Specific involvement of G proteins in regulation of serum response factor-mediated gene transcription by different receptors

Identification of a novel extracellular cation-sensing G-protein-coupled receptor

The C family G-protein-coupled receptors contain members that sense amino acid and extracellular cations, of which calcium-sensing receptor (CASR) is the prototypic extracellular calcium-sensing receptor. Some cells, such as osteoblasts in bone, retain responsiveness to extracellular calcium in CASR-deficient mice, consistent with the existence of another calcium-sensing receptor. We examined the calcium-sensing properties of GPRC6A, a newly identified member of this family. Alignment of GPRC6A with CASR revealed conservation of both calcium and calcimimetic binding sites. In addition, calcium, magnesium, strontium, aluminum, gadolinium, and the calcimimetic NPS 568 resulted in a dose-dependent stimulation of GPRC6A overexpressed in human embryonic kidney cells 293 cells. Also, osteocalcin, a calcium-binding protein highly expressed in bone, dose-dependently stimulated GPRC6A activity in the presence of calcium but inhibited the calcium-dependent activation of CASR. Coexpression of beta-arrestins 1 and 2, regulators of G-protein signaling RGS2 or RGS4, the RhoA inhibitor C3 toxin, the dominant negative Galpha(q)-(305-359) minigene, and pretreatment with pertussis toxin inhibited activation of GPRC6A by extracellular cations. Reverse transcription-PCR analyses showed that mouse GPRC6A is widely expressed in mouse tissues, including bone, calvaria, and the osteoblastic cell line MC3T3-E1. These data suggest that in addition to sensing amino acids, GPRC6A is a cation-, calcimimetic-, and osteocalcin-sensing receptor and a candidate for mediating extracellular calcium-sensing responses in osteoblasts and possibly other tissues.

Role of guanine nucleotide exchange factor P-Rex-2b in sphingosine 1-phosphate-induced Rac1 activation and cell migration in endothelial cells

Endothelial cell (EC) migration has an important role in angiogenesis. Sphingosine-1 phosphate (S1P) stimulates EC migration via activation of Gi proteins. In this study, we characterized a mouse guanine nucleotide exchange factor (GEF) P-Rex2b for its regulation by Gbetagamma and PI3K and its role in S1P-induced Rac1 activation and cell migration in ECs. We found that co-expression of Gbetagamma or an active form of PI3K (PI3K(AC)) with P-Rex2b increased the SRE. Luciferase (SRE.L) reporter gene activity that can be stimulated by the Rho family of small GTPases including Rac1. Co-expression with P-Rex2b of Gbetagamma and PI3K(AC) or wild type PI3Kgamma that can be activated by Gbetagamma led to further increases in the reporter gene activity. Together with the finding that co-expression of Gbetagamma and/or PI3K(AC) increased the levels of active Rac1, we conclude that P-Rex2b is a Rac GEF that can be regulated by Gbetagamma and PI3K. Additionally, we demonstrated that Gbetagamma interacted with P-Rex2b, probably through P-Rex2b sequences at the PH domain and that the DEP and PDZ domains of P-Rex2b exerted an inhibitory effect on P-Rex2b's activity because their deletion increased the SER.L reporter gene activity. Furthermore, we found that P-Rex2b is involved in S1P-induced Rac1 activation and cell migration in ECs because siRNA-mediated suppression of P-Rex2b expression in ECs-diminished Rac1 activation and cell migration in response to S1P. Therefore, P-Rex2b is a physiologically significant Rac1 GEF that has an important role in the regulation of EC migration.

Cell signalling diversity of the Gqalpha family of heterotrimeric G proteins

Many receptors for neurotransmitters and hormones rely upon members of the Gqalpha family of heterotrimeric G proteins to exert their actions on target cells. Galpha subunits of the Gq class of G proteins (Gqalpha, G11alpha, G14alpha and G15/16alpha) directly link receptors to activation of PLC-beta isoforms which, in turn, stimulate inositol lipid (i.e. calcium/PKC) signalling. Although Gqalpha family members share a capacity to activate PLC-beta, they also differ markedly in their biochemical properties and tissue distribution which predicts functional diversity. Nevertheless, established models suggest that Gqalpha family members are functionally redundant and that their cellular responses are a result of PLC-beta activation and downstream calcium/PKC signalling. Growing evidence, however, indicates that Gqalpha, G11alpha, G14alpha and G15/16alpha are functionally diverse and that many of their cellular actions are independent of inositol lipid signalling. Recent findings show that Gqalpha family members differ with regard to their linked receptors and downstream binding partners. Reported binding partners distinct from PLC-beta include novel candidate effector proteins, various regulatory proteins, and a growing list of scaffolding/adaptor proteins. Downstream of these signalling proteins, Gqalpha family members exhibit unexpected differences in the signalling pathways and the gene expression profiles they regulate. Finally, genetic studies using whole animal models demonstrate the importance of certain Gqalpha family members in cardiac, lung, brain and platelet functions among other physiological processes. Taken together, these findings demonstrate that Gqalpha, G11alpha, G14alpha and G15/16alpha regulate both overlapping and distinct signalling pathways, indicating that they are more functionally diverse than previously thought.

Functional genomics of the dopaminergic system in hypertension

Abnormalities in dopamine production and receptor function have been described in human essential hypertension and rodent models of genetic hypertension. Under normal conditions, D(1)-like receptors (D(1) and D(5)) inhibit sodium transport in the kidney and intestine. However, in the Dahl salt-sensitive and spontaneously hypertensive rats (SHRs) and in humans with essential hypertension, the D(1)-like receptor-mediated inhibition of epithelial sodium transport is impaired because of an uncoupling of the D(1)-like receptor from its G protein/effector complex. The uncoupling is receptor specific, organ selective, nephron-segment specific, precedes the onset of hypertension, and cosegregates with the hypertensive phenotype. The defective transduction of the renal dopaminergic signal is caused by activating variants of G protein-coupled receptor kinase type 4 (GRK4: R65L, A142V, A486V). The GRK4 locus is linked to and GRK4 gene variants are associated with human essential hypertension, especially in salt-sensitive hypertensive subjects. Indeed, the presence of three or more GRK4 variants impairs the natriuretic response to dopaminergic stimulation in humans. In genetically hypertensive rats, renal inhibition of GRK4 expression ameliorates the hypertension. In mice, overexpression of GRK4 variants causes hypertension either with or without salt sensitivity according to the variant. GRK4 gene variants, by preventing the natriuretic function of the dopaminergic system and by allowing the antinatriuretic factors (e.g., angiotensin II type 1 receptor) to predominate, may be responsible for salt sensitivity. Subclasses of hypertension may occur because of additional perturbations caused by variants of other genes, the quantitative interaction of which may vary depending upon the genetic background.

G protein-coupled receptor signaling through Gq and JNK negatively regulates neural progenitor cell migration

In the early development of the central nervous system, neural progenitor cells divide in an asymmetric manner and migrate along the radial glia cells. The radial migration is an important process for the proper lamination of the cerebral cortex. Recently, a new mode of the radial migration was found at the intermediate zone where the neural progenitor cells become multipolar and reduce the migration rate. However, the regulatory signals for the radial migration are unknown. Using the migration assay in vitro, we examined how neural progenitor cell migration is regulated. Neural progenitor cells derived from embryonic mouse telencephalon migrated on laminin-coated dishes. Endothelin (ET)-1 inhibited the neural progenitor cell migration. This ET-1 effect was blocked by BQ788, a specific inhibitor of the ETB receptor, and by the expression of a carboxyl-terminal peptide of Galpha q but not Galpha i. The expression of constitutively active mutant of Galpha q, Galpha qR183C, inhibited the migration of neural progenitor cells. Moreover, the inhibitory effect of ET-1 was suppressed by the c-Jun N-terminal kinase (JNK) inhibitor SP600125 and the expression of the JNK-binding domain of JNK-interacting protein-1, a specific inhibitor of the JNK pathway. Using the slice culture system of embryonic brain, we demonstrated that ET-1 and the constitutively active mutant of Galpha q caused the retention of the neural progenitor cells in the intermediate zone and JNK-binding domain of JNK-interacting protein-1 abrogated the effect of ET-1. These results indicated that G protein-coupled receptor signaling negatively regulates neural progenitor cell migration through Gq and JNK.

Chronic morphine up-regulates G alpha12 and cytoskeletal proteins in Chinese hamster ovary cells expressing the cloned mu opioid receptor

A growing body of literature indicates that chronic morphine exposure alters the expression and function of cytoskeletal proteins in addition to the well established interactions between mu opioid receptors and G proteins. In the present study, we hypothesized that chronic morphine alters the expression and functional effects of G alpha12, a G protein that regulates downstream cytoskeletal proteins via its control of RhoA. Our results showed that chronic morphine treatment decreased the expression of G alpha i2 (64%) and G alpha i3 (60%), had no effect of G alpha o, and increased G alpha12 (66%) expression in Chinese hamster ovary (CHO) cells expressing the cloned human mu opioid receptors (hMOR-CHO cells) but not in cells expressing a mutant mu opioid receptor that do not develop morphine tolerance and dependence (T394A-CHO cells). Morphine treatment had no significant effect on PAR-1 thrombin receptor-activated G protein activity, as measured by thrombin-stimulated guanosine 5'-O-(3-[35S]thio)triphosphate binding. Chronic morphine treatment significantly enhanced thrombin-stimulated RhoA activity and thrombin-stimulated expression of alpha-actinin, a cytoskeletal anchoring protein, in hMOR-CHO cells. Proteomic analysis of two-dimensional gel spots prepared from hMOR-CHO cells showed that morphine treatment affected the expression of a number of proteins associated with morphological changes. Up-regulation of G alpha12 and alpha-actinin by chronic morphine was also observed in mouse brain. Viewed collectively, these findings indicate, for the first time, that chronic morphine enhances the G alpha12-associated signaling system, which is involved in regulating cellular morphology and growth, supporting other findings that chronic morphine may alter cellular morphology, in addition to cellular function.

Signaling mechanisms for regulation of chemotaxis

Chemotaxis is a fascinating biological process, through which a cell migrates along a shallow chemoattractant gradient that is less than 5% difference between the anterior and posterior of the cell. Chemotaxis is composed of two independent, but interrelated processes-motility and directionality, both of which are regulated by extracellular stimuli, chemoattractants. In this mini-review, recent progresses in the understanding of the regulation of leukocyte chemotaxis by chemoattractant signaling are reviewed.

Receptors coupled to heterotrimeric G proteins of the G12 family

Much regarding the engagement of the G(12) family of heterotrimeric G proteins (G(12) and G(13)) by agonist-activated receptors remains unclear. For example, the identity of receptors that couple unequivocally to G(12) and G(13) and how signals are allocated among these and other G proteins remain open questions. Part of the problem in understanding signaling through G(12) and G(13) is that the activation of these G proteins is rarely demonstrated directly and is instead presumed usually from far removed downstream events. Furthermore, receptors that couple to G(12) and G(13) invariably couple to additional G proteins, and thus few events can be linked unambiguously to one G protein or another. In this article, we document receptors that reportedly couple to G(12), G(13) or both G(12) and G(13), evaluate the methodology used to understand the coupling of these receptors, and discuss the ability of these receptors to couple also to G(q).

Functional consequences of G alpha 13 mutations that disrupt interaction with p115RhoGEF

The G-protein alpha subunit, alpha(13), regulates cell growth and differentiation through the monomeric Rho GTPase. Alpha(13) activates Rho through direct stimulation of the guanine nucleotide exchange factor p115RhoGEF, which contains a regulator of G-protein signaling homology domain (RH) in its N-terminus. Through its RH domain, p115RhoGEF also functions as a GAP for G alpha(13). The mechanism for the G alpha(13)/p115RhoGEF interaction is not well understood. Here, we determined specific alpha(13) residues important for its interaction with p115RhoGEF. GST-pulldowns and co-immunoprecipitation assays revealed that individually mutating alpha(13) residues Lys204, Glu229, or Arg232 to opposite charge residues disrupts the interaction of activated alpha(13) with the RH domain of p115RhoGEF or full-length p115RhoGEF. We further demonstrate that mutation of Glu229, and to a lesser extent Lys204 or Arg232, disrupts the ability of activated alpha(13) to induce the recruitment of p115RhoGEF to the plasma membrane (PM) and to activate Rho-mediated serum response element-luciferase gene transcription. Interestingly, an alpha(13) mutant where a conserved Gly was mutated to a Ser (G205S) retained its ability to bind to p115RhoGEF, induce p115RhoGEF recruitment to the PM, and activate Rho-dependent signaling, even though identical Gly to Ser mutations in other alpha disrupt their interaction with regulator of G-protein signaling (RGS) proteins. These results demonstrate that, whereas several features of a typical alpha/RGS interaction are preserved in the alpha(13)/p115RhoGEF interaction, there are also significant differences.

The guanine nucleotide exchange factor p63RhoGEF, a specific link between Gq/11-coupled receptor signaling and RhoA

The monomeric GTPase RhoA, which is a key regulator of numerous cellular processes, is activated by a variety of G protein-coupled receptors, through either G12 or G(q) family proteins. Here we report that p63RhoGEF, a recently identified RhoA-specific guanine nucleotide exchange factor, enhances the Rho-dependent gene transcription induced by agonist-stimulated G(q/11)-coupled receptors (M3-cholinoceptor, histamine H1 receptor) or GTPase-deficient mutants of G alpha(q) and G alpha11. We further demonstrate that active G alpha(q) or G alpha11, but not G alpha12 or G alpha13, strongly enhances p63RhoGEF-induced RhoA activation by direct protein-protein interaction with p63RhoGEF at its C-terminal half. Moreover, the activation of p63RhoGEF by G alpha(q/11) occurs independently of and in competition to the activation of the canonical G alpha(q/11) effector phospholipase C beta. Therefore, our results elucidate a new signaling pathway by which G alpha(q/11)-coupled receptors specifically induce Rho signaling through a direct interaction of activated G alpha(q/11) subunits with p63RhoGEF.

Gα13 Signals via p115RhoGEF Cascades Regulating JNK1 and Primitive Endoderm Formation

The heterotrimeric G-protein G(13) mediates the formation of primitive endoderm from mouse P19 embryonal carcinoma cells in response to retinoic acid, signaling to the level of activation of c-Jun N-terminal kinase. The signal linkage map from MEKK1/MEKK4 to MEK1/MKK4 to JNK is obligate in this G alpha(13)-mediated pathway, whereas that between G alpha(13) and MEKKs is not known. The overall pathway to primitive endoderm formation was shown to be inhibited by treatment with Clostridium botulinum C3 exotoxin, a specific inactivator of RhoA family members. Constitutively active G alpha(13) was found to activate RhoA as well as Cdc42 and Rac1 in these cells. Although constitutively active Cdc42, Rac1, and RhoA all can activate JNK1, only the RhoA mutant was able to promote formation of primitive endoderm, mimicking expression of the constitutively activated G alpha(13). Expression of the constitutively active mutant form of p115RhoGEF (guanine nucleotide exchange factor) was found to activate RhoA and JNK1 activities. Expression of the dominant negative p115RhoGEF was able to inhibit activation of both RhoA and JNK1 in response to either retinoic acid or the expression of a constitutively activated mutant of G alpha(13). Expression of the dominant negative mutants of RhoA as well as those of either Cdc42 or Rac1, but not Ras, attenuated G alpha(13)-stimulated as well as retinoic acid-stimulated activation of all three of these small molecular weight GTPases, suggesting complex interrelationships among the three GTPases in this pathway. The formation of primitive endoderm in response to retinoic acid also could be blocked by expression of dominant negative mutants of RhoA, Cdc42, or Rac1. Thus, the signal propagated from G alpha(13) to JNK requires activation of p115RhoGEF cascades, including p115RhoGEF itself, RhoA, Cdc42, and Rac1. In a concerted effort, RhoA in tandem with Cdc42 and Rac1 activates the MEKK1/4, MEK1/MKK4, and JNK cascade, thereby stimulating formation of primitive endoderm.

Regulation of serum response factor-dependent gene expression by proteasome inhibitors

Serum response factor (SRF) is activated by contractile and hypertrophic agonists, such as endothelin-1 (ET1) to stimulate expression of cytoskeletal proteins in vascular smooth muscle cells (VSMCs). While studying the regulation of smooth muscle alpha-actin (SMA) expression at the level of protein stability, we discovered that inhibition of proteasome-dependent protein degradation by N-benzoyloxycarbonyl (Z)-Leu-Leu-leucinal (MG132) or lactacystin (LC) did not enhance the levels of SMA, but, unexpectedly, attenuated SMA expression in response to ET1, without affecting the viability of VSMCs. Down-regulation of SMA protein by MG132 or LC occurred at the level of SMA transcription and via the inhibition of SRF activity. By contrast, MG132 and LC potentiated the activity of activator protein-1 transcription factor. Regulation of SRF by MG132 was not related to inhibition of nuclear factor-kappaB, an established target of proteasome inhibitors, and was not mediated by protein kinase A, a powerful regulator of SRF activity. Signaling studies indicate that inhibition of ET1-induced SRF activity by MG132 occurs at the level downstream of heterotrimeric G proteins Gq/11 and G13, of small GTPase RhoA, and of actin dynamics but at the level of SRF-DNA binding. MG132 treatment did not result in ubiquitination or accumulation of SRF. By contrast, the levels of c-Jun were rapidly increased upon incubation of cells with MG132, and ectopic overexpression of c-Jun mimicked the effect of MG132 on SRF activity. Together, these data suggest that inhibition of proteasome results in down-regulation of SMA expression via up-regulation of c-Jun and repression of SRF activity at the level of DNA binding.

Common structural basis for constitutive activity of the ghrelin receptor family

Three members of the ghrelin receptor family were characterized in parallel: the ghrelin receptor, the neurotensin receptor 2 and the orphan receptor GPR39. In transiently transfected COS-7 and human embryonic kidney 293 cells, all three receptors displayed a high degree of ligand-independent signaling activity. The structurally homologous motilin receptor served as a constitutively silent control; upon agonist stimulation, however, it signaled with a similar efficacy to the three related receptors. The constitutive activity of the ghrelin receptor and of neurotensin receptor 2 through the G(q), phospholipase C pathway was approximately 50% of their maximal capacity as determined through inositol phosphate accumulation. These two receptors also showed very high constitutive activity in activation of cAMP response element-driven transcription. GPR39 displayed a clear but lower degree of constitutive activity through the inositol phosphate and cAMP response element pathways. In contrast, GPR39 signaled with the highest constitutive activity in respect of activation of serum response element-dependent transcription, in part, possibly, through G(12/13) and Rho kinase. Antibody feeding experiments demonstrated that the epitope-tagged ghrelin receptor was constitutively internalized but could be trapped at the cell surface by an inverse agonist, whereas GPR39 remained at the cell surface. Mutational analysis showed that the constitutive activity of both the ghrelin receptor and GPR39 could systematically be tuned up and down depending on the size and hydrophobicity of the side chain in position VI:16 in the context of an aromatic residue at VII:09 and a large hydrophobic residue at VII:06. It is concluded that the three ghrelin-like receptors display an unusually high degree of constitutive activity, the structural basis for which is determined by an aromatic cluster on the inner face of the extracellular ends of TMs VI and VII.

Rho-modifying C3-like ADP-ribosyltransferases

C3-like exoenzymes comprise a family of seven bacterial ADP-ribosyltransferases, which selectively modify RhoA, B, and C at asparagine-41. Crystal structures of C3 exoenzymes are available, allowing novel insights into the structure-function relationships of these exoenzymes. Because ADP-ribosylation specifically inhibits the biological functions of the low-molecular mass GTPases, C3 exoenzymes are established pharmacological tools to study the cellular functions of Rho GTPases. Recent studies, however, indicate that the functional consequences of C3-induced ADP-ribosylation are more complex than previously suggested. In the present review the basic properties of C3 exoenzymes are briefly summarized and new findings are reviewed.

A novel Galphaq/11-selective inhibitor

YM-254890, which was isolated from the culture broth of Chromobacterium sp., inhibits ADP-induced platelet aggregation and has antithrombotic and thrombolytic effects. YM-254890 blocks Galpha(q/11)-coupled ADP receptor P2Y1-mediated Ca(2+) mobilization. Here we report that YM-254890 is a selective Galpha(q/11) inhibitor. YM-254890 blocked Ca(2+) mobilization mediated by several Galpha(q/11)-coupled receptors but not by Galpha(i)- or Galpha(15)-coupled receptor, indicating that phospholipase Cbeta activation and subsequent signaling molecules are not the target of YM-254890. YM-254890 completely prevented the serum response factor (SRF)-mediated gene transcription induced by Galpha(q)R183C, which is constitutively active in a receptor-dependent manner because of its reduced k(cat) of GTP hydrolysis. Conversely, YM-254890 had only a modest effect on the SRF-mediated gene transcription by Galpha(q)Q209L, which is GTPase-deficient (activated) Galpha(q). These suggested that the acting point of YM-254890 is receptor-Galpha(q) interaction or the subsequent guanine nucleotide exchange step. The fact that YM-254890 (i) inhibited the SRF-mediated gene transcription by Galpha(qi5), which interacts with Galpha(i)-coupled receptor and possesses the effector function of Galpha(q), and (ii) had no effect on the K(d) value of high affinity [(3)H]2MeSADP binding to P2Y1, which reflects the agonist-receptor-Galpha ternary complex, suggested that receptor-Galpha(q/11) interaction is not the target of YM-254890. On the other hand, specific [(35)S]GTPgammaS binding to Galpha(q/11) stimulated by the M1 muscarinic acetylcholine receptor and P2Y1 were inhibited by YM-254890. These data indicate that YM-254890 blocks the exchange of GDP for GTP in Galpha(q/11) activation. This novel Galpha(q/11)-selective inhibitor is a promising and powerful tool for studying Galpha(q/11) protein activation, Galpha(q/11) -coupled receptor signaling, and Galpha(q/11)-mediated biological events.

Role of Lbc RhoGEF in Galpha12/13-induced signals to Rho GTPase

Heterotrimeric Galpha12/13 signals induce cellular responses such as serum response element (SRE)-mediated gene transcription via Rho GTPase. Guanine nucleotide exchange factors (GEFs) are strong candidates for linking Galpha signals to Rho. For example, p115 RhoGEF transduces Galpha13 signals to Rho and inhibits Galpha12/13 signals via the RhoGEF LH domain which links to Galpha subunits. Here, we have evaluated the signaling capacity of Lbc RhoGEF in the context of Galpha12/13 signals. In vitro GEF assays indicate that baculoviral-expressed proto-Lbc has minimal exchange activity, implying that a stimulus is required for Lbc activity in vivo. Expression of a catalytically inactive proto-Lbc mutant in HEK293T cells attenuates Galpha12- and thrombin-induced activation of an SRE transcriptional reporter, and the levels of inhibition observed is similar to that obtained with an analogous p115 RhoGEF mutant. proto-Lbc mutant expression also led to decreased levels of Galpha12-induced RhoA activation in vivo. Complex formation between Galpha12 and Lbc forms was detected. Analysis of the Lbc peptide sequence reveals a previously undetected region which may link to Galpha subunit signals. These findings support a role for Lbc in Galpha12-induced signaling pathways to Rho.

Historical review: Endothelin

Endothelin (ET) is a potent vasoconstrictive peptide that was isolated initially from the conditioned medium of cultured endothelial cells. In 1988, details of the isolation and identification, amino acid sequence, cDNA sequence and pharmacology of ET were published. Subsequently, ET isoforms, ET receptors and endothelin-converting enzyme (ECE) were cloned. Because ET was thought to be important in cardiovascular homeostasis, many investigators focused on the physiological and pathophysiological significance of ET. Accordingly, ET receptor antagonists and ECE inhibitors have been developed rapidly, mostly for the treatment of cardiovascular diseases. The field of molecular biology has provided valuable information about ET, including evidence that the ET system plays important roles in the early development of the neural crest and, thus, in the formation of organs. These results now present new avenues of ET research.

The small GTP-binding protein RhoA regulates serotonin-induced Na+-current response in the neurons of Aplysia

Application of serotonin (5-HT) induces a slow inward current response in identified neurons of Aplysia ganglia under voltage clamp. The 5-HT-induced current response was depressed in Na+-free media, but augmented in Ca2+-free media, and unaffected by a change in external K+. The 5-HT-induced response was markedly blocked by intracellular injection of guanosine 5'-O-(2-thiodiphosphate) (GDPbetaS). After the injection of guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS), the responses to 5-HT gradually and significantly increased at the initial period, reached its plateau, and finally decreased. Intracellular injection of Clostridium difficile toxin B, a blocker of small G-protein Rho family members such as Rho (RhoA, RhoB and RhoC), Rac and Cdc42, markedly depressed the 5-HT-induced response. Intracellular injection of Clostridium botulinum C3 exoenzyme, a specific blocker of RhoA, RhoB, RhoC, exhibited a similar depressing effect observed with toxin B. In contrast, intracellular injection of recombinant L63RhoA, a constitutively active form of RhoA, significantly augmented the 5-HT-induced response without affecting the resting membrane. These results suggested that the 5-HT-induced Na+-current response might be facilitated by the activation of Aplysia Rho which is closely homologous to RhoA, RhoB or RhoC in mammalian neuron.

Identification and Functional Analysis of the Drosophila Gene loco

In contrast to vertebrates, the fruit fly Drosophila melanogaster contains only a small number of regulator of G-protein signaling (RGS) domain genes. This article reviews current knowledge on these genes. Although the fruit fly is particularly amenable to genetic analysis and manipulation, not much is known about the functions and mechanisms of action. The best-studied RGS gene in Drosophila is loco, a member of the D/R12 subfamily. The four different protein isoforms all contain RGS, GoLoco, and RBD domains. This article describes the identification and functional analyses of loco in the Drosophila system and discusses some mechanistic models that may underlie loco function.

G Protein βγ Subunits Stimulate p114RhoGEF, a Guanine Nucleotide Exchange Factor for RhoA and Rac1

Rho GTPases integrate the intracellular signaling in a wide range of cellular processes. Activation of these G proteins is tightly controlled by a number of guanine nucleotide exchange factors (GEFs). In this study, we addressed the functional role of the recently identified p114RhoGEF in in vivo experiments. Activation of endogenous G protein-coupled receptors with lysophosphatidic acid resulted in activation of a transcription factor, serum response element (SRE), that was enhanced by p114RhoGEF. This stimulation was inhibited by the functional scavenger of Gβγ subunits, transducin. We have determined that Gβγ subunits but not Gα subunits of heterotrimeric G proteins stimulated p114RhoGEF-dependent SRE activity. Using coimmunoprecipitation assay, we have determined that Gβγ subunits interacted with full-length and DH/PH domain of p114RhoGEF. Similarly, Gβγ subunits stimulated SRE activity induced by full-length and DH/PH domain of p114RhoGEF. Using in vivo pull-down assays and dominant-negative mutants of Rho GTPases, we have determined that p114RhoGEF activated RhoA and Rac1 but not Cdc42 proteins. Functional significance of RhoA activation was established by the ability of p114RhoGEF to induce actin stress fibers and cell rounding. Functional significance of Rac1 activation was established by the ability of p114RhoGEF to induce production of reactive oxygen species (ROS) followed by activation of NADPH oxidase enzyme complex. In summary, our data showed that the novel guanine nucleotide exchange factor p114RhoGEF regulates the activity of RhoA and Rac1, and that Gβγ subunits of heterotrimeric G proteins are activators of p114RhoGEF under physiological conditions. The findings help to explain the integrated effects of LPA and other G-protein receptor-coupled agonists on actin stress fiber formation, cell shape change, and ROS production.

Dimers of class A G protein-coupled receptors function via agonist-mediated trans-activation of associated G proteins

The histamine H1 receptor and the alpha1b-adrenoreceptor are G protein-coupled receptors that elevate intracellular [Ca2+] via activation of Gq/G11. Assessed by co-immunoprecipitation and time-resolved fluorescence resonance energy transfer they both exist as homo-dimers. The addition of the G protein G11alpha to the C terminus of these receptors did not prevent dimerization. Agonists produced a large stimulation of guanosine 5'-3-O-([35S]thio)triphosphate ([35S]GTPgammaS) binding to receptor-G protein fusions containing wild type forms of both polypeptides. For both receptors this was abolished by incorporation of G208AG11alpha into the fusions. Mutation of a highly conserved leucine in intracellular loop 2 of each receptor also eliminated agonist function but not binding. Co-expression of the two non-functional but complementary fusion constructs reconstituted agonist-mediated binding of [35S]GTPgammaS in membranes of HEK293 cells and elevation of [Ca2+]i in mouse embryo fibroblasts lacking both Gq and G11. Co-expression of the histamine H1 receptor- and the alpha1b-adrenoreceptor-G11alpha fusions allowed detection of functional hetero-dimeric complexes, whereas co-expression of histamine H1 receptor-G11alpha with increasing amounts of L151Dalpha1b-adrenoreceptor resulted in decreasing levels of histamine-stimulated [35S]GTPgammaS binding. Co-expression of the alpha1b-adrenoreceptor with a fusion protein incorporating the N-terminal domain and transmembrane helix 1 of the alpha1b-adrenoreceptor and G11alpha did not result in agonist activation of the G protein but did indicate a role for transmembrane helix 1 in dimerization. These data demonstrate that dimers of these class A receptors function via trans-activation of associated G proteins.

Common Signaling Pathways Link Activation of Murine PAR-1, LPA, and S1P Receptors to Proliferation of Astrocytes

Receptors for the serine protease thrombin and for lysophospholipids are coupled to G proteins and control a wide range of cellular functions, including mitogenesis. Activators of these receptors are present in blood, and can enter the brain during central nervous system (CNS) injury. Reactive astrogliosis, a prominent component of CNS injury with potentially harmful consequences, may involve proliferation of astrocytes. In this study, we have examined the expression and activation of protease activated receptors (PARs), lysophosphatidic acid (LPA) receptors, and sphingosine-1-phosphate (S1P) receptors on murine astrocytes. We show that activation of these three receptor classes can lead to astrogliosis in vivo and proliferation of astrocytes in vitro. Cultured murine cortical astrocytes express mRNA for multiple receptor subtypes of PAR (PAR-1-4), LPA (LPA-1-3) and S1P (S1P-1, -3, -4, and -5) receptors. Comparison of the intracellular signaling pathways of glial PAR-1, LPA, and S1P receptors indicates that each receptor class activates multiple downstream signaling pathways, including Gq/11-directed inositol lipid/Ca2+ signaling, Gi/o activation of mitogen-activated protein kinases (MAPK) (extracellular signal-regulated kinase 1/2 and stress activated protein kinase/c-jun N-terminal kinase, but not p38), and activation of Rho pathways. Furthermore, activation of these different receptor classes can differentially regulate two transcription factor pathways, serum response element and nuclear factor of activated T cells. Blockade of Gi/o signaling with pertussis toxin, MAPK activation with 1,4-diamino-2,3-dicyano-1,4-bis(2-aminophynyltio)butadiene (U0126), or Rho kinase signaling with R-(+)-trans-N-(4-pyridyl)-4-(1-aminoethyl)-cyclohexane carboxamide (Y27632) can markedly reduce the proliferative response of glial cells to PAR-1, LPA, or S1P receptor activation, suggesting that each of these pathways is important in coupling of receptor activation to glial proliferation.

CrkII induces serum response factor activation and cellular transformation through its function in Rho activation

CrkII belongs to the adaptor protein family that plays a crucial role in signal transduction. In order to better understand the biological functions of CrkII, we focused on the regulation of gene expression by CrkII. Various transcriptional control elements were examined for their activation by CrkII-expression, and we found that CrkII selectively activates the serum response element (SRE), a transcriptional control element of immediate-early genes. This SRE activation induced by CrkII-overexpression was mediated by the serum response factor (SRF) via Rho. Indeed, we confirmed that the amount of activated Rho was increased in the CrkII-expressing cells. Moreover, we showed that when overexpressed, CrkII induces the cellular transformation of NIH 3T3 cells and that a dominant negative mutant of Rho suppresses this transformation, strongly suggesting that activation of Rho is essential for the transforming activity by CrkII. Furthermore, we also found that CrkII and Galpha12, a member of the heterotrimeric G proteins, synergistically activates Rho as well as the SRF, and that an SH3 mutant of CrkII can inhibit the Galpha12-induced activation of SRF. These results strongly suggest that CrkII is involved in the activation of Rho and SRF by Galpha12. Our study provides strong evidence that Rho activation plays a crucial role in CrkII-mediated signals to induce gene expression and cellular transformation.

Serum response factor function and dysfunction in smooth muscle

Tight control of smooth muscle cell (SM) proliferation, differentiation, and apoptosis requires a balance between signaling and transcriptional events. Recent developments in vascular research revealed that serum response factor (SRF) function is important for the regulation of each of these processes. The cloning and characterization of several SM specific genes and the discovery that SRF is central for their expression fueled studies aimed at understanding the role of molecular partners including co-activators and co-repressors. Perturbations of pathways involving SRF are associated with abnormalities in the myogenic program and aberrant phenotypic consequences. Surprisingly, studies on airway SM have remained an underrepresented area of investigation. Our laboratory described a novel regulatory mechanism of SRF function in airway myocytes by modulation of its subcellular localization. This review summarizes current knowledge on the structure and function of this essential transcription factor as well different modes of regulating SRF expression and activity that are becoming key players in directing SM function in health and disease.

Regulators of G protein signalling: potential targets for treatment of allergic inflammatory diseases such as asthma

Asthma, a disease that affects nearly 15% of the world's population, is characterised by lung inflammation and reversible airway obstruction, which leads to wheezing and dyspnoea. Asthma is a prototype for allergic processes initiated by tissue inflammatory leukocytes, such as mast cells, whose secreted mediators recruit lymphocytes and eosinophils to the lung parenchyma. Signals transmitted through G-protein-coupled receptors (GPCRs) contribute to both the development and perpetuation of allergic processes, and pharmacological agents that block or stimulate GPCR action have been a mainstay of allergic disease therapy. Despite the widespread use of GPCR-targeted agents, little is understood about intracellular regulation of G protein pathways in immune cells. Regulators of G protein signalling (RGS proteins) enhance G protein deactivation and may contribute to the specificity and precision characteristic of GPCR signalling pathways. This review discusses the emerging functions of RGS proteins in immune processes and inflammatory states such as asthma, and their potential value as therapeutic targets for the treatment of allergic disease.

Receptor-dependent RhoA activation in G12/G13-deficient cells: genetic evidence for an involvement of Gq/G11

The small GTPase RhoA is involved in the regulation of various cellular functions like the remodeling of the actin cytoskeleton and the induction of transcriptional activity. G-protein-coupled receptors (GPCRs), which are able to activate Gq/G11 and G12/G13 are major upstream regulators of RhoA activity, and G12/G13 have been shown to couple GPCRs to the activation of Rho by regulating the activity of a subfamily of RhoGEF proteins. However, the possible contribution of Gq/G11 to the regulation of RhoA activity via GPCRs is controversial. We have used a genetic approach to study the role of heterotrimeric G-proteins in the activation of RhoA via endogenous GPCRs. In pertussis toxin-treated Galpha12/Galpha13-deficient as well as in Galphaq/Galpha11-deficient mouse embryonic fibroblasts (MEFs), in which coupling of receptors is restricted to Gq/G11 and G12/G13, respectively, receptor activation results in Rho activation. Rho activation induced by receptor agonists via Gq/G11 occurs with lower potency than Rho activation via G12/G13. Activation of RhoA via Gq/G11 is not affected by the phospholipase-C blocker U73122 or the Ca2+-chelator BAPTA, but can be blocked by a dominant-negative mutant of the RhoGEF protein LARG. Our data clearly show that G12/G13 as well as Gq/G11 alone can couple GPCRs to the rapid activation of RhoA. Gq/G11-mediated RhoA activation occurs independently of phospholipase C-beta and appears to involve LARG.

Extracellular calcium-sensing receptors in the parathyroid gland, kidney, and other tissues

PURPOSE OF REVIEW

The discovery of the extracellular calcium-sensing receptor, CasR has broadened our understanding of calcium homeostasis and led to the development of new pharmacological agents, calcimimetics, for treating hyperparathyroidism. In the present review, I discuss the function of CasR as well as provide evidence for the presence of additional calcium-sensing mechanisms in the skeleton and possibly other tissues.

RECENT FINDINGS

Inactivating and activating mutations of the CasR respectively cause hereditary hyperparathyroidism, and demonstrate the predominant role of the CasR in controlling parathyroid gland function. Calcimimetics, which increase the sensitivity of CasR to extracellular calcium have been developed to treat secondary and primary hyperparathyroidism. In recent clinical trials in patients with end stage kidney disease, the calcimimetic cinacalcet suppressed parathyroid hormone to a greater degree than conventional therapy with vitamin D analogues without causing hypercalcemia or hyperphosphatemia. CasR receptor also has functions in other tissues, including regulation of renal calcium excretion and calcitonin secretion by thyroidal C-cells, but the presence of redundant sensing mechanisms for extracellular calcium in other tissues, including bone, confounds the assessment of the receptor's function at these sites. Mouse genetic approaches have so far failed to identify any essential, non-redundant role for the calcium-sensing receptor in regulating chondrogenesis or osteogenesis, and have failed to establish a function for the protein outside of the parathyroid gland, kidney, and thyroidal C-cells. Rather, there is evidence for other putative calcium sensing receptor-like mechanisms in osteoblasts that remain to be identified.

SUMMARY

Sensing of extracellular calcium by CasR is important in regulating calcium homeostasis, but CasR may have vestigial function in various tissues where it is expressed in low abundance. The relative importance of CasR and the novel calcium-sensing mechanisms in mediating response to extracellular calcium in many of these tissues remain to be determined.

Characterization of G alpha 13-dependent plasma membrane recruitment of p115RhoGEF

The Ras homology (Rho) guanine nucleotide exchange factor (GEF), p115RhoGEF, provides a direct link between the G-protein alpha subunit, alpha(13), and the small GTPase Rho. In the present study, we demonstrate that activated mutants of alpha(13) or alpha(12), but not alpha(q), promote the redistribution of p115RhoGEF from the cytoplasm to the plasma membrane (PM). We also show that the PM translocation of p115RhoGEF is promoted by stimulation of thromboxane A(2) receptors. Furthermore, we define domains of p115RhoGEF required for its regulated PM recruitment. The RhoGEF RGS (regulators of G-protein signalling) domain of p115RhoGEF is required for PM recruitment, but it is not sufficient for strong alpha(13)-promoted PM recruitment, even though it strongly interacts with activated alpha(13). We also identify the pleckstrin homology domain as essential for alpha(13)-mediated PM recruitment. An amino acid substitution of lysine to proline at position 677 in the pleckstrin homology domain of p115RhoGEF inhibits Rho-mediated gene transcription, but this mutation does not affect alpha(13)-mediated PM translocation of p115RhoGEF. The results suggest a mechanism whereby multiple signals contribute to regulated PM localization of p115RhoGEF.

Molecular mechanisms for the activation of Ca2+-permeable nonselective cation channels by endothelin-1 in C6 glioma cells

We recently demonstrated that endothelin-1 (ET-1) activates two types of Ca(2+)-permeable nonselective cation channels (NSCC-1 and NSCC-2) in C6 glioma cells. It is possible to discriminate between these channels by using the Ca(2+) channel blockers SK&F 96365 (1-[beta-(3-[4-methoxyphenyl]propoxy)-4-methoxyphenethyl]-1H-imidazole hydrochloride) and LOE 908 [(R,S)-(3,4-dihydro-6,7-dimethoxy-isoquinoline-1-yl)-2-phenyl-N,N-di-[2-(2,3,4-trimethoxyphenyl)ethyl]-acetamide]. LOE 908 is a blocker for NSCC-1 and NSCC-2, whereas SK&F 96365 is an inhibitor for NSCC-2. The purpose of the present study was to identify the G-proteins that are involved in ET-1-activated Ca(2+) channels in C6 glioma cells. ET-1 activated only NSCC-1 in C6 glioma cells preincubated with U73122 (1-[6-[((17beta)-3-methoxyestra-1,3,5[10]-trien-17-yl)amino]hexyl]-1H-pyrrole-2,5-dione), a phospholipase C (PLC) inhibitor. Microinjection of the dominant negative mutant of G(12)/G(13) (G(12)G228A/G(13)G225A) abolished activation of NSCC-1 and NSCC-2. In contrast, pertussis toxin did not affect any of the Ca(2+) channels in the ET-1-stimulated C6 glioma cells. These results indicate that G(12)/G(13) may couple with endothelin receptors and play an important role in the activation of NSCCs in C6 glioma cells. Moreover, the activation mechanisms of NSCC-1 and NSCC-2 by ET-1 were different. NSCC-1 activation depended upon a G(12)/G(13)-dependent cascade, whereas NSCC-2 activation depended upon both G(q)/PLC- and G(12)/G(13)-dependent cascades.

Galpha12- and Galpha13-protein subunit linkage of D5 dopamine receptors in the nephron

The roles of the G-protein alpha-subunits, Gs, Gi, and Gq/11, in the signal transduction of the D1-like dopamine receptors, D1 and D5, have been deciphered. Galpha12 and Galpha13, members of the 4th family of G protein subunits, are not linked with D1 receptors, and their linkage to D5 receptors is not known. Therefore, we studied the expression of Galpha12 and Galpha13 and interaction with D5 dopamine receptors in the kidney from normotensive Wistar-Kyoto (WKY) rats and D5 receptor-transfected HEK293 cells. Galpha12 and Galpha13 were found in the proximal tubule, distal convoluted tubule, and artery and vein in the WKY rat kidney. Whereas Galpha12 was expressed in the ascending limb of Henle, Galpha13 was expressed in the collecting duct and juxtaglomerular cells. In renal proximal tubules, Galpha12 and Galpha13, as with D5 receptors, were expressed in brush border membranes. Laser confocal microscopy revealed the colocalization of D5 receptors with Galpha12 and Galpha13 in rat renal brush border membranes, immortalized rat renal proximal tubule cells, and D5 receptor-transfected HEK293 cells. In these cells, a D1-like agonist, fenoldopam, increased the association of Galpha12 and Galpha13 with D5 receptors, results that were corroborated by immunoprecipitation experiments. We conclude that although both D1 and D5 receptors are linked to Galphas, they are differentially linked to Galpha12 and Galpha13. The consequences of the differential G-protein subunit linkage on D1- and D5-mediated sodium transport remains to be determined.

G protein-coupled receptor Kinase 2/G alpha q/11 interaction. A novel surface on a regulator of G protein signaling homology domain for binding G alpha subunits

G protein-coupled receptors (GPCRs) transduce cellular signals from hormones, neurotransmitters, light, and odorants by activating heterotrimeric guanine nucleotide-binding (G) proteins. For many GPCRs, short term regulation is initiated by agonist-dependent phosphorylation by GPCR kinases (GRKs), such as GRK2, resulting in G protein/receptor uncoupling. GRK2 also regulates signaling by binding G alpha(q/ll) and inhibiting G alpha(q) stimulation of the effector phospholipase C beta. The binding site for G alpha(q/ll) resides within the amino-terminal domain of GRK2, which is homologous to the regulator of G protein signaling (RGS) family of proteins. To map the Galpha(q/ll) binding site on GRK2, we carried out site-directed mutagenesis of the RGS homology (RH) domain and identified eight residues, which when mutated, alter binding to G alpha(q/ll). These mutations do not alter the ability of full-length GRK2 to phosphorylate rhodopsin, an activity that also requires the amino-terminal domain. Mutations causing G alpha(q/ll) binding defects impair recruitment to the plasma membrane by activated G alpha(q) and regulation of G alpha(q)-stimulated phospholipase C beta activity when introduced into full-length GRK2. Two different protein interaction sites have previously been identified on RH domains. The G alpha binding sites on RGS4 and RGS9, called the "A" site, is localized to the loops between helices alpha 3 and alpha 4, alpha 5 and alpha 6, and alpha 7 and alpha 8. The adenomatous polyposis coli (APC) binding site of axin involves residues on alpha helices 3, 4, and 5 (the "B" site) of its RH domain. We demonstrate that the G alpha(q/ll) binding site on the GRK2 RH domain is distinct from the "A" and "B" sites and maps primarily to the COOH terminus of its alpha 5 helix. We suggest that this novel protein interaction site on an RH domain be designated the "C" site.

Regulators of G-protein signalling: multifunctional proteins with impact on signalling in the cardiovascular system

Regulator of G-protein signalling (RGS) proteins form a superfamily of at least 25 proteins, which are highly diverse in structure, expression patterns, and function. They share a 120 amino acid homology domain (RGS domain), which exhibits GTPase accelerating activity for alpha-subunits of heterotrimeric G-proteins, and thus, are negative regulators of G-protein-mediated signalling. Based on the organisation of the Rgs genes, structural similarities, and differences in functions, they can be divided into at least six subfamilies of RGS proteins and three more families of RGS-like proteins. Many of these proteins regulate signalling processes within cells, not only via interaction with G-protein alpha-subunits, but are G-protein-regulated effectors, Gbetagamma scavenger, or scaffolding proteins in signal transduction complexes as well. The expression of at least 16 different RGS proteins in the mammalian or human myocardium have been described. A subgroup of at least eight was detected in a single atrial myocyte. The exact functions of these proteins remain mostly elusive, but RGS proteins such as RGS4 are involved in the regulation of G(i)-protein betagamma-subunit-gated K(+) channels. An up-regulation of RGS4 expression has been consistently found in human heart failure and some animal models. Evidence is increasing that the enhanced RGS4 expression counter-regulates the G(q/11)-induced signalling caused by hypertrophic stimuli. In the vascular system, RGS5 seems to be an important signalling regulator. It is expressed in vascular endothelial cells, but not in cultured smooth muscle cells. Its down-regulation, both in a model of capillary morphogenesis and in an animal model of stroke, render it a candidate gene, which may be involved in the regulation of capillary growth, angiogenesis, and in the pathophysiology of stroke.

The first inner loop of endothelin receptor type B is necessary for specific coupling to Galpha 13

Endothelin (EDN) receptor type B (EDNRB) activates serum response factor (SRF) via G(q/11) and G(12/13) G proteins. In this study, we investigated the involvement of intracellular loop sequences of EDNRB in coupling to these G proteins. EDNRB mutants were generated and tested for their abilities to activate SRF in NIH3T3 cells and in the mouse embryonic fibroblast cell line (F(q/11)) lacking both Galpha(q) and Galpha(11). EDNRB can activate SRF in NIH3T3 cells via G(q/11), although it can only activate SRF through G(12/13) in F(q/11) cells. Mutants with mutations in the second and third inner loops of EDNRB functioned in the same manner in both cell lines, either able or unable to activate SRF. This finding suggests that the second and third inner loops of EDNRB either participate or not in coupling to both G(q/11) and G(12/13) but are not specific for either one. However, in the first inner loop, a substitution of three Ala residues for Met(128)-Arg(129)-Asn(130) abolished the ability to activate SRF only in F(q/11) cells, suggesting that this mutation might specifically disrupt the coupling to G(12/13) rather than to G(q/11). Further characterization of this first inner loop mutant revealed that exogenous expression of Galpha(12) or Galpha(q) could restore SRF activation, whereas the expression of Galpha(13) did not. Therefore, we conclude that although the three intracellular loops of EDNRB may be involved in coupling to G proteins, residues Met(128)-Arg(129)-Asn(130) in the first intracellular loop are specifically required for activation of Galpha(13).

The proximal serum response element in the Egr-1 promoter mediates response to thrombin in primary human endothelial cells

Thrombin signaling in endothelial cells provides an important link between coagulation and inflammation. We report here that thrombin induces endogenous Egr-1 mRNA and Egr-1 promoter activity in primary human endothelial cells by approximately 6-fold and 3-fold, respectively. In transient transfection assays, deletion of the 3' cluster of serum response elements (SREs), but not the 5' cluster of SREs, resulted in a loss of thrombin response. When coupled to a heterologous core promoter, a region spanning the 3' SRE cluster contained information for thrombin response, whereas a region spanning the 5' SRE cluster had no such effect. A point mutation of the most proximal SRE (SRE-1), but not of the proximal Ets motif or upstream SREs, abrogated the response to thrombin. In electrophoretic mobility shift assays, nuclear extracts from thrombin-treated cells displayed increased binding of total and phosphorylated serum response factor (SRF) to SRE-1. Thrombin-mediated induction of Egr-1 was blocked by inhibitors of MEK1/2, but not by inhibitors of protein kinase C, phosphatidylinositol 3-kinase, or p38 mitogen-activated protein kinase (MAPK). Taken together, these data suggest that thrombin induces Egr-1 expression in endothelial cells by a MAPK-dependent mechanism that involves an interaction between SRF and SRE-1.

Activated Galphaq family members induce Rho GTPase activation and Rho-dependent actin filament assembly

Rho GTPase is required for actin filament assembly and serum response element (SRE)-dependent gene transcription. Certain G protein-coupled receptors (GPCRs) induce Rho-dependent responses, but the intermediary signaling steps are poorly understood. The heterotrimeric Galpha12 family can induce Rho-dependent responses. In contrast, there are conflicting reports on the role of the Galphaq family in Rho signaling. We report that expression of activated Galphaq members, or activation of endogenous Galphaq via GPCR stimulation, induces SRE reporter activation via Rho, and increased GTP-Rho levels. Moreover, microinjection of activated Galphaq in fibroblasts induces actin stress fiber formation via Rho. Galphaq functionally cooperates with Lbc Rho guanine nucleotide exchange factor. Overall, these findings indicate that Galphaq family signals are sufficient to induce Rho-dependent cellular responses.

Serum response factor activation by muscarinic receptors via RhoA. Novel pathway specific to M1 subtype involving calmodulin, calcineurin, and Pyk2

The muscarinic cholinergic receptor (mAChR) subtypes share high sequence similarity except in their third intracellular loop and COOH terminus, domains thought to be involved in signal transduction. Subtypes M1, M3, and M5 couple mainly through Galpha(q/11), and M2 and M4 couple mainly through Galpha(i/o). Whether subtypes within each of these two groups differ in their signaling pathways remains to be resolved. This study focused on nuclear signaling pathways leading to activation of the transcription factor, serum response factor (SRF). Genes encoding M1, M2, and M3 were co-expressed in Jurkat T lymphocytes with a reporter gene driven by a mutant serum response element, SRE.L, which responds to SRF activation. We show that only M1 mAChR activated SRF through a pathway involving the small GTPase RhoA, with no response observed for M2 and M3. Transfection of GTPase-deficient Galpha subunits (GalphaQL; constitutively active form) demonstrated that SRF was activated by Galpha(13)QL but only marginally by Galpha(q)QL and Galpha(12)QL in Jurkat cells. Yet transfection of regulator of G protein-signaling protein, RGS2 and RGS4, which inhibit Galpha(q/11) activity, indicated that Galpha(q/11) and Ca(2+) mobilization were required for SRF activation by M1. Calmodulin inhibitors suppressed the M1 and the Galpha(13)QL pathways, acting both upstream and downstream of RhoA. However, calcineurin inhibitors and the tyrosine kinase inhibitor genistein selectively suppressed SRF activation by M1, but not by Galpha(13)QL, indicating the presence of separate pathways. The calmodulin-dependent tyrosine kinase Pyk2 was also activated by M1 but not M3, and Pyk2 appears also to play a role in M1-SRF activation, as judged by experiments with two dominant-negative Pyk2 mutants. These results reveal a novel calmodulin-dependent RhoA-SRF signaling pathway unique to the M1 mAChR subtype.

Involvement of Rho and p38 MAPK in endothelin-1-induced expression of PGHS-2 mRNA in osteoblast-like cells

Prostaglandins (PGs) play an important role in bone remodeling because eicosanoids are local mediators of bone metabolism, which can induce physiological and pathological responses of bone tissue. Biosynthesis of PGs is catalyzed by constitutively expressed PG endoperoxide G/H synthase (PGHS) 1 and by the inducible isoform PGHS-2. In MC3T3-E1 osteoblast-like cells, expression of PGHS-2 was shown by mechanical forces, cytokines, growth factors, and hormones. Recently, endothelin (ET) 1-stimulated PGHS-2 mRNA expression was described, leading to a burst in prostaglandin E2 (PGE2) production. In this study, we investigated ET-1-induced signal transduction pathway(s) involved in the PGHS-2 mRNA production. Time course of PGHS-2 mRNA expression reaching the maximum within 45 minutes is in good agreement with the concept of an immediate early gene product. Inhibition of phospholipase C (PLC), phospholipase D (PLD), phosphatidylinositol-3 kinase (PI-3-kinase), and protein kinase C (PKC) had no influence on PGHS-2 synthesis. Using specific blockers of tyrosine kinases indicated involvement of p38 MAPK but not p42/44 MAPK. By preloading cells with exoenzyme C3, we were able to show requirement of the Rho family of G proteins for p38 MAPK phosphorylation and PGHS-2 mRNA synthesis, whereas pertussis toxin (PTX) and cholera toxin (CTX) had no remarkable effect.

Calcium-sensing receptor activation of rho involves filamin and rho-guanine nucleotide exchange factor

We investigated the role of Galphaq, filamin, Rho, the RhoGEF Lbc, and the C terminus of calcium-sensing receptor (CasR) in CasR signaling. We found that Ca(2+), Mg(2+), or the calcimimetic R isomer of N-(3-[2-chlorophenyl]propyl)-(R)-alpha-methyl-3-methoxybenzylamine (NPS-R568) stimulated serum response element (SRE) activity human embryonic kidney 293 cells transfected with CasR and an SRE-luciferase reporter construct. Coexpression of either the dominant negative Galphaq(305-359) minigene, regulators of G protein signaling (RGS)2 or RGS4, inhibited CasR-stimulated SRE activity, consistent with CasR activation of Galphaq. The cytoskeletal associated Rho protein is involved CasR activation of SRE, as evidenced by CasR-mediated increase in membrane-associated Rho A and by the ability of Clostridium botulinum C3 (C3) exoenzyme to inhibit both CasR and GalphaqQL-stimulated SRE activity. Overexpression of the RhoGEF Lbc, lacking either the Dbl-homology or Pleckstrin homology domain, as well as the filamin peptide (1530-1875) inhibited CasR-mediated activation of SRE. A carboxyl-terminal CasR minigene, CasR(906-980), encoding a filamin binding region, also blocked CasR- and GalphaqQL-stimulated SRE activity. Potential interactions between CasR, RhoGEF Lbc, Rho A, Galphaq, and filamin were demonstrated by reciprocal coimmunoprecipitation studies. Our results suggest that the C terminus of CasR may interact with filamin to create a cytoskeletal scaffold necessary for the spatial organization of Galphaq, RhoGEF Lbc, and Rho signaling pathways upstream of SRE activation.

Characterization of G proteins involved in activation of nonselective cation channels by endothelin(B) receptor

1: We recently demonstrated that endothelin-1 (ET-1) activates two types of Ca(2+)-permeable nonselective cation channels (NSCC-1 and NSCC-2) in Chinese hamster ovary cells expressing endothelin(B) receptors (CHO-ET(B)R) that couple with G(q) and G(i). The purpose of the present study was to identify the G proteins involved in the activation of these Ca(2+) channels by ET-1. For this purpose, we constructed CHO cells expressing an unpalmitoylated (Cys(402)Cys(403) Cys(405)-->Ser(402)Ser(403)Ser(405)) ET(B)R (CHO-SerET(B)R) and ET(B)R truncated at the cytoplasmic tail downstream of Cys(403) (CHO-ET(B)RDelta403). 2: Based on the data obtained from actin stress fibre formation, CHO-ET(B)R couple with G(13). Therefore, CHO-ET(B)R couple with G(q), G(i) and G(13). CHO-SerET(B)R and CHO-ET(B)RDelta403 couple with G(13) and G(q), respectively. 3: ET-1 activated NSCC-1 in CHO-ET(B)R preincubated with phospholipase C (PLC) inhibitor, U73122, and in CHO-SerET(B)R. On the other hand, ET-1 failed to activate Ca(2+) channels in CHO-ET(B)RDelta403. Microinjection of dominant negative mutants of G(13) (G(13)G225A) abolished activation of NSCC-1 and NSCC-2 in CHO-ET(B)R and that of NSCC-1 in CHO-SerET(B)R. 4: Y-27632, a specific Rho-associated kinase (ROCK) inhibitor, did not affect the ET-1-induced transient and sustained increase in [Ca(2+)](i) in CHO-ET(B)R. 5: These results indicate that (1) the cytoplasmic tail downstream of the palmitoylation sites of ET(B)R, but not the palmitoylation site itself, is essential for coupling with G(13), (2) the activation mechanism of each Ca(2+) channel by ET-1 is different in CHO-ET(B)R. NSCC-1 activation depends on G(13)-dependent cascade, and NSCC-2 activation depends on both G(q)/PLC- and G(13)-dependent cascades. Moreover, ROCK-dependent cascade is not involved in the activation of these channels.

Potent activation of RhoA by Galpha q and Gq-coupled receptors

Heterotrimeric G proteins of the G(i), G(s), and G(q) family control a wide array of physiological functions primarily by regulating the activity of key intracellular second messenger-generating systems. alpha subunits of the G(12) family, Galpha(12) and Galpha(13), however, can promote cellular responses that are independent of conventional second messengers but that result from the activation of small GTP-binding proteins of the Rho family and their downstream targets. These findings led to the identification of a novel family of guanine-nucleotide exchange factors (GEFs) that provides a direct link between Galpha(12/13) and Rho stimulation. Recent observations suggest that many cellular responses elicited by Galpha(q) and its coupled receptors also require the functional activity of Rho. However, available evidence suggests that Galpha(q) may act on pathways downstream from Rho rather than by promoting Rho activation. These seemingly conflicting observations and the recent development of sensitive assays to assess the in vivo levels of active Rho prompted us to ask whether Galpha(q) and its coupled receptors can stimulate endogenous Rho. Here we show that the expression of activated forms of Galpha(q) and the stimulation of G(q)-coupled receptors or chimeric Galpha(q) molecules that respond to G(i)-linked receptors can promote a robust activation of endogenous Rho in HEK-293T cells. Interestingly, this response was not prevented by molecules interfering with the ability of Galpha(13) to stimulate its linked RhoGEFs, together suggesting the existence of a novel molecular mechanism by which Galpha(q) and the large family of G(q)-coupled receptors can regulate the activity of Rho and its downstream signaling pathways.

Effective information transfer from the alpha 1b-adrenoceptor to Galpha 11 requires both beta/gamma interactions and an aromatic group four amino acids from the C terminus of the G protein

Co-expression of the alpha(1b)-adrenoreceptor and Galpha(11) in cells derived from a Galpha(q)/Galpha(11) knock-out mouse allows agonist-mediated elevation of intracellular Ca(2+) levels that is transduced by beta/gamma released from the G protein alpha subunit. Mutation of Tyr(356) of Galpha(11) to Phe, within a receptor contact domain, had little effect on function but this was reduced greatly by alteration to Ser and virtually eliminated by conversion to Asp. This pattern was replicated following incorporation of each form of Galpha(11) into fusion proteins with the alpha(1b)-adrenoreceptor. Following a [(35)S]guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) binding assay, immunoprecipitation of the wild type alpha(1b)-adrenoreceptor-Galpha(11) fusion protein indicated that the agonist phenylephrine stimulated guanine nucleotide exchange on Galpha(11) more than 30-fold. Information transfer by agonist was controlled in residue 356 Galpha(11) mutants with rank order Tyr > Phe > Trp > Ile > Ala = Gln = Arg > Ser > Asp, although these alterations did not alter the binding affinity of either phenylephrine or an antagonist ligand. Mutation of a beta/gamma contact interface in the alpha(1b)-adrenoreceptor-Tyr(356) Galpha(11) fusion protein did not alter ligand binding affinity but did reduce greatly beta/gamma binding and phenylephrine stimulation of [(35)S]GTPgammaS binding. It also prevented agonist elevation of intracellular Ca(2+) levels, as did a mutation in Galpha(11) that prevents G protein subunit dissociation. These results indicate that a bulky aromatic group is required four amino acids from the C terminus of Galpha(11) to maximize information transfer from an agonist-occupied receptor and disprove the hypothesis that tyrosine phosphorylation of this residue is required for G protein activation (Umemori, H., Inoue, T., Kume, S., Sekiyama, N., Nagao, M., Itoh, H., Nakanishi, S., Mikoshiba, K., and Yamamoto, T. (1997) Science 276, 1878-1881). This is distinct from Galpha(i1), where hydrophobicity of the amino acid is the key determinant at this location. They also further demonstrate a key role for the beta/gamma complex in enhancing receptor to G protein alpha subunit information transfer.

Interaction of G alpha(12) with G alpha(13) and G alpha(q) signaling pathways

The G(12) subfamily of heterotrimeric G-proteins consists of two members, G(12) and G(13). Gene-targeting studies have revealed a role for G(13) in blood vessel development. Mice lacking the alpha subunit of G(13) die around embryonic day 10 as the result of an angiogenic defect. On the other hand, the physiological role of G(12) is still unclear. To address this issue, we generated G alpha(12)-deficient mice. In contrast to the G alpha(13)-deficient mice, G alpha(12)-deficient mice are viable, fertile, and do not show apparent abnormalities. However, G alpha(12) does not seem to be entirely redundant, because in the offspring generated from G alpha(12)+/- G alpha(13)+/- intercrosses, at least one intact G alpha(12) allele is required for the survival of animals with only one G alpha(13) allele. In addition, G alpha(12) and G alpha(13) showed a difference in mediating cell migratory response to lysophosphatidic acid in embryonic fibroblast cells. Furthermore, mice lacking both G alpha(12) and G alpha(q) die in utero at about embryonic day 13. These data indicate that the G alpha(12)-mediated signaling pathway functionally interacts not only with the G alpha(13)- but also with the G alpha(q/11)-mediated signaling systems.

Regulation of the gonadotropin-releasing hormone receptor (GnRHR) by RGS proteins: role of the GnRHR carboxyl-terminus

The cytoplasmic carboxyl-terminus of G-protein coupled receptors (GPCRs), absent in the mammalian gonadotropin-releasing hormone receptor (GnRHR), plays an important role in receptor expression, desensitization, internalization and efficiency of coupling to G proteins. Regulators of G protein signaling (RGS) likewise are involved in regulating GPCR-G protein mediated responses and can regulate transcription of other genes. In this study, we evaluate differential expression, ligand binding and effector coupling of the rat GnRHR (rGnRHR) and a chimera of rGnRHR with the pre-mammalian carboxyl domain (rGnRHR-C-tail). Membrane expression of the chimeric receptor and G(q)alpha and G(s)alpha-mediated signaling was increased 2- and 1.5-fold, respectively by RGS10, while RGS3 did not interfere with rGnRHR and rGnRHR-C-tail cell surface expression in spite of negatively regulating GnRH-stimulated G(q)alpha-mediated signaling by both receptors. The rGnRHR and rGnRHR-C-tail showed similar internalization rates in the presence of either RGS protein, indicating that the modification of rGnRHR expression and regulation in the presence of a carboxyl-terminus by RGS10 was not caused by alteration of the internalization rate. The observations in this study implicate the carboxyl domain of the receptor as a site of interaction for RGS10, but not RGS3. This is the first evidence of an altered cell surface expression and regulation of the GnRHR bearing a carboxyl-terminus by RGS proteins.

5-Hydroxytryptamine 4(a) receptor is coupled to the Galpha subunit of heterotrimeric G13 protein

Serotonin (5-hydroxytryptamine (5-HT)) is an important neurotransmitter that regulates multiple events in the central nervous system. Many of the 5-HT functions are mediated via G protein-coupled receptors that are coupled to multiple heterotrimeric G proteins, including G(s), G(i), and G(q) subfamilies (Martin, G. R., Eglen, R. M., Hamblin, M. W., Hoyer, D., and Yocca, F. (1998) Trends Pharmacol. Sci. 19, 2-4). Here we show for the first time that the 5-hydroxytryptamine 4(a) receptor (5-HT(4(a))) is coupled not only to heterotrimeric G(s) but also to G(13) protein, as assessed both by biochemical and functional assays. Using reconstitution of 5-HT(4(a)) receptor with different G proteins in Spodoptera frugiperda (Sf.9) cells, we have proved that agonist stimulation of receptor-induced guanosine 5'-(3-O-thio)triphosphate binding to Galpha(13) protein. We then determined that expression of 5-HT(4(a)) receptor in mammalian cells induced constitutive- as well as agonist-promoted activation of a transcription factor, serum response element, through the activation of Galpha(13) and RhoA. Finally, we have determined that expression of 5-HT(4(a)) receptor in neuroblastoma x glioma NIE-115 cells cause RhoA-dependent neurite retraction and cell rounding under basal conditions and after agonist stimulation. These data suggest that by activating 5-HT(4(a)) receptor-G(13) pathway, serotonin plays a prominent role in regulating neuronal architecture in addition to its classical role in neurotransmission.

Dopamine receptor-coupling defect in hypertension

Dopamine synthesized in non-neural tissues, eg, renal proximal tubule, functions in an autocrine or paracrine manner. The effects of dopamine are transduced by two classes of receptors (D1- and D2-like) that belong to the superfamily of G protein-coupled receptors. In genetic hypertension, the D1 receptor, a member of the D1-like receptor family, is uncoupled from its G protein complex, resulting in a decreased ability to regulate renal sodium transport. The impaired D1 receptor/G protein coupling in renal proximal tubules in genetic hypertension is secondary to abnormal phosphorylation and desensitization of the D1 receptor caused by activating single nucleotide polymorphisms of a G protein-coupled receptor kinase, GRK type 4.

Leukemia-associated Rho guanine nucleotide exchange factor promotes G alpha q-coupled activation of RhoA

Leukemia-associated Rho guanine-nucleotide exchange factor (LARG) belongs to the subfamily of Dbl homology RhoGEF proteins (including p115 RhoGEF and PDZ-RhoGEF) that possess amino-terminal regulator of G protein signaling (RGS) boxes also found within GTPase-accelerating proteins (GAPs) for heterotrimeric G protein alpha subunits. p115 RhoGEF stimulates the intrinsic GTP hydrolysis activity of G alpha 12/13 subunits and acts as an effector for G13-coupled receptors by linking receptor activation to RhoA activation. The presence of RGS box and Dbl homology domains within LARG suggests this protein may also function as a GAP toward specific G alpha subunits and couple G alpha activation to RhoA-mediating signaling pathways. Unlike the RGS box of p115 RhoGEF, the RGS box of LARG interacts not only with G alpha 12 and G alpha 13 but also with G alpha q. In cellular coimmunoprecipitation studies, the LARG RGS box formed stable complexes with the transition state mimetic forms of G alpha q, G alpha 12, and G alpha 13. Expression of the LARG RGS box diminished the transforming activity of oncogenic G protein-coupled receptors (Mas, G2A, and m1-muscarinic cholinergic) coupled to G alpha q and G alpha 13. Activated G alpha q, as well as G alpha 12 and G alpha 13, cooperated with LARG and caused synergistic activation of RhoA, suggesting that all three G alpha subunits stimulate LARG-mediated activation of RhoA. Our findings suggest that the RhoA exchange factor LARG, unlike the related p115 RhoGEF and PDZ-RhoGEF proteins, can serve as an effector for Gq-coupled receptors, mediating their functional linkage to RhoA-dependent signaling pathways.

Modulation of ANP-C receptor signaling by endothelin-1 in A-10 smooth muscle cells

We have previously shown that pretreatment of A-10 smooth muscle cells (SMC) with angiotensin II (Ang II) attenuated atrial natriuretic peptide (ANP) receptor-C (ANP-C)-mediated inhibition of adenylyl cyclase without altering (125)I-ANP binding. In the present studies, we have investigated the modulation of ANP-C receptor signaling by endothelin-1 (ET-1). Pretreatment of A-10 SMC with ET-1 for 24 h attenuated the expression of ANP-C receptor by about 60% as determined by immunoblotting which was reflected in attenuation of ANP-C-receptor-mediated inhibition of adenylyl cyclase. C-ANP(4-23) [des(Gln(18),Ser(19),Gln(20),Leu(21),Gly(22))ANP(4-23)-NH(2)], a ring-deleted peptide of ANP that interacts specifically with ANP-C receptor, inhibited adenylyl cyclase activity in a concentration-dependent manner with an apparent K(i) of about 1 nM in control cells. The maximal inhibition observed was about 30% which was almost completely attenuated in ET-1-treated cells. In addition, Ang II- and oxotremorine-mediated inhibitions of adenylyl cyclase were also attenuated by ET-1 treatment; however, the expression of Gialpha-2 and Gialpha-3 proteins and not of Gsalpha and Gbeta proteins was augmented by such treatment. The increased expression of Gialpha-2 and Gialpha-3 proteins by ET-1 treatment was inhibited by actinomycin D treatment (RNA synthesis inhibitor). On the other hand, the Gsalpha-mediated effects of some agonists on adenylyl cyclase activity were significantly decreased by ET-1 treatment. These results suggest that ET-1-induced downregulation of ANP-C receptor and not the overexpression of Gi proteins may be responsible for the attenuation of C-ANP(4-23)-mediated inhibition of adenylyl cyclase activity. From these studies it may be suggested that the downregulation of ANP-C receptors by increased levels of endothelin in vivo may be one of the possible mechanisms for the pathophysiology of hypertension.

Molecular mechanism for endothelin-1-induced stress-fiber formation: analysis of G proteins using a mutant endothelin(A) receptor

The purposes of the present study were to clarify the significance of the palmitoylation site and the cytoplasmic tail of the endothelin(A) receptor (ET(A)R) in coupling with G proteins and to determine the subtypes of G protein that are involved in actin stress-fiber formation in Chinese hamster ovary cells that stably express ET(A)R (CHO-ET(A)R). For these purposes, we constructed CHO cells stably expressing an unpalmitoylated (Cys(383)Cys(385-388)-->Ser(383)Ser(385-388)) ET(A)R (CHOSerET(A)R) and a series of truncated ET(A)Rs that lacked the cytoplasmic tail downstream of either of the five cysteine residues (Cys(383)Cys(385-388)). All truncated ET(A)Rs but not SerET(A)R failed to stimulate adenylyl cyclase. With the truncated ET(A)Rs holding Cys(385), ET-1 stimulated formation of inositol phosphates, but such stimulation failed with truncated ET(A)Rs lacking Cys(385). With wild-type ET(A)Rs, ET-1 induced actin stress-fiber formation, which was inhibited by (R)-(+)-trans-N-(4-pyridyl)-4-(1-aminoethyl)-cyclohexanecarboxamide (Y-27632), a Rho-associated coiled-coil-forming protein kinase (ROCK) inhibitor. The formation was unaffected by 1-(6-[[17beta-3-methoxyestra-1,3.5(10)-trien-17-yl] amino]hexyl)-1Hpyrrole-2,5-dione (U73122), a phospholipase C (PLC) inhibitor, or dominant negative mutants of G(12) (G(12)G228A) or G(13) (G(13)G225A), whereas it was inhibited by U73122 in combination with G(12)G228A but not G(13)G225A. Dibutyryl cAMP alone did not induce stress-fiber formation. With unpalmitoylated or truncated ET(A)Rs, the formation was sensitive to G(12)G228A or U73122, respectively. These results indicate that 1) Cys(385) of ET(A)R is critical for coupling with G(q), 2) the cytoplasmic tail downstream of the palmitoylation sites of ET(A)R is essential for coupling with G(s) and G(12), and 3) the signal for ET-1-induced stress-fiber formation is transmitted through the G(q)/PLC- and G(12)-dependent pathway to the Rho/ROCK system.

Sphingosine 1-phosphate activates nuclear factor-kappa B through Edg receptors. Activation through Edg-3 and Edg-5, but not Edg-1, in human embryonic kidney 293 cells

Sphingosine 1-phosphate (S1P) exerts a variety of actions as a second messenger or as an agonist that binds to one or more members of the Edg family of G protein-coupled receptors. By using human embryonic kidney 293 cells, we show that S1P activates nuclear factor-kappa B (NF-kappa B) in a receptor-dependent fashion. Edg-3 and Edg-5, which are coupled to G(i), G(q), and G(13), affect activation of NF-kappa B, whereas Edg-1, which is coupled to G(i) alone, does not. We find that the activation of NF-kappa B requires protein kinase C and Ca(2+), probably downstream of G(q), but that the activation of Rho alone by S1P, whether through G(q) or G(13), does not translate into the activation of NF-kappa B. G beta gamma has little effect of its own but potentiates the activation of NF-kappa B achieved through other G proteins. We conclude that the activation of NF-kappa B by S1P is a receptor-mediated process that relies primarily on the activation of a phospholipase C by G(q) and secondarily on effector regulation through other G proteins.