THE EFFECT OF ELECTRICAL STIMULATION ON THE TURNOVER OF PHOSPHATIDIC ACID IN SYNAPTOSOMES FROM GUINEA-PIG BRAIN

Synaptosomes prepared from guinea-pig cerebral cortex were suspended in a medium containing [³²P]orthophosphate and subjected to electrical stimulation. When the synaptosomal phospholipids were subsequently separated, the most highly labelled was phosphatidic acid and electrical stimulation over a 10 min period increased incorporation of ³²P₁ into this lipid. Stimulated synaptosomes were osmotically lysed and subsynaptosomal fractions isolated. The electrically stimulated increase in phosphatidic acid labelling was localized in a fraction enriched in synaptic vesicles. This phospholipid effect was not merely a reflection of an increased specific radioactivity of synaptosomal ATP, due to the electrically stimulated increase in respiration. The time course of the phosphatidic acid effect suggests that it is synchronous with release of transmitter.     

CHOLINERGIC STIMULATION OF PHOSPHOLIPID LABELLING FROM [32P]ORTHOPHOSPHATE IN GUINEA-PIG CORTEX SYNAPTOSOMES IN VITRO: SUBSYNAPTOSOMAL LOCALIZATION

Abstract— Subsynaptosomal localization of stimulation of phospholipid labelling by cholinergic agents was investigated. Synaptosomes prepared from guinea-pig cortex were incubated with [³²P]orthophosphate in the presence or absence of 10⁻³ m carbamylcholine. Following incubation and osmotic shock, lysed synaptosomes were subjected to density gradient fractionation. Subsynaptosomal fractions were examined by electron microscopy and analysed for enzyme activities and ³²P-labelled lipids.
In the absence of carbamylcholine, labelled phosphatidate and phosphatidylinositol were recovered in layers and interfaces A, B, C and D formed over 0.9, 1.1, 1.2 and 1.3 m sucrose, with highest amounts of label in fractions C and D for both lipids. Carbamylcholine induced the greatest increment in these two labelled lipids in fractions A and B. This distribution correlated with the presence of acetylcholinesterase activity and membrane ghosts. No correlation was found among the four fractions between the induced increase in labelling and succinic dehydrogenase activity or with the abundance of mitochondria, synaptic vesicles, or cytoplasmic fragments identified by electron microscopy. In contrast with the increases seen in phosphatidylinositol and phosphatidate labelling, carbamylcholine caused a decrease in ³²P-labelling of the polyphosphoinositides, and this effect was seen primarily in the heavier subsynaptosomal fractions, C and D.     

Plasma-membrane location of phosphatidylinositol hydrolysis in rabbit neutrophils stimulated with formylmethionyl-leucylphenylalanine.

Rabbit peritoneal neutrophils, disrupted by sonication, were separated into three subcellular fractions by sucrose-step-gradient centrifugation and these were analysed with respect to biochemical markers. They comprised a high-speed supernatant containing the cytosol, a light particulate fraction enriched in Golgi and plasma membranes and a heavy particulate fraction enriched in granules and nuclei. The light particulate fraction was further separated into its components, which were identified as Golgi membranes (galactosyltransferase activity) and plasma membranes ((radioactivity derived from labelling intact cells with [125I]di-iodosulphanilic acid diazonium salt and [3H]formylmethionyl-leucylphenylalanine ([3H]fMet-Leu-Phe) binding)). In cells prelabelled with [3H]glycerol, the hydrolysis of phosphatidylinositol due to cell stimulation with fMet-Leu-Phe (10 nM) was shown to occur in the light particulate fraction. The [32P]Pi-labelling of phosphatidate, which is an early consequence of phosphatidylinositol hydrolysis, also occurred in this fraction. Analytical sucrose-gradient centrifugation of the light particulate fraction showed that the stimulated increment in [32P]phosphatidate (and thus by implication the initial phosphatidylinositol breakdown) was localized in the plasma membrane.     

Phosphatidic acid metabolism,calcium ions and transmitter release from electrically stimulated synaptosomes

Synaptosomes isolated from guinea pig brain cortex were stimulated electrically in a medium containing [32P]-orthophosphate. The electrical stimulation caused increased labelling of phosphatidic acid in a synaptic vesicle fraction prepared by osmotic shock of the incubated synaptosomes. Electrical stimulation also provokes transmitter release from the synaptosomes. Both increased phosphatidate labelling and transmitter release required calcium ions in the medium. The effects are discussed in relation to earlier work with acetylcholine and the possible involvement of membrane phosphatidic acid in transmitter release by exocytosis.     

SYNTHESIS OF ACETYLCHOLINE IN DIFFERENT COMPARTMENTS OF BRAIN NERVE TERMINALS IN VIVO AS STUDIED BY THE INCORPORATION OF CHOLINE FROM PLASMA AND THE EFFECT OF PENTOBARBITAL ON THIS PROCESS

The time course of the incorporation of choline from plasma into a high and a low molecular weight fraction from mouse brain synaptosomes was studied. The fractions were obtained from lysed synaptosomes by gel filtration on Sephadex G-25. An extremely rapid incorporation of radioactivity into acetylcholine was found in both fractions and in the time interval 0.25-9 min after the intravenous administration of labelled choline, higher specific radioactivities of acetylcholine were found in the high molecular weight fraction than in the low molecular weight fraction. However, the specific radioactivity of choline in the high molecular weight fraction was much lower than that of acetylcholine. It was found that barbiturate anaesthesia caused a marked decrease in the labelling of acetylcholine in the high molecular weight fraction while the incorporation into the low molecular weight fraction was affected to a much smaller extent. Acetylcholine of the high molecular weight fraction showed properties similar to those of vesicle-bound acetylcholine. The recoveries of labelled and endogenous acetylcholine and choline from the brain homogenates were calculated in different steps of the fractionation procedure. In the fraction containing lysed synaptosomes the recovery of radioactive acetylcholine was lower than that of endogenous acetylcholine. This may indicate the presence of two types of bound acetylcholine in the synaptosomes. Different models for the intraneuronal synthesis of acetylcholine are discussed and it is proposed that a site of acetylcholine synthesis in vivo may be closely associated with some constituent of the high molecular weight fraction and directly coupled with the storage of the transmitter.     

Phospholipid turnover in Torpedo marmorata electric organ during discharge in vivo.

One electric organ of anaesthetized Torpedo marmorata was stimulated through electrodes placed on the electric lobe of the brain. Nerves to the other electric organ were cut to provide an unstimulated control. Glucose 6-[32P]phosphate was injected into each organ 16h before electrical stimulation. After stimulation for 10 min at 5 Hz, the organs were removed homogenized and centrifuged on a density gradient for the preparation of subcellular fractions. Stimulation increased the incorporation of 32P into phosphatidate, phosphatidylinositol and phosphatidylcholine. The increased phosphatidate labelling, but not that of the other two lipids, was seen in fractions rich in synaptic vesicles. Stimulation had no effect on ATP labelling. The phosphatidate content of most fractions fell slightly after stimulation, but amounts of other phospholipids were not affected.     

Calcium-activated hydrolysis of phosphatidyl-myo-inositol 4-phosphate and phosphatidyl-myo-inositol 4,5-bisphosphate in guinea-pig synaptosomes

1. Addition of the bivalent ionophore A23187 to synaptosomes isolated from guinea-pig brain cortex and labelled with [(32)P]phosphate in vitro or in vivo caused a marked loss of radioactivity from phosphatidyl-myo-inositol 4-phosphate (diphosphoinositide) and phosphatidyl-myo-inositol 4,5-bisphosphate (triphosphoinositide) and stimulated labelling of phosphatidate. No change occurred in the labelling of other phospholipids. 2. In conditions that minimized changes in internal Mg(2+) concentrations, the effect of ionophore A23187 on labelling of synaptosomal di- and tri-phosphoinositide was dependent on Ca(2+) and was apparent at Ca(2+) concentrations in the medium as low as 10(-5)m. 3. An increase in internal Mg(2+) concentration stimulated incorporation of [(32)P]phosphate into di- and tri-phosphoinositide, whereas lowering internal Mg(2+) decreased labelling. 4. Increased labelling of phosphatidate was independent of medium Mg(2+) concentration and apparently only partly dependent on medium Ca(2+) concentration. 5. The loss of label from di- and tri-phosphoinositide caused by ionophore A23187 was accompanied by losses in the amounts of both lipids. 6. Addition of excess of EGTA to synaptosomes treated with ionophore A23187 in the presence of Ca(2+) caused a rapid resynthesis of di- and tri-phosphoinositide and a further stimulation of phosphatidate labelling. 7. Addition of ionophore A23187 to synaptosomes labelled in vivo with [(3)H]inositol caused a significant loss of label from di- and tri-phosphoinositide, but not from phosphatidylinositol. There was a considerable rise in labelling of inositol diphosphate, a small increase in that of inositol phosphate, but no significant production of inositol triphosphate. 8. (32)P-labelled di- and tri-phosphoinositides appeared to be located in the synaptosomal plasma membrane. 9. The results indicate that increased Ca(2+) influx into synaptosomes markedly activates triphosphoinositide phosphatase and diphosphoinositide phosphodiesterase, but has little or no effect on phosphatidylinositol phosphodiesterase.     

The incorporation of radioactive fatty acids and of radioactive derivatives of glucose into the phospholipids of subsynaptosomal fractions of cerebral cortex.

1. Crude synaptosomal fractions (P2) from guinea-pig cerebral cortex were incubated in a Krebs-glucose medium containing labelled fatty acids and [3H]glucose. After the shortest incubation period (7.5 min) a high percentage (50-80%) of the total radioactive fatty acids was found in the P2 fractions. 2. After the incubation, the synaptosomal fractions were submitted to hypo-osmotic disruption and subsynaptosomal fractionation was carried out by using discontinuous-sucrose-gradient centrifugation. The specific radioactivities of phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and phosphatidylinositol were determined in fractions D (synaptic vesicles), E (microsomal preparation) and H (disrupted synaptosomes), as were the specific activities of a number of marker enzymes and the distribution of acetylcholine. 3. By using [14C]oleate, [14C]arachidonate, [3H]palmitate and [3H]glucose, the order to specific radioactivities in fraction D was found to be: phosphatidylinositol greater than phosphatidylcholine greater than phosphatidylserine greater than phosphatidylethanolamine. 4. The specific radioactivities of phosphatidylcholine and phosphatidylethanolamine were always higher in fraction D than in fraction E. As fraction E had higher specific activities of several membrane marker enzymes, the enhanced labelling found in fraction D was considered to be localized in the synaptic vesicles. In this fraction, phosphatidylinositol made particularly large contributions to the total phospholipid labelling derived from [14C]arachidonate and [3H]glucose. 5. The similar labelling ratios of fatty acid/glucose in the phospholipids of fractions D and E, and the high specific radioactivities in the total phospholipid of the soluble fraction O, suggested intrasynaptosomal phospholipid transport.     

METABOLISM OF THE PHOSPHOINOSITIDES IN GUINEA-PIG BRAIN SYNAPTOSOMES

Abstract— The subcellular distribution of a number of enzymes concerned with inositol lipid metabolism has been studied in sub-fractions of disrupted guinea-pig brain synaptosomes. The enzymes were CDP-diglyceride: inositol phosphatidate transferase, phospha-tidylinositol kinase, diphosphoinositide kinase, diphosphoinositide phosphomonoesterase and diphosphoinositide diesterase. The distribution of phosphatidylinositol kinase in sub-fractions from water-treated synaptosomes was compared with that of other plasma membrane enzymes. After partial solubilization of synaptosomes by Triton X-100 the activities of phosphatidylinositol kinase and several other enzymes were examined.
Distribution of phosphatidylinositol kinase closely resembled that of acetylcholinesterase in sub-fractions of synaptosomes. Both enzymes appeared to be localised in the outer membrane of the synaptosome. CDP-diglyceride: inositol phosphatidate transferase was present in all types of synaptosomal membrane. All three enzymes concerned with diphosphoinositide metabolism were found in the cytoplasm of the synaptosome.     

INCORPORATION OF AMINO ACIDS INTO PROTEINS IN NEURONAL AND NEUROPIL FRACTIONS OF RAT CEREBRAL CORTEX: PRESENCE OF A RAPIDLY LABELLING NEURONAL FRACTION

Abstract— The time course of incorporation of intraperitoneally injected [³H]lysine and [¹⁴C]phenylalanine into neuronal and neuropil proteins has been followed for up to 8 days. At short times after injection (<2 h) the specific activity of the neuronal fraction was higher than that of the neuropil. At longer time intervals, although the total brain specific activity continued to rise, neuronal perikaryal specific activity fell below that of neuropil. Thus the neuronal/neuropil incorporation ratio with [³H]lysine as substrate was 1·5 at 1 h, but by 4 h had fallen to 0·4, a ratio which was maintained for up to 8 days. A similar reversal occurred with phenylalanine as substrate. These changes were interpreted as evidence for the presence of a rapidly-labelling protein fraction in the neurons which is subsequently transported out. Subcellular fractionation showed that over the 4 h period the rapidly labelling fraction was not transported to the synaptosomes. Incubation of prelabelled cortex slices followed by cell fractionation showed that a differential transport of protein of higher than average specific activity from both neurons and neuropil fractions occurred; there is a tendency for preformed highly labelled protein to accumulate during the in vitro incubation in Fraction D, a pellet enriched in red cells, some large neuronal perikarya and cell nuclei. When cell fractions were prepared after in vitro incubation, the distribution of the material down the gradient differed from that when fresh tissue was fractionated, as demonstrated by microscopic examination and the distribution of β-galactosidase, a neuronal marker. Double-label experiments showed that this redistribution could not account for the preferential loss and accumulation of prelabelled protein. It was noted that in vivo incorporation into the rapidly labelling neuronal protein is suppressed under certain changed environmental conditions, such as dark rearing. This is interpreted as lending support to the concept of the state-dependence of neuronal and neuropil protein synthesis and their inter-relations.     

The CMP-stimulated production of diacylglycerol and CDPdiacylglycerol in neuronal nuclei labelled with radioactive arachidonate

A neuronal nuclear fraction (N1), isolated from immature rabbit cerebral cortex, was preincubated with [3H]arachidonate, ATP, CoA, Mg2+ and 1-acyl-sn-glycero-3-phosphocholine or 1-acyl-sn-glycero-3-phosphoinositol. Using the former lysophospholipid, a sizeable incorporation of radioactivity was seen in N1 phosphatidylcholine. In subsequent incubations in the presence of CMP and EGTA, there was a generation of radioactive diacylglycerol in N1 and a corresponding decline in phosphatidylcholine radioactivity. Both these changes could be blocked by the addition of CDPcholine. In incubations using N1 phosphatidylinositol or phosphatidylethanolamine prelabelled with [3H]arachidonate, no evidence was found to support a direct generation of diacylglycerol from these phospholipids. The back reaction of cholinephosphotransferase in N1 is likely the principal source of diacylglycerols bearing arachidonate. Using either lysophospholipid in the preincubations described in the opening sentence, more than half of the incorporated radioactivity derived from [3H]arachidonate was found in N1 phosphatidylinositol. In subsequent incubations with EGTA and CMP there was a production of radioactive CDPdiacylglycerol and a decline in radioactive phosphatidylinositol. Both events could be blocked by the presence of myo-inositol. Radioactive CDPdiacylglycerol, produced in N1 in the presence of CMP and EGTA, was converted back into phosphatidylinositol by the addition of myo-inositol. The production of CDPdiacylglycerol is likely the result of the back reaction of CDPdiacylglycerol:inositol phosphatidate transferase in N1.     

SYNTHESIS OF RNA IN DEVELOPING RAT BRAIN IN VITRO

—Incorporation of [8-¹⁴C]adenine into a rapidly-labelled fraction of RNA derived from the nucleus, and into a cytoplasmic RNA of high molecular weight was studied in brain slices from new born rats. The kinetic behaviour of the two fractions of RNA was compatible with a precursor-product relationship between them. The change in the specific activity of adenine and the reduction of radioactivity in prelabelled RNA of brain slices in the presence of actinomycin D, suggest that the observed degradation of nuclear RNA is not due to random changes, but is limited to a relatively small fraction, presumably messenger RNA.     

THE SUBCELLULAR LOCALIZATION OF CARBAMYLCHOLINE-STIMULATED PHOSPHATIDYL INOSITOL TURNOVER IN RAT CEREBRAL CORTEX IN VIVO

Abstract— The intraventricular injection of 40 μCi of ³²P_i (carrier free) into adult rats resulted in maximum incorporation of ³²P_i into the phosphatidyl inositol of the whole cortex after 20 h. A further intraventricular injection of 2 nmol carbamylcholine plus 0.02 nmol eserine resulted in a 23% decrease in the specific activity of phosphatidyl inositol after 20 min. The specific radioactivities of phosphatidyl choline, phosphatidyl ethanolarmine and phosphatidyl serine were not changed. Cerebral cortex from rats treated in this way was subjected to an extensive subcellular fractionation. It was found that the specific radioactivity of the phosphatidyl inositol of the synaptic vesicle fraction showed a reduction of 60%. No other fractions showed effects of this magnitude.     

Incorporation of [32P]orthophosphate into brain-slice phospholipids and their precursors. Effects of electrical stimulation

1. The incorporation of [(32)P]phosphate into phospholipids was measured in slices cut from the pial surface of guinea-pig cerebral cortex; incorporation into the phosphorus of some water-soluble precursors of phospholipid was measured under similar conditions. 2. Slices subjected to overall electrical stimulation at a frequency of 5pulses/sec. differed from control slices in their pattern of phospholipid labelling. After 1hr. of stimulation, incorporation of [(32)P]phosphate into phosphatidylcholine, ethanolamine phospholipid and cardiolipin was respectively 54, 55 and 58% of the control value, and that into phosphatidylinositol was 186% of control. Phosphatidic acid labelling tended to increase with electrical stimulation, but the statistical significance of this change was marginal. Labelling of phosphatidylglycerol and di- and tri-phosphoinositides was not affected significantly by electrical stimulation. 3. Electrical stimulation of the tissue altered the specific radioactivities of water-soluble precursors of phospholipid. 4. The turnover rates of the phosphate groups of phospholipids were estimated approximately from the specific radioactivities of phospholipids and their precursors. Phosphatidylinositol (and its lipid-soluble precursors) showed the largest change in turnover rate in response to electrical stimulation of the tissue; the turnover rates of other lipids were also affected. Changes in the specific radioactivity of phospholipids did not correspond to changes in turnover in these experiments.     

Tight coupling of thrombin-induced acid hydrolase secretion and phosphatidate synthesis to receptor occupancy in human platelets.

Human platelets incubated with [32P]Pi and [3H]arachidonate were transferred to a Pi-free Tyrode's solution by gel filtration. The labile phosphoryl groups of ATP and ADP as well as Pi in the metabolic pool of these platelets had equal specific radioactivity which was identical to that of[32P]phosphatidate formed during treatment of the cells with thrombin for 5 min. Therefore, the 32P radioactivity of phosphatidate was a true, relative measure for its mass. The thrombin-induced formation of[32P]-phosphatidate had the same time course and dose-response relationships as the concurrent secretion of acid hydrolases. 125I-alpha-Thrombin bound maximally to the platelets within 13s and was rapidly dissociated from the cells by hirudin; readdition of excess 125I-alpha-thrombin caused rapid rebinding of radioligand. This binding-dissociation-rebinding sequence was paralleled by a concerted start-stop-restart of phosphatidate formation and acid hydrolase secretion. [3H]Phosphatidylinositol disappearance was initiated upon binding but little affected by thrombin dissociation and rebinding. ATP deprivation caused similar changes in the time courses for [32P]-phosphatidate formation and acid hydrolase secretion which were different from those of [3H]phosphatidylinositol disappearance. The metabolic stress did not alter the magnitude (15%) of the initial decrease in phosphatidylinositol-4,5-bis[32P]phosphate, but did abolish the subsequent increase of phosphatidylinositol-4,5-bis[32P]-phosphate in the thrombin-treated platelets. It is concluded that in thrombin-treated platelets (1) phosphatidate synthesis, but not phosphatidylinositol disappearance, is tightly coupled to receptor occupancy and acid hydrolase secretion in platelets, (2) successive phosphorylations to phosphatidylinositol-4,5-bisphosphate is unlikely to be the main mechanism for phosphatidylinositol disappearance, and (3) only a small fraction (15%) of phosphatidylinositol-4,5-bisphosphate is susceptible to hydrolysis.     

THE ORIGIN OF THE ACETYLCHOLINE RELEASED FROM THE SURFACE OF THE CORTEX

—The specific radioactivity of acetylcholine liberated from the surface of the rabbit occipital cortex has been compared with that of the underlying cortical synaptosomal and vesicular acetylcholine at varying times after the administration of [N-Me-³H]choline. Choline was administered by diffusion from solutions placed in cups formed by Perspex cylinders applied to the surface of the cortex. Acetylcholine was collected by diffusion into these cups. The specific radioactivity of the acetylcholine declined progressively. The effect of stimulation of afferent cholinergic pathways was to cause a fall in the specific radioactivity of the released acetylcholine. However this was always higher than that of the synaptosomal or vesicular acetylcholine as represented by fractions P₂ and D of the authors’fractionation scheme. It is concluded that acetylcholine released from the cortex must come from a store or stores more recently synthesized than the endogenous acetylcholine of these subcellular fractions.     

THE SITE OF SYNTHESIS OF GANGLIOSIDES IN THE CHICK OPTIC SYSTEM

Abstract– In the retinas of 1-day-old chickens that received an intraocular injection of N-[³H]acetylmannosamine the labelling of N-acetylneuraminic acid and CMP-N-acetylneuraminic acid increased for at least 8 h and that of gangliosides for at least 24 h after injection. In the optic tectum contralateral to the injected eye at 8 h after the intraocular injection, the labelling of gangliosides exceeded the labelling of gangliosides in the ipsilateral tectum by approx 20-fold. In the contralateral tectum the highest concentration of labelled gangliosides was in subfractions enriched in synaptosomes and synaptic plasma membranes. No significant contralateral ipsilateral differences were found in the acid soluble substances of the tectum. In the optic tectum, labelled gangliosides appeared earlier in the neuronal perikarya than in synaptosomes when the injection was intracranial. Conversely, when the injection was intraocular the labelling appeared earlier in the synaptosomes than in the neuronal perikarya. The radioactivity pattern of the optic tectum gangliosides resembled the pattern of retina gangliosides when N-[³H]acetylmannosamine was injected intraocularly, but when N-[³H]acetylmannosamine was given intracerebrally the radioactivity pattern resembled that of optic tectum gangliosides. Intraocular injection of colchicine or vinblastine did not affect the labelling of retinal gangliosides from N-[³H]acetylmannosamine injected into the same eye but prevented the appearance of labelled gangliosides in the optic tectum. In vitro the ganglioside glycosylating activity of optic tectum synaptosomes and synaptic plasma membranes was between 6 and 10-fold lower than that found in the optic tectum neuronal perikarya. These findings support the notion that the main subcellular site of synthesis of neuronal gangliosides is in the neuronal perikarya, from which they are translocated to the nerve endings.     

EFFECTS OF ACETYLCHOLINE ON THE INCORPORATION OF [32P]ORTHOPHOSPHATE IN VITRO INTO THE PHOSPHOLIPIDS OF NERVE-ENDING PARTICLES FROM GUINEA PIG BRAIN

Abstract— Guinea pig brain nerve-ending particles (synaptosomes) were incubated with [³²P]orthophosphate in a medium with or without 10⁻⁴M-acetylcholine and 10⁻⁴ M-eserine. Phospholipids were then extracted and separated by chromatography. About 60 per cent of the ³²P was found in phosphatidic acid and about 20 per cent in triphosphoinositide. Acetylcholine significantly increased the specific radioactivity of phosphatidic acid but had no effect on that of phosphatidylinositol or the nucleotide fraction. Labelling of the other phospholipids, including diphosphoinositide and triphosphoinositide, was not altered significantly by acetylcholine. Labelling of the nucleotide fraction and the polyphosphoinositides reached a peak at 40 min, that of phosphatidic acid at 80 min, while that of phosphatidylinositol was still rising at 160 min.     

EFFECTS OF ACETYLCHOLINE ON THE IN CORPORATION OF [32P]ORTHOPHOSPHATE IN VITRO INTO THE PHOSPHOLIPIDS OF SUBSYNAPTOSOMAL MEMBRANES FROM GUINEA-PIG BRAIN

-Synaptosomes prepared from guinea-pig cerebral cortex were incubated with ³²P₁ in a medium with or without 10^?4 M-acetylcholine and 10^?4 M-eserine. They were then subjected to osmotic shock and density-gradient centrifugation for the preparation of subsynaptosomal fractions and the phospholipids of each fraction were separated by two-dimensional thin-layer chromatography. The fraction containing synaptic vesicles and that containing mitochondria were the most highly labelled of the sub-synaptosomal fractions. Phosphatidic acid followed by phosphatidylinositol had the highest specific activity of the phospholipids studied. Acetylcholine caused a marked increase in the specific activity of the vesicular but not of the mitochondrial phosphatidic acid. Phosphatidylinositol specific activity also increased in the presence of acetylcholine but the increase was more reproducible in the fraction containing microsomal membranes than in the vesicle fraction. The other phospholipids were relatively poorly labelled and no effect of acetylcholine on the incorporation of ³²P₁ into these lipids could be detected. Acetylcholine also caused a decrease in the amount of phosphatidic acid in the synaptic vesicles.     

Activation of phospholipase C and prostaglandin synthesis by [arginine]vasopressin in cultures.

[Arginine]vasopressin (AVP) stimulates maximal prostaglandin E2 production in cultured rat renal mesangial cells within 2 min. As early as 10s after addition of AVP (10(-6)M) a significant loss of radioactivity from phosphatidylinositol 4,5-bisphosphate but not from phosphatidylinositol 4-phosphate and phosphatidylinositol was observed in cells prelabelled with 32Pi. Cells labelled with [14C]arachidonic acid showed an increase of label in 1,2-diacylglycerol after 15 s and in phosphatidic acid after 30 s upon stimulation with AVP. Pretreatment of the cells with indomethacin (10(-5)M) did not abolish the effect of AVP on the increased labelling of phosphatidic acid.