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 ionophore A23187 and Ba++ ions on labelling of phospholipids in rat pancreatic islets

Ionophore A23187, either in the presence or absence of added Ca2+ or Mg2+, caused a marked accumulation of [32P]-phosphatidic acid in pancreatic islets pre-labelled with 32 Pi. A similar effect was observed following the addition of 4 mM Ba2+ ions in the absence of added Ca2+. Neither agent caused a significant modification of labelling in other lipid fractions, although there was a persistent trend towards reduced labelling of phosphatidylcholine and phosphatidylethanolamine. Ionophore A23187 also potentiated the incorporation of 3H-glycerol into phosphatidic acid and reduced the incorporation of this precursor into phosphatidylcholine. In islets pre-labelled with 3H-glycerol and subsequently exposed to A23187 or Ba2+, no significant changes were observed in label associated with either phospholipids or neutral glycerolipids. These results suggest that ionophore A23187 and Ba2+ ions can divert the synthesis of phospholipids resulting in increased formation of phosphatidic acid at the expense of non-acidic phospholipids, principally phosphatidylcholine. We tentatively suggest that this effect may be the result of inhibition by Ca2+ of the breakdown of phosphatidic acid to diglyceride, an enzymic step which may regulate the relative amounts of acidic and neutral phospholipids.     

Modulation of 32Pi incorporation into phospholipids of polymorphonuclear leukocytes by ionophore A23187.

The effects of ionophore A23187 on the incorporation of 32Pi into phospholipids and on 45Ca2+ uptake and release by polymorphonuclear leukocytes were examined. A23187 increased 32Pi incorporation into phosphatidic acid, phosphatidylglycerol, phosphatidylserine, and the phosphoinositides. It also promoted a rapid burst uptake and release of 45Ca2+ by leukocytes. External Ca2+, but not Mg2+, was required for full stimulation of 32Pi incorporation into phosphatidic acid and the phosphoinositides. In the absence of external Ca2+, the increased radiophosphorus activity of phosphatidic acid, phosphatidylserine and the phosphoinositides was grossly reduced but not eliminated, and the decreased radiophosphorus activity of phosphatidylcholine became pronounced. In addition, the ionophore effect on 32Pi incorporation into leukocyte phospholipids was not abolished by ethyleneglycol bis(beta-amino-ethylether)-N,N'-tetraacetic acid. ATP radiophosphorus activity was also enhanced by the presence of A23187, but the enhancement was much less than that of the acidic phospholipids. Based on these findings, it is suggested that the increased 32Pi incorporation into the acidic phospholipids of leukocytes induced by A23187 was not solely derived from the higher radioactivity of ATP, increased Ca2+ fluxes and perturbation of cellular Ca2+ distribution of leukocytes exposed to A 23187 may trigger part of the altered 32Pi incorporation into phospholipids.     

Effects of carbachol and pancreozymin (cholecystokinin-octapeptide) on polyphosphoinositide metabolism in the rat pancreas in vitro.

We studied the possibility that hydrolysis of phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] may be the initiating event for the increase in [32P]Pi incorporation into phosphatidic acid (PtdA) and phosphatidylinositol (PtdIns) during carbachol and pancreozymin (cholecystokinin-octapeptide) action in the rat pancreas. After prelabelling acini for 2h, [32P]Pi incorporation into PtdA, PtdIns(4,5)P2 and phosphatidylinositol 4-phosphate (PtdIns4P) had reached equilibrium. Subsequent addition of carbachol or pancreozymin caused 32P in PtdIns(4,5)P2 to decrease by 30-50% within 10-15 s, and this was followed by sequential increases in [32P]Pi incorporation into PtdA and PtdIns. Similar changes in 32P-labelling of PtdIns4P were not consistently observed. Confirmation that the decrease in 32P in chromatographically-purified PtdIns(4,5)P2 reflected an actual decrease in this substance was provided by the fact that similar results were obtained (a) when PtdIns(4,5)P2 was prelabelled with [2-3H]inositol, and (b) when PtdIns(4,5)P2 was measured as its specific product (glycerophosphoinositol bisphosphate) after methanolic alkaline hydrolysis and ion-exchange chromatography. The secretogogue-induced breakdown of PtdIns(4,5)P2 was not inhibited by Ca2+ deficiency (severe enough to inhibit amylase secretion and Ca2+-dependent hydrolysis of PtdIns), and ionophore A23187 treatment did not provoke PtdIns(4,5)P2 hydrolysis. The increase in the hydrolysis of PtdIns(4,5)P2 and the increase in [32P]Pi incorporation into PtdA commenced at the same concentration of carbachol in dose-response studies. Our findings suggest that the hydrolysis of PtdIns(4,5)P2 is an early event in the action of pancreatic secretogogues that mobilize Ca2+, and it is possible that this hydrolysis may initiate the Ca2+-independent labelling of PtdA and PtdIns. Ca2+ mobilization may follow these responses, and subsequently cause Ca2+-dependent hydrolysis of PtdIns and exocytosis.     

Compartmentation of phosphorylated precursors of phospholipid biosynthesis in cultured neuroblastoma cells

The continuous turnover of membrane phospholipids requires a steady supply of biosynthetic precursors. We evaluated the effects of decreasing extracellular Na+ concentration on phospholipid metabolism in cultured neuroblastoma (N1E 115) cells. Incubating cultures with 145 to 0 mM NaCl caused a concentration-dependent inhibition of [32P]phosphate uptake into the water-soluble intracellular pool and incorporation into phospholipid. Phospholipid classes were differentially affected; [32P]phosphate incorporated into phosphati-dylethanolamine (PE) and phosphatidylcholine (PC) was consistently less than into phosphatidylinositol (PI) and phosphatidylserine (PS). This could not be attributed to decreased phospholipid synthesis since under identical conditions, there was no effect on arachidonic acid or ethanolamine incorporation, and choline utilization for PC synthesis was increased. The effect of Na+ was highly specific since reducing phosphate uptake to a similar extent by incubating cultures in a phosphate-deficient medium containing Na+ did not alter the relative distribution of [32P]phosphate in phospholipid. Of several cations tested only Li+ could partially (50%) replace Na+. Incubation in the presence of ouabain or amiloride had no effect on [32P]phosphate incorporation into phospholipid. The differential effects of low Na+ on [32P]phosphate incorporation into PI relative to PC and PE suggests preferential compartmentation of [32P]phosphate into ATP in pools used for phosphatidic acid synthesis and relatively less in ATP pools used for synthesis of phosphocholine and phosphoethanolamine, precursors of PC and PE, respectively. This suggestion of heterogeneous and distinct pools of ATP for phospholipid biosynthesis, and of potential modulation by Na+ ion, has important implications for understanding intracellular regulation of metabolism.     

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.     

Phosphatidic acid and phosphatidylinositol labelling in adipose tissue. The role of endogenously formed adenosine.

Incorporation of [32P]Pi into phosphatidic acid and phosphatidylinositol of hamster epididymal adipocytes was partially inhibited by 3-isobutyl-1-methylxanthine. This effect of 3-isobutyl-1-methylxanthine was antagonized by isopropyl-N6-phenyladenosine but not by 2',5'-dideoxyadenosine, prostaglandin E1 or clonidine. N6-Phenylisopropyladenosine did not affect incorporation of [32P]Pi into phosphatidic acid or phosphatidylinositol when 3-isobutyl-1-methylxanthine was not present. In contrast with 3-isobutyl-1-methylxanthine inhibition of [32P]Pi incorporation into phospholipids, which was blocked only by N6-phenylisopropyladenosine, accelerated lipolysis was blocked by prostaglandin E1, clonidine and 2',5'-dideoxyadenosine as well as by N6-phenylisopropyladenosine. Phospholipid labelling was also decreased in the presence of adenosine deaminase, but not in the presence of isoprenaline (isoproterenol). The stimulatory effect of N6-phenylisopropyladenosine on [32P]Pi incorporation into phospholipids in cells exposed to 3-isobutyl-1-methylxanthine was evident as soon as 3 min after addition of the adenosine analogue and maximum 10 min after its addition. As observed by others, [32P]Pi incorporation into phospholipids was increased by the alpha 1-selective agonist methoxamine. The stimulatory effect of methoxamine occurred with a time course similar to that of N6-phenylisopropyladenosine and was present at nearly equal magnitude in the absence or presence of 3-isobutyl-1-methylxanthine. The inhibitory effects of 3-isobutyl-1-methylxanthine and adenosine deaminase on phospholipid labelling are attributed to blockade of the action, or to the enzymic removal, of adenosine formed in and released from the fat-cells during their incubation. Supporting this view is the selective reversal of the actions of 3-isobutyl-1-methylxanthine and of adenosine deaminase by N6-phenylisopropyladenosine. These findings suggest an important role for endogenous adenosine in regulation of phospholipid turnover in adipocytes.     

Effects of Na+, Ca2+, and Acetylcholine on Phosphoinositide- and ATP-Phosphate Turnover in 32P-Labeled Rabbit Iris Smooth Muscle

Parallel studies were carried out in the rabbit iris on (a) the effects of Na+ and/or Ca2+ on the acetylcholine-stimulated 32P labeling of phosphatidic acid (PA) and phosphatidylinositol (PI) and the breakdown of polyphosphoinositides (poly PI), and (b) the effects of these cations on the specific radioactivity of [gamma-32P]ATP. Incorporation of 32P1 into ATP and phosphoinositides is time-dependent, and it is remarkably dependent upon Na+ concentration in the incubation medium. The Na+ effect is reversible. Calcium ion, in the absence of Na+, had no effect on the specific radioactivity of ATP in 32P-labeled iris muscle; however, it moderately stimulated the 32P labeling of PA and PI and the breakdown of poly PI. In contrast, the addition of Na+, in the presence or absence of Ca2+, significantly reduced the specific radioactivity of ATP and 32P labeling of phospholipids in the 32P-labeled iris muscle. Acetylcholine had no measurable effect on the specific radioactivity of ATP. Furthermore, the neurotransmitter stimulated the 32P labeling of PA and PI and the breakdown of poly PI in the 32P-labeled muscle only in the presence of both Na+ and Ca2+. These data provide additional support for the concept that in the rabbit iris receptor-activated Ca2+ fluxes mediate or precede the effects of alpha-adrenergic and cholinergic muscarinic agents on phosphoinositide breakdown into 1,2-diacylglycerol and inositol phosphates and that restoration of the polar head groups to the 1,2-diacylglycerol (i.e., the recovery stage) is probably associated with Na+ outflux, via the Na+ -pump mechanism.     

Evidence that chlorpromazine and prostaglandin E1 but not neomycin interfere with the inositol phospholipid metabolism in intact human platelets

Human platelets that had been prelabelled with [32P]Pi were stimulated with trombin in the presence or absence of neomycin, prostaglandin E1 (PGE1) or chlorpromazine. The content of [32P]Pi in phosphatidylinositol 4-phosphate, phosphatidylinositol 4,5-bisphosphate and phosphatidic acid (PA) were determined. The data demonstrate that PGE1 and chlorpromazine but not neomycin interfere with the tight metabolic relationship that exists between the inositol phospholipids and PA in thrombin-stimulated platelets [(1989) Biochem. J. 263, 621-624]. Our results therefore indicate that neomycin does not inhibit signal transduction in intact platelets at the level of the inositol phospholipid metabolism.     

Phosphoinositide metabolism of rat pineal gland in a low ionic strength medium

Pineal glands were incubated in the presence of 32P orthophosphate. When all NaCl in a conventional incubation medium was replaced by isotonic sucrose, i.e. when the ionic strength of the medium was decreased, there was a marked increase in 32P labelling of phosphatidylinositol (PI) and phosphatidic acid (PA). The 32P labelling of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) was not affected. No net synthesis of PI was observed. The increased labelling of PI therefore represents an increase in the turnover of PI. The 32P labelling of PI was observed also in media where NaCl was replaced by fructose or mannitol, but not in media, where NaCl was replaced by choline chloride. The effect depends on the concentration of the HEPES buffer and was not found in the medium with a bicarbonate buffer. 32P labelling of PI was not blocked by alpha 1 adrenergic blockers, phentolamine and prazosin, and did not depend on the presence of Ca2+ in the incubation medium. The effect was blocked by a Ca2+ channel blocker, MnCl2. Only 32P labelling of PI and not that of phosphatidylinositol 4-phosphate (PIP) and phosphatidylinositol 4,5-bisphosphate (PIP2) was increased during prolonged incubation in the sucrose medium. It is suggested that a decrease in the charge distribution across the plasma membrane as a result of the absence of most monovalent cations is responsible for the increased metabolism of phosphatidylinositol.     

Differences in phospholipid incorporation of 32P relevant to alpha 1-receptor coupling events in rat and rabbit aorta

Labelling of membrane phospholipids with 32P was compared in rat and rabbit aorta under basal conditions and during alpha 1-receptor stimulation. Incorporation of 32P proceeded at a significantly higher rate in rat tissue. The ratio of basal labelling following 30 min of incubation for rat/rabbit arteries was 4.8 for phosphatidylinositol diphosphate (PIP2), 6.0 for phosphatidylinositol phosphate (PIP), 9.0 for phosphatidylinositol (PI), 6.0 for phosphatidic acid (PA) and 18.7 for phosphatidylcholine (PC). Addition of 10(-5)M norepinephrine (NE) to labelled tissues resulted in a similar decrease in [32P]-PIP2 in both rat and rabbit tissues. Greater percent increases were seen in rabbit tissue of [32P]-PA (4-6 fold), and [32P]-PI (3-5 fold), when measured over the initial 10 minutes of agonist exposure. While NE caused a gradual increase of 32P incorporation into PC in rabbit aorta, reaching 180% above control after 10 minutes, PC labelling was not increased in rat aorta. Our findings provide evidence for the enhanced labelling of rat vs rabbit aorta phospholipids. This may account for differences in receptor responses and associated Ca+ movements which have been previously recognized to exist between aorta of these two species.     

Inositol phospholipid metabolism in human platelets stimulated by ADP

ADP-induced changes in inositol phospholipids, phosphatidic acid and inositol phosphates of human platelets have been studied in detail, using not only 32P labelling, but also by examining changes in amounts of the phospholipids, their labelling with [3H]glycerol and their specific radioactivities; changes in the labelling of inositol phosphates in platelets prelabelled with [3H]inositol were also measured. During the early (10 s) stage of reversible ADP-induced primary aggregation in a medium containing fibrinogen and with a concentration of Ca2+ in the physiological range (2 mM), the amounts of phosphatidylinositol 4,5-bisphosphate (PtdInsP2) and phosphatidylinositol 4-phosphate (PtdInsP) decreased (by 11.2 +/- 4.9% and 11.3 +/- 5.3%, respectively) while the labelling, but not the amount, of phosphatidic acid increased. The decreases do not appear to be attributable to the action of phospholipase C because the specific radioactivity of phosphatidic acid labelling with [3H]glycerol was not significantly increased at 10 s (although the initial specific radioactivities of the inositol phospholipids and PtdCho were more than double that of phosphatidic acid), and no increases in the labelling of inositol trisphosphate (InsP3), inositol bisphosphate (InsP2) or inositol phosphate (InsP) were detectable at 10 s. Shifts in the interconversions between PtdInsP2 and PtdInsP, and PtdInsP and PtdIns may occur. By 30 to 60 s, when deaggregation was beginning, the amounts of PtdInsP2, PtdInsP and phosphatidic acid were not different from those in unstimulated platelets, but large increases in the 32P-labelling and [3H]glycerol labelling of phosphatidic acid were observed. Formation of [3H]inositol-labelled InsP3 was not detectable at any time in association with ADP-induced primary aggregation, indicating that degradation of PtdInsP2 by phospholipase C is not appreciably stimulated by ADP. These findings were compared with those obtained when platelets were aggregated by ADP in a medium without added of Ca2+ in which secondary aggregation associated with thromboxane A2 (TXA2) formation and release of granule contents occurs. At 10 s (during primary aggregation) the changes were similar in the two media. At 30 s and 60 s (during secondary aggregation in the low-Ca2+ medium), the increases in PtdInsP2, PtdInsP and phosphatidic acid in platelets suspended in the absence of added Ca2+ were larger than those in platelets suspended in the presence of 2 mM Ca2+. In the absence of added Ca2+, ADP-induced increases in the labelling of InsP3, InsP2 and InsP which were probably due to the effects of TXA2 since they were abolished by aspirin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigen-stimulated metabolism of inositol phospholipids in the cloned murine mast-cell line MC9.

Cells of the murine mast-cell clone MC9 grown in suspension culture were sensitized with an anti-DNP (dinitrophenol) IgE and subsequently prelabelled by incubating with [32P]Pi. Stimulation of these cells with DNP-BSA (bovine serum albumin) caused marked decreases in [32P]polyphosphoinositides (but not [32P]phosphatidylinositol) with concomitant appearance of [32P]phosphatidic acid. Whereas phosphatidylinositol monophosphate levels returned to baseline values after prolonged stimulation, phosphatidylinositol bisphosphate levels remained depressed. Stimulation of sensitized MC9 cells with DNP-BSA increased rates of incorporation of [32P]Pi into other phospholipids in the order: phosphatidylcholine greater than phosphatidylinositol greater than phosphatidylethanolamine. In sensitized cells prelabelled with [3H]inositol, release of inositol monophosphate, inositol bisphosphate and inositol trisphosphate, was observed after stimulation with DNP-BSA. When Li+ was added to inhibit the phosphatase activity that hydrolysed the phosphomonoester bonds in the sugar phosphates, greater increases were observed in all three inositol phosphates, particularly in inositol trisphosphate. The IgE-stimulated release of inositol trisphosphate was independent of the presence of extracellular Ca2+. In addition, the Ca2+ ionophore A23187 caused neither the decrease in [32P]polyphosphoinositides nor the stimulation of the release of inositol phosphates. These results demonstrate that stimulation of the MC9 cell via its receptor for IgE causes increased phospholipid turnover, with effects on polyphosphoinositides predominating. These data support the hypothesis that hapten cross-bridging of IgE receptors stimulates phospholipase C activity, which may be an early event in stimulus-secretion coupling of mast cells. The results with the Ca2+ ionophore A23187 indicate that an increase in intracellular Ca2+ alone is not sufficient for activation of this enzyme.     

Triton X-100 promotes the accumulation of phosphatidic acid and inhibits the synthesis of phosphatidylcholine in human decidua and chorion frondosum tissues in vitro

Triton X-100 is known to affect phospholipid metabolism and the generation of various signal molecules from cellular phospholipids. In the present work the effect of Triton X-100 on phospholipid metabolism of human decidua and of the primordial placenta (chorion frondosum) was studied. Triton X-100 (0.05%, v/v) added to tissue mince 30 min before the end of a 60 min incubation stimulated 2-4-fold (decidua) and 4-6-fold (placenta) the incorporation of [32P]phosphate ([32P]Pi) into phosphatidic acid, while markedly decreasing the labeling of phosphatidylcholine. Triton X-100 had no effect on the labeling of phosphatidylinositol in the decidua, and only a slight increase was observed in the placenta. When labeled glucose was used to assess phospholipid synthesis, the addition of Triton had no effect on phosphatidic acid, while decreasing the synthesis of phosphatidylcholine. Incorporation of [32P]Pi into phosphatidic acid was not accelerated by a submicellar concentration (0.01%) of Triton, whereas the synthesis of phosphatidylcholine was decreased irrespective of detergent concentration. Anionic or cationic detergents could not mimic the action of Triton on phosphatidic acid synthesis. Although Triton inhibited the synthesis of ATP in a dose-dependent manner, this could not account for the above results. Instead, it is suggested that diacylglycerol kinase and phosphocholine:CTP cytidylyltransferase are possible targets of the action of Triton X-100.     

Phospholipid biosynthesis in mature human erythrocytes

Mature human erythrocytes were tested for their ability to synthetize membrane phospholipids from simple precursors: [32P]-orthophosphate (32Pi), [U-14C] glycerol, [U-14C] glucose, [U-14C] serine, and [U-14C] choline. The incorporation of these labels into phosphatidylcholine (PC), phosphatidylethanolamine (PE), phosphatidylserine (PS), phosphatidylinositol (PI), phosphatidic acid (PA), lysophosphatidylcholine (lyso-PC), phosphatidylinositol-4-phosphate (PIP), and phosphatidylinositol-4,5-bisphosphate (PIP2) was measured. All the phospholipids tested incorporated 32Pi, glycerol, and glucose in a time dependent manner. According to the rate of 32Pi incorporation, three groups of phospholipids could be distinguished: 1) PA, PIP2, PIP, lyso-PC; 2) PI and PS; 3) PC and PE, which incorporated 5 x 10(3), 40, and 6 nmol 32Pi/mmol phospholipid per 1 h, respectively. Moreover, [U-14C] serine and [U14C] choline were found to incorporate into phospholipids, and PS-decarboxylase activity could be measured. The possibility that the observed incorporation was due to contamination with bacteria or other blood cells could be ruled out. Our results bring evidence for de novo phospholipid synthesis of human red blood cells.     

Phosphatidylinositol metabolism in rat hepatocytes stimulated by vasopressin.

In isolated rat hepatocytes, vasopressin evoked a large increase in the incorporation of [32P]Pi into phosphatidylinositol, accompanied by smaller increases in the incorporation of [1-14C]oleate and [U-14C]glycerol. Incorporation of these precursors into the other major phospholipids was unchanged during vasopressin treatment. Vasopressin also promoted phosphatidylinositol breakdown in hepatocytes. Half-maximum effects on phosphatidylinositol breakdown and on phosphatidylinositol labelling occurred at about 5 nM-vasopressin, a concentration at which approximately half of the hepatic vasopressin receptors are occupied but which is much greater than is needed to produce half-maximal activation of glycogen phosphorylase. Insulin did not change the incorporation of [32P]Pi into the phospholipids of hepatocytes and it had no effect on the response to vasopressin. Although the incorporation of [32P]Pi into hepatocyte lipids was decreased when cells were incubated in a Ca2+-free medium, vasopressin still provoked a substantial stimulation of phosphatidylinositol labelling under these conditions. Studies with the antagonist [1-(beta-mercapto-beta, beta-cyclopentamethylenepropionic acid),8-arginine]vasopressin indicated that the hepatic vasopressin receptors that control phosphatidylinositol metabolism are similar to those that mediate the vasopressor response in vivo. When prelabelled hepatocytes were stimulated for 5 min and then subjected to subcellular fractionation. The decrease in [3H]phosphatidylinositol content in each cell fraction with approximately in proportion to its original phosphatidylinositol content. This may be a consequence of phosphatidylinositol breakdown at a single site, followed by rapid phosphatidylinositol exchange between membranes leading to re-establishment of an equilibrium distribution.     

Subcellular incorporation of 32P into phosphoinositides and other phospholipids in isolated hepatocytes

Isolated rat hepatocytes were incubated with 32Pi for various times and then fractionated into plasma membranes, mitochondria, nuclei, lysosomes, and microsomes by differential centrifugation and Percoll density gradient centrifugation. The phospholipids were isolated and deacylated by mild alkaline treatment. The glycerophosphate esters were separated by anion exchange high pressure liquid chromatography and assayed for radioactivity. It was found that plasma membranes, mitochondria, nuclei, lysosomes, and microsomes displayed similar rates of 32P incorporation into the major phospholipids, phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, phosphatidylglycerol, and phosphatidic acid. This suggests that the phospholipids of these organelles are undergoing rapid turnover and replacement with newly synthesized phospholipids from the endoplasmic reticulum. However, the plasma membrane fraction incorporated 32P into phosphatidylinositol 4-phosphate (DPI) and phosphatidylinositol 4,5-bisphosphate (TPI) at rates 5-10 and 25-50 times, respectively, faster than any of the other subcellular fractions. Although the plasma membrane is the primary site of 32P incorporation into DPI and TPI, this study also demonstrates that significant incorporation of 32P into DPI occurs in other subcellular sites, especially lysosomes.     

Phosphatidylinositol and phosphatidic acid metabolism in rat pancreatic islets in response to neurotransmitter and hormonal stimuli

Carbamylcholine produced a concentration-dependent stimulation of labelling of phosphatidylinositol and phosphatidic acid in rat islets of Langerhans following preincubation with 32PO43(-). The time course of these effects suggested that the initial action of carbamylcholine was to stimulate phosphatidic acid production, presumably by causing hydrolysis of phosphatidylinositol. This conclusion was substantiated by experiments in which islet phospholipids were pre-labelled with [3H]arachidonic acid. Under these conditions, carbamylcholine caused a loss of radioactivity from phosphatidylinositol, together with an increase in labelling of phosphatidic acid. The effects of carbamylcholine on islet phospholipid labelling were not dependent upon the presence of added Ca2+, but were abolished by EDTA and by atropine. An apparent stimulation of phosphatidylinositol and phosphatidic acid metabolism was also induced by cholecystokinin-pancreozymin, whereas glucagon, arginine, glibenclamide and thyrotropin had no significant effect. The data suggest that enhanced activity of the so-called phosphatidylinositol cycle may be an important event in regulating secretory activity of islets in response to certain neurotransmitter and hormonal stimuli. Furthermore, the results are compatible with the hypothesis that increased phospholipid metabolism may play a role in the modulation of ionic fluxes during stimulation by such agents.     

Stimulation of inorganic-phosphate incorporation into phosphatidylinositol in rat thoracic aorta mediated through V1-vasopressin receptors.

Vasopressin stimulates the incorporation of [32P]Pi into phosphatidylinositol but not into other phospholipids in rat thoracic aorta strips. The relative abilities of three vasopressin analogues to stimulate phosphatidylinositol labelling in rat aorta are similar to their relative pressor potencies in vivo and to their relative potencies in stimulating the metabolism of rat hepatocytes, but very different from their relative antidiuretic potencies. The vasopressor antagonist [1-(beta-mercapto-beta, beta-cyclopentamethylenepropionic acid),8-arginine]vasopressin competitively inhibits [Arg8]vasopressin-stimulated phosphatidylinositol labelling in rat aorta with a pA2 of 8.1. It is concluded that the Ca2+-mobilizing vasopressin receptors (V1-receptors) of the rat aorta stimulate phosphatidylinositol metabolism, probably by enhancing phosphatidylinositol breakdown.     

The relationship of calcium to receptor-controlled stimulation of phosphatidylinositol turnover. Effects of acetylcholine, adrenaline, calcium ions, cinchocaine and a bivalent cation ionophore on rat parotid-gland fragments.

The possibility that Ca2+ ions are involved in the control of the increased phosphatidylinositol turnover which is provoked by alpha-adrenergic or muscarinic cholinergic stimulation of rat parotid-gland fragments has been investigated. Both types of stimulation provoked phosphatidylinositol breakdown, which was detected either chemically or radiochemically, and provoked a compensatory synthesis of the lipid, detected as an increased rate of incorporation of 32Pi into phosphatidylinositol. Acetylcholine had little effect on the incorporation of labelled glycerol, whereas adrenaline stimulated it significantly, but to a much lower extent than 32P incorporation: this suggests that the response to acetylcholine was entirely accounted for by renewal of the phosphorylinositol head-group of the lipid, but that some synthesis de novo was involved in the response to adrenaline. The responses to both types of stimulation, whether measured as phosphatidylinositol breakdown or as phosphatidylinositol labelling, occurred equally well in incubation media containing 2.5 mm-Ca2+ or 0.2 mm-EGTA [ethanedioxybis(ethylamine)-tetra-acetic acid]. Incubation with a bivalent cation ionophore (A23187) led to a small and more variable increase in phosphatidylinositol labelling with 32Pi, which occurred whether or not Ca2+ was available in the extracellular medium: this was not accompanied by significant phosphatidylinositol breakdown. Cinchocaine, a local anaesthetic, produced parallel increases in the incorporation of Pi and glycerol into phosphatidylinositol. This is compatible with its known ability to inhibit phosphatidate phosphohydrolase (EC 3.1.3.4) and increase phosphatidylinositol synthesis de novo in other cells. These results indicate that the phosphatidylinositol turnover evoked by alpha-adrenergic or muscarinic cholinergic stimuli in rat parotid gland probably does not depend on an influx of Ca2+ into the cells in response to stimulation. This is in marked contrast with the K+ efflux from this tissue, which is controlled by the same receptors, but is strictly dependent on the presence of extracellular Ca2+. The Ca2+-independence of stimulated phosphatidylinositol metabolism may mean that it is controlled through a mode of receptor function different from that which controls other cell responses. Alternatively, it can be interpreted as indicating that stimulated phosphatidylinositol breakdown is intimately involved in the mechanisms of action of alpha-adrenergic and muscarinic cholinergic receptor systems.