Phospholipase C beta2 association with phospholipid interfaces assessed by fluorescence resonance energy transfer. G protein betagamma subunit-mediated translocation is not required for enzyme activation

Molecular regulation of PLCβ signaling

Phospholipase C (PLC) enzymes convert the membrane phospholipid phosphatidylinositol-4,5-bisphosphate (PIP2) into inositol-1,4,5-triphosphate (IP3) and diacylglycerol (DAG). IP3 and DAG regulate numerous downstream pathways, eliciting diverse and profound cellular changes and physiological responses. In the six PLC subfamilies in higher eukaryotes, PLCβ is intensively studied due to its prominent role in regulating crucial cellular events underlying many processes including cardiovascular and neuronal signaling, and associated pathological conditions. In addition to GαqGTP, Gβγ generated upon G protein heterotrimer dissociation also regulates PLCβ activity. Here, we not only review how Gβγ directly activates PLCβ, and also extensively modulates Gαq-mediated PLCβ activity, but also provide a structure-function overview of PLC family members. Given that Gαq and PLCβ are oncogenes, and Gβγ shows unique cell-tissue-organ specific expression profiles, Gγ subtype-dependent signaling efficacies, and distinct subcellular activities, this review proposes that Gβγ is a major regulator of Gαq-dependent and independent PLCβ signaling.

Structure and regulation of phospholipase Cβ and ε at the membrane

Phospholipase C (PLC) β and ε enzymes hydrolyze phosphatidylinositol (PI) lipids in response to direct interactions with heterotrimeric G protein subunits and small GTPases, which are activated downstream of G protein-coupled receptors (GPCRs) and receptor tyrosine kinases (RTKs). PI hydrolysis generates second messengers that increase the intracellular Ca²⁺ concentration and activate protein kinase C (PKC), thereby regulating numerous physiological processes. PLCβ and PLCε share a highly conserved core required for lipase activity, but use different strategies and structural elements to autoinhibit basal activity, bind membranes, and engage G protein activators. In this review, we discuss recent structural insights into these enzymes and the implications for how they engage membranes alone or in complex with their G protein regulators.

G-protein βγ subunits as multi-functional scaffolds and transducers in G-protein-coupled receptor signaling

G-protein βγ subunits are key participants in G-protein signaling. These subunits facilitate interactions between receptors and G proteins that are critical for the G protein activation cycle at the plasma membrane. In addition, they play roles in directly transducing signals to an ever expanding range of downstream targets, including integral membrane and cytosolic proteins. Emerging data indicate that Gβγ may play additional roles at intracellular compartments including endosomes, the Golgi apparatus, and the nucleus. Here, we discuss the molecular and structural basis for their ability to coordinate this wide range of cellular activities.

Gαq and the Phospholipase Cβ3 X-Y Linker Regulate Adsorption and Activity on Compressed Lipid Monolayers

Phospholipase Cβ (PLCβ) enzymes are peripheral membrane proteins required for normal cardiovascular function. PLCβ hydrolyzes phosphatidylinositol 4,5-bisphosphate, producing second messengers that increase intracellular Ca²⁺ level and activate protein kinase C. Under basal conditions, PLCβ is autoinhibited by its C-terminal domains and by the X-Y linker, which contains a stretch of conserved acidic residues required for interfacial activation. Following stimulation of G protein-coupled receptors, the heterotrimeric G protein subunit Gα_q allosterically activates PLCβ and helps orient the activated complex at the membrane for efficient lipid hydrolysis. However, the molecular basis for how the PLCβ X-Y linker, its C-terminal domains, Gα_q, and the membrane coordinately regulate activity is not well understood. Using compressed lipid monolayers and atomic force microscopy, we found that a highly conserved acidic region of the X-Y linker is sufficient to regulate adsorption. Regulation of adsorption and activity by the X-Y linker also occurs independently of the C-terminal domains. We next investigated whether Gα_q-dependent activation of PLCβ altered interactions with the model membrane. Gα_q increased PLCβ adsorption in a manner that was independent of the PLCβ regulatory elements and targeted adsorption to specific regions of the monolayer in the absence of the C-terminal domains. Thus, the mechanism of Gα_q-dependent activation likely includes a spatial component.

Phospholipase Cβ3 Membrane Adsorption and Activation Are Regulated by Its C-Terminal Domains and Phosphatidylinositol 4,5-Bisphosphate

Phospholipase Cβ (PLCβ) enzymes hydrolyze phosphatidylinositol 4,5-bisphosphate to produce second messengers that regulate intracellular Ca²⁺, cell proliferation, and survival. Their activity is dependent upon interfacial activation that occurs upon localization to cell membranes. However, the molecular basis for how these enzymes productively interact with the membrane is poorly understood. Herein, atomic force microscopy demonstrates that the ∼300-residue C-terminal domain promotes adsorption to monolayers and is required for spatial organization of the protein on the monolayer surface. PLCβ variants lacking this C-terminal domain display differences in their distribution on the surface. In addition, a previously identified autoinhibitory helix that binds to the PLCβ catalytic core negatively impacts membrane binding, providing an additional level of regulation for membrane adsorption. Lastly, defects in phosphatidylinositol 4,5-bisphosphate hydrolysis also alter monolayer adsorption, reflecting a role for the active site in this process. Together, these findings support a model in which multiple elements of PLCβ modulate adsorption, distribution, and catalysis at the cell membrane.

Structural insights into phospholipase C-β function

Phospholipase C (PLC) enzymes convert phosphatidylinositol-4,5-bisphosphate into the second messengers diacylglycerol and inositol-1,4,5-triphosphate. The production of these molecules promotes the release of intracellular calcium and activation of protein kinase C, which results in profound cellular changes. The PLCβ subfamily is of particular interest given its prominent role in cardiovascular and neuronal signaling and its regulation by G protein-coupled receptors, as PLCβ is the canonical downstream target of the heterotrimeric G protein Gαq. However, this is not the only mechanism regulating PLCβ activity. Extensive structural and biochemical evidence has revealed regulatory roles for autoinhibitory elements within PLCβ, Gβγ, small molecular weight G proteins, and the lipid membrane itself. Such complex regulation highlights the central role that this enzyme plays in cell signaling. A better understanding of the molecular mechanisms underlying the control of its activity will greatly facilitate the search for selective small molecule modulators of PLCβ.

Latest developments in experimental and computational approaches to characterize protein-lipid interactions

Understanding the functional roles of all the molecules in cells is an ultimate goal of modern biology. An important facet is to understand the functional contributions from intermolecular interactions, both within a class of molecules (e.g. protein-protein) or between classes (e.g. protein-DNA). While the technologies for analyzing protein-protein and protein-DNA interactions are well established, the field of protein-lipid interactions is still relatively nascent. Here, we review the current status of the experimental and computational approaches for detecting and analyzing protein-lipid interactions. Experimental technologies fall into two principal categories, namely solution-based and array-based methods. Computational methods include large-scale data-driven analyses and predictions/dynamic simulations based on prior knowledge of experimentally identified interactions. Advances in the experimental technologies have led to improved computational analyses and vice versa, thereby furthering our understanding of protein-lipid interactions and their importance in biological systems.

WDR26 functions as a scaffolding protein to promote Gβγ-mediated phospholipase C β2 (PLCβ2) activation in leukocytes

We have recently identified WDR26 as a novel WD40 repeat protein that binds Gβγ and promotes Gβγ signaling during leukocyte migration. Here, we have determined the mechanism by which WDR26 enhances Gβγ-mediated phospholipase C β2 (PLCβ2) activation in leukocytes. We show that WDR26 not only directly bound Gβγ but also PLCβ2. The binding sites of WDR26 and PLCβ2 on Gβ1γ2 were overlapping but not identical. WDR26 used the same domains for binding Gβγ and PLCβ but still formed a signaling complex with Gβγ and PLCβ2 probably due to the fact that WDR26 formed a higher order oligomer through its Lis homology and C-terminal to LisH (LisH-CTLH) and WD40 domains. Additional studies indicated that the formation of higher order oligomers was required for WDR26 to promote PLCβ2 interaction with and activation by Gβγ. Moreover, WDR26 was required for PLCβ2 translocation from the cytosol to the membrane in polarized leukocytes, and the translocation of PLCβ2 was sufficient to cause partial activation of PLCβ2. Collectively, our data indicate that WDR26 functions as a scaffolding protein to promote PLCβ2 membrane translocation and interaction with Gβγ, thereby enhancing PLCβ2 activation in leukocytes. These findings have identified a novel mechanism of regulating Gβγ signaling through a scaffolding protein.

Full-length Gα(q)-phospholipase C-β3 structure reveals interfaces of the C-terminal coiled-coil domain

Phospholipase C-β (PLCβ) is directly activated by Gα_q, but the molecular basis for how its distal C-terminal domain (CTD) contributes to maximal activity is poorly understood. Herein we present both the crystal structure and cryo-EM 3D reconstructions of human full-length PLCβ3 in complex with murine Gα_q. The distal CTD forms an extended, monomeric helical bundle consisting of three anti-parallel segments with structural similarity to membrane-binding bin–amphiphysin–Rvs (BAR) domains. Sequence conservation of the distal CTD identifies putative membrane and protein interaction sites, the latter of which bind the N-terminal helix of Gα_q in both the crystal structure and cryo-EM reconstructions. Functional analysis suggests the distal CTD plays roles in membrane targeting and in optimizing the orientation of the catalytic core at the membrane for maximal rates of lipid hydrolysis.

The correlation between multidomain enzymes and multiple activation mechanisms--the case of phospholipase Cβ and its membrane interactions

Phospholipase Cβ2 (PLCβ2) is a large, multidomain enzyme that catalyzes the hydrolysis of the signaling lipid phosphoinositol 4,5 bisphosphate (PIP2) to promote mitogenic and proliferative changes in the cell. PLCβ2 is activated by Gα and Gβγ subunits of heterotrimeric G proteins, as well as small G proteins and specific peptides. Activation depends on the nature of the membrane surface. Recent crystal structures suggest one model of activation involving the movement of a small autoinhibitory loop upon membrane binding of the enzyme. Additionally, solution studies indicate multiple levels of activation that involve changes in the membrane orientation as well as interdomain movement. Here, we review the wealth of biochemical studies of PLCβ2-G protein activation and propose a comprehensive model that accounts for both the crystallographic and solution results.

Quantification of protein-lipid selectivity using FRET

Membrane proteins exhibit different affinities for different lipid species, and protein-lipid selectivity regulates the membrane composition in close proximity to the protein, playing an important role in the formation of nanoscale membrane heterogeneities. The sensitivity of Förster resonance energy transfer (FRET) for distances of 10 A up to 100 A is particularly useful to retrieve information on the relative distribution of proteins and lipids in the range over which protein-lipid selectivity is expected to influence membrane composition. Several FRET-based methods applied to the quantification of protein-lipid selectivity are described herein, and different formalisms applied to the analysis of FRET data for particular geometries of donor-acceptor distribution are critically assessed.

G protein βγ subunits: central mediators of G protein-coupled receptor signaling

G protein betagamma subunits are central participants in G protein-coupled receptor signaling pathways. They interact with receptors, G protein alpha subunits and downstream targets to coordinate multiple, different GPCR functions. Much is known about the biology of Gbetagamma subunits but mysteries remain. Here, we will review what is known about general aspects of structure and function of Gbetagamma as well as discuss emerging mechanisms for regulation of Gbetagamma signaling. Recent data suggest that Gbetagamma is a potential therapeutic drug target. Thus, a thorough understanding of the molecular and physiological functions of Gbetagamma has significant implications.

Stimulation of phospholipase Cbeta by membrane interactions, interdomain movement, and G protein binding--how many ways can you activate an enzyme?

Signaling proteins are usually composed of one or more conserved structural domains. These domains are usually regulatory in nature by binding to specific activators or effectors, or species that regulate cellular location, etc. Inositol-specific mammalian phospholipase C (PLC) enzymes are multidomain proteins whose activities are controlled by regulators, such as G proteins, as well as membrane interactions. One of these domains has been found to bind membranes, regulators, and activate the catalytic region. The recently solved structure of a major region of PLC-beta2 together with the structure of PLC-delta1 and a wealth of biochemical studies poises the system towards an understanding of the mechanism through which their regulations occurs.

Signaling by a non-dissociated complex of G protein βγ and α subunits stimulated by a receptor-independent activator of G protein signaling, AGS8

Accumulating evidence suggests that heterotrimeric G protein activation may not require G protein subunit dissociation. Results presented here provide evidence for a subunit dissociation-independent mechanism for G protein activation by a receptor-independent activator of G protein signaling, AGS8. AGS8 is a member of the AGS group III family of AGS proteins thought to activate G protein signaling primarily through interactions with Gbetagamma subunits. Results are presented demonstrating that AGS8 binds to the effector and alpha subunit binding "hot spot" on Gbetagamma yet does not interfere with Galpha subunit binding to Gbetagamma or phospholipase C beta2 activation. AGS8 stimulates activation of phospholipase C beta2 by heterotrimeric Galphabetagamma and forms a quaternary complex with Galpha(i1), Gbeta(1)gamma(2), and phospholipase C beta2. AGS8 rescued phospholipase C beta binding and regulation by an inactive beta subunit with a mutation in the hot spot (beta(1)(W99A)gamma(2)) that normally prevents binding and activation of phospholipase C beta2. This demonstrates that, in the presence of AGS8, the hot spot is not used for Gbetagamma interactions with phospholipase C beta2. Mutation of an alternate binding site for phospholipase C beta2 in the amino-terminal coiled-coil region of Gbetagamma prevented AGS8-dependent phospholipase C binding and activation. These data implicate a mechanism for AGS8, and potentially other Gbetagamma binding proteins, for directing Gbetagamma signaling through alternative effector activation sites on Gbetagamma in the absence of subunit dissociation.

Phospholipase Cβ3 is distributed in both somatodendritic and axonal compartments and localized around perisynapse and smooth endoplasmic reticulum in mouse Purkinje cell subsets

Phospholipase Cbeta3 (PLCbeta3) and PLCbeta4 are the two major isoforms in cerebellar Purkinje cells (PCs), displaying reciprocal expression across the cerebellum. Here, we examined subcellular distribution of PLCbeta3 in the mouse cerebellum by producing specific antibody. PLCbeta3 was detected as a particulate pattern of immunostaining in various PC elements. Like PLCbeta4, PLCbeta3 was richly distributed in somatodendritic compartments, where it was colocalized with molecules constituting the metabotropic glutamate receptor (mGluR1) signalling pathway, i.e. mGluR1alpha, G alpha q/G alpha 11 subunits of G q protein, inositol 1,4,5-trisphosphate receptor IP3R1, Homer1, protein kinase C PKCgamma, and diacylglycerol lipase DAGLalpha. Unlike PLCbeta4, PLCbeta3 was also distributed at low to moderate levels in PC axons, which were intense for IP3R1 and PKCgamma, low for G alpha q/G alpha 11, and negative for mGluR1alpha, Homer1, and DAGLalpha. By immunoelectron microscopy, PLCbeta3 was preferentially localized around the smooth endoplasmic reticulum in spines, dendrites, and axons of PCs, and also accumulated at the perisynapse of parallel fibre-PC synapses. Consistent with the ultrastructural localization, PLCbeta3 was biochemically enriched in the microsomal and postsynaptic density fractions. These results suggest that PLCbeta3 plays a major role in mediating mGluR1-dependent synaptic transmission, plasticity, and integration in PLCbeta3-dominant PCs, through eliciting Ca2+ release, protein phosphorylation, and endocannabinoid production at local somatodendritic compartments. Because PLCbeta3 can be activated by G betagamma subunits liberated from Gi/o and Gs proteins as well, axonal PLCbeta3 seems to modulate the conduction of action potentials through mediating local Ca2+ release and protein phosphorylation upon activation of a variety of G protein-coupled receptors other than mGluR1.

Analysis and pharmacological targeting of phospholipase C beta interactions with G proteins

Phosphatidylinositol-specific phospholipase C enzymes (PLC) catalyze hydrolysis of phosphatidylinositol 4,5-bisphosphate generating the second messengers diacylglycerol and inositol 1,4,5-triphosphate. Mammalian phosphoinositide-specific phospholipase C beta (PLCbeta) activity is regulated by the alpha(q) family of G-protein alpha subunits and by Gbetagamma subunits. Regulation of PLCbeta enzymatic activity can be assayed by reconstituting purified G-protein subunits with purified PLCbeta in the presence of phospholipid vesicles containing the substrate phosphatidylinositol 4,5-bisphosphate. This chapter describes methods for expression and purification of PLCbeta and Gbetagamma from insect cells, assay of G-protein-dependent regulation of PLC activity, and assessment of G-protein-PLC direct binding interactions. This combination of functional and direct binding analysis provides a powerful approach to characterizing PLC and G-protein interfaces, identifying inhibitors of this interaction, and potentially uncovering new modes of PLC regulation.

PGE(1) stimulation of HEK293 cells generates multiple contiguous domains with different [cAMP]: role of compartmentalized phosphodiesterases

There is a growing appreciation that the cyclic adenosine monophosphate (cAMP)–protein kinase A (PKA) signaling pathway is organized to form transduction units that function to deliver specific messages. Such organization results in the local activation of PKA subsets through the generation of confined intracellular gradients of cAMP, but the mechanisms responsible for limiting the diffusion of cAMP largely remain to be clarified. In this study, by performing real-time imaging of cAMP, we show that prostaglandin 1 stimulation generates multiple contiguous, intracellular domains with different cAMP concentration in human embryonic kidney 293 cells. By using pharmacological and genetic manipulation of phosphodiesterases (PDEs), we demonstrate that compartmentalized PDE4B and PDE4D are responsible for selectively modulating the concentration of cAMP in individual subcellular compartments. We propose a model whereby compartmentalized PDEs, rather than representing an enzymatic barrier to cAMP diffusion, act as a sink to drain the second messenger from discrete locations, resulting in multiple and simultaneous domains with different cAMP concentrations irrespective of their distance from the site of cAMP synthesis.

The pleckstrin homology domain of phospholipase Cbeta transmits enzymatic activation through modulation of the membrane-domain orientation

Phospholipase Cbeta (PLCbeta) enzymes are activated by Galpha q and Gbetagamma subunits and catalyze the hydrolysis of the minor membrane lipid phosphatidylinositol 4,5-bisphosphate [PI(4,5)P2]. Activation of PLCbeta2 by Gbetagamma subunits has been shown to be conferred through its N-terminal pleckstrin homology (PH) domain, although the underlying mechanism is unclear. Also unclear are observations that the extent of Gbetagamma activation differs on different membrane surfaces. In this study, we have identified a unique region of the PH domain of the PLCbeta2 domain (residues 71-88) which, when added to the enzyme as a peptide, causes enzyme activation similar to that with Gbetagamma subunits. This PH domain segment interacts strongly with membranes composed of lipid mixtures but not those containing lipids with electrically neutral zwitterionic headgroups. Also, addition of this segment perturbs interaction of the catalytic domain, but not the PH domain, with membrane surfaces. We monitored the orientation of the PH and catalytic domains of PLC by intermolecular fluorescence resonance energy transfer (FRET) using the Gbetagamma activatable mutant, PLCbeta2/delta1(C193S). We find an increase in the level of FRET with binding to membranes with mixed lipids but not to those containing only lipids with electrically neutral headgroups. These results suggest that enzymatic activation can be conferred through optimal association of the PHbeta71-88 region to specific membrane surfaces. These studies allow us to understand the basis of variations of Gbetagamma activation on different membrane surfaces.

G protein betagamma complex translocation from plasma membrane to Golgi complex is influenced by receptor gamma subunit interaction

On activation of a receptor the G protein betagamma complex translocates away from the receptor on the plasma membrane to the Golgi complex. The rate of translocation is influenced by the type of gamma subunit associated with the G protein. Complementary approaches--imaging living cells expressing fluorescent protein tagged G proteins and assaying reconstituted receptors and G proteins in vitro--were used to identify mechanisms at the basis of the translocation process. Translocation of Gbetagamma containing mutant gamma subunits with altered prenyl moieties showed that the differences in the prenyl moieties were not sufficient to explain the differential effects of geranylgeranylated gamma5 and farnesylated gamma11 on the translocation process. The translocation properties of Gbetagamma were altered dramatically by mutating the C terminal tail region of the gamma subunit. The translocation characteristics of these mutants suggest that after receptor activation, Gbetagamma retains contact with a receptor through the gamma subunit C terminal domain and that differential interaction of the activated receptor with this domain controls Gbetagamma translocation from the plasma membrane.

Regulatory interactions between the amino terminus of G-protein betagamma subunits and the catalytic domain of phospholipase Cbeta2

We previously identified a 10-amino acid region from the Y domain of phospholipase Cbeta2 (PLCbeta2) that associates with G-protein betagamma subunits (Sankaran, B., Osterhout, J., Wu, D., and Smrcka, A. V. (1998) J. Biol. Chem. 273, 7148-7154). We mapped the site for cross-linking of a synthetic peptide (N20K) corresponding to this Y domain region to Cys(25) within the amino-terminal coiled-coil domain of Gbetagamma (Yoshikawa, D. M., Bresciano, K., Hatwar, M., and Smrcka, A. V. (2001) J. Biol. Chem. 276, 11246-11251). Here, further experiments with a series of variable length cross-linking agents refined the site of N20K binding to within 4.4-6.7 angstroms of Cys(25). A mutant within the amino terminus of the Gbeta subunit, Gbeta(1)(23-27)gamma(2), activated PLCbeta2 more effectively than wild type, with no significant change in the EC(50), indicating that this region is directly involved in the catalytic regulation of PLCbeta2. This mutant was deficient in cross-linking to N20K, suggesting that a binding site for the peptide had been eliminated. Surprisingly, N20K could still inhibit Gbeta(1)(23-27)gamma(2)-dependent activation of PLC, suggesting a second N20K binding site. Competition analysis with a peptide that binds to the Galpha subunit switch II binding surface of Gbetagamma indicates a second N20K binding site at this surface. Furthermore, mutations to the N20K region within the Y-domain of full-length PLCbeta2 inhibited Gbetagamma-dependent regulation of the enzyme, providing further evidence for aGbetagamma binding site within the catalytic domain of PLCbeta2. The data support a model with two modes of PLC binding to Gbetagamma through the catalytic domain, where interactions with the amino-terminal coiled-coil domain are inhibitory, and interactions with the Galpha subunit switch II binding surface are stimulatory.

Signaling complex formation of phospholipase Cβ4 with metabotropic glutamate receptor type 1α and 1,4,5-trisphosphate receptor at the perisynapse and endoplasmic reticulum in the mouse brain

Upon activation of cell surface receptors coupled to the Gq subclass of G proteins, phospholipase C (PLC) beta hydrolyses membrane phospholipid to yield a pair of second messengers, inositol 1,4,5-trisphosphate (IP3) and 1,2-diacylglycerol. PLCbeta4 has been characterized as the isoform enriched in cerebellar Purkinje cells (PCs) and the retina and involved in motor and visual functions. Here we examined cellular and subcellular distributions of PLCbeta4 in adult mouse brains. Immunohistochemistry showed that high levels of PLCbeta4 were detected in the somatodendritic domain of neuronal populations expressing the metabotropic glutamate receptor (mGluR) type 1alpha, including olfactory periglomerular cells, neurons in the bed nucleus anterior commissure, thalamus, substantia nigra, inferior olive, and unipolar brush cells and PCs in the cerebellum. Low to moderate levels were detected in many other mGluR1alpha-positive neurons and in a few mGluR1alpha-negative neurons. In PCs, immunogold electron microscopy localized PLCbeta4 to the perisynapse, at which mGluR1alpha is concentrated, and to the smooth endoplasmic reticulum in dendrites and spines, an intracellular Ca2+ store gated by IP3 receptors. In the cerebellum, immunoblot demonstrated its concentrated distribution in the post-synaptic density and microsomal fractions, where mGluR1alpha and type 1 IP3 receptor were also greatly enriched. Furthermore, PLCbeta4 formed coimmunoprecipitable complexes with mGluR1alpha, type 1 IP3 receptor and Homer 1. These results suggest that PLCbeta4 is preferentially localized in the perisynapse and smooth endoplasmic reticulum as a component of the physically linked phosphoinositide signaling complex. This close molecular relationship might provide PLCbeta4 with a high-fidelity effector function to mediate various neuronal responses under physiological and pathophysiological conditions.

Use of chimeric fluorescent proteins and fluorescence resonance energy transfer to monitor cellular responses

In recent years, the development of new technologies based on the green fluorescent protein and fluorescence resonance energy transfer has introduced a new perspective in the study of cell biology. Real-time imaging of fluorescent biosensors has made it possible to directly visualize individual molecular events as they happen in intact, live cells, providing important and original insights for our understanding of biologically relevant problems. This review discusses some essential methodological aspects concerning the generation and use of fluorescence resonance energy transfer-based biosensors and presents selected examples of specific applications that highlight the power of this technology.

Molecular modeling of the membrane targeting of phospholipase C pleckstrin homology domains

Phospholipases C (PLCs) reversibly associate with membranes to hydrolyze phosphatidylinositol-4, 5-bisphosphate (PI[4,5]P(2)) and comprise four main classes: beta, gamma, delta, and epsilon. Most eukaryotic PLCs contain a single, N-terminal pleckstrin homology (PH) domain, which is thought to play an important role in membrane targeting. The structure of a single PLC PH domain, that from PLCdelta1, has been determined; this PH domain binds PI(4,5)P(2) with high affinity and stereospecificity and has served as a paradigm for PH domain functionality. However, experimental studies demonstrate that PH domains from different PLC classes exhibit diverse modes of membrane interaction, reflecting the dissimilarity in their amino acid sequences. To elucidate the structural basis for their differential membrane-binding specificities, we modeled the three-dimensional structures of all mammalian PLC PH domains by using bioinformatic tools and calculated their biophysical properties by using continuum electrostatic approaches. Our computational analysis accounts for a large body of experimental data, provides predictions for those PH domains with unknown functions, and indicates functional roles for regions other than the canonical lipid-binding site identified in the PLCdelta1-PH structure. In particular, our calculations predict that (1). members from each of the four PLC classes exhibit strikingly different electrostatic profiles than those ordinarily observed for PH domains in general, (2). nonspecific electrostatic interactions contribute to the membrane localization of PLCdelta-, PLCgamma-, and PLCbeta-PH domains, and (3). phosphorylation regulates the interaction of PLCbeta-PH with its effectors through electrostatic repulsion. Our molecular models for PH domains from all of the PLC classes clearly demonstrate how a common structural fold can serve as a scaffold for a wide range of surface features and biophysical properties that support distinctive functional roles.

The Pleckstrin homology domains of phospholipases C-beta and -delta confer activation through a common site

Mammalian inositol-specific phospholipase C-beta2 (PLC beta 2) and PLC delta 1 differ in their cellular activators. PLC beta 2 can be activated by G beta gamma subunits, whereas PLC delta 1 can be activated by phosphatidylinositol 4,5 bisphosphate (PI(4,5)P2). For both proteins, the N-terminal pleckstrin homology (PH) domain appears to mediate activation. Here, we have constructed a chimera in which we placed the N-terminal PH domain of PLC delta 1 into remaining C-terminal regions of PLC beta 2. The PH delta PLC beta chimera showed PI(4,5)P2-dependent membrane binding similar to PLC delta 1 and a G beta gamma interaction energy close to that of PLC delta 1. Like PLC delta 1, the chimera was activated by PI(4,5)P2 through the PH domain but not by G beta gamma. Because these and previous results indicate a common site of contact between the PH and catalytic domains in these two enzymes, we computationally docked the known structures of the PH and catalytic domains of PLC delta 1. A synthetic peptide whose sequence matches a potential interaction site between the two domains inhibited the basal activity of PLC beta 2, PLC delta 1, and a G beta gamma-activable PH beta 2-PLC delta 1 chimera. Also, the peptide was able to inhibit PI(4,5)P2 and G beta gamma activation of the PH-PLC delta 1 PH-PLC beta 2 enzymes in a concentration-dependent manner, suggesting that this is the region responsible for PH domain-mediated activation of the catalytic core.

Adenophostin A and imipramine are two activators of the olfactory inositol 1,4,5-trisphosphate-gated channel in fish olfatory cilia

Binding of an odorant to its receptor activates the cAMP-dependent pathway, and also leads to inositol 1,4,5-trisphosphate (InsP(3)) production. This induces opening of a plasma membrane channel in olfactory receptor cells (ORCs). We investigated single-channel properties of this channel in the presence of a phospholipase C (PLC) activator (imipramine) and of a potent activator of the InsP(3)/Ca(2+) release channel (adenophostin A) by reconstituting carp olfactory cilia into planar lipid bilayers. In the presence of 53 mM barium as a charge carrier, the addition of 50 microM imipramine induced a current of 1.53+/-0.05 pA at 0 mV. There were two different mean open times (6.0+/-0.6 ms and 49.6+/-6.4 ms). The I/ V curve displayed a slope conductance of 50+/-2 pS. Channel activity was transient and was blocked by neomycin (50 microM). These observations suggest that imipramine may activate the olfactory InsP(3)-gated channel through PLC. Using the same ionic conditions, the application of 0.5 microM adenophostin A triggered a current of 1.47+/-0.04 pA at 0 mV. The I/ V curve displayed a slope conductance of 60+/-2 pS. This channel showed only a single mean open time (15.0+/-0.3 ms) and was strongly inhibited by ruthenium red (30 microM) and heparin (10 microg/mL). These results indicate that adenophostin A and imipramine may act on the ciliary InsP(3)-gated channel and are potentially valuable pharmacological tools for studying olfactory transduction mechanisms.

Rac2 regulation of phospholipase C-beta 2 activity and mode of membrane interactions in intact cells

Phospholipase C-beta (PLCbeta) isozymes play important roles in transmembrane signaling. Their activity is regulated by heterotrimeric G proteins. The PLCbeta(2) isozyme is unique in being stimulated also by Rho GTPases (Rac and Cdc42). However, the mechanism(s) of this stimulation are still unclear. Here, we employed fluorescence recovery after photobleaching to investigate the interaction of green fluorescent protein (GFP)-PLCbeta(2) with the plasma membrane. For either GFP-PLCbeta(2) or GFP-PLCbeta(2)Delta, a C-terminal deletion mutant lacking the region required for stimulation by Galpha(q), these interactions were characterized by a mixture of exchange with a cytoplasmic pool and lateral diffusion. Constitutively active Rac2(12V) stimulated the activity of both GFP-PLCbeta(2) and GFP-PLCbeta(2)Delta in live cells, and enhanced their membrane association as evidenced by the marked reduction in their fluorescence recovery rates. Both effects required the putative N-terminal pleckstrin homology (PH) domain of PLCbeta(2). Importantly, Rac2(12V) dramatically increased the contribution of exchange to the fluorescence recovery of GFP-PLCbeta(2), but had the opposite effect on GFP-PLCbeta(2)Delta, where lateral diffusion became dominant. Our results demonstrate for the first time the regulation of membrane association of a PLCbeta isozyme by a GTP-binding protein and assign a novel function to the PLCbeta(2) C-terminal region, regulating its exchange between membrane-bound and cytosolic states.

Specificity and structural requirements of phospholipase C-beta stimulation by Rho GTPases versus G protein beta gamma dimers

Phospholipase C-beta(2) (PLC beta(2)) is activated both by heterotrimeric G protein alpha- and beta gamma- subunits and by Rho GTPases. In this study, activated Rho GTPases are shown to stimulate PLC beta isozymes with the rank order of PLC beta(2) > PLC beta(3) > or = PLC beta(1). The sensitivity of PLC beta isozymes to Rho GTPases was clearly different from that observed for G protein beta gamma dimers, which decreased in the following order: PLC beta(3) > PLC beta(2) > PLC beta(1) for beta(1)gamma(1/2) and PLC beta(2) > PLC beta(1) >>> PLC beta(3) for beta(5)gamma(2). Rac1 and Rac2 were found to be more potent and efficacious activators of PLC beta(2) than was Cdc42Hs. The stimulation of PLC beta(2) by Rho GTPases and G protein beta gamma dimers was additive, suggesting that PLC beta(2) activation can be augmented by independent regulation of the enzyme by the two stimuli. Using chimeric PLC beta(1)-PLC beta(2) enzymes, beta gamma dimers, and Rho GTPases are shown to require different regions of PLC beta(2) to mediate efficient stimulation of the enzyme. Although the catalytic subdomains X and Y of PLC beta(2) were sufficient for efficient stimulation by beta gamma, the presence of the putative pleckstrin homology domain of PLC beta(2) was absolutely required for the stimulation of the enzyme by Rho GTPases. Taken together, these results identify Rho GTPases as novel PLC beta regulators, which mediate PLC beta isozyme-specific stimulation and are potentially involved in coordinating the activation of PLC beta(2) by extracellular mediators in intact cells.

Role of the G protein gamma subunit in beta gamma complex modulation of phospholipase Cbeta function

The G protein betagamma complex regulates a wide range of effectors, including the phospholipase C isozymes (PLCbetas). Different domains on the beta subunit are known to contact phospholipase Cbeta and affect its regulation. In contrast, the role of the gamma subunit in Gbetagamma modulation of PLCbeta function is not known. Results here show that the gamma subunit C-terminal domain is involved in mediating Gbetagamma interactions with phospholipase Cbeta. Mutations were introduced to alter the position of the post-translational prenyl modification at the C terminus of the gamma subunit with reference to the beta subunit. These mutants were appropriately post-translationally modified with the geranylgeranyl moiety. A deletion that shortened the C-terminal domain, insertions that extended this domain, and a point mutation, F59A, that disrupted the interaction of this domain with the beta subunit were all affected in their ability to activate PLCbeta to varying degrees. All mutants, however, interacted equally effectively with the G(o)alpha subunit. The results indicate that the G protein gamma subunit plays a direct role in the modulation of effector function by the betagamma complex.

Mechanism of the regulation of type IB phosphoinositide 3OH-kinase byG-protein betagamma subunits

Type IB phosphoinositide 3OH-kinase (PI3K) is activated by G-protein betagamma subunits (Gbetagammas). The enzyme is soluble and largely cytosolic in vivo. Its substrate, PtdIns(4,5)P(2), and the Gbetagammas are localized at the plasma membrane. We have addressed the mechanism by which Gbetagammas regulate the PI3K using an in vitro approach. We used sedimentation assays and surface plasmon resonance to determine association of type IB PI3K with lipid monolayers and vesicles of varying compositions, some of which had Gbetagammas incorporated. Association and dissociation rate constants were determined. Our results indicated that in an assay situation in vitro the majority of PI3K will be associated with lipid vesicles, irrespective of the presence or absence of Gbetagammas. In line with this, a constitutively active membrane-targeted PI3K construct could still be activated substantially by Gbetagammas in vitro. We conclude that Gbetagammas activate type IB PI3K by a mechanism other than translocation to the plasma membrane.

Binding of a Pleckstrin homology domain protein to phosphoinositide in membranes: a miniaturized FRET-based assay for drug screening

Pleckstrin homology (PH) domains are present in key proteins involved in many vital cell processes. For example, the PH domain of Bruton's tyrosine kinase (Btk) binds to phosphatidylinositol triphosphate (PIP(3)) in the plasma membrane after stimulation of the B-cell receptor in B cells. Mutations in the Btk PH domain result in changes in its affinity for PIP(3), with higher binding leading to cell transformation in vitro and lower binding leading to antibody deficiencies in both humans and mice. We describe here a fluorescence resonance energy transfer (FRET)-based biochemical assay that directly monitors the interaction of a PH domain with PIP(3) at a membrane surface. We overexpressed a fusion protein consisting of an enhanced green fluorescent protein (GFP) and the N-terminal 170 amino acids of a Tec family kinase that contains its PH domain (PH170). Homogeneous unilamellar vesicles were made that contained PIP(3) and octadecylrhodamine (OR), a lipophilic FRET acceptor for GFP. After optimization of both protein and vesicle components, we found that binding of the GFP-PH170 protein to PIP3 in vesicles that contain OR results in about a 90% reduction of GFP fluorescence. Using this assay to screen 1440 compounds, we identified three that efficiently inhibited binding of GFP-PH170 to PIP(3) in vesicles. This biochemical assay readily miniaturized to 1.8-microl reaction volumes and was validated in a 3456-well screening format.

Role of the gamma subunit prenyl moiety in G protein beta gamma complex interaction with phospholipase Cbeta

The G protein betagamma complex regulates a wide range of effectors, including the phospholipase Cbeta isozymes (PLCbetas). Prenyl modification of the gamma subunit is necessary for this activity. Evidence presented here supports a direct interaction between the G protein gamma subunit prenyl group and PLCbeta isozymes. A geranylgeranylated peptide corresponding to the C-terminal region of the gamma subunit type, gamma2, strongly inhibits stimulation of PLCbeta2 and PLCbeta3 activity by the betagamma complex. This effect is specific because the same peptide has no effect on stimulation of PLCbeta by an alpha subunit type, alphaq. Prenylation of the gamma peptide is required for its inhibitory effect. When interaction of prenylated gamma subunit peptide to fluorophore-tagged PLCbeta2 was examined by fluorescence spectroscopy, prenylated but not unprenylated peptide increased PLCbeta2 fluorescence emission energy, indicating direct binding of the prenyl moiety to PLCbeta. In addition, fluorescence resonance energy transfer was detected between fluorophore tagged PLCbeta and wild type betagamma complex but not an unprenylated mutant betagamma complex. We conclude that a major function of the gamma subunit prenyl group is to facilitate direct protein-protein interaction between the betagamma complex and an effector, phospholipase Cbeta.

G Protein beta subunit types differentially interact with a muscarinic receptor but not adenylyl cyclase type II or phospholipase C-beta 2/3

In comparison with the alpha subunit of G proteins, the role of the beta subunit in signaling is less well understood. During the regulation of effectors by the betagamma complex, it is known that the beta subunit contacts effectors directly, whereas the role of the beta subunit is undefined in receptor-G protein interaction. Among the five G protein beta subunits known, the beta(4) subunit type is the least studied. We compared the ability of betagamma complexes containing beta(4) and the well characterized beta(1) to stimulate three different effectors: phospholipase C-beta2, phospholipase C-beta3, and adenylyl cyclase type II. beta(4)gamma(2) and beta(1)gamma(2) activated all three of these effectors with equal efficacy. However, nucleotide exchange in a G protein constituting alpha(o)beta(4)gamma(2) was stimulated significantly more by the M2 muscarinic receptor compared with alpha(o)beta(1)gamma(2). Because alpha(o) forms heterotrimers with beta(4)gamma(2) and beta(1)gamma(2) equally well, these results show that the beta subunit type plays a direct role in the receptor activation of a G protein.

Characterization of a phospholipase C beta 2-binding site near the amino-terminal coiled-coil of G protein beta gamma subunits

In previous work (Sankaran, B., Osterhout, J., Wu, D., and Smrcka, A. V. (1998) J. Biol. Chem. 273, 7148-7154), we showed that overlapping peptides, N20K (Asn(564)-Lys(583)) and E20K (Glu(574)-Lys(593)), from the catalytic domain of phospholipase C (PLC) beta2 block Gbetagamma-dependent activation of PLC beta2. The peptides could also be directly cross-linked to betagamma subunits with a heterobifunctional cross-linker succinimidyl 4-[N-maleimidomethyl]-cyclohexane-1-carboxylate. Cross-linking of peptides to Gbeta(1) was inhibited by PLC beta2 but not by alpha(i1)(GDP), indicating that the peptide-binding site on beta(1) represents a binding site for PLC beta2 that does not overlap with the alpha(i1)-binding site. Here we identify the site of peptide cross-linking and thereby define a site for PLC beta2 interaction with beta subunits. Each of the 14 cysteine residues in beta(1) were altered to alanine. The ability of the PLC beta2-derived peptide to cross-link to each betagamma mutant was then analyzed to identify the reactive sulfhydryl moiety on the beta subunit required for the cross-linking reaction. We find that C25A was the only mutation that significantly affected peptide cross-linking. This indicates that the peptide is specifically binding to a region near cysteine 25 of beta(1) which is located in the amino-terminal coiled-coil region of beta(1) and identifies a PLC-binding site distinct from the alpha subunit interaction site.

Evidence that a protein-protein interaction 'hot spot' on heterotrimeric G protein betagamma subunits is used for recognition of a subclass of effectors

To understand the requirements for binding to G protein betagamma subunits, phage-displayed random peptide libraries were screened using immobilized biotinylated betagamma as the target. Selected peptides were grouped into four different families based on their sequence characteristics. One group (group I) had a clear conserved motif that has significant homology to peptides derived from phospholipase C beta (PLC beta) and to a short motif in phosducin that binds to G protein beta subunits. The other groups had weaker sequence homologies or no homology to the group I sequences. A synthetic peptide from the strongest consensus group blocked activation of PLC by G protein betagamma subunits. The peptide did not block betagamma-mediated inhibition of voltage-gated calcium channels and had little effect on betagamma-mediated inhibition of Gs-stimulated type I adenylate cyclase. Competition experiments indicated that peptides from all four families bound to a single site on betagamma. These peptides may bind to a protein-protein interaction 'hot spot' on the surface of betagamma subunits that is used by a subclass of effectors.

Phospholipase C(epsilon): a novel Ras effector

Three classes of mammalian phosphoinositide-specific phospholipase C (PLC) have been characterized, PLCbeta, PLCgamma and PLCdelta, that are differentially regulated by heterotrimeric G-proteins, tyrosine kinases and calcium. Here we describe a fourth class, PLCepsilon, that in addition to conserved PLC domains, contains a GTP exchange factor (GRF CDC25) domain and two C-terminal Ras-binding (RA) domains, RA1 and RA2. The RA2 domain binds H-Ras in a GTP-dependent manner, comparable with the Ras-binding domain of Raf-1; however, the RA1 domain binds H-Ras with a low affinity in a GTP-independent manner. While G(alpha)q, Gbetagamma or, surprisingly, H-Ras do not activate recombinant purified protein in vitro, constitutively active Q61L H-Ras stimulates PLC(epsilon) co-expressed in COS-7 cells in parallel with Ras binding. Deletion of either the RA1 or RA2 domain inhibits this activation. Site-directed mutagenesis of the RA2 domain or Ras demonstrates a conserved Ras-effector interaction and a unique profile of activation by Ras effector domain mutants. These studies identify a novel fourth class of mammalian PLC that is directly regulated by Ras and links two critical signaling pathways.

Reassembly of phospholipase C-beta2 from separated domains: analysis of basal and G protein-stimulated activities

Phosphatidylinositol-specific phospholipase C-betas (PLC-betas) are the only PLC isoforms that are regulated by G protein subunits. To further understand the regulation of PLC-beta(2) by G proteins and the functional roles of PLC-beta(2) structural domains, we tested whether the separately expressed amino and carboxyl halves of PLC-beta(2) could associate to form catalytically active enzymes as two polypeptides, and we explored how the complexes thus formed would be regulated by G protein betagamma subunits (Gbetagamma). We expressed cDNA constructs encoding PLC-beta(2) fragments of different lengths in COS-7 cells and demonstrated by coimmunoprecipitation that the coexpressed fragments could assemble and functionally reconstitute an active PLC-beta(2). The pleckstrin homology domain of PLC-beta(2) was required for its targeting to the membrane and for substrate hydrolysis. Reconstituted enzymes that contained the linker region that joins the two catalytic domains were as active or more active than the wild-type PLC-beta(2). When the linker region was removed, basal PLC-beta(2) enzymatic activity was increased further, suggesting that the linker region exerts an inhibitory effect on basal PLC-beta(2) activity. The reconstituted enzymes, like wild-type PLC-beta(2), were activated by Gbetagamma; when the C-terminal region was present in these constructs, they were also activated by Galpha(q). Gbetagamma and Galpha(q) activated these PLC-beta(2) constructs equally in the presence or absence of the linker region. We conclude that the linker region is an inhibitory element in PLC-beta(2) and that Gbetagamma and Galpha(q) do not stimulate PLC-beta(2) through easing the inhibition of enzymatic activity by the linker region.

Selective role of G protein gamma subunits in receptor interaction

Receptor stimulation of nucleotide exchange in a heterotrimeric G protein (alphabetagamma) is the primary event-modulating signaling by G proteins. The molecular mechanisms at the basis of this event and the role of the G protein subunits, especially the betagamma complex, in receptor activation are unclear. In a reconstituted system, a purified muscarinic receptor, M2, activates G protein heterotrimers alphai2beta1gamma5 and alphai2beta1gamma7 with equal efficacy. However, when the alpha subunit type is substituted with alphao, alphaobeta1gamma7 shows a 100% increase in M2-stimulated GTP hydrolysis compared with alphaobeta1gamma5. Using a sensitive assay based on betagamma complex stimulation of phospholipase C activity, we show that both beta1gamma5 and beta1gamma7 form heterotrimers equally well with alphao and alphai. These results indicate that the gamma subunit interaction with a receptor is critical for modulating nucleotide exchange and is influenced by the subunit-type composition of the heterotrimer.

Identification of a region at the N-terminus of phospholipase C-beta 3 that interacts with G protein beta gamma subunits

Members of the phospholipase C-beta (PLC-beta) family of proteins are activated either by G alpha or G beta gamma subunits of heterotrimeric G proteins. To define specific regions of PLC-beta 3 that are involved in binding and activation by G beta gamma, a series of fragments of PLC-beta 3 as glutathione-S-transferase (GST) fusion proteins were produced. A fragment encompassing the N-terminal pleckstrin homology (PH) domain and downstream sequence (GST-N) bound to G protein beta 1 gamma 2 in an in vitro binding assay, and binding was inhibited by G protein alpha subunit, G alpha i1. This PLC-beta 3 fragment also inhibited G beta gamma-stimulated PLC-beta activity in a reconstitution system, while having no significant effect on G alpha q-stimulated PLC-beta 3 activity. The N-terminal G beta gamma binding region was delineated further to the first 180 amino acids, and the sequence Asn150-Ser180, just distal to the PH domain, was found to be required for the interaction. Mutation of basic residues 154Arg, 155Lys, 159Lys, and 161Lys to Glu within this region reduced G beta gamma binding affinity and specifically reduced the EC50 for G beta gamma-dependent activation of the mutant enzyme 3-fold. Basal activity and G alpha q-dependent activation of the enzyme were unaffected by the mutations. While these basic residues may not directly mediate the interaction with G beta gamma, the data provide evidence for an N-terminal G beta gamma binding region of PLC-beta 3 that is involved in activation of the enzyme.

Mammalian phosphoinositide-specific phospholipase C

Mammalian phosphoinositide-specific phospholipases C (PI-PLCs) are involved in most receptor-mediated signal transduction pathways. The mammalian isozymes employ a modular arrangement of domains to achieve a regulated production of two key second messengers. The roles of the PH, EF hand, C2, SH2 and SH3 modules in regulation of these enzymes and in interactions with membranes and other proteins is becoming apparent from recent structural and functional studies.

Genetic alteration of phospholipase C beta3 expression modulates behavioral and cellular responses to mu opioids

Morphine and other micro opioids regulate a number of intracellular signaling pathways, including the one mediated by phospholipase C (PLC). By studying PLC beta3-deficient mice, we have established a strong link between PLC and mu opioid-mediated responses at both the behavioral and cellular levels. Mice lacking PLC beta3, when compared with the wild type, exhibited up to a 10-fold decrease in the ED(50) value for morphine in producing antinociception. The reduced ED(50) value was unlikely a result of changes in opioid receptor number or affinity because no differences were found in whole-brain B(max) and K(d) values for mu, kappa, and delta opioid receptors between wild-type and PLC beta3-null mice. We also found that opioid regulation of voltage-sensitive Ca(2+) channels in primary sensory neurons (dorsal root ganglion) was different between the two genotypes. Consistent with the behavioral findings, the specific mu agonist [D-Ala(2),(Me)Phe(4),Gly(ol)(5)]enkephalin (DAMGO) induced a greater whole-cell current reduction in a greater proportion of neurons isolated from the PLC beta3-null mice than from the wild type. In addition, reconstitution of recombinant PLC protein back into PLC beta3-deficient dorsal root ganglion neurons reduced DAMGO responses to those of wild-type neurons. In neurons of both genotypes, activation of protein kinase C with phorbol esters markedly reduced DAMGO-mediated Ca(2+) current reduction. These data demonstrate that PLC beta3 constitutes a significant pathway involved in negative modulation of mu opioid responses, perhaps via protein kinase C, and suggests the possibility that differences in opioid sensitivity among individuals could be, in part, because of genetic factors.

Development of an assay for phospholipase C using column-reconstituted, extruded phospholipid vesicles

The reconstitution of heterotrimeric G proteins into phospholipid vesicles has been widely used for the measurement of PLC-beta activity in vitro. We have developed an improved and sensitive method for the assay of PLC-beta activity. This approach involves reconstitution of purified betagamma dimers into extruded phospholipid vesicles containing phosphatidylinositol 4, 5-bisphosphate and using a gel-filtration technique to separate the reconstituted vesicles from monodispersed betagamma dimers and the detergent used to solubilize G proteins. The method provides physical information about the partitioning of betagamma dimers into phospholipid vesicles and was used to examine the effect of different prenyl groups on the gamma subunits in the activation of PLC-beta. The beta1gamma1 dimer (containing the farnesyl group) and the beta1gamma2 dimer (containing the geranylgeranyl group) were purified from baculovirus-infected Sf9 insect cells and were found to partition equally into phospholipid vesicles. The beta1gamma2 dimer is more potent and effective in stimulating PLC-beta activity than the beta1gamma1 dimer. The EC50 values of betagamma dimers for the activation of PLC-beta determined with this method were lower than those determined by previous methodology, showing that betagamma subunits have a subnanomolar affinity for PLC-beta.

Determination of the affinities between heterotrimeric G protein subunits and their phospholipase C-beta effectors

Phosphatidylinositide-specific phospholipase C-betas play a key role in Ca2+ signaling and are specifically activated by the alphaq family of heterotrimeric G proteins and as well as betagamma subunits. We have determined the affinity between Gbetagamma subunits and GTPgammaS and GDP-liganded Galphaq subunits on membrane surfaces, and their respective affinities to PLC-beta1, -beta2 and -beta3 effectors by fluorescence spectroscopy. We find that activation of Galphaq by GTPgammaS decreases its affinity for Gbetagamma subunits at least 36-fold compared to the GDP-liganded form, but increases its affinity for PLC-betas at least 40-200-fold depending on the PLC-beta isoform. The affinity of Galphaq(GTPgammaS) is similar for PLC-beta1 and -beta3 and 10-fold stronger for PLC-beta2, which corresponds to the reported relationship between the concentration of Galphaq(GTPgammaS) and PLC-beta activation on lipid bilayers. We find that a large portion of the PLC-beta-Galphaq association energy lies within the 400 residue C-terminal region of PLC-beta1 since truncating this region reduces its Galphaq affinity. In contrast, the isolated N-terminal region does not interact with Galphaq. Gbetagamma subunits interact with all three PLC-beta isotypes, but only showed strong binding to PLC-beta2, and activation of the three PLC-betas by Gbetagamma subunits parallels this behavior. We also tested the possibility that both Galphaq and Gbetagamma can simultaneously bind PLC-beta2. Our data argue against simultaneous binding and show that Galphaq and Gbetagamma independently regulate this effector.

Families of phosphoinositide-specific phospholipase C: structure and function

A large number of extracellular signals stimulate hydrolysis of phosphatidylinositol 4,5-bisphosphate by phosphoinositide-specific phospholipase C (PI-PLC). PI-PLC isozymes have been found in a broad spectrum of organisms and although they have common catalytic properties, their regulation involves different signalling pathways. A number of recent studies provided an insight into domain organisation of PI-PLC isozymes and contributed towards better understanding of the structural basis for catalysis, cellular localisation and molecular changes that could underlie the process of their activation.

Regulation of the rate and extent of phospholipase C beta 2 effector activation by the beta gamma subunits of heterotrimeric G proteins

The activity of mammalian phosphoinositide-specific phospholipase C beta 2 (PLC-beta 2) is regulated by the alpha q family of G proteins and by beta gamma subunits. We measured the affinity between the laterally associating PLC-beta 2 and G beta gamma on membrane surfaces by fluorescence resonance energy transfer. Using a simple model, we translated this apparent affinity to a bulk or three-dimensional equilibrium constant (Kd) and obtained a value of 3.2 microM. We confirmed this Kd by separately measuring the on and off (kf and kr) rate constants. The kf was slower than a diffusion-limited value, suggesting that conformational changes occur when the two proteins interact. The off rate shows that the PLC-beta 2.G beta gamma complexes are long-lived ( approximately 123 s) and that activation of PLC-beta 2 by G beta gamma would be sustained without a deactivating factor. The addition of alpha i1(GDP) subunits failed to physically dissociate the complex as determined by fluorescence. However, enzyme activity studies performed under similar conditions show that the addition of G alpha i1(GDP) results in reversal of PLC-beta 2 activation by G beta gamma during the time of the assay (30 s). From these results, we propose that G alpha(GDP) subunits can bind to the PLC-beta 2.G beta gamma complex to allow for rapid deactivation without complex dissociation. In support of this model, we show by fluorescence that G alpha i1(GDP).G beta gamma.PLC-beta 2 can form.

Molecular basis for interactions of G protein betagamma subunits with effectors

Both the alpha and betagamma subunits of heterotrimeric guanine nucleotide-binding proteins (G proteins) communicate signals from receptors to effectors. Gbetagamma subunits can regulate a diverse array of effectors, including ion channels and enzymes. Galpha subunits bound to guanine diphosphate (Galpha-GDP) inhibit signal transduction through Gbetagamma subunits, suggesting a common interface on Gbetagamma subunits for Galpha binding and effector interaction. The molecular basis for interaction of Gbetagamma with effectors was characterized by mutational analysis of Gbeta residues that make contact with Galpha-GDP. Analysis of the ability of these mutants to regulate the activity of calcium and potassium channels, adenylyl cyclase 2, phospholipase C-beta2, and beta-adrenergic receptor kinase revealed the Gbeta residues required for activation of each effector and provides evidence for partially overlapping domains on Gbeta for regulation of these effectors. This organization of interaction regions on Gbeta for different effectors and Galpha explains why subunit dissociation is crucial for signal transmission through Gbetagamma subunits.