The signalling profile of recombinant human orexin-2 receptor

Orexin-A and orexin-B orchestrate their diverse central and peripheral effects via two G-protein coupled receptors, OX1R and OX2R, which activate multiple G-proteins. In many tissues, orexins activate extracellular signal-regulated kinase (ERK(1/2)) and p38 mitogen-activated protein kinase (MAPK); however, the mechanism by which OX2R alone mediates MAPK activation is not understood. This study describes the intracellular signalling pathways involved in OX2R-mediated ERK(1/2) and p38 MAPK activation. In HEK-293 cells stably over-expressing recombinant human OX2R, orexin-A/B resulted in a rapid, dose and time dependent increase in activation of ERK(1/2) and p38 MAPK, with maximal activation at 10 min for ERK(1/2) and 30 min for p38 MAPK. Using dominant-negative G-proteins and selective inhibitors of intracellular signalling cascades, we determined that orexin-A and orexin-B induced ERK(1/2) and p38 MAPK activation through multiple G-proteins and different intracellular signalling pathways. ERK(1/2) activation involves Gq/phospholipase C (PLC)/protein kinase C (PKC), Gs/adenylyl cyclase (AC)/cAMP/protein kinase A (PKA) and Gi cascades; however, the Gq/PLC/PKC pathway, as well as PKA is not required for OX2R-mediated p38 MAPK activation. Interestingly, orexin-B-induced ERK(1/2) activation is predominantly mediated through the Gq/PLC/PKC pathway. In conclusion, this is the first comprehensive signalling study of the human OX2R recombinant receptor, showing ERK(1/2) and p38 MAPK activation are regulated by differential signalling pathways in HEK-293 cells, and that the ERK(1/2) activation is severely affected by naturally occurring mutants associated with narcolepsy. Moreover, it is evident that the human OX2R has ligand specific effects, with orexin-B being more potent in this transfected system and this distinct modulation of the MAPKs through OX2R, may translate to the regulation of diverse biological actions of orexins.     

Insights into cellular signalling by G protein coupled receptor transactivation of cell surface protein kinase receptors

G protein coupled receptor (GPCR) signalling is mediated by transactivation independent and transactivation dependent pathways. GPCRs transactivate protein tyrosine kinase receptors (PTKRs) and protein serine/threonine kinase receptors (PS/TKR). Since the initial observations of transactivation dependent signalling, there has been an effort to understand the mechanisms behind this phenomena. GPCR signalling has evolved to include biased signalling. Biased signalling, whereby selected ligands can activate the same GPCR that can generate multiple signals, but drive only a unique response. To date, there has been no focus on the ability of biased agonists to activate the PTKR and PS/TKR transactivation pathways differentially. As such, this represents a novel direction for future research. This review will discuss the main mechanisms of GPCR mediated receptor transactivation and the pathways involved in intracellular responses.     

In situ binding of a photo-affinity GTP analog to synaptic membrane G-proteins. Distribution of bound GTP analog reflects the status of adenylate cyclase

Regulation of synaptic membrane adenylate cyclase is likely to involve interaction between neurotransmitter receptors, G-proteins and the adenylate cyclase catalytic unit as well as several other membrane proteins and lipids. Despite intensive study of this system, regulation of guanine nucleotide binding by the G-proteins which stimulate [Gs] or inhibit [Gi] adenylate cyclase has been examined only when those proteins have been purified and removed from the influence of the membrane environment. The hydrolysis-resistant photoaffinity GTP-analog, P3-(4-azidoanilido)-P1 5'-GTP (AAGTP) is able to bind specifically to the G-proteins in rat cerebral cortex synaptic membranes and, in this study, we have used this probe to examine the specificity and selectivity of guanine nucleotide binding to each G-protein without removing those proteins from the synaptic membrane. Marked differences were noted between guanine nucleotide binding data obtained with detergent-soluble G-proteins and data from this in situ approach. In these studies it was found that the affinity of the G-proteins binding AAGTP correlated well with the expression of adenylate cyclase activity, the affinity of both forms of Gs increasing under conditions favoring the stimulation of that enzyme.     

Adaptor proteins of blood platelets

Adaptor proteins play a pivotal role in the regulation of signal transduction events elicited after the engagement of cell surface receptors. Platelets exhibit a number of integral membrane receptors capable of initiating a cellular response. These include collagen receptors, von Willebrand factor receptors, the fibrinogen receptor, and a number of G-protein coupled receptors, such as those for thrombin and ADP. The primary function of platelet receptors is the translation of externally applied signals into appropriate responses leading to platelet activation being a prerequisite for normal hemostasis. Multitude of signalling pathways described in platelets is based on the interaction of compounds of many different categories, such as transmembrane receptors, protein kinases, protein phoshatases, G-proteins, transmembrane and cytosolic adaptor proteins, phosphoinositides, cyclic AMP or GMP. Adaptor proteins lack intrinsic effector function, but contain distinct molecular domains, which mediate protein-protein and protein-lipid interactions. These molecules thus serve as a scaffolding, around which effectors and their substrates are assembled into three-dimensional signaling complexes. Adaptor proteins integrate receptor-mediated signals at intracellular levels and couple signaling receptors to cytosolic signaling pathways. While the function of adaptor proteins is well established in immune cells, the knowledge about their role in platelet activation is still at the onset Over the last decade numerous adaptor proteins have been identified in platelets and shown to be involved in accurate assembly of intracellular signaling complexes. Collagen-induced platelet intracellular signaling through GPVI resembles the functional response of B- and T-cell antigen receptors and is the best described in the literature. This review focuses on the structure and functional role of the most extensively studied adaptor proteins during platelet activation induced by physiological agonists.     

Urocortin, but not corticotropin-releasing hormone (CRH), activates the mitogen-activated protein kinase signal transduction pathway in human pregnant myometrium: an effect mediated via R1alpha and R2beta CRH receptor subtypes and stimulation of Gq-proteins

CRH and CRH-related peptides such as urocortin mediate their actions in the human myometrium via activation of two distinct classes of CRH receptors, R1 and R2. These heptahelical receptors are able to stimulate a number of different intracellular signals; one key mediator of G protein-activated intracellular signaling is the cascade of p42/p44, mitogen-activated protein kinase (MAPK). We therefore hypothesized that activation of MAPK might mediate CRH and or/urocortin actions in the myometrium. In cultured human pregnant myometrial cells, urocortin but not CRH was able to induce MAPK phosphorylation and activation, suggesting that in the human myometrium these two peptides have distinct actions and biological roles. To identify the particular receptor subtypes mediating this phenomenon, all known CRH receptors present in the human myometrial cells were stably expressed individually in HEK293 and CHO cells, and their ability to activate MAPK was tested. The R1alpha and R2beta, but not the R1beta, R1c, or R1d, receptor subtypes were able to mediate urocortin-induced MAPK activation. The signaling components were further investigated; activation of Gs, Go, or Gi proteins did not appear to be involved, but activation of Gq with subsequent production of inositol triphosphates (IP3) and protein kinase C (PKC) activation correlated with MAPK phosphorylation. Studies on Gq protein activation using [alpha-32P]-GTP-gamma-azidoanilide and IP3 production in cells expressing the R1alpha or R2beta CRH receptors demonstrated that urocortin was 10 times more potent than CRH. Moreover, urocortin (UCN) generated peak responses that were 50-70% greater than CRH in activating the Gq protein and stimulating IP3 production. In conclusion, UCN acting thought multiple receptor subtypes can stimulate myometrial MAPK via induction of the Gq/phospholipase C/IP3/PKC pathway, whereas CRH-induced activation of this pathway appears to be insufficient to achieve MAPK activation.     

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Thechemokinesareafamilyofproinflammatorycytokinesthatactthroughcellsurfacereceptorstoregulatenumerousroutinephysiologicalandpathophysiologicalprocesses,includinghematopoiesis,T cellactivation ,angiogenesis,inflammatorydiseasesaswellasHIV 1infection[1,2 ].Thesesmallpeptidesaretypicallycomposedof 70 - 1 30aminoacidsandarecharacterizedbythepresenceoftwodisulphidebondsformedbetweenfourconservedcysteineresidues.Chemokinesareclassifiedintofoursubfamiliesaccordingtothepatternofconservedcysteinesinth…     

Heterotrimeric G-proteins mediated hormonal responses in plants

Phytohormones not only orchestrate intrinsic developmental programs from germination to senescence but also regulate environmental inputs through complex signalling pathways. Despite building an own signalling network, hormones mutually contribute several signalling systems, which are also essential for plant growth and development, defense, and responses to abiotic stresses. One of such important signalling cascades is G-proteins, which act as critical regulators of a wide range of fundamental cellular processes by transducing receptor signals to the intracellular environment. G proteins are composed of α, β, and γ subunits, and the molecular switching between active and inactive conformation of Gα controls the signalling cycle. The active GTP bound Gα and freed Gβγ have both independent and tightly coordinated roles in the regulation of effector molecules, thereby modulating multiple responses, including hormonal responses. Therefore, an interplay of hormones with G-proteins fine-tunes multiple biological processes of plants; however, their molecular mechanisms are largely unknown. Functional characterization of hormone biosynthesis, perception, and signalling components, as well as identification of few effector molecules of G-proteins and their interaction networks, reduces the complexity of the hormonal signalling networks related to G-proteins. In this review, we highlight a valuable insight into the mechanisms of how the G-protein signalling cascades connect with hormonal responses to regulate increased developmental flexibility as well as remarkable plasticity of plants.     

Localization of mRNAs encoding the alpha-subunits of signal-transducing G-proteins within rat brain and among peripheral tissues

The sequence of the mRNAs which encode the alpha-subunits of the signal-transducing G-proteins Gs, Go and two forms of Gi (termed Gi1 and Gi2) have recently been reported. Based on rat sequences we prepared oligodeoxynucleotide probes for measurement of these mRNAs in rat brain and peripheral tissues. The relative abundance of these mRNA species in brain was Gs greater than Go approximately Gi2 greater than Gi1. The Gs and Gi2 mRNAs had somewhat lower levels in heart, kidney and liver than in brain, and Go and Gi1 mRNAs were not detected in the peripheral tissues. Using in situ hybridization we localized each of these mRNAs within slices of the rat brain. The patterns of distribution of Gs and Gi2 mRNA were very similar, but very different from that of Go and Gi1 mRNA. These data illustrate that receptor-effector coupling G-proteins are regionally specialized in their expression. This regional specialization may reflect a selective coupling of individual G-proteins with the various neurotransmitter receptors and effector pathways.     

PKC-dependent autoregulation of membrane kainate receptors

Agonists of kainate receptors (KARs) cause both the opening of the associated ion channels and the activation of signalling pathways driven by G-proteins and PKC. Here we report the existence of an unknown mechanism of KAR autoregulation, involving the interplay of this two signalling mechanisms. Repetitive activation of native KARs evoked the rundown of the ionotropic responses in a manner that was dependent on the activation of PKC. Experiments on recombinant GluR5 expressed in neuroblastoma cells indicated that KARs trigger the activation of PKC and induce the internalization of membrane receptors. This phenomenon depends on the PKC-mediated phosphorylation of serines 879 and 885 of the GluR5-2b subunits, since mutation of these two residues abolished internalization. These results reveal that the non-canonical signalling of KARs is associated with a sensitive mechanism that detects afferent activity. Such a mechanism represents an active way to limit overactivation of the KAR system, by regulating the number of KARs in the cell membrane.     

Dehydroepiandrosterone activates endothelial cell nitric-oxide synthase by a specific plasma membrane receptor coupled to Galpha(i2,3)

The adrenal steroid dehydroepiandrosterone (DHEA) has no known cellular receptor or unifying mechanism of action, despite evidence suggesting beneficial vascular effects in humans. Based on previous data from our laboratory, we hypothesized that DHEA binds to specific cell-surface receptors to activate intracellular G-proteins and endothelial nitric-oxide synthase (eNOS). We now pharmacologically characterize a putative plasma membrane DHEA receptor and define its associated G-proteins. The [3H]DHEA binding to isolated plasma membranes from bovine aortic endothelial cells was of high affinity (K(d) = 48.7 pm) and saturable (B(max) = 500 fmol/mg protein). Structurally related steroids failed to compete with DHEA for binding. The putative DHEA receptor was functionally coupled to G-proteins, because guanosine 5'-O-(3-thio)triphosphate (GTPgammaS) inhibited [3H]DHEA binding to plasma membranes by 69%, and DHEA increased [35S]GTPgammaS binding by 157%. DHEA stimulated [35S]GTPgammaS binding to Galpha(i2) and Galpha(i3), but not to Galpha(i1) or Galpha(o). Pretreatment of plasma membranes with antibody to Galpha(i2) or Galpha(i3), but not to Galpha(i1), inhibited the DHEA activation of eNOS. Thus, DHEA receptors are expressed on endothelial cell plasma membranes and are coupled to eNOS activity through Galpha(i2) and Galpha(i3). These novel findings should allow us to isolate the putative receptor and reevaluate the physiological role of DHEA activity.     

The mouse 5HT5 receptor reveals a remarkable heterogeneity within the 5HT1D receptor family.

Serotonin (5-HT) is a neuromodulator that mediates a wide range of physiological functions by activating multiple receptors. Using a strategy based on amino acid sequence homology between 5-HT receptors that interact with G proteins, we have isolated a cDNA encoding a new serotonin receptor from a mouse brain library. Amino acid sequence comparisons revealed that this receptor was a distant relative of all previously identified 5-HT receptors; we therefore named it 5HT5. When expressed in Cos-7 cells and NIH-3T3 cells, the 5HT5 receptor displayed a high affinity for the serotonergic radioligand [125I]LSD. Surprisingly, its pharmacological profile resembled that of the 5HT1D receptor, which is a 5-HT receptor subtype which has been shown to inhibit adenylate cyclase and which is predominantly expressed in basal ganglia. However, unlike 5HT1D receptors, the 5HT5 receptor did not inhibit adenylate cyclase and its mRNA was not found in basal ganglia. On the contrary, in situ hybridization experiments revealed that the 5HT5 mRNA was expressed predominantly in cerebral cortex, hippocampus, habenula, olfactory bulb and granular layer of the cerebellum. Our results therefore demonstrate that the 5HT1D receptors constitute a heterogeneous family of receptors with distinct intracellular signalling properties and expression patterns.     

Coupling of exogenous receptors to phospholipase C in Xenopus oocytes through pertussis toxin-sensitive and -insensitive pathways. Cross-talk through heterotrimeric G-proteins

Heterotrimeric guanine nucleotide-binding proteins (G-proteins) can be categorized into molecularly divergent groups by their differential sensitivity to pertussis toxin. Receptors specifically use either pertussis toxin-sensitive or-insensitive G-proteins to couple to specific effectors. Receptor stimulation of phospholipase C, however, is pertussis toxin sensitive in some systems and pertussis toxin insensitive in others. We studied the coupling of receptors to phospholipase C by expressing receptors from both systems into a single cell, the Xenopus oocyte. [Arg8]Vassopressin (AVP) receptors from liver and cholecystokinin-8(sulfated) (CCK) receptors from brain were expressed in oocytes by intracellular injection of RNA. Both receptors stimulated a Ca2+-dependent Cl- current which can also be evoked by intracellular injection of inositol 1,4,5-tris-phosphate. Hence, receptor stimulation of phospholipase C was measured as the evoked Ca2+-dependent Cl- current. The liver AVP receptor, which is known to stimulate phospholipase C in a pertussis toxin-insensitive manner (Lynch, C. J., Prpic, V., Blackmore, P. F., and Exton, J. H. (1986) Mol. Pharmacol. 29, 196-203), was found to stimulate phospholipase C through a pertussis toxin-sensitive pathway in the Xenopus oocyte. The CCK receptor from brain stimulated phospholipase C through a pertussis toxin-insensitive pathway. Both AVP and CCK stimulation of phospholipase C were attenuated by the intracellular injection of excess G-protein beta gamma subunits. Neither pertussis toxin treatment nor intracellular injection of beta gamma subunits affected any steps subsequent to inositol 1,4,5-tris-phosphate production. From these data we conclude that both the pertussis toxin-sensitive and -insensitive pathways for receptor coupling to phospholipase C are transduced by heterotrimeric G-proteins. We also find that there is a lack of coupling fidelity of receptors to G-proteins in stimulation of phospholipase C which can be influenced by the membrane environment.     

Expression of TNF and TNF receptors (p55 and p75) in the rat brain after focal cerebral ischemia.

Cerebral ischemia induces a rapid and dramatic up-regulation of tumor necrosis factor (TNF) protein and mRNA, but the cellular sources of TNF in the ischemic brain have not been defined. The diverse activities of TNF are mediated via ligand interaction with two distinct receptors, p55 and p75, which activate separate intracellular signal transduction pathways, leading to distinct biological effects. Since the effects of cerebral ischemia on TNF receptor (TNFR) expression are unknown, we examined the cellular localization and protein expression of TNF and its two receptors in the rat cerebral cortex in response to permanent middle cerebral artery (MCA) occlusion. The results indicate that focal. cerebral ischemia up-regulates expression of TNF and both TNFRs within the ischemic cortex. The most abundant type of TNF immunoreactivity (IR) was a punctate and filamentous pattern of transected cellular processes; however, cell bodies of neurons, astrocytes, and microglia, as well as infiltrating polymorphonuclear (PMN) leukocytes also showed TNF IR. Brain vasculature displayed TNF IR not only within endothelial cells but also in the perivascular space. MCA occlusion induced significant up-regulation of TNF receptors, with p55 IR appearing within 6 hr, significantly before the appearance of p75 IR at 24 hr after the onset of ischemia. Since p55 has been implicated in transducing cytotoxic signalling of TNF, these results support the proposed injurious role of excessive TNF produced during the acute response to cerebral ischemia.     

G protein selectivity is regulated by multiple intracellular regions of GPCRs

GTP-binding protein coupled receptors (GPCRs) bind to a vast diversity of extracellular ligands to regulate a wide variety of physiological responses. Upon binding of extracellular ligands, these seven-transmembrane-spanning receptor molecules couple to one or several subtypes of G protein which reside at the intracellular side of the plasma membrane to trigger intracellular signaling events. Amid the large structural diversity at the intracellular regions of GPCRs, there are only 18 different subtypes of G protein belonging to four subfamilies. The question of how GPCRs select and activate a single or multiple G protein subtype(s) has been the topic of intense investigations. This review will attempt to summarize the available data on the structural determinants in GPCRs that regulate the selectivity of G protein activation. The available data suggest that G protein can be activated by structurally diverse cationic alpha-helical structures with no obvious homology in primary sequence. The selectivity of receptor-G protein coupling is maintained by a combination of two functional domains at the intracellular region. One is the 'activation domain' which can activate multiple G protein subtypes, while the other is the 'selectivity domain' which restricts the coupling to the desired signaling pathway(s). A slight change in the conformation at these two functional domains can affect the fidelity of G protein selectivity. This hypothesis can account for the vast structural diversity of GPCRs which link a fascinating variety of extracellular inputs, yet couple to a limited number of intracellular signaling pathways.     

Supervised membrane swimming: small G-protein lifeguards regulate PIPK signalling and monitor intracellular PtdIns(4,5)P2 pools

Regulation of PIPK (phosphatidylinositol phosphate kinase) and PtdIns(4,5)P2 signalling by small G-proteins and their effectors is key to many biological functions. Through selective recruitment and activation of different PIPK isoforms, small G-proteins such as Rho, Rac and Cdc42 modulate actin dynamics and cytoskeleton-dependent cellular events in response to extracellular signalling. These activities affect a number of processes, including endocytosis, bacterial penetration into host cells and cytolytic granule-mediated targeted cell killing. Small G-proteins and their modulators are also regulated by phosphoinositides through translocation and conformational changes. Arf family small G-proteins act at multiple sites as regulators of membrane trafficking and actin cytoskeletal remodelling, and regulate a feedback loop comprising phospholipase D, phosphatidic acid, PIPKs and PtdIns(4,5)P2, contributing to enhancement of PtdIns(4,5)P2-mediated cellular events and receptor signalling. Na+, Kir (inwardly rectifying K+), Ca2+ and TRP (transient receptor potential) ion channels are regulated by small G-proteins and membrane pools of PtdIns(4,5)P2. Yeast phosphatidylinositol 4-phosphate 5-kinases Mss4 and Its3 are involved in resistance against disturbance of sphingolipid biosynthesis and maintenance of cell integrity through the synthesis of PtdIns(4,5)P2 and downstream signalling through the Rom2/Rho2 and Rgf1/Rho pathways. Here, we review models for regulated intracellular targeting of PIPKs by small G-proteins and other modulators in response to extracellular signalling. We also describe the spatial and temporal cross-regulation of PIPKs and small G-proteins that is critical for a number of cellular functions.     

Developmental regulation of GABA(B) receptor function in rat spinal cord

GABA(B) receptors are heterodimers coupled to G-proteins. The present study was undertaken to investigate activation of GABA(B) receptors in cerebral cortex and spinal cord using [35S]GTPgammaS binding assays, a direct measure of G-protein activity. The results revealed that the GABA(B) agonist baclofen stimulates GTPgammaS binding in cerebral cortex, with an ED50 of 50microM. This response is blocked by the GABA(B) receptor antagonist CGP 55845A (100nM). In contrast, baclofen-stimulated GTPgammaS binding was not observed in adult spinal cord tissue under similar incubation conditions, or after varying magnesium, calcium, GDP, [35S]GTPgammaS, or membrane concentrations in the assay medium. Stimulation of adult rat spinal cord muscarinic receptors did result in a concentration-related increase in [35S]GTPgammaS binding. Baclofen-stimulated GTPgammaS binding in adult spinal cord did not appear after peripheral inflammation, despite significant increases in GABA(B) subunit mRNA levels. As opposed to adult, appreciable GTPgammaS binding was observed in membranes prepared from spinal cords of rats within the first 14 days of postnatal development, suggesting that GABA(B) receptor function in the rat spinal cord is developmentally regulated. The results indicate that GABA(B) receptors may not be coupled to G-proteins in the adult rat spinal cord, or couple in a way that differs from that in newborns or adult cerebral cortex.     

Levels of Gsα(short and long), Gα(olf) and Gβ(common) subunits, and calcium-sensitive adenylyl cyclase isoforms (1, 5/6, 8) in post-mortem human brain caudate and cortical membranes: comparison with rat brain membranes and potential stoichiometric relationships

The levels of expression of Gsα(short and long), Gα(olf) and Gβ(common) subunits, and calcium-sensitive adenylyl cyclases isoforms (AC1, 5/6, and 8) in human brain cortical and caudate membranes were quantified by western blot analysis in order to establish their contribution to the patterns of AC functioning. Both areas expressed Gsα(long) (52 kDa) with values ranging from about 1400 ng/mg of membrane protein in cerebral cortex to close to 600 ng/mg of membrane protein in caudate nucleus. In contrast, Gsα(short) and Gsα(olf) were expressed separately, Gsα(short) in cortical membranes with values around 500 ng/mg of membrane protein and Gα(olf) in caudate membranes with values around 1300 ng/mg of membrane protein. Quantitative measurements of Gβ, revealed a similar expression level in cortical and caudate membranes (5444±732 versus 5511±394 ng/mg protein; p=0.966). The B(max) values of GTPγS-dependent [(3)H]-forskolin binding show the following descending order: rat striatal membranes>rat cortical membranes=human caudate membranes>human cortical membranes. Therefore, as measured immunochemically and by [(3)H]-forskolin binding, there seems to be a vast excess of Gsα subunits over catalytic units of AC. The highest levels of AC5/6 expression were detected in caudate membranes. AC8 was little expressed, and there were no significant differences in the relative values between both human brain regions. Finally, the levels of the AC1 isoform were significantly lower in caudate than in cortical membranes. It is concluded that these stoichiometric data contribute nonetheless to explain the significant differences observed in signalling capacities through the AC system in both human brain regions.     

Signalling mechanisms regulating lipolysis

Adipose tissue plays an important role providing energy to other tissues and functioning as an energy reserve organ. The energy supply is produced by triglycerides stored in a large vacuole representing approximately 95% of adipocyte volume. In the fasting period, triglyceride hydrolysis produces glycerol and free fatty acids which are important oxidative fuels for other tissues such as liver, skeletal muscle, kidney and myocardium. Hormone-sensitive lipase (HSL) is the enzyme that hydrolyzes intracellular triacylglycerol and diacylglycerol, and is one of the key molecules controlling lipolysis. Hormones and physiological factors such as dieting, physical exercise and ageing regulate intensively the release of glycerol and free fatty acids from adipocytes. One of the best known mechanisms that activate lipolysis in the adipocyte is the cAMP dependent pathway. cAMP production is modulated by hormone receptors coupled to Gs/Gi family of GTP binding proteins, such as beta-adrenergic receptors, whereas cAMP degradation is controlled by modulation of phosphodiesterase activity, increased by insulin receptor signalling. cAMP activates PKA which activates HSL by promoting its phosphorylation. Hormonal control of lipolysis can also be achieved by receptors coupled G proteins of the Gq family, through molecular mechanisms that involve PKC and MAPK, which are currently under investigation. cGMP and PKG have also been found to activate lipolysis in adipocytes. In this review we have compiled data from literature reporting both the classical and the alternative mechanisms of lipolysis.     

AGS proteins, GPR motifs and the signals processed by heterotrimeric G proteins

A long term objective of our research effort is to define factors that influence the specificity and efficiency of signal propagation by heterotrimeric G-proteins (G). G-proteins play a central role in cellular communication mediating the cell response to numerous hormones and neurotransmitters. A major determinant of signalling specificity for heterotrimeric G-proteins is the cell specific expression of the subtypes of the primary signalling entities, receptor, G and effector (E). Another major site for regulating signalling specificity lies at the R-G or G-E interface where these interactions are influenced by cell architecture, the stoichiometry of signalling components and accessory proteins that may segregate the receptor to microdomains of the cell, regulate the efficiency and/or specificity of signal transfer and/or influence the activation state of G-protein independent of a classical G-protein coupled receptor. One strategy to address these issues in our laboratory involves the identification of cellular proteins that regulate the transfer of signal from receptor to G or directly influence the activation state of G independent of a classical G-protein coupled receptor. We identified three proteins, AGS1, AGS2 and AGS3 (for Activators of G-protein Signaling), that activated heterotrimeric G-protein signalling pathways in the absence of a typical receptor. AGS1, 2 and 3 interact with different subunits and/or conformations of heterotrimeric G-proteins, selectively activate different G-proteins, provide unexpected mechanisms for regulation of the G-protein activation cycle and have opened up a new area of research related to the cellular role of G-proteins as signal transducers.