Phospholipid signalling and lipid-derived second messengers in plants

Phospholipid signalling is mediated by phospholipid breakdown products generated by phospholipases. The enzymes from animals and plants generating known or potential lipid-derived second messengers are compared. Plants possess a phospholipase C and a phospholipase A₂ both of which are agonist-activated. These agonists (auxin, elicitors, perhaps others) bind to the external surface of the plasma membrane. The target enzyme for potential plant lipid-derived second messengers is lipid-activated protein kinase but the possibility that other enzymes may be also lipid-modulated should not be precluded.Abbreviations DAG diacylglycerol - CDPK calmodulin-like domain protein kinase - PLA2 phospholipase A₂ - PLC phospholipase C - PLD phospholipase D - PKC protein kinase C - PS phosphatidylserine     

Regulation and functional significance of phospholipase D in myocardium

There is now clear evidence that receptor-dependent phospholipase D is present in myocardium. This novel signal transduction pathway provides an alternative source of 1,2-diacylglycerol, which activates isoforms of protein kinase C. The members of the protein kinase C family respond differently to various combinations of Ca²⁺, phosphatidylserine, molecular species of 1,2-diacylglycerol and other membrane phospholipid metabolites including free fatty acids. Protein kinase C isozymes are responsible for phosphorylation of specific cardiac substrate proteins that may be involved in regulation of cardiac contractility, hypertrophic growth, gene expression, ischemic preconditioning and electrophysiological changes. The initial product of phospholipase D, phosphatidic acid, may also have a second messenger role. As in other tissues, the question how the activity of phospholipase D is controlled by agonists in myocardium is controversial. Agonists, such as endothelin-1, atrial natriuretic factor and angiotensin 11 that are shown to activate phospholipase D, also potently stimulate phospholipase C- in myocardium. PMA stimulation of protein kinase C inactivates phospholipase C and strongly activates phospholipase D and this is probably a major mechanism by which agonists that promote phosphatidyl-4,5-bisphosphate hydrolysis secondary activate phosphatidylcholine-hydrolysis. On the other hand, one group has postulated that formation of phosphatidic acid secondary activates phosphatidyl-4,5-bisphosphate hydrolysis in cardiomyocytes. Whether GTP-binding proteins directly control phospholipase D is not clearly established in myocardium. Phospholipase D activation may also be mediated by an increase in cytosolic free Ca²⁺ or by tyrosine-phosphorylation.     

Organelle motility regulated by the cell's environment: dissection of signaling pathways regulating movements of peroxisomes

Summary Chloroplasts and pigment granules are known to be intracellularly translocated upon discrete extracellular stimuli. The machineries transducing these signals inside cells are yet not understood. In studies investigating the motility of peroxisomes, we were able to identify both extracellular and intracellular signaling steps regulating movements of these organelles. Following simultaneous stimulation of CHO cells with both extracellular ATP and lysophosphatidic acid, an arrest of peroxisomes was observed. This block of motility was shown to be dependent on signaling cascades involving heterotrimeric G proteins of the class G_i/G_o, phospholipase C, calcium influx, and activation of protein kinase C as well as of mitogen-activated protein kinase. Cytosolic phospholipase A₂ is a point of convergence for these pathways, resulting in the release of arachidonic acid. This signaling pathway is specific for peroxisomes and does not influence motility of mitochondria, lysosomes, or endosomes. However, since the cytoskeleton and its associated proteins including the motor proteins play an important role in mediating motility of all cell organelles, it may well be that variant signaling cascades exist ensuring specific regulation of each distinct compartment.Abbreviations AA arachidonic acid - ATPS adenosine-5-O-(3-thiotriphosphate) - cAMP cyclic adenosine monophosphate - CaM-PK calmodulin-dependent protein kinase - CLIP cytosolic linker protein - DAG diacylglycerol - DiC₈ 1,2-dioctanoyl-sn-glycerol - GFP green-fluorescent protein - GTPS guanosine-5-O-(3-thiotriphosphate) - IP₃ inositol trisphosphate - LPA lysophosphatidic acid - MAPK mitogen-activated protein kinase - MEK MAPK kinase - PKA protein kinase A - PKC protein kinase C - cPKC classical PKC isoforms - PLA₂ phospholipase A₂ - PLAP PLA₂-activating proteinpeptide - PLC phospholipase C - PP2A protein phosphatase 2A     

A Novel Predicted Calcium-Regulated Kinase Family Implicated in Neurological Disorders

The catalogues of protein kinases, the essential effectors of cellular signaling, have been charted in Metazoan genomes for a decade now. Yet, surprisingly, using bioinformatics tools, we predicted protein kinase structure for proteins coded by five related human genes and their Metazoan homologues, the FAM69 family. Analysis of three-dimensional structure models and conservation of the classic catalytic motifs of protein kinases present in four out of five human FAM69 proteins suggests they might have retained catalytic phosphotransferase activity. An EF-hand Ca²⁺-binding domain in FAM69A and FAM69B proteins, inserted within the structure of the kinase domain, suggests they may function as Ca²⁺-dependent kinases. The FAM69 genes, FAM69A, FAM69B, FAM69C, C3ORF58 (DIA1) and CXORF36 (DIA1R), are by large uncharacterised molecularly, yet linked to several neurological disorders in genetics studies. The C3ORF58 gene is found deleted in autism, and resides in the Golgi. Unusually high cysteine content and presence of signal peptides in some of the family members suggest that FAM69 proteins may be involved in phosphorylation of proteins in the secretory pathway and/or of extracellular proteins.     

A role for synaptotagmin (p65) in regulated exocytosis

Proteins that are specifically localized to synaptic vesicles in the nervous system have been proposed to mediate aspects of synaptic transmission. Antibodies raised against the cytoplasmic domains of five of these proteins, vamp, rab3A, synaptophysin, synaptotagmin, and SV2, were used to investigate their function. Microinjection of monoclonal and polyclonal antibodies raised against synaptotagmin (p65), but not the other vesicle proteins, decreases K⁺/Ca²⁺-mediated dopamine β-hydroxylase surface staining, a measure of regulated secretion in PC12 cells. Microinjection of a soluble fragment of synaptotagmin encompassing one of the domains homologous to the C2 regulatory region of protein kinase C, but lacking the membrane anchor, also inhibits evoked dopamine β-hydroxylase surface staining. These results provide support for the hypothesis that synaptotagmin, a Ca²⁺- and phospholipid-binding protein, is important for regulated exocytosis in neurons.     

Evidence that a starfish egg Src family tyrosine kinase associates with PLC-gamma1 SH2 domains at fertilization

The initiation of calcium release at fertilization in the eggs of most animals relies on the production of IP3, implicating the activation of phospholipase C. Recent work has demonstrated that injection of PLC-gamma SH2 domain fusion proteins into starfish eggs specifically inhibits the initiation of calcium release in response to sperm, indicating that PLC-gamma is necessary for Ca2+ release at fertilization [Carroll et al. (1997) J. Cell Biol. 138, 1303-1311]. Here we investigate how PLC-gamma may be activated, by using the PLC-gamma SH2 domain fusion protein as an affinity matrix to identify interacting proteins. A tyrosine kinase activity and an egg protein of ca. Mr 58 K that is recognized by an antibody directed against Src family tyrosine kinases associate with PLC-gamma SH2 domains in a fertilization-dependent manner. These associations are detected by 15 s postfertilization, consistent with a function in releasing Ca2+. Calcium ionophore treatment of eggs did not cause association of the kinase activity or of the Src family protein with the PLC-gamma SH2 domains. These data identify an egg Src family tyrosine kinase as a potential upstream regulator of PLC-gamma in the activation of starfish eggs.     

Application of high-pressure to subfractionate membrane protein-lipid complexes: a case study of protein kinase C

Current procedures for solubilization of membrane proteins involve the use of detergents. A procedure using high hydrostatic pressures without detergent has been applied in this study to subfractionate membrane proteins and their endogenously associated lipids. Rat brain membrane preparations were suspended in hypotonic buffer containing the membrane fluidizer benzyl alcohol in a sealed pressure cell and subjected to hydrostatic pressures of up to 1500 atmospheres (approx 22,000 psi) in a French press. Under these conditions, specific membrane proteins including protein kinase C, phospholipase A2, calmodulin-binding proteins, G-proteins, and microtubule-associated proteins all coextracted and were associated to lipid particles, suggesting inherent physical contact. Two populations of membrane-associated protein kinase C were identified according to molecular weight estimations. The first coeluted with the lipid particles composed predominantly of phospholipids, while the second contained much less lipid and was similar to the soluble monomer, i.e., cytosolic protein kinase C. This procedure provides an important technique for selective subfractionation of membrane proteins in their native lipid environment which could be used for structure-function studies.     

Rapid effects of phorbol esters on isolated rat adipocytes. Relationship to the action of protein kinase C

Treatment of isolated rat adipocytes with tumor-promoting phorbol esters, caused a fivefold stimulation of glucose oxidation, determined as 14CO2 production from [1-14C]glucose and a fivefold increase in the rate of lipid synthesis from [14C]glucose. Treatment of the cells with 12-O-tetradecanoylphorbol 13-acetate increased the rate of 86Rb+ uptake into the cells. Also phospholipase C was able to stimulate the rate of glucose oxidation; phospholipase C and 12-O-tetradecanoylphorbol 13-acetate stimulated glucose oxidation in a non-synergistic fashion, indicating a common mechanism for their action. Active phorbol esters and, in part, also phospholipase C, caused a translocation of protein kinase C activity from the soluble to the particulate fraction of the adipocytes. This process was rapid, being complete 30 s after the addition of phorbol ester, and resulted in the appearance of the kinase mainly in the mitochondrial and plasma membrane fractions. A comparison between the binding characteristics of adipocyte protein kinase C and the metabolic effects of the phorbol esters on the adipocytes revealed that the dose-response relationship did not correlate with binding of the phorbol esters, but, rather, a correlation was observed between the dose of phorbol esters required for translocation of protein kinase C and the intracellular effects. The results indicate that the intracellular translocation of protein kinase C might be a trigger for the effects of phorbol esters on the adipocyte and that binding of the esters to protein kinase C is not a sufficient event to cause this effect. Furthermore, it is suggested that activation of protein kinase C might be partly the action of hormones, such as insulin, on the fat cells.     

Tyrosine phosphorylation of Grb2-associated proteins correlates with phospholipase C gamma 1 activation in T cells.

Ligation of the T-cell antigen receptor (TCR) results in the rapid activation of several protein tyrosine kinases, with the subsequent phosphorylation of numerous cellular proteins. We investigated the requirement for tyrosine phosphorylation of proteins which bind the Grb2 SH2 domain in TCR-mediated signal transduction by transfecting the Jurkat T-cell line with a cDNA encoding a chimeric protein designed to dephosphorylate these molecules. Stimulation of the TCR on cells expressing this engineered enzyme fails to result in sustained tyrosine phosphorylation of a 36-kDa protein likely to be the recently cloned pp36/Lnk. Interestingly, TCR ligation of the transfected cells also fails to induce soluble inositol phosphate production and intracellular calcium mobilization, although receptor-mediated tyrosine phosphorylation of phospholipase C gamma 1 still occurs. TCR-mediated Ras and mitogen-activated protein kinase activation remain intact in cells expressing the engineered phosphatase. These data demonstrate that tyrosine phosphorylation of a protein(s) which binds the SH2 domain of Grb2 correlates with phospholipase C gamma 1 activation and suggest that such a phosphoprotein(s) plays a critical role in coupling the TCR with the phosphatidylinositol second-messenger pathway.     

Different sensitivity to phorbol esters and pertussis toxin of bombesin- and platelet-derived growth factor-induced, phospholipase C-mediated hydrolysis of phosphoinositides in NIH/3T3 cells

Incubation of the serum-deprived cultures of NIH/3T3 cells with bombesin or platelet-derived growth factor (PDGF) induced the phospholipase C-mediated hydrolysis of phosphoinositides. Protein kinase C-activating 12-O-tetradecanoylphorbol 13-acetate (TPA) and pertussis toxin inhibited the bombesin-induced phospholipase C reactions. AlF4-, a direct activator of GTP-binding proteins (G proteins), also induced the phospholipase C reactions and TPA inhibited the AlF4- -induced reactions. These results suggest that a pertussis toxin-sensitive G protein is involved in the coupling of the bombesin receptor to the phospholipase C and that the coupling of the G protein to the phospholipase C is inhibited by protein kinase C. In contrast, neither TPA nor pertussis toxin inhibited the PDGF-induced phospholipase C reactions, indicating that a pertussis toxin-sensitive G protein is not involved in the coupling of the PDGF receptor to the phospholipase C and that this coupling is insensitive to protein kinase C. These results suggest that the regulatory mechanism of the PDGF receptor for the phospholipase C activation is different from that of the bombesin receptor.     

Phospholipase C activity in NCB-20 cells is inhibited by protein kinase A-mediated phosphorylation of low molecular mass GTP-binding proteins.

We have previously shown that bradykinin-induced production of second messengers such as inositol trisphosphate and diacylglycerol in neurotumor cells is inhibited by raising cellular cyclic AMP levels, which in turn inhibit phospholipase C. A monoclonal antibody to phospholipase C-II immunoprecipitated the 140-kDa form of phospholipase C-II from [35S]methionine/[3H]eucine-labeled cells, but not [32P]orthophosphate-labeled phospholipase C-II, following treatment with either forskolin or dibutyryl cyclic AMP. This suggested that phospholipase C is not the target for cyclic AMP-dependent protein kinase-mediated phosphorylation. In vitro studies confirmed that phospholipase C activity was inhibited by raising cellular cAMP levels, and partial sensitivity to Bordetella pertussis toxin suggested the involvement of a GTP-binding protein which could be the target for protein kinase A. The involvement of a GTP-binding protein in coupling the bradykinin receptor to phospholipase C was further suggested by the ability of both guanosine 5'-O-(thio-triphosphate) and fluoride (NaF) to release inositol phosphates from NCB-20 cell membranes previously labeled with [3H]inositol. Both effects were blocked by pretreatment of the cells with protein kinase A activators, further suggesting a GTP-binding protein as the target for protein kinase A-mediated phosphorylation. When whole NCB-20 cell extracts were blotted onto nitrocellulose and incubated with [alpha- 32P]GTP, a major 24-kDa band plus minor bands at 22 and 20 kDa were revealed by autoradiography. A pH 3.0/6.0 soluble (basic protein) NCB-20 cell extract revealed the major 24-kDa band plus the 20-kDa band, and similar basic proteins were shown to be heavily phosphorylated following [32P]orthophosphate labeling and pretreatment with forskolin. The size and ability to bind GTP on Western blots are characteristic of the ras, rho, smg, etc. family of GTP-binding proteins recently suggested to be the much sought after GPLC (Lapetina, E.G., Lacal, J. C., Reep, B. R., and Molina y Vedia, L. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 3131-3134; Wang, P., Nishihata, J., Takabori, E., Yamamoto, K., Toyoshima, S., and Osawa, T. (1989) J. Biochem. (Tokyo) 105, 461-466; Nagata, K.-I., Nagao, S., and Nozawa, Y. (1989) Biochem. Biophys. Res. Commun. 160, 235-242). We propose that GPLC is uniquely sensitive to protein kinase A-mediated phosphorylation and that phosphorylation inhibits stimulus-secretion coupling in these cells.     

Tyrosine kinase 2 interacts with and phosphorylates receptor for activated C kinase-1, a WD motif-containing protein

Receptor for activated C kinase (Rack)-1 is a protein kinase C-interacting protein, and contains a WD repeat but has no enzymatic activity. In addition to protein kinase C, Rack-1 also binds to Src, phospholipase Cgamma, and ras-GTPase-activating proteins. Thus, Rack-1 is thought to function as a scaffold protein that recruits specific signaling elements. In a cytokine signaling cascade, Rack-1 has been reported to interact with the IFN-alphabeta receptor and Stat1. In addition, we show here that Rack-1 associates with a member of Jak, tyrosine kinase 2 (Tyk2). Rack-1 interacts weakly with the kinase domain and interacts strongly with the pseudokinase domain of Tyk2. Rack-1 associates with Tyk2 via two regions, one in the N terminus and one in the middle portion (aa 138-203) of Rack-1. Jak activation causes the phosphorylation of tyrosine 194 on Rack-1. After phosphorylation, Rack-1 is translocated toward the perinuclear region. In addition to functioning as a scaffolding protein, these results raise the possibility that Rack-1 functions as a signaling molecule in cytokine signaling cascades.     

GKAP, a Novel Synaptic Protein That Interacts with the Guanylate Kinase-like Domain of the PSD-95/SAP90 Family of Channel Clustering Molecules

The molecular mechanisms underlying the organization of ion channels and signaling molecules at the synaptic junction are largely unknown. Recently, members of the PSD-95/SAP90 family of synaptic MAGUK (membrane-associated guanylate kinase) proteins have been shown to interact, via their NH₂-terminal PDZ domains, with certain ion channels (NMDA receptors and K⁺ channels), thereby promoting the clustering of these proteins. Although the function of the NH₂-terminal PDZ domains is relatively well characterized, the function of the Src homology 3 (SH3) domain and the guanylate kinase-like (GK) domain in the COOH-terminal half of PSD-95 has remained obscure. We now report the isolation of a novel synaptic protein, termed GKAP for guanylate kinase-associated protein, that binds directly to the GK domain of the four known members of the mammalian PSD-95 family. GKAP shows a unique domain structure and appears to be a major constituent of the postsynaptic density. GKAP colocalizes and coimmunoprecipitates with PSD-95 in vivo, and coclusters with PSD-95 and K⁺ channels/ NMDA receptors in heterologous cells. Given their apparent lack of guanylate kinase enzymatic activity, the fact that the GK domain can act as a site for protein– protein interaction has implications for the function of diverse GK-containing proteins (such as p55, ZO-1, and LIN-2/CASK).     

C2 domain is responsible for targeting rice phosphoinositide specific phospholipase C

Phosphoinositide-specific phospholipase C (PLC) is involved in Ca²⁺ mediated signalling events that lead to altered cellular status. Using various sequence-analysis methods, we identified two conserved motifs in known PLC sequences. The identified motifs are located in the C2 domain of plant PLCs and are not found in any other protein. These motifs are specifically found in the Ca²⁺ binding loops and form adjoining beta strands. Further, we identified certain conserved residues that are highly distinct from corresponding residues of animal PLCs. The motifs reported here could be used to annotate plant-specific phospholipase C sequences. Furthermore, we demonstrated that the C2 domain alone is capable of targeting PLC to the membrane in response to a Ca²⁺ signal. We also showed that the binding event results from a change in the hydrophobicity of the C2 domain upon Ca²⁺ binding. Bioinformatic analyses revealed that all PLCs from Arabidopsis and rice lack a transmembrane domain, myristoylation and GPI-anchor protein modifications. Our bioinformatic study indicates that plant PLCs are located in the cytoplasm, the nucleus and the mitochondria. Our results suggest that there are no distinct isoforms of plant PLCs, as have been proposed to exist in the soluble and membrane associated fractions. The same isoform could potentially be present in both subcellular fractions, depending on the calcium level of the cytosol. Overall, these data suggest that the C2 domain of PLC plays a vital role in calcium signalling.     

The C2 domain calcium-binding motif: structural and functional diversity.

The C2 domain is a Ca(2+)-binding motif of approximately 130 residues in length originally identified in the Ca(2+)-dependent isoforms of protein kinase C. Single and multiple copies of C2 domains have been identified in a growing number of eukaryotic signalling proteins that interact with cellular membranes and mediate a broad array of critical intracellular processes, including membrane trafficking, the generation of lipid-second messengers, activation of GTPases, and the control of protein phosphorylation. As a group, C2 domains display the remarkable property of binding a variety of different ligands and substrates, including Ca2+, phospholipids, inositol polyphosphates, and intracellular proteins. Expanding this functional diversity is the fact that not all proteins containing C2 domains are regulated by Ca2+, suggesting that some C2 domains may play a purely structural role or may have lost the ability to bind Ca2+. The present review summarizes the information currently available regarding the structure and function of the C2 domain and provides a novel sequence alignment of 65 C2 domain primary structures. This alignment predicts that C2 domains form two distinct topological folds, illustrated by the recent crystal structures of C2 domains from synaptotagmin 1 and phosphoinositide-specific phospholipase C-delta 1, respectively. The alignment highlights residues that may be critical to the C2 domain fold or required for Ca2+ binding and regulation.     

The protein kinase C family.

Protein kinase C represents a structurally homologous group of proteins similar in size, structure and mechanism of activation. They can modulate the biological function of proteins in a rapid and reversible manner. Protein kinase C participates in one of the major signal transduction systems triggered by the external stimulation of cells by various ligands including hormones, neurotransmitters and growth factors. Hydrolysis of membrane inositol phospholipids by phospholipase C or of phosphatidylcholine, generates sn-1,2-diacylglycerol, considered the physiological activator of this kinase. Other agents, such as arachidonic acid, participate in the activation of some of these proteins. Activation of protein kinase C by phorbol esters and related compounds is not physiological and may be responsible, at least in part, for their tumor-promoting activity. The cellular localization of the different calcium-activated protein kinases, their substrate and activator specificity are dissimilar and thus their role in signal transduction is unlike. A better understanding of the exact cellular function of the different protein kinase C isoenzymes requires the identification and characterization of their physiological substrates.     

Tyrosine kinase but not phospholipid/Ca2+ signaling pathway is involved in interferon-γ stimulation of I-a expression in macrophages

The specific signal transduction pathway(s) involved in the induction of the expression of the MHC class II molecule, la, on macrophages by interferon-γ (IFN-γ) is unclear. In this paper, we assessed the role of several signal transduction pathways including calcium mobilization, phospholipase C, protein kinase C and cyclic nucleotide-dependent protein kinase, and the tyrosine kinase pathways. IFN-γ was unable to mobilize intracellular calcium, unlike platelet-activating factor, which stimulated a threefold increase in cytosolic Ca²⁺ concentration in macrophages. Inhibition of the phospholipase C pathway by U73122 or ET-180CH₃ and of phosphatidic acid phosphohydrolase by propranolol did not suppress IFN-γ-induced la expression. In addition, inhibition of protein kinase C by calphostin C or cyclic nucleotide-dependent protein kinase by HA1004 did not suppress la expression. However, IFN-γ-induced la expression was significantly suppressed when the tyrosine kinase pathway was inhibited with herbimycin A and genestein. In addition, those two inhibitors suppressed tyrosine phosphorylation of several proteins in macrophages that may or may not be involved in the induction of la expression. Thus, IFN-γ used only the tyrosine kinase signaling pathway, but not the phospholipid/Ca²⁺ signaling pathways, to induce la expression in macrophages. © 1996 Wiley-Liss, Inc.     

Regulation of phospholipase activity in potato leaves by calmodulin and protein phosphorylation-dephosphorylation

High levels of phospholipase activity were measured in potato (Solanum tuberosum L. cv. Kennebec or Russett Burbank) leaf extracts using a new fluorometric phospholipase assay based on 1-acyl-2-[6-[(7-nitro-2, 1, 3 benzoxadiazol-4-yl)amino]-caproyl] phosphatidylcholine (C₆-NBD-PC). Time-course studies revealed that phospholipase activity could be stimulated for a brief time by the addition of calmodulin or the catalytic subunit of cyclic AMP-dependent protein kinase. The short-lived calmodulin stimulation or protein kinase stimulation of phospholipase activity could be prolonged by either conducting the time-course reactions in the cold (5°C) or adding sodium fluoride (a phosphatase inhibitor) to the reaction mixtures. Centrifugation studies revealed that calmodulin-stimulated or protein kinase-stimulated phospholipase activities were soluble and not associated with membranes. When potatp leaves were homogenized in the presence of either of two phosphatase inhibitors, the levels of phospholipase activity in the corresponding high-speed supernatant fractions were 36–47% higher than in controls. These experiments suggest a possible protein phosphorylation-dephosphorylation mechanism for the regulation of phospholipase activity in potato leaves.     

Angiotensin II induces phosphatidic acid formation in neonatal rat cardiac fibroblasts: Evaluation of the roles of phospholipases C and D

Phosphatidic acid has been proposed to contribute to the mitogenic actions of various growth factors. In³²P-labeled neonatal rat cardiac fibroblasts, 100 nM [Sar¹]angiotensin II was shown to rapidly induce formation of³²P-phosphatidic acid. Levels peaked at 5 min (1.5-fold above control), but were partially sustained over 2 h. Phospholipase D contributed in part to phosphatidic acid formation, as³²P- or³H-phosphatidylethanol was produced when cells labeled with [³²P]H₃PO₄ or 1-O-[1,2-³H]hexadecyl-2-lyso-sn-glycero-3-phosphocholine were stimulated in the presence of 1% ethanol. [Sar¹]angiotensin II-induced phospholipase D activity was transient and mainly mediated through protein kinase C (PKC), since PKC downregulation reduced phosphatidylethanol formation by 68%. Residual activity may have been due to increased intracellular Ca²⁺, as ionomycin also activated phospholipase D in PKC-depleted cells. Phospholipase D did not fully account for [Sar¹]angiotensin II-induced phosphatidic acid: 1) compared to PMA, a potent activator of phospholipase D, [Sar¹]angiotensin II produced more phosphatidic acid relative to phosphatidylethanol, and 2) PKC downregulation did not affect [Sar¹]angiotensin II-induced phosphatidic acid formation. The diacylglycerol kinase inhibitor R59949 depressed [Sar¹]angiotensin II-induced phosphatidic acid formation by only 21%, indicating that activation of a phospholipase C and diacylglycerol kinase also can not account for the bulk of phosphatidic acid. Thus, additional pathways not involving phospholipases C and D, such asde novo synthesis, may contribute to [Sar¹]angiotensin II-induced phosphatidic acid in these cells. Finally, as previously shown for [Sar¹]angiotensin II, phosphatidic acid stimulated mitogen activated protein (MAP) kinase activity. These results suggest that phosphatidic acid may function as an intracellular second messenger of angiotensin II in cardiac fibroblasts and may contribute to the mitogenic action of this hormone on these cells. (Mol Cell Biochem141: 135–143, 1994)Abbreviations DAG diacylglycerol - DMSO dimethyl sulfoxide - lysoPC 1-O-hexadecyl-2-lyso-sn-glycero-3-phosphocholine - NRCF newborn rat cardiac fibroblasts - PA phosphatidic acid - PAPase phosphatidic acid phosphohydrolase - PC phosphatidylcholine - PEt phosphatidylethanol - PI phosphatidylinositol - PL (labeled) phospholipids - PLC phospholipase C - PLD phospholipase D Drs. G. W. Booz and M. M. Taher contributed equally to the work described here.     

Lipid-Dependent Modulation of Ca2+ Availability in Isolated Mossy Fiber Nerve Endings

An enhancement of glutamate release from hippocampal neurons has been implicated in long-term potentiation, which is thought to be a cellular correlate of learning and memory. This phenomenom appears to be involved the activation of protein kinase C and lipid second messengers have been implicated in this process. The purpose of this study was to examine how lipid-derived second messengers, which are known to potentiate glutamate release, influence the accumulation of intraterminal free Ca²⁺, since exocytosis requires Ca²⁺ and a potentiation of Ca²⁺ accumulation may provide a molecular mechanism for enhancing glutamate release. The activation of protein kinase C with phorbol esters potentiates the depolarization-evoked release of glutamate from mossy fiber and other hippocampal nerve terminals. Here we show that the activation of protein kinase C also enhances evoked presynaptic Ca²⁺ accumulation and this effect is attenuated by the protein kinase C inhibitor staurosporine. In addition, the protein kinase C-dependent increase in evoked Ca²⁺ accumulation was reduced by inhibitors of phospholipase A₂ and voltage-sensitive Ca²⁺ channels, as well as by a lipoxygenase product of arachidonic acid metabolism. That some of the effects of protein kinase C activation were mediated through phospholipase A₂ was also indicated by the ability of staurosporine to reduce the Ca²⁺ accumulation induced by arachidonic acid or the phospholipase A₂ activator melittin. Similarly, the synergistic facilitation of evoked Ca²⁺ accumulation induced by a combination of arachidonic acid and diacylglycerol analogs was attenuated by staurosporine. We suggest, therefore, that the protein kinase C-dependent potentiation of evoked glutamate release is reflected by increases in presynaptic Ca²⁺ and that the lipid second messengers play a central role in this enhancement of chemical transmission processes.