Formation of phosphatidylethanol in rat brain by phospholipase D

The mechanism of phosphatidyl [14C]ethanol formation was studied in rat brain microsomal fraction. Phospholipase D and base-exchange enzymes were assayed with [14C]ethanol as substrate. Phospholipase D was found to catalyse the formation of phosphatidylethanol. The reaction was dependent on sodium-oleate as activating factor. Phosphatidylethanol formation by phospholipase D has previously only been reported to occur in plant tissues. Stimulation of base-exchange enzymes with calcium in the presence of [14 C]ethanol did not induce any formation of phosphatidylethanol. These findings indicate that phosphatidylethanol formation in ethanol intoxicated rats is catalysed by phospholipase D.     

Specific inhibition of rat brain phospholipase D by lysophospholipids

Although the importance of phospholipase D (PLD) in signal transduction in mammalian cells is well documented, the negative regulation of PLD is poorly understood. This is primarily due to a lack of known specific inhibitors of PLD. We herein report that the activity of partially purified rat brain PLD is inhibited by certain lysophospholipids, such as lysophosphatidylinositol, lysophosphatidylglycerol, and lysophosphatidylserine in a highly specific manner. Inhibition of PLD by lysophospholipids was dose-dependent: the concentration of lysophosphatidylinositol required for half-maximal inhibition was about 3 micrometer. An analysis of the enzyme-kinetics suggested that lysophospholipids act as non-competitive inhibitors of PLD activity. As expected, PLD activity was stimulated by ADP-ribosylation factor (Arf) and phosphatidylinositol 4,5-bisphosphate (PIP(2)). The inhibition of PLD by lysophospholipids, however, was not affected by the presence or absence of Arf or by an increase in PIP(2) concentration. A protein-binding assay suggested that lysophospholipids bind directly to PLD. These results indicate that the observed inhibition of PLD by lysophospholipids is due to their direct interaction rather than to an interaction between lysophospholipids and either Arf or PIP(2). The present study suggests that certain lysophospholipids are specific inhibitors of rat brain PLD in a cell-free system and may provide the new opportunities to investigate mechanisms by which PLD is regulated by lysophospholipids, presumably liberated by phospholipase A(2) activation, in mammalian cells.     

Regional distribution and age-dependent expression of N-acylphosphatidylethanolamine-hydrolyzing phospholipase D in rat brain

The endocannabinoid anandamide (N-arachidonoylethanolamine) and other bioactive long-chain N-acylethanolamines are thought to be formed from their corresponding N-acylphosphatidylethanolamines by a specific phospholipase D (NAPE-PLD) in the brain as well as other tissues. However, regional distribution of NAPE-PLD in the brain has not been examined. In the present study, we investigated the expression levels of NAPE-PLD in nine different regions of rat brain by enzyme assay, western blotting and real-time PCR. The NAPE-PLD activity was detected in all the tested brain regions with the highest activity in thalamus. Similar distribution patterns of NAPE-PLD were observed at protein and mRNA levels. We also found a remarkable increase in the expression levels of protein and mRNA of the brain NAPE-PLD with development, which was in good agreement with the increase in the activity. The age-dependent increase was also seen with several brain regions and other NAPE-PLD-enriched organs (heart and testis). p-Chloromercuribenzoic acid and cetyltrimethylammonium chloride, which inhibited recombinant NAPE-PLD dose-dependently, strongly inhibited the enzyme of all the brain regions. These results demonstrated wide distribution of NAPE-PLD in various brain regions and its age-dependent expression, suggesting the central role of this enzyme in the formation of anandamide and other N-acylethanolamines in the brain.     

Eosinophilic leucocytes and phospholipase B of rat tissues

The correlation between the eosinophilic leucocyte population and the phospholipase B activity of rat tissues has been tested with isolated cell preparations from intestine, lung, blood, bone marrow and spleen containing eosinophils in varying proportions and with pure eosinophil fractions separated by centrifugation on discontinuous metrizoate and metrizamide gradients. A uniform value of activity per cell was found in all these tissues extending previous histochemical and biochemical evidence that the eosinophil is the carrier cell for the phospholipase B to all major sites of distribution. The enzyme marker approach has been used for estimating the normal eosinophil population of rat organs and show the distribution pattern of the eosinophils in peripheral organs in the wake of increased production and release from the marrow.     

Cross-talk between receptor-regulated phospholipase D and phospholipase C in brain

Because receptors, G proteins, and phospholipases all exist within a membrane lipid environment, it is not unreasonable to assume that an enzyme capable of changing the lipid environment can affect the coupling relationship among these signal transducing components. Our previous study showed that a muscarinic acetylcholine receptor regulates phosphatidylcholine phospholipase D via a G protein in brain. We demonstrate here that phosphatidylinositol phospholipase C and phosphatidylcholine phospholipase D are simultaneously activated within 15 s by muscarine in the presence of 1 microM GTP gamma S. More important, inhibition of phospholipase D by zinc attenuated carbamylcholine-induced activation of phospholipase C by 30%. Our additional evidence strongly indicates that the receptor-regulated phospholipase D plays an important modulatory role in agonist-stimulated phosphatidylinositol breakdown. This modulatory effect may be achieved by changing the membrane microenvironment in which phospholipase C and phosphoinositol lipids reside, consequently amplifying the inositol phospholipid signaling process. Our results lead us to postulate that the potential interaction between two different signaling pathways may provide a cell with intracellular coordination and enable the cell to achieve functional responses.     

Developmental changes and regional distribution of phospholipase D and base exchange enzyme activities in rat brain

Phospholipase D (PL-D) activity per mg protein of whole homogenate increased 5.1 fold between Embryonic (E) day 17 and Postpartum (P) day 14 and slightly decreased by P 30 days. This was due to the decrease of PL-D activity of the P₂ fraction. The PL-D activity of P₂ and P₃ fractions increased 11.2 and 6.1 fold respectively between E 17 and P 14. The 3 base exchange enzyme (BEE) activities per mg protein of whole homogenate increased up to P 14 or P 21 and then decreased. This decrease was greater in the P₂ fraction and the P₃ fraction increased after P14. Brains from 1 day to 25 month old rats were dissected into 7 separate regions and both PL-D and BEE activities were measured. In adult rats, the hippocampus and hypothalamus had the highest PL-D activities while medulla+pons and cerebellum had the lowest PL-D activities. The developmental patterns of 5 regions except for hippocampus and hypothalamus were similar. PL-D activity in the hippocampus was maximum at P 7 followed by a steep decrease till P30 suggesting that the PL-D activity of the hypothalamus develops later and that of the hippocampus develops earlier than any other region. The distributions of BEE activities were quite different from those of PL-D activities. In adult rats, the cerebellum had the highest activity while the striatum and medulla+pons had the lowest. The BEE activities of cerebellum were lowest at P 1 and showed steep increase during the next 2 weeks.To whom to address reprint request are to be sent.     

A neutral phospholipase D activity from rat brain synaptic plasma membranes. Identification and partial characterization

Rapid activation of phospholipase D (PLD) in response to cell stimulation was recently demonstrated in many systems, raising the hypothesis that PLD participates in transduction of extracellular signals across the plasma membrane. In the present study, we describe the identification of a neutral PLD activity in purified rat brain synaptic plasma membranes, and the in vitro conditions required to assay its catalytic activity with exogenous [3H]phosphatidylcholine as substrate. Production of [3H]phosphatidic acid, the natural lipid product of PLD and of [3H]phosphatidylethanol, catalyzed by PLD in the presence of ethanol via transphosphatidylation, were measured. The synaptic membrane PLD exhibited its highest activity at pH 7.2 and was thus defined as a neutral PLD. Enzyme activity was absolutely dependent on the presence of sodium oleate and was strongly activated by Mg2+ ions (at 1 mM). Ca2+ at concentrations up to 0.25 mM was as stimulatory as Mg2+, but at 2 mM it completely inhibited enzyme activity. Mg2+ extended the linear phase of PLD activity from 2 to 15 min, suggesting that it may stabilize the enzyme under our assay conditions. The production of [3H]phosphatidylethanol was a saturable function of ethanol concentration. Production of [3H] phosphatidic acid was inversely related to the concentration of ethanol and to the accumulation of phosphatidylethanol, indicating that the two phospholipids are indeed produced by the competing hydrolase and transferase activities of the same enzyme. beta,beta-Dimethylglutaric acid, utilized previously as a buffer in studies of rat brain PLD, inhibited enzyme activity at neutral pH but not at acidic pH. The properties of the neutral synaptic membrane PLD and its relationships with other in vitro, acid, and neutral PLD activities, as well as with the signal-dependent PLD detected in intact cells, are discussed.     

Enzymatic properties of phosphatidylinositol-glycan-specific phospholipase C from rat liver and phosphatidylinositol-glycan-specific phospholipase D from rat serum.

Using phosphatidylinositol-glycan (PtdIns-glycan) anchored acetylcholinesterase from bovine erythrocytes as substrate, we found PtdIns-glycan-anchor-degrading activity in rat liver and serum [corrected]. The hepatic enzyme was only soluble in detergents, whereas the serum enzyme occurs as soluble, slightly amphiphilic protein. Using 3-trifluoromethyl-3-(m- [125I]iodophenyl)diazirine-labelled acetylcholinesterase as substrate, we showed that the hepatic anchor-degrading enzyme had a cleavage specificity of a phospholipase C, whereas the serum enzyme was a phospholipase D. Both enzyme exhibited maximal activity in slightly acidic conditions and at low ionic strength. They had a high affinity for the PtdIns-glycan anchor of the substrate (Km = 0.1 microM and 0.16 microM, respectively). Both hepatic PtdIns-glycan-specific phospholipase C and serum PtdIns-glycan-specific phospholipase D gave a large increase in activity between 0.1-10 microM Ca2+, indicating that PtdIns-glycan-specific phospholipases are only marginally active at physiological intracellular Ca2+ concentrations. The enzymes were inhibited by heavy metal chelating agents such as 1,10-phenanthroline and 2,2'-bipyridyl but not by the corresponding Fe2+ complexes or non-chelating analogues, indicating that they both require a heavy metal ion for the expression of catalytic activity in addition to Ca2+. Another interesting property of PtdIns-glycan-specific phospholipases is their inactivation by bicarbonate and cyanate. The inactivation was time- and pH-dependent and could be reversed by dialysis. These observations are in agreement with a covalent modification of the enzymes by carbamoylation.     

Functions and pathophysiological roles of phospholipase D in the brain

Ten years after the isoforms of mammalian phospholipase D (PLD), PLD1 and 2, were cloned, their roles in the brain remain speculative but several lines of evidence now implicate these enzymes in basic cell functions such as vesicular trafficking as well as in brain development. Many mitogenic factors, including neurotransmitters and growth factors, activate PLD in neurons and astrocytes. Activation of PLD downstream of protein kinase C seems to be a required step for astroglial proliferation. The characteristic disruption of the PLD signaling pathway by ethanol probably contributes to the delay of brain growth in fetal alcohol syndrome. The post-natal increase of PLD activities concurs with synapto- and myelinogenesis in the brain and PLD is apparently involved in neurite formation. In the adult and aging brain, PLD activity has antiapoptotic properties suppressing ceramide formation. Increased PLD activities in acute and chronic neurodegeneration as well as in inflammatory processes are evidently due to astrogliosis and may be associated with protective responses of tissue repair and remodeling. ARF-regulated PLD participates in receptor endocytosis as well as in exocytosis of neurotransmitters where PLD seems to favor vesicle fusion by modifications of the shape and charge of lipid membranes. Finally, PLD activities contribute free choline for the synthesis of acetylcholine in the brain. Novel tools such as RNA interference should help to further elucidate the roles of PLD isoforms in brain physiology and pathology.     

Stimulation of phospholipase D activity and indication of acetylcholine synthesis by oleate in rat brain synaptosomal preparations

It had been previously demonstrated that the oleate activation of synaptosomal membrane phospholipase D liberated choline which was available for acetylcholine formation. The present investigations were undertaken to determine if oleate might have an effect on choline uptake by synaptosomes. It was observed that oleate interfered with choline uptake when incubations were carried out at 37°C but uptake was stimulated at 3°C. Oleate was the most effective fatty acid of several tested. Preliminary observations suggest the presence of a membranous form of choline acetyltransferase.     

Detection of phospholipase D in rat liver mitochondria

It is determined that the rat liver mitochondria contain phospholipase D. It is active during incubation of the intact mitochondria, their "ghosts", as well as fractions of outer and inner membranes. This enzyme is shown to be able to realize the catalytic transformations of substrates by the reaction of hydrolysis and exchange of bases.     

Partial purification and properties of a rat brain phospholipase.

At least 90% of a membrane-bound phospholipase D was solubilized by extraction of freeze-dried rat brain with 0.8% Miranol H2M and 0.5% cholate. The bulk of base exchange reaction enzymes remained firmly bound to the particulate fraction under these conditions. The phospholipase D specific activity was enriched 240-fold by a purification protocol employing ammonium sulfate precipitation, and both Sepharose 4B and DEAE-cellulose column chromatography. The approximate molecular weight of the partially purified enzyme was calculated to be 200,000 based upon the elution profile from Sepharose 4B and Sephadex G-200 columns. The optimum pH was 6.0, and Km values for phosphatidylcholine and phosphatidylethanolamine were 0.75 mM and 0.91 mM, respectively. The enzyme activity was not dependent on the presence of divalent cation although Ca2+ and Fe2+ showed stimulatory effects.     

Microsomal protein mediates a pH-dependent fusion of liposomes to rat brain microsomes

The fusion between rat brain microsomes and liposomes is investigated by measuring the release of octadecylrhodamine B (R18) fluorescence self-quenching. In the experimental conditions used in this work, the method allows a rapid and quantitative evaluation of the mixing of microsome and liposome lipid phases. The decrease of pH below 7 produces an extensive fusion between microsomes and acidic phospholipid liposomes. Microsomal protein is necessary for fusion, which is inactivated by exposure of microsomes to pronase. Therefore, H(+)-induced fusion differs from Ca(2+)-induced fusion since the latter does not require microsomal protein. The pretreatment of microsomes with trinitrobenzenesulfonic acid (TNBS) in nonpenetrating conditions does not affect the extent of fusion. On the other hand, N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ), a reagent able to react with carboxyl groups, causes an extensive inactivation of fusion. Therefore, the H(+)-induced fusion described here depends on some microsomal protein and may have physiological significance because it occurs at pH values present in the living cell. H(+)-dependent fusion can be also considered as a means to enrich membranes in some selected lipid.     

Imipramine stimulates phospholipase C activity in rat brain

We previously demonstrated that antidepressant drugs (ADs) cause Ca²⁺ release from inositol 1,4,5-trisphosphate-sensitive Ca²⁺ stores in cultured neurons of rat frontal cortex. The present study examines the mechanism by which tricyclic ADs activate phospholipase C (PLC) in rat frontal cortex. Using an exogenous substrate to measure PLC activity, we demonstrated that a tricyclic AD, imipramine, stimulated PLC activity of the frontal cortex membrane in a concentration-dependent manner. Two tricyclic ADs, desipramine and amitriptyline, also stimulated PLC activity, while Li⁺ or pargyline had no effect on PLC activity. Although imipramine did not activate PLC in the membrane in the absence of Ca²⁺, imipramine synergistically activated PLC in the presence of Ca²⁺. This result indicates that the mechanism of PLC activation by imipramine is different from its activation by Ca²⁺. Imipramine stimulated PLC activity in the cytosol of rat frontal cortex as well as in the membrane. Preincubation of the cytosol with anti-PLC-β₁ antibody prevented the imipramine-mediated activation of PLC. However, preincubation with anti-PLC-γ₁ or anti-PLC-δ₁ did not prevent activation of PLC. These results suggest that imipramine activates PLC-β₁ directly without receptor or guanine nucleotide binding protein mediation.     

Isolation and characterization of a phosphatidylinositol-glycan-anchor-specific phospholipase D from bovine brain

In recent years an increasing number of proteins has been shown to be membrane-anchored by a covalently attached PtdIns-glycan residue. In mammalian cells little is known about PtdIns-glycan-specific phospholipases which might play a role in the metabolism of PtdIns-glycan-anchored proteins. In order to identify PtdIns-glycan-specific phospholipases, a rapid and sensitive assay for such enzymes was developed using the PtdIns-glycan-anchored amphiphilic membrane form of acetylcholinesterase as substrate. The rate of product formation was monitored by the increase in soluble hydrophilic acetylcholinesterase in the aqueous phase after separation in Triton X-114. With this assay we established the presence of a PtdIns-glycan-specific phospholipase in bovine brain. This enzyme was soluble and could be partially purified by a heat step followed by chromatography on DEAE-cellulose and by gel filtration on Sepharose CL-6B. PtdIns-glycan-specific phospholipase had a high affinity for the PtdIns-glycan anchor of the substrate (Km = 52 nM) and did not degrade either PtdCho or PtdIns. Hydrophobic labeling of the anchor of the substrate with 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine [( 125I]TID) caused a marked decrease in the cleavage rate and methylation of the amino group of the glucosamine residue of the anchor decreased the cleavage rate to zero. Using [125I]TID-labeled substrate, diradylglycerol phosphate was identified as the second product showing that the cleavage specificity of PtdIns-glycan-specific phospholipase was that of a phospholipase D. PtdIns-glycan-specific phospholipase D was inhibited by mercurials, omicron-phenanthroline and EGTA. It was stimulated by Ca2+ in micromolar concentrations indicating that PtdIns-glycan-phospholipase D is a Ca2(+)-regulated enzyme.     

Lysophosphoinositide-specific phospholipase C in rat brain synaptic plasma membranes

A membrane preparation from rat brain catalyzed the hydrolysis of [2-³H]glycerol-labeled lysophosphatidylinositol (lysoPI) to yield monoacylglycerol (MG) and inositolphosphates. This phospholipase C activity had an optimal pH of 8.2. The membrane preparation did not require the addition of Ca²⁺ for its maximum activity, but the activity was inhibited by addition of 0.1 mM EDTA to the assay mixture and was restored by simultaneous addition of 0.2 mM Ca²⁺. The activity was found to be localized in synaptic plasma membranes prepared by Ficoll and Percoll density gradients. The phospholipase C was highly specific for lysoPI; diacylglycerol formation from phosphatidylinositol, and MG formation from lysophosphatidylcholine, lysophosphatidylethanolamine, and lysophosphatidylserine were below 5% of that observed with lysoPI under the conditions used. We concluded that there is a pathway for phosphatidylinositol metabolism in brain synaptic membranes which is different from the well-characterized phosphoinositide-specific phospholipase C pathway.Abbreviations PI phosphatidylinositol - lysoPI lysophosphatidylinositol - lysoPI-PLC lysophosphoinositide-specific phospholipase C - PI-PLC phosphoinositide-specific phospholipase C - MG monoacylglycerol - PLC phospholipase C To whom to address reprint requests.     

Nucleases of cell fractions of rat brain tissues

Nucleases are found in different fractions of nerve cells in the rat brain. The nuclease denaturating preferably the one-chain DNA at pH 8.0 is located chiefly in the neuron nuclei. Fractions of cell nuclei containg mainly neuron nuclei or glial nuclei were obtained by the method of ultracentrifugation within the sucrose gradient.