Phospholipids in synaptic function

Calcium-dependent turnover of brain polyphosphoinositides in vitro after prelabelling in vivo

Rat brain phospholipids were labelled in vivo by an intraventricular injection of 32P. The radioactivity was found to accumulate predominantly in limbic structures, particularly hippocampus and diencephalon. A rapid and high specific labelling of the inositol phospholipids and phosphatidic acid was observed. The rate of incorporation into a crude myelin fraction was similar to that into a mitochondrial/synaptosomal fraction although phosphatidyl-myo-inositol 4,5-diphosphate was especially enriched in myelin. Upon incubation in vitro high specific labelling of the inositol phospholipids and phosphatidic acid was observed. The rate of incorporation into a crude myelin fraction was similar to that into a mitochondrial/synaptosomal fraction although phosphatidyl-myo-inositol 4,5-diphosphate was especially enriched in myelin. Upon incubation in vitro high specific labelling of the inositol phospholipids and phosphatidic acid was observed. The rate of incorporation into a crude myelin fraction was similar to that into a mitochondrial/synaptosomal fraction although phosphatidyl-myo-inositol 4,5-diphosphate was especially enriched in myelin. Upon incubation in vitro of the brain fraction after 2 h prelabelling in vivo, both phosphatidyl-myo-inositol 4-phosphate and phosphatidyl-myo-inositol 4,5-diphosphate rapidly lost their radioactivity. Half of the labile fraction of the incorporated 32P was removed within 2 min. None of the other phospholipids changed in the 30 min in vitro incubation period. The metabolism of the polyphosphoinositide proceeded at a lower rate when the temperature was lowered, and was Ca2+-dependent. Further subcellular fractionation revealed that purified synaptosomes and myelin contained highly labelled phosphatidyl-myo-inositol 4-phosphate or phosphatidyl-myo-inositol 4,5-diphosphate. Mitochondria contained highly labelled phosphatidyl-myo-inositol but no phosphatidyl-myo-inositol 4-phosphate or phosphatidyl-myo-inositol 4,5-diphosphate. ACTH1-24 did not inhibit the in vitro dephosphorylation of prelabelled polyphosphoinositide, confirming previous findings that the peptide affects the polyphosphoinositide kinases and not the respective phosphatases.

Detergent solubilization and hydrophobic chromatography of rat brain phosphatidylinositol kinase

Rat brain microsomal phosphatidylinositol kinase activity was maximally activated in the presence of either 3 mM sodium deoxycholate, 2% Triton-X-100, or 30-40 mM octylglucoside. Among these detergents, 1% Triton-X-100 was most effective in solubilizing the enzyme, and after treatment with this agent, 100% of the activity was recovered in the high speed supernatant. Octylglucoside solubilized 40% of the enzyme at concentrations below its critical micelle concentration of 25 mM and up to 80% at higher levels. Solubilized phosphatidylinositol kinase failed to absorb to adenosine nucleotide affinity resins. However, when the Triton-X-100 extract was chromatographed on an uncharged hydrophobic resin, consisting of dodecyl chains attached to Sepharose 4B by ether bonds, nearly all the enzyme activity was retained, and from 44-85% could be eluted with 8 mM sodium deoxycholate. Solubilization followed by hydrophobic chromatography resulted in several-fold purification of phosphatidylinositol kinase and may have disrupted interactions of the enzyme with other hydrophobic proteins sufficiently to allow its substantial purification by conventional or affinity chromatography techniques.

Light stimulates the incorporation of inositol into phosphatidylinositol in the retina

The incorporation of [3H]inositol into phosphatidylinositol in retinas of Xenopus laevis tadpoles or young adults in short-term organ culture is stimulated by light, compared to retinas maintained under identical conditions in darkness. Over 95% of the label incorporated into lipid was in phosphatidylinositol, and none was incorporated into retinal proteins. The stimulation of incorporation was localized by autoradiography to the outer plexiform layer, a neurophil composed primarily of horizontal cell processes.

Degradation of phosphatidylinositol by soluble enzymes of rat gastric mucosa

Rat gastric mucosa homogenates contain two enzymatic systems for hydrolyzing phosphatidylinositol: a deacylation activity yielding lysophosphatidylinositol and free fatty acid, and a phospholipase C-like activity producing 1,2-diacylglycerol and inositol phosphates. These activities were found mainly in the 105 000 x g supernatant and could be distinguished by differential stabilities, metal requirements and the action of deoxycholate and mepacrine. Each lipolytic reaction displayed a major pH optimum at 7.5 and a minor pH optimum at 5.5. The deacylation system was 8-10 times as active as the phospholipase C, with an apparent Km of 0.63 mM towards 1-acyl-2-arachidonylphosphatidylinositol at pH 7.5. The phospholipase C activity, on the other hand, hydrolyzed 1-acyl-2-arachidonylphosphatidylinositol or 1-acyl-2-arachidonylphosphatidylethanolamine and yielded 1-acyl-2-arachidonyl-sn-glycerol. This 1,2-diacylglycerol could be phosphorylated to form 1-acyl-2-[14C]arachidonyl-sn-phosphoglycerol (phosphatidic acid), but could not be hydrolyzed to produce free [14C]arachidonic acid using stomach mucosal microsomes. Phospholipase A2 and phospholipase C attack 1-acyl-2-arachidonylphosphatidylethanolamine and phosphatidylinositol equally well, but hydrolyze 1-acyl-2-arachidonylphosphatidylcholine poorly.

Effects of changes in calcium concentration on basal and stimulated 32P incorporation into phospholipids in rat pineal cells

The Ca2+ requirement for alpha-agonist stimulation of 32P incorporation into acidic phospholipids (the phosphatidylinositol effect) of dispersed pineal cells was evaluated by means of several different compounds that interfere with Ca2+ disposition. Simple omission of Ca2+ led to slight increases in basal and norepinephrine-stimulated phosphatidyl-CMP (CDP-diacylglycerol) and phosphatidylglycerol labeling without affecting phosphatidylinositol labeling. In the absence of Ca2+, EGTA (200 microM) or the ionophore for divalent cations A23187 (10 microM) elicited large increases in phosphatidic acid, phosphatidyl-CMP, and phosphatidylglycerol labeling while strongly inhibiting the phosphatidylinositol effect. The Ca2+ translocation inhibitor LaCl3 also reduced the magnitude of this effect. The phosphatidylinositol effect is, however, not induced by increased Ca2+ entry into the cytosol, since A23187 did not mimic the effect of norepinephrine. Under conditions where membrane Ca2+ was lowered, the addition of 1 mM-inositol greatly reduced phosphatidic acid, phosphatidylglycerol, and phosphatidyl-CMP labeling with concomitant increases in basal and norepinephrine-stimulated phosphatidylinositol labeling approaching that observed in the presence of norepinephrine and 2.5 mM-Ca2+. In the presence of 2.5 mM-Ca2+, inositol had negligible effects on phosphatidylinositol labeling. It was concluded that changes in membrane Ca2+ availability and/or disposition alter phospholipid metabolism and concurrently reduce the magnitude of the phosphatidylinositol effect, perhaps by making the pool of readily available inositol in pinealocytes rate-limiting.

Muscarinic receptors in chromaffin cell cultures mediate enhanced phospholipid labeling but not catecholamine secretion

The addition of either carbachol or muscarinic agonists to cultured bovine adrenal chromaffin cells results in a selective stimulation of phosphatidate (PhA) and phosphatidylinositol (PhI) labeling from 32Pi and [3H]glycerol that can be inhibited by the inclusion of atropine, but not d-tubocurarine. In contrast, increased catecholamine secretion is observed on the addition of carbachol or nicotinic agonists and is inhibited by d-tubocurarine but not by atropine. Added calcium is essential for catecholamine secretion but not for stimulated phospholipid labeling. Chelation of endogenous Ca2+ with EGTA does, however, inhibit the stimulated phospholipid labeling. These results suggest that stimulated phospholipid labeling in the bovine chromaffin cell and catecholamine secretion are separate and distinct processes.

Phosphatidate as a molecular link between depolarization and neurotransmitter release in the brain

Phosphatidate, a neuronal phospholipid, stimulated the uptake of calcium by nerve terminals isolated from the striatum of rat brain. This effect was not produced by other phospholipids or glycolipids. Phosphatidate, but not other phospholipids, evoked the release of [3H] dopamine from striatal synaptosomes. The magnitude of both effects was similar to that observed after chemical depolarization of the nerve terminals. These results show that phosphatidate is the only membrane lipid component that acts as a functionally competent ionophore and support the suggestion that phosphatidate may serve as a link between depolarization and neurotransmitter release in the brain.

Evidence that lithium alters phosphoinositide metabolism: chronic administration elevates primarily D-myo-inositol-1-phosphate in cerebral cortex of the rat

The administration of LiCl (3.6 mequiv./kg/day) to adult male rats for 9 days results in an increase in the cerebral cortex level of myo-inositol-1-phosphate (M1P) to 4.43 +/- 0.52 mmol/kg (dry weight) compared with a control level of 0.24 +/- 0.02 mmol/kg. This establishes that the previously observed acute effect of lithium on M1P (Allison et al., 1976) is both prolonged and augmented by repeated doses of lithium. Larger doses of LiCl over a 3-5 day period result in even larger increases in M1P and a 35% decrease in myo-inositol. In each case, 90% of the increase is due to the D-enantiomer, evidence that lithium is largely producing this effect via phospholipase C-mediated phosphoinositide metabolism. Data are presented showing that lithium is an uncompetitive inhibitor of the hydrolysis of both D- and L-M1P by M1P'ase.

Effects of polyamines on calcium-dependent rat brain phosphatidylinositol-phosphodiesterase

The effect of polyamines on the ability of calcium-dependent soluble rat brain phosphatidylinositol-phosphodiesterase to hydrolyze dispersed phosphatidylinositol was examined. Putrescine and cadaverine stimulated activity at all concentrations tested. In contrast, spermine and spermidine stimulated the reaction slightly at low concentrations but caused progressively greater inhibition as their levels were further increased. Phosphatidylinositol hydrolysis was inhibited by several multivalent cations, especially lanthanum and manganese. Spermidine partially replaced the calcium requirement of the enzyme. The possibility that polyamines may play a role in the regulation in vivo of phosphatidylinositol-phosphodiesterase is discussed.

Myo-inositol turnover in the intact rat brain: increased production after d-amphetamine

Apparent turnover of myo-inositol in the brain of urethane-anesthetized rats was estimated in vivo from the rate of appearance of endogenous myo-inositol in the cerebroventricular compartment. Ventricular-cisternal perfusion technique combined with isotope dilution of [14C]myo-inositol was used to determine the rate of appearance of brain-produced myo-inositol and its modification by d-amphetamine. A mean value of 0.75 nmol/min was obtained for the rate of appearance in the cerebroventricular system. A dose-dependent increase in this rate was seen after the administration of d-amphetamine. The endogenous removal of myo-inositol from the perfusate was also studied and found to be mediated in part by a saturable transport system that was not influenced by d-amphetamine. The rate of entry of myo-inositol from blood to the cerebroventricular system was very low and accounted for only 2% of the total rate of appearance, indicating that the majority of myo-inositol in the rat cerebroventricular fluid originates in the brain.

Properties of a CDP-diglyceride hydrolase from guinea pig brain

Enzymatic hydrolysis of the pyrophosphate bond of CDP-diglyceride (CDP-DG), previously shown to occur in bacteria, is demonstrable in mammalian tissues. Activity was enriched in a lysosomal fraction obtained from guinea pig cerebral cortex and was purified 92-fold relative to the homogenate by a combination of XM-300 ultrafiltration and DEAE-cellulose column chromatography. When incubated with CDP-dipalmitin, the purified enzyme produced stoichiometric amounts of CMP and phosphatidate. dCDP-DG served as a substrate, while ADP-DG was an inhibitor, as were 5'-AMP and 5'-dAMP. CDP-DG hydrolysis was not affected by the presence of excess amounts of CDP-choline, CDP-glycerol, sodium pyrophosphate, or cyclic 3',5'-AMP.

Degradation of arachidonoyl-labeled phosphatidylinositols by brain synaptosomes

Incubation of synaptosomes together with 1-acyl-2-[14C]arachidonoyl-sn-glycerophosphoinositols (GPI) and sodium deoxycholate yielded diacylglycerols and free arachidonic acid. Diacylglycerol formation is attributed to hydrolysis by the diacyl-GPI-specific phospholipase C (EC 3.1.4.10), and this reaction requires sodium deoxycholate for optimal activity. The free arachidonic acid formed is attributed to hydrolysis of diacyl-GPI by phospholipase A (EC 3.1.1.5). Free fatty acid release was observed during incubation, even in the absence of bile salts, but this process was preferentially stimulated by sodium taurocholate. The release of fatty acids was not specific for diacyl-GPI, as similar release was obtained during incubation with other phosphoglycerides. In the presence of deoxycholate (2 mg/ml), the release of diacylglycerols was maximal at a diacyl-GPI concentration around 1.0 mM. However, the free fatty acid release was linear with respect to the substrate at least up to 1.4 mM. The rate of diacylglycerol release from diacyl-GPI was more rapid in the initial 30 min, whereas the free fatty acid release was linear with time up to 2 h. Under this incubation condition, calcium was found to stimulate both types of hydrolytic action, although the concentration needed to achieve this stimulation was rather high. This type of labeled precursor is potentially useful for studies of the different modes of diacyl-GPI degradation by enzymes in brain subcellular membranes.

Lipids of synaptic vesicles: relevance to the mechanism of membrane fusion

Synaptic vesicles from the electric organ of the marine ray Narcine brasiliensis, purified to at least 90% homogeneity, were analyzed for the lipid and fatty acid content of their membranes. The major lipids (mol %) were phosphatidylcholine (32.3%), phosphatidylethanolamine (20.5%), phosphatidylserine (6.1%), sphingomyelin (3.0%), and cholesterol (33.3%), a composition which did not differ greatly from that of the parent electric organ. While the number of double bonds per fatty acid molecule was similar for both synaptic vesicle and whole electric organ phospholipids, the vesicles were highly enriched in docosahexenoic acid (22:6). Reaction with the amine labeling reagents isethionylacetimidate and trinitrobenzenesulfonic acid indicated that 40% of the phosphatidylserine and 60% of the phosphatidylethanolamine are present on the external (cytoplasmic) surface of the synaptic vesicle. These data on a natural fusing membrane have relevance to models of membrane fusion, which have been based largely on studies of in vitro fusion using synthetic membranes.

Corticotropin-(1--24)-tetracosapeptide affects protein phosphorylation and polyphosphoinositide metabolism in rat brain

1. Effects of corticotropin-(1--24)-tetracosapeptide on the endogenous phosphorylation of proteins and lipids were studied in a membrane/cytosol fraction prepared from a lysed crude mitochondrial/synaptosomal fraction. 2. The labelling of proteins and lipids was monitored by incubation of the subcellular fraction for 10s with [gamma-32P]ATP. 3. The phosphorylation of proteins was dose-dependently inhibited by the peptide (40% of control incubations at 100 microM-corticotropin). 4. Of the membrane phospholipids only phosphatidylinositol phosphate, phosphatidylinositol bisphosphate and phosphatidic acid became labelled. Corticotropin dose-dependently increased the formation of phosphatidylinositol bisphosphate and inhibited the production of phosphatidic acid (470% and 50% respectively of control incubations, at 100 microM of the peptide) and had no effect on phosphatidylinositol phosphate. 5. Phosphatase activity was observed to act on phosphatidylinositol bisphosphate, phosphatidylinositol phosphate and phosphoprotein but not on phosphatidic acid. 6. Corticotropin interacted with the kinases rather than with the phosphatases. 7. The formation of phosphatidylinositol bisphosphate and phosphatidic acid was maximal at 1--10mM-Mg2+ in the absence of Ca2+, and the production of phosphatidylinositol phosphate was maximal at 30mM-Mg2+. 8. The basal value of lipid phosphorylation decreased with increasing Ca2+ concentration. 9. Ca2+ abolished the effect of corticotropin on phosphatidylinositol bisphosphate formation (470%, 190% and 100% of control incubations at respectively 0, 0.1 and 1 mM-Ca2+). 10. The data provide evidence that the effects of corticotropin on protein phosphorylation and on polyphosphoinositide metabolism in brain membranes are related.

Enzymes of phospholipid synthesis: axonal versus Schwann cell distribution

Using quantitative EM autoradiography to localize sites of incorporation of tritiated inositol and choline into mouse sciatic nerve, we observed a substantial axon-based phosphatidylinositol synthesis, but no axonal phosphatidylcholine synthesis. In the present communication we provide biochemical evidence for the axonal transport of CDP-diglyceride:inositol transferase (EC 2.7.8.11), the terminal enzyme in de novo phosphatidylinositol biosynthesis. Axonal transport of 1,2-diacyl-glycerol:CDP-choline choline phosphotransferase (EC 2.7.8.2), required for de novo phosphatidylcholine synthesis, was not apparent in these studies. During subcellular fractionation activities for the synthesis of phosphatidylinositol by inositol transferase (IT) and phosphatidylcholine by choline phosphotransferase (CPT) were recovered in crude microsomal fraction of rat sciatic nerve. However, CPT was much more highly enriched in the microsome fraction than IT, which may be an indication of the different subcellular localizations of these enzymes. Following ligation, we detected localized increases in the activities of both enzymes in 5 (and 3) mm segments taken immediately proximal and distal to the ligature. Both activities increased in a linear fashion in the proximal segments over the ensuing 72 h period. It took about 40 h (IT) and 56 h (CPT) for the activities in the segments proximal to the ligature to double compared to unligated contralateral (control) nerves. The time-dependent accumulation of IT was primarily due to axonal transport, while that of CPT was largely a result of increased enzyme activity in local Schwann cells. Evidence came from double ligation studies, where a proximal ligature, acting to restrict orthograde axonal transport, reduced accumulation in a distal ligature by 80% for IT, but only 28% for CPT. Conversely, blockage of the Schwann cell response with actinomycin D, reduced accumulation of CPT by 83% and IT by only 36%. Finally, light microscopic autoradiography was used to show that in the segment proximal to the ligature, tritiated inositol incorporation into lipid was primarily axonal, whereas that of tritiated choline remained primarily associated with Schwann cells.

Regulation of the immune response by polyamines

Regulation of the immune system is accomplished, in part, by numerous soluble factors and small molecules. One such class of regulatory substances may be the polyamines which are present in a variety of tissues. Stimulation of the immune response often occurs by crosslinking of lymphocyte surface proteins, followed by the production of some transmembrane signal. The activation pathway may be interrupted if certain necessary steps are blocked. It is proposed that polyamines exert regulatory influences by modulating crosslink formation; a step catalyzed by the enzyme transglutaminase. A model is outlined which describes the events initiating lymphocyte activation and the role of polyamines in this process. Certain drugs which might mimic the actions of polyamines are also discussed. During evolution of the control of growth processes in cells, relatively simple molecules (the polyamines) may have assumed a pivotal role in initiating and terminating the proliferative response. This idea has been applied to regulation of the immune system.