol substrates indicates that the solubilized kinase prefers long-chain (C90-95) polyprenols with saturated alpha-isoprene units. The effect of exogenous phosphoglycerides on the kinase activity in the dialyzed CHAPS extracts has also been evaluated. These studies describe the properties and polyprenol specificity of stable, solubilized preparations of dolichol kinase that should be useful for further purification of the enzyme.     

Characterization of a novel dUTP-dependent activity of CTP synthetase from Saccharomyces cerevisiae

CTP synthetase [EC 6.3.4.2, UTP:ammonia ligase (ADP-forming)] from the yeast Saccharomyces cerevisiae catalyzes the ATP-dependent transfer of the amide nitrogen from glutamine to the C-4 position of UTP to form CTP. In this work, we demonstrated that CTP synthetase utilized dUTP as a substrate to synthesize dCTP. The dUTP-dependent activity was linear with time and with enzyme concentration. Maximum dUTP-dependent activity was dependent on MgCl(2) (4 mM) and GTP (K(a) = 14 microM) at a pH optimum of 8.0. The apparent K(m) values for dUTP, ATP, and glutamine were 0.18, 0.25, and 0.41 mM, respectively. dUTP promoted the tetramerization of CTP synthetase, and the extent of enzyme tetramerization correlated with dUTP-dependent activity. dCTP was a poor inhibitor of dUTP-dependent activity, whereas CTP was a potent inhibitor of this activity. The enzyme catalyzed the synthesis of dCTP and CTP when dUTP and UTP were used as substrates together. CTP was the major product synthesized when dUTP and UTP were present at saturating concentrations. When dUTP and UTP were present at concentrations near their K(m) values, the synthesis of dCTP increased relative to that of CTP. The synthesis of dCTP was favored over the synthesis of CTP when UTP was present at a concentration near its K(m) value and dUTP was varied from subsaturating to saturating concentrations. These data suggested that the dUTP-dependent synthesis of dCTP by CTP synthetase activity may be physiologically relevant.     

Affinity of phosphatidylglycerophosphate synthetase for the liponucleotides in Bacillus subtilis

Abstract In Bacillus subtilis , the synthesis of phosphatidylglycerol, the more reactive phospholipid, was investigated in vitro. The phosphatidylglycerophosphate synthetase was exclusively localized in the membrane fraction. Three phospholipids (phosphatidylglycerophosphate, phosphatidylglycerol and diphosphatidylglycerol) were synthesized by this fraction. Exogenous CDP-diglyceride and dCDP-diglyceride were substrates with the same K _m (0.11 mM). In coupled system with CDP-diglyceride synthetase, endogenous dCDP-diglyceride was a less effective substrate than CDP-diglyceride.     

An RNA-dependent ATPase from Chlamydomonas reinhardII

An RNA-dependent ATPase has been isolated from extracts of Chlamydomonas reinhardii. The enzyme catalyzes the hydrolysis of ATP, dATP, CTP and dCTP to the corresponding nucleoside diphosphate and Pi in the presence of Mg2+ or Mn2+ and an RNA cofactor. In 1 mM MgCl2 it displays the greatest activity with poly(A), poly(I) and poly(U); and somewhat lower activity with poly(C) and T7 RNA. Although the enzyme is active with single-stranded DNA, all the single-stranded RNAs tested were significantly more effective cofactors than any of the single or double-stranded DNAs tested. A comparison of this ATPase with other RNA-dependent ATPases indicates that is has more in common with the ATPase isolated from the nuclei of animal cells than with the RNA synthesis termination protein rho, the major RNA-dependent ATPase from Escherichia coli. Although chloroplasts of C. reinhardii are known to contain many bacterial-like gene expression components, the presence of an enzyme with close homology to the E. coli rho protein was not detected.     

Enzymatic synthesis of cytidine diphosphate diglyceride

Evidence is presented for the enzymatic formation of cytidine diphosphate diglyceride in microsomal preparations from guinea pig liver according to the reaction: CTP + phosphatidic acid right harpoon over left harpoon CDP-diglyceride + p-O-P. Conditions have been found in which the incorporation of labeled CTP into CDP-diglyceride is almost entirely dependent upon added phosphatidic acid. The incorporation of CMP into lipid is very slight. A substantial net synthesis of CDP-diglyceride takes place under these conditions. Some properties of the enzyme system are described.     

Chloroform-soluble nucleotides in Escherichia coli. Role of CDP-diglyceride in the enzymatic cytidylylation of phosphomonoester acceptors

CDP-diglyceride, the precursor of all the phospholipids in Escherichia coli, is cleaved in vitro to phosphatidic acid and CMP by a membrane-bound hydrolase. Since the physiological function of CDP-diglyceride hydrolase is unknown, we have explored the possibility that this enzyme acts in vivo as either a phosphatidyl- or cytidylyltransferase. To distinguish between these two alternatives, partially purified hydrolase was incubated with CDP-diglyceride in the presence of 50% H218O. Analysis of the reaction products by 31P NMR showed that 18O is incorporated exclusively into CMP, suggesting that the enzyme is a cytidylyltransferase. This conclusion is further supported by the following experimental results: (i) the hydrolase catalyzes the transfer of CMP from CDP-diglyceride to Pi; (ii) numerous phosphomonoesters, such as glycerol 3-phosphate, phosphoserine, and glucose 1-phosphate also function as CMP acceptors, but the corresponding compounds lacking the phosphate residues are not substrates for the enzyme; and (iii) CDP-diglyceride hydrolase exchanges [32P]phosphatidic acid for the phosphatidyl moiety of CDP-diglyceride and 32Pi for the beta-phosphate residue of CDP, indicating the involvement of a novel CMP-enzyme complex. These data suggest a biosynthetic role for CDP-diglyceride hydrolase, and extend the possible functions of CDP-diglyceride in the E. coli envelope.     

Identification of cytidine diphosphate-diglyceride in the pineal gland of the rat and its accumulation in the presence of DL-propranolol.

CDP-diglyceride, an important metabolic intermediate in the biosynthesis of phospholipids, has been isolated for the first time from a mammalian tissue. The isolated material, labeled in incubations of intact rat pineal glands with 32P, [3H]cytidine, or [3H]CTP in the presence of DL-propranolol, was chromatographically identical with authentic CDP-diglyceride and was able to serve as phosphatidyl donor in the enzymatic synthesis of phosphatidylinositol and phosphatidyglycerol. It yielded the expected products upon enzymatic and chemical degradation. No dCDP-diglyceride was detected No radioactive CDP-diglyceride was detected following incubations in the absence of propranolol. Stimulation of CDP-diglyceride labeling from 32P1 occurred at propranolol concentrations between 0.03 and 1.0 mM. Net synthesis of the liponucleotide was shown. At 0.1 mM, propranolol incrased the incorporation of radioactivity into phosphatidylglycerol, phosphatidylinositol, and phosphatidic acid. When inositol (10 mM) and propranolol (0.1 mM) were both present, phosphatidylinositol labeling was further increased, wheas stimulation of phosphatidylglycerol and CPD-diglyceride labeling was abolished. Since CDP-diglyceride did not accumulate in the absence of the drug, its availability may normally be the limiting factor in phosphatidylinositol and phosphatidylglycerol biosynthesis. When propranol is present, inositol may become limiting and thus may lead to the observed labeling pattern.     

THE FORMATION OF CDP-DIGLYCERIDE BY ISOLATED NEURONAL NUCLEI

—A population of neuronal nuclei isolated from the rabbit cerebral cortex actively incorporates cytidine-5′-triphosphate into an acid-insoluble product, the incorporation is stimulated by magnesium or manganese ions and appears to utilize CTP directly as substrate. Other nucleoside triphosphates stimulate CTP incorporation at low substrate concentrations, apparently by preventing CTP breakdown, while higher concentrations of nucleoside triphosphates strongly inhibit CTP incorporation at either low or saturating substrate concentrations. CTP incorporation appears to be unrelated to RNA synthesis in that it exhibits a different pH and divalent cation optimum, is unaffected by inhibitors of RNA synthesis, and is strongly inhibited by low concentrations of detergent but not by preincubation of nuclei at 37°C. The product of CTP incorporation is almost entirely soluble in acidified lipid solvents and is not sensitive to digestion by RNAase under conditions where the enzyme can digest newly synthesized RNA. CTP incorporation is markedly stimulated by phosphatidic acid, the stimulated incorporation showing the same characteristics as the unstimulated incorporation, and is inhibited by inositol. Alkaline hydrolysis of the product releases the great majority of radioactivity as 5′-CMP as judged by chromatography and by 5′-nucleotidase action. The product of CTP incorporation migrates with synthetic CDP-diglyceride in five solvent systems. It is concluded that under optimal conditions for CTP incorporation, less than 5% of the incorporated CTP can be included in a polynucleotide chain, this small proportion of the total incorporation could either represent residual RNA synthesis or the formation of poly (C) with an average chain length of less than 3 residues. Under optimal conditions the great majority of CTP incorporation by neuronal nuclei in the presence of either magnesium or manganese ions represents the formation of the unique liponucleotide CDP-diglyceride.     

Structures of dCTP deaminase from Escherichia coli with bound substrate and product: reaction mechanism and determinants of mono- and bifunctionality for a family of enzymes

dCTP deaminase (EC 3.5.4.13) catalyzes the deamination of dCTP forming dUTP that via dUTPase is the main pathway providing substrate for thymidylate synthase in Escherichia coli and Salmonella typhimurium. dCTP deaminase is unique among nucleoside and nucleotide deaminases as it functions without aid from a catalytic metal ion that facilitates preparation of a water molecule for nucleophilic attack on the substrate. Two active site amino acid residues, Arg(115) and Glu(138), were identified by mutational analysis as important for activity in E. coli dCTP deaminase. None of the mutant enzymes R115A, E138A, or E138Q had any detectable activity but circular dichroism spectra for all mutant enzymes were similar to wild type suggesting that the overall structure was not changed. The crystal structures of wild-type E. coli dCTP deaminase and the E138A mutant enzyme have been determined in complex with dUTP and Mg(2+), and the mutant enzyme also with the substrate dCTP and Mg(2+). The enzyme is a third member of the family of the structurally related trimeric dUTPases and the bifunctional dCTP deaminase-dUTPase from Methanocaldococcus jannaschii. However, the C-terminal fold is completely different from dUTPases resulting in an active site built from residues from two of the trimer subunits, and not from three subunits as in dUTPases. The nucleotides are well defined as well as Mg(2+) that is tridentately coordinated to the nucleotide phosphate chains. We suggest a catalytic mechanism for the dCTP deaminase and identify structural differences to dUTPases that prevent hydrolysis of the dCTP triphosphate.     

Poly(C) synthesis by class I and class II CCA-adding enzymes

The CCA-adding enzymes [ATP(CTP):tRNA nucleotidyl transferases], which catalyze synthesis of the conserved CCA sequence to the tRNA 3' end, are divided into two classes. Recent studies show that the class II Escherichia coli CCA-adding enzyme synthesizes poly(C) when incubated with CTP alone, but switches to synthesize CCA when incubated with both CTP and ATP. Because the poly(C) activity can shed important light on the mechanism of the untemplated synthesis of CCA, it is important to determine if this activity is also present in the class I CCA enzymes, which differ from the class II enzymes by significant sequence divergence. We show here that two members of the class I family, the archaeal Sulfolobus shibatae and Methanococcus jannaschii CCA-adding enzymes, are also capable of poly(C) synthesis. These two class I enzymes catalyze poly(C) synthesis and display a response of kinetic parameters to the presence of ATP similar to that of the class II E. coli enzyme. Thus, despite extensive sequence diversification, members of both classes employ common strategies of nucleotide addition, suggesting conservation of a mechanism in the development of specificity for CCA. For the E. coli enzyme, discrimination of poly(C) from CCA synthesis in the intact tRNA and in the acceptor-TPsiC domain is achieved by the same kinetic strategy, and a mutation that preferentially affects addition of A76 but not poly(C) has been identified. Additionally, we show that enzymes of both classes exhibit a processing activity that removes nucleotides in the 3' to 5' direction to as far as position 74.     

Interaction of sn-glycerol 3-phosphorothioate with Escherichia coli. In vitro and in vivo incorporation into phospholipids

sn-Glycerol 3-phosphorothioate, a bacteriocidal analog of sn-glycerol 3-phosphate in strains of Escherichia coli with a functioning glycerol phosphate transport system, was investigated for its ability to be incorporated into phospholipid under in vitro and in vivo conditions. A cell-free particulate fraction from E. coli strain 8 catalyzes the transfer of sn-[3H]glycerol 3-phosphoro[35S]thioate to chloroform-soluble material in the presence of either CDP-diglyceride or palmitoyl coenzyme A. With CDP-diglyceride as the co-substrate, the product of the reaction was tentatively identified as phosphatidylglycerol phosphorothioate. No formation of phosphatidylglycerol was observed, suggesting that the specific phosphatase required for the synthesis of phosphatidylglycerol does not catalyze, or else at a greatly reduced rate, the hydrolysis of the phosphorothioate monoester linkage. The kinetics of incorporation of sn-[3H]glycerol 3-phosphate and phosphorothioate into chloroform-soluble material in the presence of CDP-diglyceride are almost identical. In the presence of palmitoyl coenzyme A, sn-[3H]glycerol 3-phosphoro[35S]thioate was converted to the phosphorothioate analog of phosphatidic acid. Kinetic analysis showed that the apparent Km values for the incorporation of the phosphate and the phosphorothioate derivatives into phospholipid were 0.4 and 0.8 mM, respectively. The Vmax for the phosphorothioate analog was approximately half that for the phosphate derivative. Chemically synthesized thiophosphatidic acid was not a substrate for CTP:phosphatidic acid cytidylyltransferase. sn-[3H]Glycerol 3-phosphoro[35S]thioate was incorporated into phospholipid by cultures of E. coli strain 8. The major phosphorothioate-containing phospholipid synthesized in vivo was identified as 1,2-diacyl-sn-[3H]glycerol 3-phosphoro[35S]thioate. The phosphorothioate analog of phosphatidylglycerol phosphate was not observed despite our observations that this analog can be synthesized in vitro. Our results indicate that the phosphorothioate analog is an effective sn-glycerol 3-phosphate surrogate and suggest that a major reason for its toxicity toward E. coli strain 8 may be due to a total blockade of endogenous phospholipid biosynthesis.     

An improved procedure for the synthesis of 14C-labeled phosphatidylserine from cerebral phosphatidic acid

A complete procedure to prepare a highly labeled phosphatidyl-L-[U-14C]serine possessing the same fatty acid composition of brain phospholipids is reported. CDP-diglyceride was synthesized by reaction between phosphatidic acid and CMP-morpholidate as the dicyclohexylcarboxamidium salt. The reaction between CDP-diglyceride and L-[U-14C]serine to produce the labeled phosphatidylserine was catalyzed by the CDP-diglyceride: L-serine phosphatidyl transferase (EC 2.7.8.8) from E. coli. A selective inhibition of phosphatidylserine decarboxylase activity, present as contaminant in the enzyme extract, was introduced in order to avoid a low yield of product. Traces of phosphatidylethanolamine (about 1%) were easily removed by preparative thin-layer chromatography. The yield of the labeled product was as high as 87% and it specific radioactivity was 170 mCi/mmol.     

Control of membrane lipid synthesis in Escherichia coli during growth and during the stringent response.

The regulation of phospholipid synthesis in cells of Escherichia coli was studied in vivo during growth and during the stringent response to amino acid starvation. Strains harboring the hybrid plasmid pLC44-14 (Clark, L., and Carbon, J. (1976) Cell 9, 91-99), which had increased levels of glycerophosphate acyltransferase, were used to study the involvement of this enzyme in the control of phospholipid synthesis. In addition, regulation was studied by measuring the levels of three early intermediates of phospholipid synthesis:phosphatidic acid, CDP-diglyceride, and dCDP-diglyceride. The liponucleotides were measured by a new enzymatic method which allows determinations to be made on crude lipid extracts. Results from experiments on growing cells are consistent with regulation of membrane lipid synthesis occurring in fatty acid synthesis or at the level of glycerophosphate acylation, but not at any later step. Experiments on the inhibition of lipid synthesis during the stringent response make it possible to rule out explanations which involve the inhibition of a single enzyme; enzymes both before and after the liponucleotides in phospholipid synthesis must be affected.     

Insight into the activation mechanism of Escherichia coli octaprenyl pyrophosphate synthase derived from pre-steady-state kinetic analysis

Octaprenyl pyrophosphate synthase (OPPs) catalyzes the sequential condensation of five molecules of isopentenyl pyrophosphate with farnesyl pyrophosphate to generate all-trans C40-octaprenyl pyrophosphate, which constitutes the side chain of ubiquinone. Due to the slow product release, a long-chain polyprenyl pyrophosphate synthase often requires detergent or another factor for optimal activity. Our previous studies in examining the activity enhancement of Escherichia coli undecaprenyl pyrophosphate synthase have demonstrated a switch of the rate-determining step from product release to isopentenyl pyrophosphate (IPP) condensation reaction in the presence of Triton [12]. In order to understand the mechanism of enzyme activation for E. coli OPPs, a single-turnover reaction was performed and the measured IPP condensation rate (2 s(-1)) was 100 times larger than the steady-state rate (0.02 s(-1)). The high molecular weight fractions and Triton could accelerate the steady-state rate by 3-fold (0.06 s(-1)) but insufficient to cause full activation (100-fold). A burst product formation was observed in enzyme multiple turnovers indicating a slow product release.