Studies on the Carrier Function of Phosphatidic Acid in Sodium Transport : I. The turnover of phosphatidic acid and phosphoinositide in the avian salt gland on stimulation of secretion

Incubation of slices of the salt gland of the albatross with acetylcholine, which is the physiological secretogogue for this tissue, led to a 13-fold increase in the rate of incorporation of P³² into phosphatidic acid and a 3-fold increase in the incorporation of P³² and inositol-2-H³ into phosphoinositide. The incorporation of P³² into phosphatidyl choline and phosphatidyl ethanolamine was increased relatively slightly or not at all. Respiration was doubled. The "phospholipid effect" occurred in the microsome fraction, which is known to contain fragments of the endoplasmic reticulum. The enzymes, diglyceride kinase and phosphatidic acid phosphatase, which catalyze the stimulated turnover of phosphatidic acid in brain cortex, were also found in highest concentration in the microsome fraction. The phosphatides which respond to acetylcholine are bound to protein in the membrane. On the basis of these findings it appears that phosphatidic acid and possibly phosphoinositide participate in sodium transport. A scheme, termed the phosphatidic acid cycle, is presented as a working hypothesis, in which the turnover of phosphatidic acid in the membrane, catalyzed by diglyceride kinase and phosphatidic acid phosphatase, functions as a sodium pump.     

The Effects of Acetylcholine on the Turnover of Phosphatidic Acid and Phosphoinositide in Sympathetic Ganglia, and in Various Parts of the Central Nervous System in Vitro

The effect of acetylcholine on the incorporation of P³² into the individual phosphatides in slices of various structures of the nervous system has been studied. There was a marked stimulation of P³² incorporation into phosphoinositide and phosphatidic acid, but not into phosphatidyl choline and phosphatidyl ethanolamine, in the cat stellate and celiac ganglia in vitro. Acetylcholine stimulated P³² incorporation into certain phosphatides, primarily phosphoinositide and phosphatidic acid, in several structures of the cat and guinea pig brain; there was little or no effect of acetylcholine on phosphatide turnover in the inferior corpora quadrigsemina and cerebellar cortex. The suggestion is made that the phospholipid effect can best be explained as being concerned with the active transport of sodium ions out of the cell across the postsynaptic membrane of cholinergic neurons in response to acetylcholine.     

The relationship between the incorporation of 32P into phosphatidic acid and phosphatidylinositol in rat parotid acinar cells

Muscarinic and α-adrenergic stimulation of rat parotid acinar cells increases the turnover of phosphatidylinositol and phosphatidic acid. It is thought that this is initiated by hydrolysis of phosphatidylinositol, which would predict an increase in ³²P incorporation into phosphatidic acid before phosphatidylinositol. We have demonstrated an increase in ³²P incorporation into the former within 1 minute and into the latter by 2 minutes. The initial rapid rate of ³²P incorporation into phosphatidic acid slows, and the ³²P content reaches a steady state after 15 minutes. During the first 2 minutes after the addition of atropine to carbamylcholine stimulated cells, ³²P is lost from phosphatidic acid, and an equal amount is gained by phosphatidylinositol, after which ³²P incorporation equals that of the control. In cells prelabelled with ³²P, carbamylcholine, in the presence of oligomycin stimulated the loss of ³²P from phosphatidylinositol but had no effect on phosphatidic acid.     

Effects of norepinephrine and acetylcholine on 32P incorporation into phospholipids of the rabbit iris muscle following unilateral superior cervical ganglionectomy.

The effect of norepinephrine and acetylcholine on the ³²P incorporation into phospholipids of normal and sympathetically denervated rabbit iris muscle was investigated. (1) In the absence of exogenously added neurotransmitters sympathetic denervation exerted little effect on the incorporation of ³²P into the phospholipids of the excised iris muscle. $\text{In vivo}$ thr iris muscle incorporated ³²P into phosphatidylinositol, phosphatidic acid, phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and sphingomyelin in that order of activity while $\text{in vitro}$ phosphatidylinositol was followed by phosphatidylcholine. (2) Tension responses of iris dilator muscle from denervated irises exhibited supersensitivity to norepinephrine. Furthermore, norepinephrine at concentrations of 3 μM and 30 μM produced 1.6 times and 3 times stimulation of the phosphatidic acid of the denervated muscle respectively. In contrast at 30 μM it stimulated this phospholipid by 1.6 times in the normal muscle. This stimulation was completely blocked by phentolamine. (3) While in the normal muscle acetylcholine stimulated the labelling of phosphatidic acid and phosphatidylinositol by more than 2 times, in the denervated muscle it only stimulated 1.4 to 1.7 times. (4) Similarly when ³²Pi was administered intracamerally, the labelling found in the various phospholipids of the denervated iris was significantly lower than that of the normal. (5) It was concluded that denervation decreases the ³²P labelling in the presence of acetylcholine. (6) The norepinephrine-stimulated ³²P incorporation into phosphatidic acid appears to be post-synaptic.     

Effects of neurotransmitters and other pharmacological agents on 32Pi incorporation into phospholipids of the iris muscle of the rabbit

The effects of norepinephrine, other catecholamines, α- and β- adrenergic receptor blocking agents and acetylcholine on the incorporation of ³²Pi into phospholipids of the iris muscle of the rabbit were studied $\text{in vitro}$. There was a marked stimulation of ³²Pi into phosphatidic acid (PhA), phosphatidyl inositol (PhI) and to a much lesser extent phosphatidyl choline but not into phosphatidyl ethanolamine. The increase in the ³²P labeling of PhA and PhI in the presence of norepinephrine or acetylcholine, which ranged from 2- to 6-fold, was found to be time- and concerntration-dependent. Under our experimental conditions, several adrenergic drugs, including DL-propranolol, phentolamine, isoproterenol, phenylephrine, but not sotalol, increased markedly (nearly up to 5-fold) the ³²Pi incorporation into PhA and PhI of the iris. In contrast, phenoxybenzamine, an α-receptor blocker, blocked completely the stimulatory effects of norepinephrine on phospholipid synthesis. The stimulation of phospholipid synthesis by acetylcholine was completely abolished by atropine. Incorporation of ³²Pi into PhA and PhI was significantly increased in the presence of serotonin, dopamine, epinephrine or histamine. Addition of γ-aminobutyric acid or cyclic AMP was ineffective. These observations suggest that in the iris muscle of the rabbit, which is innervated by cholinergic and adrenergic fibers, the phospholipid effect is probably a membrane effect that is not associated with synaptic transmission.     

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.     

Effects of dopamine, gamma-aminobutyric acid and 5-hydroxytryptamine on incorporation of 32P into phosphatides in slices from the guinea pig brain

(1) Dopamine–In slices from guinea pig corpus striatum, dopamine significantly inhibited incorporation of ³²P into phosphatidylethanolamine-plus-phosphatidylserine at a concentration of 0001 mM, and into phosphatidylinositol and phosphatidylcholine at 001 mM. In eight areas of the guinea pig brain in which the effects of 01 mM-dopamine were studied, the only significant increase in incorporation of ³²P into phosphatides was into phosphatidic acid in the hypothalamus; there was significant inhibition of incorporation of ³²P into phosphatidylcholine in cerebellar cortex and thalamus, and into phosphatidylethanolamine-plus-phosphatidylserine in the olfactory bulbs. (2) Gamma-aminobutyric acid—In slices of guinea pig cerebral cortex, GABA (1 mM) significantly inhibited incorporation of ³²P into only phosphatidic acid, diphosphoinositide and phosphatidylinositol and did not significantly affect the level or the specific activity of the nucleotide ～P. GABA (10 mM), significantly inhibited incorporation of ³²P into diphosphoinositide, phosphatidylinositol and phosphatidylcholine, and significantly lowered the specific activity of the nucleotide ～P. (3) 5-Hydroxytryptamine—In slices of guinea pig cerebral cortex, 5HT, (1 mM) significantly increased incorporation of ³²P into phosphatidic acid; in a concentration of 10 mM, 5HT increased incorporation of ³²P into phosphatidic acid four-fold and into both diphosphoinositide and phosphatidylinositol two-fold; other phosphatides were not significantly affected and the specific activity of the nucleotide ～P was not significantly different. In eight brain areas studied, 5HT (10 mM) significantly increased incorporation of ³²P into phosphatidic acid in all areas; into phosphatidylinositol in six areas (excepting cerebellar cortex and hypothalamus); and into diphosphoinositide in the olfactory bulbs, cerebral cortex, hypothalamus and corpus striatum. Incorporation of ³²P into triphosphoinositide was not significantly affected in any area. Incorporation of ³²P into phospha-tidylethanolamine-plus-phosphatidylserine was significantly greater than the control in the olfactory bulbs and incorporation of ³²P into phosphatidylcholine was significantly less than the control in the cerebellar cortex, olfactory bulbs and hypothalamus. (4) The possibility is discussed that increased incorporation of ³²P into phosphatidic acid and/or phosphatidylinositol in response to neurotransmitters might be associated with excitatory, but not inhibitory, neurotransmission; and that inhibition of incorporation of ³²P into various phosphatides may be associated with inhibitory neurotransmission or neuromodulation.     

Epidermal growth factor stimulates the incorporation of phosphate into phosphatidic acid and phosphoinositides but does not affect phosphoinositide breakdown by phospholipase C in renal cortical slices

The effects of epidermal growth factor (EGF) on the metabolism of phosphatidic acid and phosphoinositides were examined using renal cortical slices labelled with either sodium [³²P]orthophosphate or myo-[³H]inositol. EGF was found to increase the incorporation of phosphate into phosphatidic acid and phosphoinositides. This effect is not dependent on external calcium and is inhibited by 12-O-tetradecanoylphorbol 13-acetate (TPA). When phospholipids were prelabelled, EGF did not decrease the level of ³²P in phosphatidic acid and phosphoinositides, and EGF did not affect the formation of inositol phosphates or the concentration of cAMP and cGMP in renal tissue. The results show that EGF stimulates the incorporation of phosphate into phosphatidic acid and phosphoinositides, but does not affect breakdown of phosphoinositides by phospholipase C in renal cortical slices.     

Phospholipide Turnover in Microsomal Membranes of the Pancreas during Enzyme Secretion

After incubation of pigeon pancreas slices with P³² and isolation of various fractions by differential centrifugation the deoxycholate extract of the microsome fraction was found to account for over half of the phospholipide P and over half of the P³² incorporated into the phospholipides. The remaining phospholipide P and P³² were fairly evenly distributed in the nuclei, zymogen granules, mitochondria, microsomal ribonucleoprotein particles, and the soluble fraction. When enzyme secretion was stimulated with acetylcholine about two-thirds of the increment in radioactivity in the total phospholipides was found in deoxycholate soluble components of the microsome fraction. The remainder of the increment was distributed in the other fractions. This indicates that the cellular component in which the increase in phospholipide turnover occurs on stimulation of secretion is a membranous structure. Evidence is presented which indicates that the increment in radioactivity in the non-microsomal fractions on stimulation of secretion is due to contamination of these fractions with fragments of the stimulated membranous structure. The distribution of P³² radioactivity in each of the chromatographically separated phospholipides in the various fractions from unstimulated tissue paralleled the distribution of radioactivity in the total phospholipide fraction, indicating that individual phospholipides are not concentrated in different fractions but are associated together in the membranous structures of the microsome fraction. The major proportion of the stimulation of the turnover of the individual phospholipides also occurred in the microsome fraction. The distribution of radioactivity from glycerol-1-C¹⁴ in the total phospholipides and in the individual phospholipides in the various fractions was similar to the distribution of P³². In the microsome fraction acetylcholine stimulated the incorporation of glycerol-1-C¹⁴ in each phospholipide which showed a stimulation of P³² incorporation. The significance of the turnover of phosphatides in microsomal membranes in relation to the mechanism of secretion is discussed.     

Studies on the metabolism of ATP by isolated bacterial membranes: solubilization and phosphorylation of a protein component of the diglyceride kinase system

A soluble fraction, obtained by extracting E. coli cytoplasmic membrane vesicles with water, transfers radioactivity from [γ-³²P]ATP to a protein present in this soluble fraction. The formation of the [³²P]phosphoprotein appears to be reversible. Thus the protein can transfer its ³²P to ADP to form [³²P]ATP, and the phosphate on the protein can exchange with the phosphate of ATP. Preliminary evidence indicates that the phosphate moiety is linked to a histidine residue of the protein. The Mn²⁺ and ATP dependencies of [³²P]phosphoprotein formation are almost identical to the diglyceride kinase reaction previously reported in intact membrane vesicles. Although indirect evidence supports the involvement of the phosphoprotein in the diglyceride kinase reaction, the soluble fraction catalyzes only a slow formation of [³²P]phosphatidie acid from [γ-³²P]ATP and α,β-diglyceride.     

Effect of neurotransmitters on phospholipid metabolism in rat cerebral-cortex slices: cellular and subcellular distribution

Abstract— Young rat cerebral-cortex slices were incubated with ³²Pi in the absence and presence of ACh plus eserine, norepinephrine, dopamine or serotonin for 1 h. their cellular and subcellular fractions were isolated, and the specific radioactivities of the various phospholipids determined. In the neuronal- and astroglial-enriched fractions ACh plus eserine increased the ³²P-labelling of phosphatidyl inositol (PhI) phosphatidic acid (PhA) and phosphatidylcholine (PhC) by increments which ranged from 108 per cent for PhI to 30 per cent for PhC and in the presence of norepinephrine or dopamine these increments ranged from 180 per cent for PhI to 29 per cent for PhC. In the subcellular fractions ACh plus eserine exerted maximal stimulatory effect on the labelling of the synaptosomal phospholipids, which was 88 per cent for PhI and 79 per cent for PhA, followed by those of microsomes, mitochondria and nuclei. ACh plus eserine exerted no effect on [^l4C]glucose incorporation, but inhibited the incorporation of [¹⁴C]glycerol into phospholipids by amounts which ranged from 30 per cent for PhI to 3 per cent for PhE. Although the rate of incorporation of ³²Pi into phospholipids of 0.2 mm slices was higher than that of the 0.5 mm slices the stimulatory effect of ACh plus eserine on the ³²Pi incorporation into the lipids of the latter was higher. When neuronal- and astroglial enriched fractions were first isolated from the cerebra then incubated with ³²Pi or [¹⁴C]choline, labelling of phospholipids in the neuronal fraction was higher than that of the astroglial fraction; however, ACh plus eserine had no effect on the incorporation of ³²Pi into the lipids of either fraction. ACh plus eserine stimulated the activity of phosphatidic acid phosphatase in the various subcellular fractions by increments which ranged from 13 per cent in nuclei to 37 per cent in microsomes. It was concluded that the nonspecific localization of the neurotransmitter effect could be due to the widespread distribution of the enzymes which appear to be responsive to cholinergic and adrenergic neurotransmitters.     

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.     

Phosphorylation of membrane-located proteins of soybean in vitro and response to auxin

Isolated membranes of soybean incorporate ³²P from γ-[³²P]ATP in vitro. The incorporation was rapid and did not require added calcium. When displayed on 10% sodium dodecyl sulfate-polyacrylamide gels, several protein bands were revealed. An apparent auxin (2,4-dichlorophenoxyacetic acid) stimulation of ³²P incorporation into material from membrane vesicles insoluble in trichloroacetic acid-perchloric acid may be reflected partly in enhanced incorporation into protein bands with apparent molecular weights of 45,000 and 50,000. Additionally, a low molecular weight component was sometimes observed where incorporation was stimulated 2- to 3-fold by auxin. However, protein-bound radioactivity represented only a small fraction of the total radioactivity of the acid-insoluble material. Other labeled constituents, not retained on the gels, may contribute to the apparent, rapid (10 s or less) auxin response of the isolated membranes. Stimulation of incorporation into the low molecular weight component was given by diglyceride plus calcium, constituents known to augment protein kinase activities in other systems.     

Involvement of phospholipids in triglyceride biosynthesis by developing soybean cotyledons

The incorporation of phospholipids specifically labeled with glycerol-2³H and acyl-¹⁴C by whole cell tissues of developing soybean cotyledons (Glycine max L.) reveals that phosphatidylinositol, phosphatidylcholine, phosphatidylethanolamine, N-acylphosphatidylethanolamine, and phosphatidic acid can be metabolized to diglyceride. The diglyceride formed may be recylced into phospholipid or acylated to triglyceride. Diglyceride from phosphatidic acid and phosphatidylethanolamine is used readily in triglyceride biosynthesis compared to the other phospholipids. Incorporation of N-acylphosphatidylethanolamine having [9-10-³H(N)]oleic acid esterified at sn-3 in cotyledons shows rapid acyltransfer of ³H into triglyceride and therefore N-acylphosphatidylethanolamine appears to participate in triglyceride biosynthesis as an acyl donor. These studies emphasize phospholipid metabolism in developing soybean cotyledons is a dynamic process which plays a key role in triglyceride formation.     

Phosphatidic acid mimics the muscarinic action of acetylcholine in cultured bovine chromaffin cells

In cultured bovine chromaffin cells, acetylcholine as well as muscarine stimulated the 32Pi incorporation into phosphatidic acid, induced the efflux of 45Ca2+ from prelabelled cells, and, in parallel, elevated intracellular cyclic GMP content. Phosphatidic acid added to the medium also stimulated the efflux of 45Ca2+ and the synthesis of cyclic GMP in the cells in the same fashion as muscarinic agents, whereas it did not induce the secretion of catecholamines indicating that the effect of phosphatidic acid is specific to muscarinic action. The result supports the hypothesis that phosphatidic acid produced during phosphatidylinositol turnover is linked to the regulation mechanism of Ca2+ mobilization and cyclic GMP synthesis by muscarinic stimulation.     

Acetylcholine stimulation of selective increases in stearic and arachidonic acids in phosphatidic acid in mouse pancreas.

During the acetylcholine-stimulated loss of phosphatidylinositol and gain in the level of phosphatidic acid in mouse pancreas, there is a selective increase in stearic and arachidonic acids in phosphatidic acid. The amounts parallel the decrease in phosphatidylinositol, which contains predominantly these two fatty acids. Addition of atropine to stimulated tissue reverses the changes. There is a selective disappearance of the stearoyl, arachidonoyl phosphatidic acid, and phosphatidylinositol increases. The changes support the hypothesis that the 1-stearoyl, 2-arachidonoyl diglyceride backbone of phosphatidylinositol becomes phosphatidic acid during acetylcholine stimulation, and is transformed back to phosphatidylinositol on reversion to the unstimulated state.     

The metabolism of phospholipids in mouse brain slices

1. Slices of mouse brain grey matter were incubated with [³²P]phosphate and [1-¹⁴C]acetate. Doubly labelled phospholipids were extracted from subcellular fractions prepared from the slices in a mixture of metabolic inhibitors, under conditions where there was negligible change in radioactive labelling during the preparation. Two tissue fractions were studied in detail; one contained a high proportion of mitochondria and the other was mainly microsomal. 2. In all tissue fractions the highest incorporations of both [³²P]phosphate and [1-¹⁴C]acetate occurred into phosphatidylcholine. 3. After incubation for 1hr., the ³²P/¹⁴C ratios for phosphatidylcholine, phosphatidylethanolamine and phosphatidic acid in the mitochondrial fraction were similar to those in the microsomal fraction. 4. The ³²P/¹⁴C ratios were similar in phosphatidylcholine and phosphatidylethanolamine and much lower than those in phosphatidic acid and phosphatidylinositol.     

Two distinct pools of membrane phosphatidylglycerol in Bacillus megaterium.

The predominant membrane lipid in Bacillus megaterium ATCC 14581, phosphatidylglycerol (PG), is present in two distinct pools, as shown by [32P]phosphate incorporation and chase experiments. One pool (PGt) undergoes rapid turnover of the phosphate moiety, whereas the second pool (PGs) exhibits metabolic stability in this group. The phosphate moiety of the other major phospholipid, phosphatidylethanolamine, is stable to turnover. [32P]phosphate- and [2-3H]glycerol-equilibrated cultures yielded the following glycerolipid composition: 56 mol% PG (34 mol% PGt and 22 mol% PGs), 21 mol% phosphatidylethanolamine, 1 to 2 mol% phosphatidylserine, 20 mol% diglycerides, less than 0.5 mol% cardiolipin, and 0.2 to 0.4 mol% lysophosphatidylglycerol. Accumulation of PG was halted immediately after the addition of cerulenin, an inhibitor of de novo fatty acid synthesis, whereas phosphatidylethanolamine accumulation continued at the expense of the diglyceride and PG pools. Strikingly, initial rates of [32P]phosphate incorporation into PG were unaffected by cerulenin. In control cultures at 35 degrees C, incorporation of [32P]phosphate into PG exhibited a biphasic time course, whereas incorporation into phosphatidylethanolamine was concave upward and lagged behind that of PG during the initial rapid phase of PG incorporation. Finally, levels of lysophosphatidylglycerol expanded rapidly after cerulenin addition at 20 degrees C, but not at 35 degrees C. Moreover, incorporation of [32P]phosphate into lysophosphatidylglycerol lagged behind incorporation into PG in both the presence and absence of cerulenin at 20 and 35 degrees C.     

Inhibition by gamma-hexachlorocyclohexane of acetylcholine-stimulated phosphatidylinositol synthesis in cerebral cortex slices and of phosphatidic acid-inositol transferase in cerebral cortex particulate fractions

• 1 γ-Hexachlorocyclohexane inhibits the ACh-stimulated synthesis of phosphatidylinositol in guinea pig cerebral cortex slices, as measured either by the incorporation of [2-³H]inositol or of ³²P. Phosphatidylinositol synthesis in the control slices is not inhibited.
• 2 The synthesis of phosphatidylinositol from CDP-diglyceride in cerebral cortex microsomal preparations is inhibited by γ-hexachlorocyclohexane. The incorporation of [2-³H]inositol into lipid in the absence of added cytidine nucleotide in these preparations is not inhibited.
• 3 δ-Hexachlorocyclohexane profoundly inhibits phosphatide synthesis and phosphate metabolism in cerebral cortex slices both in the presence and absence of ACh. This isomer also inhibits the exchange reaction for the incorporation of [2-³H]inositol into lipid in the microsomal preparations.
• 4 α-, and β-Hexachlorocyclohexanes do not inhibit either ACh-stimulated or control synthesis of phosphatidylinositol in cerebral cortex slices; nor do they inhibit the exchange reaction for [2-³H]inositol incorporation into lipid in the microsomal preparations.
• 5 The specific effects of γ-hexachlorocyclohexane are taken as providing evidence that ACh-stimulated phosphatidylinositol synthesis in cerebral cortex slices probably involves the CDP-diglyceride pathway. The possibility is discussed that the primary action of ACh in this system is to cause an increased activity of diglyceride kinase to provide phosphatidic acid for this pathway.

     

Phosphoinositide synthesis in bovine rod outer segments

Phosphoinositide turnover has been implicated in signal transduction in a variety of cells, including photoreceptors. We demonstrate here the presence of a complete pathway for rapid synthesis of phosphoinositides in isolated bovine retinal rod outer segments (ROS) free of microsomal contaminants. Synthesis was measured by the incorporation of label from radioactive precursors, [gamma-32P]ATP and [3H]inositol. [gamma-32P]ATP also produced large amounts of labeled phosphatidic acid. Incorporation of [3H]inositol required CTP and Mn2+. Mn2+ increased 32P incorporation into phosphatidylinositol 4-phosphate, while spermine increased phosphoinositide labeling generally. ROS that had been washed to remove soluble and peripheral proteins incorporated less label than unwashed ROS into phosphatidic acid and phosphatidylinositol. No effects of light were detected. Inhibitory effects of high concentrations of nonhydrolyzable GTP analogues were probably due to competition with ATP.