Effects of insulin and phorbol esters on diacylglycerol generation and synthesis and hydrolysis of phosphatidylcholine in BC3H-1 myocytes

Insulin was found to provoke simultaneous, rapid, biphasic increases in [3H]choline-labeling of phosphatidylcholine and phosphocholine in BC3H-1 myocytes. Phorbol esters increased [3H]choline-labeling of phosphocholine, but not phosphatidylcholine. Both agonists increased diacylglycerol production. These results suggest that: (a) insulin provokes coordinated increases in the synthesis and hydrolysis of PC; and, (b) insulin-induced activation of protein kinase C may activate a PC-specific phospholipase.     

Effect of D609 on phosphatidylcholine metabolism in the nuclei of LA-N-1 neuroblastoma cells: a key role for diacylglycerol.

In our previous studies, TPA treatment of LA-N-1 cells stimulated the production of diacylglycerol in nuclei, probably through the activation of a phospholipase C. Stimulation of the synthesis of nuclear phosphatidylcholine by the activation of CTP:phosphocholine cytidylyltransferase was also observed. The present data show that both effects were inhibited by the pretreatment of the cells with D609, a selective phosphatidylcholine-phospholipase C inhibitor, indicating that the diacylglycerol produced through the hydrolysis of phosphatidylcholine in the nuclei is reutilized for the synthesis of nuclear phosphatidylcholine and is required for the activation of CTP:phosphocholine cytidylyltransferase.     

Vasopressin induces V1 receptors to activate phosphatidylinositol- and phosphatidylcholine-specific phospholipase C and stimulates the release of arachidonic acid by at least two pathways in the smooth muscle cell line, A-10

The rat thoracic aortic smooth muscle cell line, A-10, expresses vasopressin receptors of the V1 subtype. Vasopressin treatment of these cells stimulated the release of arachidonic acid and the formation of diacylglycerol and phosphocholine. These responses to vasopressin were inhibited by the V1-specific antagonist SK&F 100273, indicating that these were receptor-mediated phenomena. The mechanisms by which V1 receptors mediate arachidonic acid release appeared to be unaffected by cycloheximide or actinomycin D, suggesting that the release is independent of protein and RNA synthesis. The V1 receptors also appeared to be coupled to a phospholipase C which can hydrolyze phosphatidylcholine, a possible source of the released arachidonic acid. Phosphocholine and diacylglycerol were also generated. The release of arachidonic acid, phosphocholine, or diacylglycerol was not affected by prior treatment of the cells with pertussis toxin (islet-activating protein). Thus, the release of these second messengers is not mediated by the guanine nucleotide-binding protein Gi or other pertussis toxin-sensitive substrates. We conclude that V1 receptors induce the release of arachidonic acid and the formation of diacylglycerol and phosphocholine via the activation of both a phosphatidylinositol- and phosphatidylcholine-specific phospholipase C.     

Mechanisms of action of calcium-mobilizing agonists: some variations on a young theme

It is now accepted that many hormones and neurotransmitters exert their effects through G protein-mediated activation of a phospholipase C, which breaks down phosphatidylinositol bisphosphate. This releases inositol trisphosphate, which mobilizes intracellular calcium, and diacylglycerol, which, in turn, activates protein kinase C. However, recent evidence indicates that other mechanisms are involved. In some cells, the increases in cytosolic calcium elicited within 1-2 s by high concentrations of agonists or at later times by low, physiological concentrations of agonists occur without any detectable changes in inositol phosphates and calcium mobilization, and result from the opening of plasma membrane channels that are permeable to Ca2+. This response appears to be mediated more directly by G proteins. These findings question the postulated roles of inositol phosphates and calcium mobilization in the stimulation of calcium influx. Measurements of the mass and fatty acid composition of the inositol phospholipids and of the diacylglycerol and phosphatidic acid generated by agonists in several cell types indicate that phosphatidylinositol bisphosphate is probably a minor source of these lipids. On the other hand, measurements of phosphatidylcholine, choline, and phosphocholine indicate that this phospholipid is a major source, and that its breakdown involves both phospholipase C and D. These findings indicate that phosphatidylcholine breakdown may be more important than phosphoinositide hydrolysis in the regulation of protein kinase C and perhaps other cell functions.     

Kinetic evidence of a rapid activation of phosphatidylcholine hydrolysis by Ki-ras oncogene. Possible involvement in late steps of the mitogenic cascade

A novel phospholipase C specific for phosphatidylcholine has been shown to be activated by several agonists. Also, recent evidence suggests that transformation mediated by the ras oncogene possibly involves the activation of this novel phospholipid degradative pathway which would account for the increased diacylglycerol levels associated with transformation. Here we use a mutant of Ki-ras which is temperature-sensitive for transformation to investigate the kinetics of activation of the phosphodiesterase-mediated turnover of phosphatidylcholine. Upon shift to the permissive temperature, products of the activated phosphatidylcholine-specific phospholipase C were detected by 30 min and reached maximal levels by 1-2 h. These results suggest that the product of the ras oncogene rapidly activates the phosphodiesteratic hydrolysis of phosphatidylcholine. Furthermore, the fact that at least 4 h are required for serum to activate this phospholipase C strongly suggests that the ras oncogene product might be involved in late steps of the mitogenic signaling cascade.     

Studies on the enzymatic pathways of calcium ionophore-induced phospholipid degradation and arachidonic acid mobilization in peritoneal macrophages

Exposure of mouse peritoneal macrophages to ionophore A23187 caused a rapid and extensive Ca2+-dependent phospholipid degradation and mobilization of arachidonic acid. Phosphatidylinositol, phosphatidylcholine and phosphatidylethanolamine all contributed to the arachidonic acid release, although the ethanolamine phospholipids incorporated [3H]arachidonic acid more slowly during the prelabeling period, particularly the plasmalogen form. Several enzymatic pathways could be positively identified as contributing to the ionophore-induced phospholipid degradation by the use of several different radiolabeled phospholipid precursors: (i) a phospholipase A-mediated deacylation, (ii) a phosphodiesterase (phospholipase C) reaction, rapidly generating diacylglycerol units from inositol phospholipids, and (iii) enzymatic processes generating diacylglycerol and CDP- and phosphocholine/ethanolamine from phosphatidylcholine/ethanolamine. The diacylglycerol formed was in part phosphorylated and in part hydrolyzed to monoacylglycerol, with retention of its arachidonic acid. These, and other, results indicate that the Ca2+-ionophore activates several apparently distinct phospholipid-degrading processes, in contrast to stimuli acting via cellular receptors.     

Diacylglycerol production induced by growth hormone in Ob1771 preadipocytes arises from phosphatidylcholine breakdown

Growth Hormone has recently been shown to stimulate the formation of diacylglycerol in Ob1771 mouse preadipocyte cells without increasing inositol lipid turnover. Addition of growth hormone to Ob1771 cells prelabelled with [3H]glycerol or [3H]choline led to a rapid, transient and stoechiometric formation of labelled diacylglycerol and phosphocholine, respectively. In contrast, no change was observed in the level of choline and phosphatidic acid whereas the release of water-soluble metabolites in [3H]ethanolamine prelabelled cells exposed to growth hormone was hardly detectable. Stimulation by growth hormone of cells prelabelled with (2-palmitoyl 9, 10 [3H])phosphatidylcholine also induced the production of labelled diacyglycerol. Pertussis toxin abolished both diacylglycerol and phosphocholine formation induced by growth hormone. It is concluded that growth hormone mediates diacylglycerol production in Ob1771 cells by means of phosphatidylcholine breakdown involving a phospholipase C which is likely coupled to the growth hormone receptor via a pertussis toxin-sensitive G-protein.     

Elevated phosphocholine concentration in ras-transformed NIH 3T3 cells arises from increased choline kinase activity, not from phosphatidylcholine breakdown.

The cellular concentration of phosphocholine has been reported to be significantly elevated in Ha-ras-transformed NIH 3T3 cells, but not in v-sis transformants (J. C. Lacal, J. Moscat, and S. A. Aaronson, Nature [London] 330:269-271, 1987). It was suggested that the phosphocholine arises from constitutive hydrolysis of phosphatidylcholine by phospholipase C, an activity that would also account for the elevated 1,2-diacylglycerol found in ras-transformed cells. I have demonstrated that the increased phosphocholine arises through the induction of choline kinase activity. No increased breakdown of phosphatidylcholine was observed in ras-transformed cells. The elevation in diacylglycerol is therefore unlikely to be a consequence of phosphatidylinositol or phosphatidylcholine turnover.     

Production of diacylglycerol by exogenous phospholipase C stimulates CTP:phosphocholine cytidylyltransferase activity and phosphatidylcholine synthesis in human neuroblastoma cells.

The involvement of endogenous diacylglycerol production in the stimulation of phosphatidylcholine synthesis by exogenous phospholipase C was examined using a neuroblastoma (LA-N-2) cell line. Phospholipase C treatment (0.1 unit/ml) of intact cells stimulated CTP:phosphocholine cytidylyltransferase activity significantly more effectively than did maximally effective concentrations of the synthetic diacylglycerol sn-1,2-dioctanoylglycerol (1 mM). When added to cells together with phospholipase C, oleic acid, but not dioctanoylglycerol, further increased cytidylyltransferase activity with respect to phospholipase C treatment alone, indicating that the enzyme was not maximally activated by the lipase. This suggests that the lack of additivity of diacylglycerol and phospholipase C reflects a common mechanism of action. The time course of activation of cytidylyltransferase by phospholipase C paralleled that of [3H]diacylglycerol production in cells prelabeled for 24 h with [3H]oleic acid. Diacylglycerol mass was similarly increased. Significant elevations of [3H]oleic acid and total fatty acids occurred later than did the increases in cytidylyltransferase activity and diacylglycerol levels. No significant reduction in total or [3H]phosphatidylcholine was elicited by this concentration of phospholipase C, but higher concentrations (0.5 unit/ml) significantly reduced phosphatidylcholine content. The stimulation of cytidylyltransferase activity by phospholipase C or dioctanoylglycerol was also associated with enhanced incorporation of [methyl-14C]choline into phosphatidylcholine. Dioctanoylglycerol was more effective than phospholipase C at stimulating the formation of [14C]phosphatidylcholine, and the effects of the two treatments were additive. However, further analysis revealed that dioctanoylglycerol served as a precursor for [14C]dioctanoylphosphatidylcholine as well as an activator of cytidylyltransferase; and when corrections were made for this effect, the apparent additivity disappeared. The results indicate that the generation of diacylglycerol by exogenous phospholipase C (and possibly the subsequent production of fatty acids via diacylglycerol metabolism) activates cytidylyltransferase activity in neuronal cells under conditions in which membrane phosphatidylcholine content is not measurably reduced.     

Cell signalling through phospholipid breakdown

There is much evidence that G-proteins transduce the signal from receptors for Ca²⁺-mobilizing agonists to the phospholipase C that catalyzes the hydrolysis of phosphoinositides. However, the specific G-proteins involved have not been identified. We have recently purified a 42 kDa protein from liver that activates phosphoinositide phospholipase C and cross-reacts with antisera to a peptide common to G-protein -subunits. It is proposed that this protein is the a-subunit of the G-protein that regulates the phospholipase in this tissue.Ca²⁺-mobilizing agonists and certain growth factors also promote the hydrolysis of phosphatidylcholine through the activation of phospholipases C and D in many cell types. This yields a larger amount of diacylglycerol for a longer time than does the hydrolysis of inositol phospholipids. Consequently phosphatidylcholine breakdown is probably a major factor in long-term regulation of protein kinase C. The functions of phosphatidic acid produced by phospholipase D are speculative, but there is evidence that it is a major source of diacylglycerol in many cell types. The regulation of phosphatidylcholine phospholipases is multiple and involves direct activation by G-proteins, and regulation by Ca²⁺ protein kinase C and perhaps growth factor receptor tyrosine kinases.     

Mechanism of inhibition of adenylate cyclase by phospholipase C-catalyzed hydrolysis of phosphatidylcholine. Involvement of a pertussis toxin-sensitive G protein and protein kinase C.

The phospholipase C-mediated hydrolysis of phosphatidylcholine has been shown recently to be activated by a number of agonists. Muscarinic receptors, which trigger various signal transduction mechanisms including inhibition of adenylate cyclase through Gi, have been shown to be potent stimulants of this novel phospholipid degradative pathway. We demonstrate here, by exogenous addition of Bacillus cereus phosphatidylcholine-hydrolyzing phospholipase C, that phosphatidylcholine breakdown mimics the ability of carbachol to inhibit adenylate cyclase. This effect is sensitive to pertussis toxin and is entirely dependent on the presence of protein kinase C. This kinase is also required for the inhibition by carbachol of adenylate cyclase. These results suggest that the activation of phosphatidylcholine breakdown by phospholipase C may play an important role linking or favoring the coupling muscarinic receptors to Gi. Results presented here also show that phospholipase C-mediated hydrolysis of phosphoinositides by exogenous addition of Bacillus thuringiensis phosphoinositide-hydrolyzing phospholipase C does not affect adenylate cyclase, despite the fact that protein kinase C is translocated to an extent similar to that produced by the hydrolysis of phosphatidylcholine. According to the results shown here, both phospholipases also differ in their ability to down-regulate protein kinase C as well as to phosphorylate p80 and to transmodulate the binding of epidermal growth factor, two well established effects of protein kinase C in Swiss 3T3 fibroblasts. This emphasizes the complexity, from a functional point of view, of protein kinase C activation "in vivo."     

Bradykinin Activates a Phospholipase D that Hydrolyzes Phosphatidylcholine in PC12 Cells

In PC12 pheochromocytoma cells whose phospholipids had been prelabelled with [3H]palmitic acid, bradykinin increased the production of [3H]phosphatidic acid. The increase in [3H]phosphatidic acid occurred within 1-2 min. before the majority of the increase in [3H]diacylglycerol. When the phospholipids were prelabeled with [3H]choline, bradykinin increased the intracellular release of [3H]choline. The production of phosphatidic acid and choline suggests that bradykinin was increasing the activity of phospholipase D. Transphosphatidylation is a unique property of phospholipase D. In cells labeled with [3H]palmitic acid, bradykinin stimulated the transfer of phosphatidyl groups to both ethanol and propanol to form [3H]phosphatidylethanol and [3H]phosphatidylpropanol, respectively. The effect of bradykinin on [3H]phosphatidic acid and [3H]phosphatidylethanol formation was partially dependent on extracellular Ca2+. In cells treated with nerve growth factor, carbachol also increased [3H]phosphatidylethanol formation. To investigate the substrate specificity of phospholipase D, cells were labeled with [14C]stearic acid and [3H]palmitic acid, and then incubated with ethanol in the absence or presence of bradykinin. The 14C/3H ratio of the phosphatidylethanol that accumulated in response to bradykinin was almost identical to the 14C/3H ratio of phosphatidylcholine. The 14C/3H ratio in phosphatidic acid and diacylglycerol was higher than the ratio in phosphatidylcholine. These data provide additional support for the idea that bradykinin activates a phospholipase D that is active against phosphatidylcholine. The hydrolysis of phosphatidylcholine by phospholipase D accounts for only a portion of the phosphatidic acid and diacylglycerol that accumulates in bradykinin-stimulated cells: bradykinin evidently stimulates several pathways of phospholipid metabolism in PC12 cells.     

The role of polyphosphoinositides and their breakdown products in A23187-induced release of arachidonic acid from rabbit polymorphonuclear leucocytes.

Stimulation of rabbit polymorphonuclear leucocytes with A23187 causes phospholipase C mediated breakdown of polyphosphoinositides, as evidenced by accumulation of [3H]inositol-labelled inositol bisphosphate and inositol trisphosphate. At the same time the polyphosphoinositides and the products of their breakdown, diacylglycerol and phosphatidic acid, label rapidly with radioactive arachidonic acid. Enhancement of polyphosphoinositide labelling is not as great as enhancement of diacylglycerol or phosphatidic acid labelling, suggesting additional early activation of a second independent synthetic pathway to the last named lipids. Experiments using double (3H/14C) labelling, to distinguish pools with different rates of turnover, suggest the major pool of arachidonic acid used for synthesis of lipoxygenase metabolites turns over more slowly than arachidonic acid in diacylglycerol, but at about the same rate as arachidonic acid esterified in phosphatidylcholine or phosphatidylinositol. Further, when cells are prelabelled with [14C]arachidonic acid, then stimulated for 5 min, it is only from phosphatidylcholine, and to a lesser extent phosphatidylinositol, that radiolabel is lost. Release of arachidonic acid is probably via phospholipase A2, since it is blocked by the phospholipase A2 inhibitor manoalide. The absence of accumulated lysophosphatides can be explained by reacylation and, in the case of lysophosphatidylinositol, deacylation. The importance of phospholipase A2 in phosphatidylinositol breakdown contrasts with the major role of phospholipase C in polyphosphoinositide hydrolysis. Measurements of absolute free fatty acid levels, as well as studies showing a correlation between production of radiolabelled hydroxyeicosatetraenoic acids and release of radiolabel from the phospholipid pool, both suggest that hydrolysis of arachidonic acid esterified into phospholipids is the limiting factor regulating formation of lipoxygenase metabolites. By contrast with A23187, fMet-Leu-Phe (a widely used polymorphonuclear leucocyte activator) is a poor stimulant for arachidonic acid release unless a 'second signal' (e.g. cytochalasin B, or a product of A23187-stimulated cells) is also present. In the presence of cytochalasin B, fMet-Leu-Phe, like A23187, stimulates release of radiolabelled arachidonic acid principally from phosphatidylcholine.     

Carbachol stimulates a different phospholipid metabolism than nerve growth factor and basic fibroblast growth factor in PC12 cells.

We have examined 1,2-diglycerides (DGs) generated in PC12 cells in response to the muscarinic agonist carbachol and compared them with those generated in response to the differentiation factors nerve growth factor and basic fibroblast growth factor. Whereas carbachol stimulates a greater release of inositol phosphates, all three agonists generate similar levels of DGs. In this report, we have analyzed the molecular species of PC12 DGs generated in response to these three agonists. Additionally, we have analyzed the molecular species of PC12 phospholipids. The data indicate that 1) after 1 min of either nerve growth factor or basic fibroblast growth factor stimulation, DGs arise primarily from phosphoinositide hydrolysis; 2) in contrast, after 1 min of carbachol stimulation, DG are generated equally by both phosphoinositide and phosphatidylcholine hydrolysis; and 3) after 15 min of stimulation by any of these agonists, DGs are generated largely by phosphatidylcholine hydrolysis, with a smaller component arising from the phosphoinositides. These results suggest that at least part of the mechanism by which PC12 cells distinguish between different agonists is via alterations in phospholipid sources and kinetics of DG generation.     

Evidence for the activation of phospholipases during acrosome reaction of human sperm elicited by calcium ionophore A23187

Incubation of washed human sperm with [3H]- or [14C]arachidonic acid allowed a major incorporation of the label into phospholipids, provided that the final concentration of the fatty acid did not exceed 20 microM. A further challenge with calcium ionophore A23187 of spermatozoa suspended in a calcium-containing medium led to phospholipid hydrolysis, which could account for 10-12% of total cell radioactivity. Degradation products were identified as free, unconverted arachidonic acid, occurring with some diacylglycerol. Phospholipid hydrolysis was significant after 15 min of incubation and became maximal after 120 min. It was found to be calcium dependent, diacylglycerol and free arachidonate production occurring maximally at 2 mM and 5 mM CaCl2, respectively. Phosphatidylcholine and phosphatidylinositol were the most significantly degraded phospholipids after 60 min of incubation. Similar incubations conducted with 32P-labeled sperm confirmed the selective hydrolysis of phosphatidylcholine and revealed an increase production of phosphatidic acid probably due to a phosphorylation of diacylglycerol. Under the same conditions, one third of the cells remained motile and electron microscopy revealed that acrosome reaction was completed in 40% of the cells and displayed an intermediary state in 40-50% of the spermatozoa. Furthermore, a good parallelism was observed between the extent of the acrosome reaction and the extent of phospholipid hydrolysis promoted by increasing concentrations of A23187. It is concluded that calcium entry into the cells activates both a phospholipase A2 and a phospholipase C, leading to the production of substances, like lysophospholipid, diacylglycerol or phosphatidic acid, which may or may not be involved in acrosome reaction.     

Phosphatidylcholine metabolism in human endothelial cells: modulation by phosphocholine

Phosphatidylcholine is the principal phospholipid in mammalian tissues, and a major source for the production of arachidonic acid. In this study, the effect of exogenous phosphocholine, a precursor of phosphatidylcholine biosynthesis, on the metabolism of phosphatidylcholine in human umbilical vein endothelial cells was investigated. Incubation of endothelial cells with exogenous phosphocholine at concentrations of 1 to 5 mM was found to inhibit choline uptake and its subsequent incorporation into phosphatidylcholine. Phosphocholine appeared to inhibit choline uptake in a competitive manner. Since phosphatidylcholine is metabolized mainly by the action of phospholipase A₂, with the release of arachidonic acid and other fatty acids, the effect of phosphocholine on arachidonic acid release in endothelial cells was also examined. The induction of arachidonic acid release by ATP was enhanced in cells treated with 1 mM phosphocholine. In vitro assays of phospholipase A₂ activity in cells incubated with phosphocholine, however, did not produced any significant change in the activity of this enzyme. The results of this study show that phosphocholine modulates the biosynthesis and catabolism of phosphatidylcholine in an indirect manner.     

Diacylglycerol metabolism in phospholipase C-treated mammalian cells

Treatment of cultured cells with phospholipase C causes increased rates of hydrolysis of cellular phosphatidylcholine and increased rates of incorporation of choline into phosphatidylcholine. The fate of the diacylglycerol produced by the phospholipase C hydrolysis was examined in two cell lines, Chinese hamster ovary and HeLa. In the former cells, turnover of the glycerol moiety of phosphatidylcholine was not enhanced by phospholipase C treatment, indicating that the phospholipase C-generated diacylglycerol was recycled into new phosphatidylcholine. In HeLa cells, turnover of the glycerol backbone of phosphatidylcholine was enhanced by phospholipase C treatment, and the increased rate of turnover of the glycerol moiety was similar to that of the phosphate moiety. Thus, the fate of diacylglycerol generated at the plasma membrane was demonstrated to differ in these two cell lines. Incorporation of precursors of diacylglycerol into phosphatidylcholine was not enhanced by phospholipase C treatment in either cell line.     

A major role for phospholipase A2 in antigen-induced arachidonic acid release in rat mast cells.

Cross-linking of IgE receptors by antigen stimulation leads to histamine release and arachidonic acid release in rat peritoneal mast cells. Investigators have reported a diverse distribution of [3H]arachidonate that is dependent on labelling conditions. Mast cells from rat peritoneal cavity were labelled with [3H]arachidonic acid for different periods of time at either 30 or 37 degrees C. Optimum labelling was found to be after 4 h incubation with [3H]arachidonate at 30 degrees C, as judged by cell viability (Trypan Blue uptake), responsiveness (histamine release) and distribution of radioactivity. Alterations in 3H-radioactivity distribution in mast cells labelled to equilibrium were examined on stimulation with antigen (2,4-dinitrophenyl-conjugated Ascaris suum extract). The results indicated that [3H]arachidonic acid was lost mainly from phosphatidylcholine and, to a lesser extent, from phosphatidylinositol. A transient appearance of radiolabelled phosphatidic acid and diacylglycerol indicated phosphatidylinositol hydrolysis by phospholipase C. Pretreatment with a phospholipase A2 inhibitor, mepacrine, substantially prevented the antigen-induced liberation of [3H]arachidonic acid from phosphatidylcholine. It can be thus concluded that, in the release of arachidonic acid by antigen-stimulated mast cells, the phospholipase A2 pathway, in which phosphatidylcholine is hydrolysed, serves as the major one, the phospholipase C/diacylglycerol lipase pathway playing only a minor role.     

Phosphatidylcholine metabolism in endothelial cells: evidence for phospholipase A and a novel Ca2+-independent phospholipase C

The metabolism of phosphatidylcholine (PC) was investigated in sonicated suspensions of bovine pulmonary artery endothelial cells and in subcellular fractions using two PC substrates: 1-oleoyl-2-[3H]oleoyl-sn-glycero-3-phosphocholine and 1,2-dipalmitoyl-sn-glycero-3-phospho[14C]choline. When these substrates were incubated with the whole cell sonicate at pH 7.5, all of the metabolized 3H label was recovered in [3H]oleic acid (95%) and [3H]diacylglycerol (5%). All of the 14C label was identified in [14C]lysoPC (92%) and [14C]phosphocholine (8%). These data indicated that PC was metabolized via phospholipase(s) A and phospholipase C. Substantial diacylglycerol lipase activity was identified in the cell sonicate. Production of similar proportions of diacylglycerol and phosphocholine and the low relative activity of phospholipase C compared to phospholipase A indicated that the phospholipase C-diacylglycerol lipase pathway contributed little to fatty acid release from the sn-2 position of PC. Neither phospholipase A nor phospholipase C required Ca2+. The pH profiles and subcellular fractionation experiments indicated the presence of multiple forms of phospholipase A, but phospholipase C activity displayed a single pH optimum at 7.5 and was located exclusively in the particulate fraction. The two enzyme activities demonstrated differential sensitivities to inhibition by p-bromophenacylbromide, phenylmethanesulfonyl fluoride and quinacrine. Each of these agents inhibited phospholipase A, whereas phospholipase C was inhibited only by p-bromophenacylbromide. The unique characteristics observed for phospholipase C activity towards PC indicated the existence of a novel enzyme that may play an important role in lipid metabolism in endothelial cells.     

Signal transduction in esophageal and LES circular muscle contraction

Contraction of normal esophageal circular muscle (ESO) in response to acetylcholine (ACh) is linked to M2 muscarinic receptors activating at least three intracellular phospholipases, i.e., phosphatidylcholine-specific phospholipase C (PC-PLC), phospholipase D (PLD), and the high molecular weight (85 kDa) cytosolic phospholipase A2 (cPLA2) to induce phosphatidylcholine (PC) metabolism, production of diacylglycerol (DAG) and arachidonic acid (AA), resulting in activation of a protein kinase C (PKC)-dependent pathway. In contrast, lower esophageal sphincter (LES) contraction induced by maximally effective doses of ACh is mediated by muscarinic M3 receptors, linked to pertussis toxin-insensitive GTP-binding proteins of the G(q/11) type. They activate phospholipase C, which hydrolyzes phosphatidylinositol bisphosphate (PIP2), producing inositol 1,4,5-trisphosphate (IP3) and DAG. IP3 causes release of intracellular Ca++ and formation of a Ca++-calmodulin complex, resulting in activation of myosin light chain kinase and contraction through a calmodulin-dependent pathway. Signal transduction pathways responsible for maintenance of LES tone are quite distinct from those activated during contraction in response to maximally effective doses of agonists (e.g., ACh). Resting LES tone is associated with activity of a low molecular weight (approximately 14 kDa) pancreatic-like (group 1) secreted phospholipase A2 (sPLA2) and production of arachidonic acid (AA), which is metabolized to prostaglandins and thromboxanes. These AA metabolites act on receptors linked to G-proteins to induce activation of PI- and PC-specific phospholipases, and production of second messengers. Resting LES tone is associated with submaximal PI hydrolysis resulting in submaximal levels of inositol trisphosphate (IP3-induced Ca++ release, and interaction with DAG to activate PKC. In an animal model of acute esophagitis, acid-induced inflammation alters the contractile pathway of ESO and LES. In LES circular muscle, after induction of experimental esophagitis, basal levels of PI hydrolysis are substantially reduced and intracellular Ca++ stores are functionally damaged, resulting in a reduction of resting tone. The reduction in intracellular Ca++ release causes a switch in the signal transduction pathway mediating contraction in response to ACh. In the normal LES, ACh causes release of Ca++ from intracellular stores and activation of a calmodulin-dependent pathway. After esophagitis, ACh-induced contraction depends on influx of extracellular Ca++, which is insufficient to activate calmodulin, and contraction is mediated by a PKC-dependent pathway. These changes are reproduced in normal LES cells by thapsigargin-induced depletion of Ca++ stores, suggesting that the amount of Ca++ available for release from intracellular stores defines the signal transduction pathway activated by a maximally effective dose of ACh.