Cloning and characterization of a phospholipase C-beta isoform from the sea urchin Lytechinus pictus

Calcium is a ubiquitous intracellular signaling molecule controlling a wide array of cellular processes including fertilization and egg activation. The mechanism for triggering intracellular Ca(2+) release in sea urchin eggs during fertilization is the generation of inositol-1,4,5-trisphosphate by phospholipase C (PLC) hydrolysis of phosphatidylinositol-4,5-bisphosphate. Of the five PLC isoforms identified in mammals (beta, gamma, delta, epsilon and zeta), only PLCgamma and PLCdelta have been detected in echinoderms. Here, we provide direct evidence of the presence of a PLCbeta isoform, named suPLCbeta, within sea urchin eggs. The coding sequence was cloned from eggs of Lytechinus pictus and determined to have the greatest degree of homology and identity with the mammalian PLCbeta4. The presence of suPLCbeta within the egg was verified using a specifically generated antibody. The majority of the enzyme is localized in the non-soluble fraction, presumably the plasma membrane of the unfertilized egg. This distribution remains unchanged 1 min postfertilization. Unlike PLCbeta4, suPLCbeta is activated by G protein betagamma subunits, and this activity is Ca(2+)-dependent. In contrast to all known PLCbeta enzymes, suPLCbeta is not activated by Galphaq-GTPgammaS subunit suggesting other protein regulators may be present in sea urchin eggs.     

Expression of phospholipase C beta family isoenzymes in C2C12 myoblasts during terminal differentiation

In the present work, we have analyzed the expression and subcellular localization of all the members of inositide-specific phospholipase C (PLCbeta) family in muscle differentiation, given that nuclear PLCbeta1 has been shown to be related to the differentiative process. Cell cultures of C2C12 myoblasts were induced to differentiate towards the phenotype of myotubes, which are also indicated as differentiated C2C12 cells. By means of immunochemical and immunocytochemical analysis, the expression and subcellular localization of PLCbeta1, beta2, beta3, beta4 have been assessed. As further characterization, we investigated the localization of PLCbeta isoenzymes in C2C12 cells by fusing their cDNA to enhanced green fluorescent protein (GFP). In myoblast culture, PLCbeta4 was the most expressed isoform in the cytoplasm, whereas PLCbeta1 and beta3 exhibited a lesser expression in this cell compartment. In nuclei of differentiated myotube culture, PLCbeta1 isoform was expressed at the highest extent. A marked decrease of PLCbeta4 expression in the cytoplasm of differentiated C2C12 cells was detected as compared to myoblasts. No relevant differences were evidenced as regards the expression of PLCbeta3 at both cytoplasmatic and nuclear level, whilst PLCbeta2 expression was almost undetectable. Therefore, we propose that the different subcellular expression of these PLC isoforms, namely the increase of nuclear PLCbeta1 and the decrease of cytoplasmatic PLCbeta4, during the establishment of myotube differentiation, is related to a spatial-temporal signaling event, involved in myogenic differentiation. Once again the subcellular localization appears to be a key step for the diverse signaling activity of PLCbetas.     

Inositides in the nucleus: presence and characterisation of the isozymes of phospholipase beta family in NIH 3T3 cells.

Previous reports from our laboratories and others have hinted that the nucleus is a site for an autonomous signalling system acting through the activation of the inositol lipid cycle. Among phospholipases (PLC) it has been shown previously that PLCbeta1 is specifically localised in the nucleus as well as at the plasma membrane. Using NIH 3T3 cells, it has been possible to obtain, with two purification strategies, in the presence or in the absence of Nonidet P-40, both intact nuclei still maintaining the outer membrane and nuclei completely stripped of their envelope. In these nuclei, we show that not only PLCbeta1 is present, but also PLCbeta2, PLCbeta3 and PLCbeta4. The more abounding isoform is PLCbeta1 followed by PLCbeta3, PLCbeta2 and PLCbeta4, respectively. All the isoforms are enriched in nuclear preparations free from nuclear envelope and cytoplasmatic debris, indicating that the actual localisation of the PLCbeta isozymes is in the inner nuclear compartment.     

Angiotensin II-induced delayed stimulation of phospholipase C gamma1 requires activation of both phosphatidylinositol 3-kinase gamma and tyrosine kinase in vascular myocytes

In vascular smooth muscles, angiotensin II (AII) has been reported to activate phospholipase C (PLC) and phosphatidylinositol 3-kinase (PI3K). We investigated the time-dependent effects of AII on both phosphatidylinositol 3,4,5-trisphosphate (PtdInsP3) and inositol phosphates (InsPs) accumulation in permeabilized microsomes from rat portal vein smooth muscle in comparison with those of noradrenaline (NA). AII stimulated an early production of PtdInsP3 (within 30 s) followed by a delayed production of InsPs (within 3-5 min), in contrast to NA which activated only a fast production of InsPs. The use of pharmacological inhibitors and antibodies raised against the PI3K and PLC isoforms expressed in portal vein smooth muscle showed that AII specifically activated PI3Kgamma and that this isoform was involved in the AII-induced stimulation of InsPs accumulation. NA-induced InsPs accumulation depended on PLCbeta1 activation whereas AII-induced InsPs accumulation depended on PLCgamma1 activation. AII-induced PLCgamma1 activation required both tyrosine kinase and PI3Kgamma since genistein and tyrphostin B48 (inhibitors of tyrosine kinase), LY294002 and wortmannin (inhibitors of PI3K) and anti-PI3Kgamma antibody abolished AII-induced stimulation of InsPs accumulation. Increased tyrosine phosphorylation of PLCgamma1 was only detected for long-lasting applications of AII and was suppressed by genistein. These data indicate that activation of both PI3Kgamma and tyrosine kinase is a prerequisite for AII-induced stimulation of PLCgamma1 in vascular smooth muscle and suggest that the sequential activation of the three enzymes may be responsible for the slow and long-lasting contraction induced by AII.     

PTH stimulates PLCbeta and PLCgamma isoenzymes in rat enterocytes: influence of ageing

We previously reported that in rat duodenal cells (enterocytes), parathyroid hormone (PTH [1-34]: PTH) stimulates the hydrolysis of polyphosphoinositides by phospholipase C (PLC), generating the second messengers inositol trisphosphate (IP(3)) and diacylglycerol (DAG) and that this mechanism is severely altered in old animals. In the present study, we show that PTH [1-34]-dependent IP(3) release in young rats was blocked to a great extent by an antibody against guanine nucleotide binding protein Galphaq/11, indicating that the hormone activates a beta isoform of PLC coupled to the alpha subunit of Gq/11. In addition, PTH rapidly (within 30 s, with maximal effects at 1 min) stimulated tyrosine phosphorylation of PLCgamma in a dose-dependent fashion (10(-10)-10(-7) M). The hormone response was specific as PTH [7-34] was without effects. The tyrosine kinase inhibitors, genistein (100 microM) and herbimycin (2 microM), suppressed PTH-dependent PLCgamma tyrosine phosphorylation. Stimulation of PLCgamma tyrosine phosphorylation by PTH [1-34] greatly decreased with ageing. PP1 (10 microM), a specific inhibitor of the Src family of tyrosine kinases, completely abolished PLCgamma phosphorylation. The hormone-induced Src tyrosine dephosphorylation, a major mechanism of Src activation, an effect that was blunted in old animals. These results indicate that in rat enterocytes PTH generates IP(3) mainly through G-protein-coupled PLCbeta and stimulates PLCgamma phosphorylation via the nonreceptor tyrosine kinase Src. Impairment of PTH activation of both PLC isoforms upon ageing may result in abnormal hormone regulation of cell Ca(2+) and proliferation in the duodenum.     

Norepinephrine stimulates the direct breakdown of phosphatidyl inositol in rat tail artery.

When segments of rat tail artery were labeled with [3H]inositol and then stimulated with norepinephrine (NE), the inositol phosphates produced were primarily IP and IP2, together with a small but significant amount of Ins(1,4,5)P3 and a very small amount of Ins(1,3,4,5)P4. It has been unclear in many studies whether or not the relatively large levels of IP and IP2 produced in [3H]inositol-labeled tissue represent indirect products of phosphatidyl inositol(4,5)bis phosphate breakdown (through Ins(1,4,5)P3) or direct products of phosphatidyl inositol 4 monophosphate and phosphatidyl inositol breakdown. In order to answer this question tail artery segments were prelabeled with [3H]inositol and then permeabilized with beta escin and stimulated with norepinephrine and GTP gamma S, so that increases in IP, IP2, and Ins(1,4,5)P3 were still observed. If these permeable segments were stimulated with agonist in the presence of compounds known to inhibit Ins(1,4,5)P3 5-phosphatase, such as glucose 6P, (2,3)diphosphoglycerate, or Ins(1,4,5)P3, the levels of labeled Ins(1,4,5)P3 and labeled IP2 were increased, while the level of stimulated labeled IP was unchanged. This indicated that some of the IP2 and IP formed in these cells was produced from PIP2 but that some of these compounds might be formed from PIP or PI. When the isomers of inositol monophosphate, Ins 1P and Ins 4P, were separated by HPLC, it was shown that after prelabeled tail artery was stimulated by norepinephrine for periods of 1-2 min, the predominant isomer formed was Ins 4P, indicating either PIP2 or PIP as the source. However, after 5-20 min stimulation, both Ins 1P and Ins 4P were formed in equal amounts, suggesting that during sustained stimulation of smooth muscle PI itself was broken down directly. Therefore it appears that within 1-2 min of norepinephrine addition to vascular smooth muscle the bulk of the IP and IP2 produced are derived from PIP2 via IP3, while after 20 min of norepinephrine treatment much of the IP comes directly from PI. This suggests that the regulation of PLC in this tissue is more complicated than has been previously believed.     

Identification and chromosomal localisation by fluorescence in situ hybridisation of human gene of phosphoinositide-specific phospholipase C beta(1)

Members of phosphoinositide-specific phospholipase C (PLC) families are central intermediary in signal transduction in response to the occupancy of receptors by many growth factors. Among PLC isoforms, the type beta(1) is of particular interest because of its reported nuclear localisation in addition to its presence at the plasma membrane. It has been previously shown that both the stimulation and the inhibition of the nuclear PLCbeta(1) under different stimuli implicate PLCbeta(1) as an important enzyme for mitogen-activated cell growth as well as for murine erythroleukaemia cell differentiation. The above findings hinting at a direct involvement of PLCbeta(1) in controlling the cell cycle in rodent cells, and the previously reported mapping of its gene in rat chromosome band 3q35-36, a region frequently rearranged in rat tumours induced by chemical carcinogenesis, prompted us to identify its human homologue. By screening a human foetal brain cDNA library with the rat PLCbeta(1) cDNA probe, we have identified a clone homologous to a sequence in gene bank called KIAA 0581, which encodes a large part of the human PLCbeta(1). By using this human cDNA in fluorescence in situ hybridisation on human metaphases, it has been possible to map human PLCbeta(1) on chromosome 20p12, confirming the synteny between rat chromosome 3 and human chromosome 20 and providing a novel locus of homology between bands q35-36 in rat and p12 in man. Since band 20p12 has been recently reported amplified and/or deleted in several solid tumours, the identification and chromosome mapping of human PLCbeta(1) could pave the way for further investigations on the role exerted both in normal human cells and in human tumours by PLCbeta(1), which has been shown to behave as a key signalling intermediate in the control of the cell cycle.     

Differences in inositol phosphate production in rat tail artery and thoracic aorta

Pharmacomechanical coupling of vascular smooth muscle is believed to be mediated by inositol trisphosphate (IP3). Numerous studies have demonstrated an increase in inositol phosphates following tissue stimulation using either intact aortic strips or cultured cells from aorta. However, little information is available concerning inositol phosphates in vascular tissue other than in the large conduit vessel, the aorta. This present study was designed to examine the role of inositol phosphate metabolism following adrenergic stimulation of the muscular rat tail artery as compared to the aorta. Segments of thoracic aorta and tail artery from male Sprague Dawley rats were labeled with [3H]inositol and stimulated with norepinephrine. The norepinephrine concentration that resulted in a half-maximal stimulation of inositol phosphates was approximately 10(-6) M in both the aorta and tail artery. Although the sensitivity of the two vessels to norepinephrine stimulation were similar, the stimulated levels of IP, IP2, and IP3 were from 1 to 2 orders of magnitude greater in the tail artery than in aorta. IP production in aorta and tail artery was a linear function of time (from 0 to 30 min). Significant levels of IP3 (the 1,4,5-IP3 isomer as determined by HPLC) could only be detected in the tail artery and appeared to be produced optimally after 5 min of stimulation. The several order of magnitude increase in adrenergic stimulated inositol phosphate production in the tail artery was not due to either an increased magnitude of [3H]inositol incorporated into PI, PIP, and PIP2 or to a greater percentage of smooth muscle cells per unit tissue of the rat tail artery. We believe the results of this study demonstrate that the increased inositol phosphate metabolism in the vascular smooth muscle cells of the tail artery is an intrinsic property of the cell. Moreover, due to the significant levels of all inositol phosphates produced in the tail artery, this muscular artery may be a better model, as compared to the aorta, for future studies investigating pharmacomechanical coupling of vascular smooth muscle.     

Immunocytochemical localization of phospholipase C isozymes in cord blood and adult T-lymphocytes.

The response of T-cells to peptide antigen plus major histocompatibility complex (MHC) consists of a series of cellular events collectively called T-cell activation. An essential component of this pathway is phospholipase C (PLC)gamma1, whose hydrolytic activity increases rapidly after binding of ligands to the T-cell receptor (TCR) and consequent activation of tyrosine kinases. Recent studies also suggest a GTP binding protein-dependent activation of PLCbeta during the early steps of T-cell activation. On the basis of these findings, we first checked the expression of PLC isoforms by Western blotting and by confocal and electron microscopy techniques, and then we looked for the phosphoinositide breakdown induced by CD3 engagement in cord and adult T-lymphocytes. Our results indicated that PLCbeta1 was almost exclusively expressed in cord T-cells, whereas PLCbeta2 was more strongly represented in the adult. The amount of PLCgamma1 was found to be larger in the adult than in cord cells. No significant differences were found in PLCgamma2 and delta2 expression. PLCdelta1 was scarcely detectable. On CD3 stimulation, adult lymphocytes gave rise, as expected, to a dramatic increase in phosphoinositide breakdown, whereas in cord cells this response was scarcely detected. These results indicate that a shift in PLC expression occurs in the postnatal period and that this change is associated with induction of the capability to respond to CD3 engagement with phosphoinositide hydrolysis.     

Calcium responses to thyrotropin-releasing hormone, gonadotropin-releasing hormone and somatostatin in phospholipase css3 knockout mice

These studies examined the importance of phospholipase Cbeta (PLCbeta) in the calcium responses of pituitary cells using PLCbeta3 knockout mice. Pituitary tissue from wild-type mice contained PLCbeta1 and PLCbeta3 but not PLCbeta2 or PLCbeta4. Both Galphaq/11 and Gbetagamma can activate PLCbeta3, whereas only Galphaq/11 activates PLCss1 effectively. In knockout mice, PLCbeta3 was absent, PLCbeta1 was not up-regulated, and PLCbeta2 and PLCbeta4 were not expressed. Since somatostatin inhibited influx of extracellular calcium in pituitary cells from wild-type and PLCbeta3 knockout mice, the somatostatin signal pathway was intact. However, somatostatin failed to increase intracellular calcium in pituitary cells from either wild-type or knockout mice under a variety of conditions, indicating that it did not stimulate PLCbeta3. In contrast, somatostatin increased intracellular calcium in aortic smooth muscle cells from wild-type mice, although it evoked no calcium response in cells from PLCbeta3 knockout animals These results show that somatostatin, like other Gi/Go-linked hormones, can stimulate a calcium transient by activating PLCbeta3 through Gbetagamma, but this response does not normally occur in pituitary cells. The densities of Gi and Go, as well as the relative concentrations of PLCbeta1 and PLCbeta3, were similar in cells that responded to somatostatin with an increase in calcium and pituitary cells. Calcium responses to 1 nM and 1 microM TRH and GnRH were identical in pituitary cells from wild-type and PLCbeta3 knockout mice, as were responses to other Gq-linked agonists. These results show that in pituitary cells, PLCbeta1 is sufficient to transmit signals from Gq-coupled hormones, whereas PLCbeta3 is required for the calcium-mobilizing actions of somatostatin observed in smooth muscle cells.     

Norepinephrine causes alpha 1-adrenergic receptor-mediated decrease of phosphatidylinositol in isolated rat liver plasma membranes supplemented with cytosol

When purified rat liver plasma membranes were incubated with norepinephrine, rat liver cytosol, and Ca2+, the amount of membrane-bound phosphatidylinositol was reduced by up to 50%. The levels of other major membrane phospholipids underwent negligible change. The decrease in phosphatidylinositol levels was not observed if norepinephrine was omitted or cytosol was absent. The disappearance of phospholipid persisted when soluble Ca2+ was depleted by ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. The decrease was prevented by phentolamine, benextramine, and prazosin, but not by sotalol. The results show that norepinephrine elicits a specific alpha 1-adrenergic receptor-mediated breakdown of phosphatidylinositol in isolated plasma membranes which is dependent on the presence of cytosol.     

Linking phospholipase C isoforms with differentiation function in human vascular smooth muscle cells

The phosphoinositol-phospholipase C (PLC) family of enzymes consists of a number of isoforms, each of which has different cellular functions. PLCγ₁ is primarily linked to tyrosine kinase transduction pathways, whereas PLCδ₁ has been associated with a number of regulatory proteins, including those controlling the cell cycle. Recent studies have shown a central role of PLC in cell organisation and in regulating a wide array of cellular responses. It is of importance to define the precise role of each isoform, and how this changes the functional outcome of the cell. Here we investigated differences in PLC isoform levels and activity in relation to differentiation of human and rat vascular smooth muscle cells. Using Western blotting and PLC activity assay, we show that PLCδ₁ and PLCγ₁ are the predominant isoforms in randomly cycling human vascular smooth muscle cells (HVSMCs). Growth arrest of HVSMCs for seven days of serum deprivation was consistently associated with increases in PLCδ₁ and SM α-actin, whereas there were no changes in PLCγ₁ immuno-reactivity. Organ culture of rat mesenteric arteries in serum free media (SFM), a model of de-differentiation, led to a loss of contractility as well as a loss of contractile proteins (SM α-actin and calponin) and PLCδ₁, and no change in PLCγ₁ immuno-reactivity. Taken together, these data indicate that PLCδ₁ is the predominant PLC isoform in vascular smooth muscle, and confirm that PLCδ₁ expression is affected by conditions that affect the cell cycle, differentiation status and contractile function.     

Phospholipase C β2 in vascular smooth muscle

Receptor-mediated inositol 1,4,5-trisphosphate formation in most tissues is dependent on a variety of phospholipase C isoforms. To determine which phospholipase C isoforms were present in vascular smooth muscle compared to brain, liver, and spleen, we extracted proteins from these tissues and separated and identified the phospholipase C isoforms by immunoblotting. Aliquots of rat tail artery were examined by this procedure, together with aliquots of rat liver, spleen, cerebral cortex, hippocampus, cerebellum, aorta, and mesenteric artery. Phospholipase C γ1 was shown to be present in all of these tissues, while phospholipase C β1 was shown to be limited to fractions from brain. Phospholipase C Δ1 was detected in rat tail artery, mesenteric artery, aorta, and brain. Phospholipase C β2 was found in rat tail artery, liver, and brain. This is the first report of phospholipase C β2 in tissues other than HL60 cells. Since G proteins activate IP₃ production via stimulation of phospholipase Cβ isoforms in many tissues, and agonist-stimulated IP₃ production in smooth muscle requires G protein activation, phospholipase C β2 may be required for agonist-stimulated force production in vascular smooth muscle. © 1996 Wiley-Liss, Inc.     

Effect of ageing on the expression of protein kinase C and its activation by 1,25(OH)2-vitamin D3 in rat skeletal muscle

To characterize age-induced effects on muscle protein kinase C (PKC) and its regulation by the steroid hormone 1,25(OH)2-vitamin D3 [1,25(OH)2D3], changes in PKC activity and the expression and translocation of the specific PKC conventional isoforms alpha and beta, novel isoforms delta, epsilon, and theta and atypical isoform zeta were studied in homogenates and subcellular fractions from skeletal muscle of young (3 months) and aged (24 months) rats treated in vitro with 1,25(OH)2D3. The hormone (10(-9) M) increased total and membrane PKC activity, within 1 min, and these effects were completely blunted in muscle from aged rats. The presence of PKC isoenzymes was shown by Western blot analysis with the use of specific antibodies. The expression of PKC alpha, beta and delta was greatly diminished in old rats, whereas age-related changes were less pronounced in the isoforms epsilon, theta and zeta. After a short exposure (1 min) of muscle to 1,25(OH)2D3, increased amounts of PKC alpha and beta in muscle membranes and reverse translocation (from membrane to cytosol) of PKC epsilon were observed only in young animals. The data indicate that, in rat muscle, ageing impairs calcium-dependent PKC (alpha and beta) and calcium-independent PKC (delta, epsilon, theta and zeta) signal transduction pathways under selective regulation by 1,25(OH)2D3.     

Identification of the changes in phospholipase C isozymes in ischemic-reperfused rat heart

Phospholipase C (PLC) influences cardiac function. This study examined PLC isozymes of the cardiac sarcolemma (SL) membrane and in the cytosol compartment in isolated perfused rat hearts subjected to global ischemia for 30 min followed by up to 30 min of reperfusion. Although the total SL PLC activity was decreased in ischemia and increased upon reperfusion, differential changes in PLC isozymes were detected. PLC beta(1) mRNA and SL protein abundance and activity were increased in ischemia, with concomitant decreases in activity and protein level in the cytosol. On the other hand, upon reperfusion, PLC beta(1) activity was decreased, but remained higher than control values. Although no change in the PLC delta(1) mRNA level in ischemia was detected, SL PLC delta(1) activity and content were depressed. Furthermore, in the cytosol, PLC delta(1) activity was increased, but the protein level decreased. SL PLC gamma(1) activity was decreased, independent of gene expression and protein content; however, decreases in the activity and protein abundance were detected in the cytosol. Increases in PLC gamma(1) and delta(1) activities occurred upon reperfusion, but were not accounted for by altered mRNA and protein levels. The results indicate that ischemia-reperfusion induces differential changes in PLC isozymes.     

Activation of betagamma subunits of G(i2) and G(i3) proteins by basic secretagogues induces exocytosis through phospholipase Cbeta and arachidonate release through phospholipase Cgamma in mast cells.

Mast cells are activated by Ag-induced clustering of IgE bound to FcepsilonRI receptors or by basic secretagogues that stimulate pertussis toxin-sensitive heterotrimeric G proteins. The cell response includes the secretion of stored molecules, such as histamine, through exocytosis and of de novo synthesized mediators, such as arachidonate metabolites. The respective roles of G proteins alpha and betagamma subunits as well as various types of phospholipase C (PLC) in the signaling pathways elicited by basic secretagogues remain unknown. We show that a specific Ab produced against the C-terminus of Galpha(i3) and an anti-recombinant Galpha(i2) Ab inhibited, with additive effects, both exocytosis and arachidonate release from permeabilized rat peritoneal mast cells elicited by the basic secretagogues mastoparan and spermine. A specific Ab directed against Gbetagamma dimers prevented both secretions. Anti-PLCbeta Abs selectively prevented exocytosis. The selective phosphatidylinositol 3-kinase inhibitor LY 294002 prevented arachidonate release without modifying exocytosis. Gbetagamma coimmunoprecipitated with PLCbeta and phosphatidylinositol 3-kinase. The anti-PLCgamma1 and anti-phospholipase A(2) Abs selectively blocked arachidonate release. Protein tyrosine phosphorylation was inhibited by anti-Gbetagamma Abs, LY294002, and anti PLCgamma1 Abs. These data show that the early step of basic secretagogue transduction is common to both signaling pathways, involving betagamma subunits of G(i2) and G(i3) proteins. Activated Gbetagamma interacts, on one hand, with PLCbeta to elicit exocytosis and, on the other hand, with phosphatidylinositol 3-kinase to initiate the sequential activation of PLCgamma1, tyrosine kinases, and phospholipase A(2), leading to arachidonate release.     

Norepinephrine stimulates arachidonic acid release from vascular smooth muscle via activation of cPLA2

The mechanism of agonist-activated arachidonate release wasstudied in segments of rat tail artery. Tail artery segments were prelabeled with[³H]arachidonate andthen stimulated with norepinephrine (NE), and the radioactivity of theextracellular medium was determined. NE stimulated arachidonate releasefrom the tissue without increasing arachidonic acid levels withincellular cytosol or crude membranes. About 90% of the extracellularradioactivity was shown to be unmetabolized arachidonate by TLC.Arachidonic acid release was not inhibited by the removal of theendothelium from the artery. NE exerted a half-maximal effect ata concentration of 0.2 µM. NE-stimulated arachidonate release was notinhibited by blockers of phospholipase C (U-73122), diacylglycerollipase (RHC-80267), secretory phospholipase A₂ (manoalide),calcium-insensitive phospholipase A₂ (HELSS), or-adrenergic receptors (propranolol). NE-stimulated arachidonic acidrelease was inhibited by blockers of cytosolic phospholipase A₂(cPLA₂)(AACOCF₃),₁-adrenergic receptors(prazosin), and specific G proteins (pertussis toxin). This indicatedthat NE stimulated arachidonate release from vascular smooth muscle via activation of -adrenergic receptors, eitherG_i orG_o, andcPLA₂. NE-activated arachidonicacid release from vascular smooth muscle may play a role in forcegeneration by the tissue. Perhaps arachidonic acid extends the effectof NE on one specific smooth muscle cell to its nearby neighbor cells.

     

Phospholipase C isoforms are localized at the cleavage furrow during cytokinesis

It has recently been demonstrated that phosphatidylinositol 4,5-bisphosphate (PIP2) is localized at the cleavage furrow in dividing cells and its hydrolysis is required for complete cytokinesis, suggesting a pivotal role of PIP2 in cytokinesis. Here, we report that at least three mammalian isoforms of phosphoinositide-specific phospholipase C (PLC), PLCdelta1, PLCdelta3 and PLCbeta1, are localized to the cleavage furrow during cytokinesis. Targeting of the delta1 isoform to the furrow depends on the specific interaction between the PH domain and PIP2 in the plasma membrane. The necessity of active PLC in animal cell cytokinesis was confirmed using the specific inhibitors for PIP2 hydrolysis. These results support the model that activation of selected PLC isoforms at the cleavage furrow controls progression of cytokinesis through regulation of PIP2 levels: induction of the cleavage furrow by a contractile ring consisting of actomyosin is regulated by PIP2-dependent actin-binding proteins and formation of specific lipid domains required for membrane separation is affected by alterations in the lipid composition of the furrow.     

Basal protein kinase Cδ activity is required for membrane localization and activity of TRPM4 channels in cerebral artery smooth muscle cells

The melastatin (M) transient receptor potential channel (TRP) channel TRPM4 is a critical regulator of vascular smooth muscle cell membrane potential and contractility. We recently reported that PKCδ activity influences smooth muscle cell excitability by promoting translocation of TRPM4 channel protein to the plasma membrane. Here we further investigate the relationship between membrane localization of TRPM4 protein and channel activity in native cerebral arterial myocytes. We find that TRPM4 immunolabeling is primarily located at or near the plasma membrane of freshly isolated cerebral artery smooth muscle cells. However, siRNA mediated downregulation of PKCδ or brief (15 min) inhibition of PKCδ activity with rottlerin causes TRPM4 protein to move away from the plasma membrane and into the cytosol. In addition, we find that PKCδ inhibition diminishes TRPM4-dependent currents in smooth muscle cells patch clamped in the amphotericin B perforated patch configuration. We conclude that TRPM4 channels are mobile in native cerebral myocytes and that basal PKCδ activity supports excitability of these cells by maintaining localization TRPM4 protein at the plasma membrane.