Irene Litosch

Regulation of phosphoinositide breakdown by guanine nucleotides

Phosphoinositide hydrolysis is coupled to receptor systems involved in the elevation of cytosolic Ca2+ and activation of protein kinase C. In cell-free systems, guanine nucleotides are required to transduce the effects of receptor activation to phosphoinositide breakdown. Non-hydrolyzable guanine nucleotides stimulate phosphoinositide breakdown in permeabilized cells as well as membranes prepared from salivary glands, GH3 cells, neutrophils, hepatocytes and cerebral cortical tissue. In blowfly salivary gland membranes, 5-hydroxytryptamine stimulates a guanine-nucleotide dependent breakdown of both endogenous and exogenous phosphoinositide substrate through activation of phospholipase C. These data suggest that a GTP-binding protein modulates phospholipase C activity. The identity of this GTP-binding protein has not been established but may resemble other regulatory GTP-binding proteins which have been identified as transducing proteins in a variety of receptor systems.

Regulatory GTP-binding proteins: Emerging concepts on their role in cell function

The last few years have evidenced a tremendous expansion in our appreciation of the role of regulatory GTP-binding proteins in cellular activation. The availability of cholera and pertussis toxins to detect G proteins as well as methodological advances in the study of cellular function has afforded the opportunity to examine G protein participation in many cellular events. Regulation of adenylyl cyclase and cyclic GMP phosphodiesterase by G proteins has been demonstrated. Phosphatidylinositol-4,5-biphosphate specific phospholipase C activity appears to be subject to G protein control. G proteins regulate inward K+ and Ca2+ channels through a mechanism which may be independent of effects on the above mentioned enzymes. Certainly, the number of G proteins which have been identified from sequencing of complementary DNA affords the potential for G protein involvement in many cellular events. Only three G proteins have however been isolated and functionally characterized, Gs, Gi and transducin. Whether all the functions of these proteins have been identified remains to be seen.

Synergistic activation of rat hepatocyte glycogen phosphorylase by A23187 and phorbol ester.

The combination of 1.6 microM 4 beta phorbol, 12 beta myristate, 13 alpha acetate (PMA) and 1 microM A23187 produced a five-fold greater stimulation of rat hepatocyte glycogen phosphorylase activity than was seen with PMA alone. Vasopressin activation of glycogen phosphorylase was comparable to that seen with PMA plus A23187. Glycogen phosphorylase activity due to PMA plus A23187 was increased significantly after 30 sec, maximal at 120 and sustained at elevated levels for 240 sec. In contrast, activation due to vasopressin was maximal at 30 sec followed by a decrease. The addition of PMA 5 min prior to the A23187 abolished the synergism between these two agents. These data are compatible with the hypothesis that diacylglycerol and Ca2+ synergistically increase glycogen phosphorylase activity in rat hepatocytes.

Structural Determinants for Phosphatidic Acid Regulation of Phospholipase C-β1

Signaling from G protein-coupled receptors to phospholipase C-β (PLC-β) is regulated by coordinate interactions among multiple intracellular signaling molecules. Phosphatidic acid (PA), a signaling phospholipid, binds to and stimulates PLC-β1 through a mechanism that requires the PLC-β1 C-terminal domain. PA also modulates Gαq stimulation of PLC-β1. These data suggest that PA may have a key role in the regulation of PLC-β1 signaling in cells. The present studies addressed the structural requirements and the mechanism for PA regulation of PLC-β1. We used a combination of enzymatic assays, PA-binding assays, and circular dichroism spectroscopy to evaluate the interaction of PA with wild-type and mutant PLC-β1 proteins and with fragments of the Gαq binding domain. The results identify a region that includes the αA helix and flexible loop of the Gαq-binding domain as necessary for PA regulation. A mutant PLC-β1 with multiple alanine/glycine replacements for residues 944LIKEHTTKYNEIQN957 was markedly impaired in PA regulation. The high affinity and low affinity component of PA stimulation was reduced 70% and PA binding was reduced 45% in this mutant. Relative PLC stimulation by PA increased with PLC-β1 concentration in a manner suggesting cooperative binding to PA. Similar concentration dependence was observed in the PLC-β1 mutant. These data are consistent with a model for PA regulation of PLC-β1 that involves cooperative interactions, probably PLC homodimerization, that require the flexible loop region, as is consistent with the dimeric structure of the Gαq-binding domain. PA regulation of PLC-β1 requires unique residues that are not required for Gαq stimulation or GTPase-activating protein activity.

Novel Mechanisms for Feedback Regulation of Phospholipase C‐β Activity

The receptor‐regulated phospholipase C‐ β(PLC‐ β) signaling pathway is an important component in a network of signaling cascades that regulate cell function. PLC‐ βsignaling has been implicated in the regulation of cardiovascular function and neuronal plasticity. The G q family of G proteins mediate receptor stimulation of PLC‐ βactivity at the plasma membrane. Mitogens stimulate the activity of a nuclear pool of PLC‐ β. Stimulation of PLC‐ βactivity results in the rapid hydrolysis of phosphatidylinositol‐4,5‐bisphosphate, with production of inositol‐1,4,5‐trisphosphate and diacylglycerol, intracellular mediators that increase intracellular Ca 2+ levels and activate protein kinase C activity, respectively. Diacylglycerol kinase converts diacylglycerol to phosphatidic acid, a newly emerging intracellular mediator of hormone action that targets a number of signaling proteins. Activation of the G q linked PLC‐ βsignaling pathway can also generate additional signaling lipids, including phosphatidylinositol‐3‐phosphate and phosphatidylinositol‐3,4,5‐trisphosphate, which regulate the activity and/or localization of a number of proteins. Novel feedback mechanisms, directed at the level of G q and PLC‐ β, have been identified. PLC‐ βand regulators of G protein signaling (RGS) function as GTPase‐activating proteins on G q to control the amplitude and duration of stimulation. Protein kinases phosphorylate and regulate the activation of specific PLC‐ βisoforms. Phosphatidic acid regulates PLC‐ β1 activity and stimulation of PLC‐ β1 activity by G proteins. These feedback mechanisms coordinate receptor signaling and cell activation. Feedback mechanisms constitute possible targets for pharmacological intervention in the treatment of disease.

III. Hormonal regulation of phosphatidylinositol breakdown

Cyclic AMP and Ca2+ are intracellular mediators of hormone action. Catecholamines interact with beta adrenoceptors to activate adenylate cyclase or with alpha 2 adrenoceptors to inhibit adenylate cyclase. Alpha 1 adrenoceptor activation results in elevation of cytosol Ca2+ and an increased breakdown of phosphatidylinositol. In blowfly salivary glands, 5-hydroxytryptamine (5-HT) interacts with beta type receptors resulting in adenylate cyclase activation while alpha type receptors are involved in phosphatidylinositol breakdown and elevation of cytosol Ca2+. The link between Ca2+ mobilization and phosphatidylinositol breakdown remains to be established but breakdown of the receptor-regulated pool of phosphatidylinositol is not secondary to the rise in Ca2+. Direct addition of 5-HT to cell-free homogenates of blowfly salivary glands results in activation of phosphatidylinositol breakdown in the absence of Ca2+. In rat liver plasma membrane preparations, vasopressin increases phosphatidylinositol breakdown in the absence of Ca2+ or cytosol if deoxycholate is present. The data do not indicate whether hormone activation increases the availability of substrate to enzymatic hydrolysis or activates phospholipase C. However, they demonstrate that hormones directly accelerate phosphatidylinositol breakdown.

Norepinephrine stimulates the production of inositol trisphosphate and inositol tetrakisphosphate in rat aorta

Norepinephrine stimulated the rapid hydrolysis of [3H]phosphatidylinositol-4,5-bisphosphate in rat aorta with a maximal decrease of 30% within 60 sec of stimulation. Levels of [3H]phosphatidylinositol-4,5-bisphosphate returned to control by 5 min despite the continued presence of agonist. Hydrolysis of [3H]phosphatidylinositol-4,5-bisphosphate occurred concurrently with the formation of inositol phosphates. Inositol-tris and tetrakisphosphate levels were increased within 30 sec of agonist stimulation. Increases in inositol phosphate levels due to agonist were dose-dependent with half-maximal activation at 1 microM norepinephrine.

Phosphatidic acid regulates signal output by G protein coupled receptors through direct interaction with phospholipase C-β1 ☆

Phosphatidic acid (PA), generated downstream of monomeric Rho GTPases via phospholipase D (PLD) and additionally by diacylglycerol kinases (DGK), both stimulates phospholipase C-beta(1) (PLC-beta(1)) and potentiates stimulation of PLC-beta(1) activity by Galpha(q) in vitro. PA is a potential candidate for integrating signaling by monomeric and heterotrimeric G proteins to regulate signal output by G protein coupled receptors (GPCR), and we have sought to understand the mechanisms involved. We previously identified the region spanning residues 944-957, lying within the PLC-beta(1) C-terminus alphaA helix and flexible loop of the Galpha(q) binding domain, as required for stimulation of lipase activity by PA in vitro. Regulation by PA does not require residues essential for stimulation by Galpha(q) or GTPase activating activity. The present studies evaluated shorter alanine/glycine replacement mutants and finally point mutations to identify Tyr(952) and Ile(955) as key determinants for regulation by PA, assessed by both in vitro enzymatic and cell-based co-transfection assays. Replacement of Tyr(952) and Ile(955), PLC-beta(1) (Y952G/I955G), results in an 85% loss in stimulation by PA relative to WT-PLC-beta(1) in vitro. COS 7 cells co-transfected with PLC-beta(1) (Y952G/I955G) demonstrate a 10-fold increase in the EC(50) for stimulation and a 60% decrease in maximum stimulation by carbachol via Galpha(q) linked m1 muscarinic receptors, relative to cells co-transfected with WT-PLC-beta(1) but otherwise similar conditions. Residues required for regulation by PA are not essential for stimulation by G protein subunits. WT-PLC-beta(1) and PLC-beta(1) (Y952G/I955G) activity is increased comparably by co-transfection with Galpha(q) and neither is markedly affected by co-transfection with Gbeta(1)gamma(2). Inhibiting PLD-generated PA production by 1-butanol has little effect on maximum stimulation, but shifts the EC(50) for agonist stimulation of WT-PLC-beta(1) by 10-fold, producing a phenotype similar to PLC-beta(1) (Y952G/I955G) with respect to agonist potency. 1-Butanol is without effect on carbachol stimulated PLC activity in cells co-transfected with either PLC-beta(1)(Y952G/I955G) or on endogenous PLC activity, indicating that regulation by PA requires direct interaction with the PLC-beta(1) PA-binding region. These data show that endogenous PA regulates signal output by Galpha(q)-linked GPCRs in transfected cells directly through PLC-beta(1). Galpha(q) and PA may co-ordinate to regulate signaling. Regulation by PA may constitute part of a mechanism that routes receptor signaling to specific PLC isoforms.

Effect of thyroid status on α- and β-catecholamine responsiveness of hamster adipocytes

Abstract It has been suggested that part of the increased β-catecholamine responsiveness in hyperthyroid animals is due to a decrease in α-catecholamine action. The present results indicate that neither hyperthyroidism nor hypothyroidism altered the α 2 -adrenergic inhibition of adenylate cyclase or the α 1 -adrenergic stimulation of phosphatidylinositol turnover in adipocytes from the white adipose tissue of hamster. No effect of hyperthyroidism was found on the K d of [ 3 H]dihydroegocryptine or the number of binding sites in membranes prepared from hamster adipocyte tissue. The stimulation of cyclic AMP due to β-catecholamines was enhanced in adipocytes from hyperthyroid hamster, as was lipolysis. However, in adipocytes from hyperthyroid hamster the maximal stimulation of cyclic AMP due to isoproterenol, ACTH or epinephrine plus yohimbine, as seen in the presence of adenosine deaminase and theophylline, was less than in adipocytes from euthyroid hamsters. The activation of adenylate cyclase by isoproterenol was the same in membranes from hyperthyroid as compared to those from euthyroid hamsters in the absence or presence of guanine nucleotides. These data suggest that thyroid status has little effect on α-catecholamine action but enhances the activation of lipolysis by β-catecholamine agonists.

Phosphatidic acid potentiates Gαq stimulation of phospholipase C-β1 signaling

Phosphatidic acid (PA) is interactive with G(alpha)q-linked agonists to stimulate GPCR signaling via phospholipase C-beta(1) (PLC-beta(1)). Phorbol 12-myristate 13-acetate (PMA) increases cellular levels of PA and phospholipase D activity (PLD). This study evaluated whether PMA can stimulate PLC-beta(1) activity via PA, independent of GPCR input in transfected COS 7 cells. PMA alone had little effect on PLC activity in cells co-transfected with PLC-beta(1) and G(alpha)q. Activated G(alpha)q, induced by co-transfecting muscarinic cholinergic receptor (m1R), was necessary for stimulation of PLC-beta(1) activity by PMA. Stimulation by PMA was dependent on the PA-regulatory motif of PLC-beta(1) implicating PA in this mechanism. PLD1 knockdown by antisense decreased responsiveness of PLC-beta(1) to both PMA and carbachol. PA alone thus has little effect on PLC-beta(1) activity, but PA and PLD1 synergize with activated G(alpha)q to stimulate PLC-beta(1) signaling. Coordinate interaction with activated G(alpha)q may serve as an important mechanism to fine tune response to ligands while preventing spurious initiation of PLC-beta signaling by PA in cells.