A novel human nucleolar protein, Nop132, binds to the G proteins, RRAG A/C/D

RRAG A (Rag A)/Gtr1p is a member of the Ras-like small G protein family that genetically interacts with RCC1, a guanine nucleotide exchange factor for RanGTPase. RRAG A/Gtr1p forms a heterodimer with other G proteins, RRAG C and RRAG D/Gtr2p, in a nucleotide-independent manner. To further elucidate the function of RRAG A/Gtr1p, we isolated a protein that interacts with RRAG A. This protein is a novel nucleolar protein, Nop132. Nop132 is associated with the GTP form, but not the GDP form, of RRAG A, suggesting that RRAG A might regulate Nop132 function. Nop132 is also associated with RRAG C and RRAG D. The Nop132 amino acid sequence is similar to the Saccharomyces cerevisiae nucleolar Nop8p, which is associated with Gtr1p, Gtr2p, and Nip7p. Nop132 also interacts with human Nip7 and is colocalized with RRAG A, RRAG C, and Nip7. RNA interference knockdown of Nop132 inhibited cell growth of HeLa cells.     

Saccharomyces cerevisiae putative G protein, Gtr1p, which forms complexes with itself and a novel protein designated as Gtr2p, negatively regulates the Ran/Gsp1p G protein cycle through Gtr2p.

Prp20p and Rna1p are GDP/GTP exchanging and GTPase-activating factors of Gsp1p, respectively, and their mutations, prp20-1 and rna1-1, can both be suppressed by Saccharomyces cerevisiae gtr1-11. We found that gtr1-11 caused a single amino acid substitution in Gtr1p, forming S20L, which is a putative GDP-bound mutant protein, while Gtr1p has been reported to bind to GTP alone. Consistently, gtr1-S20N, another putative GDP-bound mutant, suppressed both prp20-1 and rna1-1. On the other hand, gtr1-Q65L, a putative GTP-bound mutant, was inhibitory to prp20-1 and rna1-1. Thus, the role that Gtr1p plays in vivo appears to depend upon the nucleotide bound to it. Our data suggested that the GTP-bound Gtr1p, but not the GDP-bound Gtr1p, interacts with itself through its C-terminal tail. S. cerevisiae possesses a novel gene, GTR2, which is homologous to GTR1. Gtr2p interacts with itself in the presence of Gtr1p. The disruption of GTR2 suppressed prp20-1 and abolished the inhibitory effect of gtr1-Q65L on prp20-1. This finding, taken together with the fact that Gtr1p-S20L is a putative, inactive GDP-bound mutant, implies that Gtr1p negatively regulates the Ran/Gsp1p GTPase cycle through Gtr2p.     

Crystal Structure of the Gtr1pGTP-Gtr2pGDP Protein Complex Reveals Large Structural Rearrangements Triggered by GTP-to-GDP Conversion

The heterodimeric Rag GTPases consisting of RagA (or RagB) and RagC (or RagD) are the key regulator activating the target of rapamycin complex 1 (TORC1) in response to the level of amino acids. The heterodimer between GTP-loaded RagA/B and GDP-loaded RagC/D is the most active form that binds Raptor and leads to the activation of TORC1. Here, we present the crystal structure of Gtr1p(GTP)-Gtr2p(GDP), the active yeast Rag GTPase heterodimer. The structure reveals that GTP-to-GDP conversion on Gtr2p results in a large conformational transition of this subunit, including a large scale rearrangement of a long segment whose corresponding region in RagA is involved in binding to Raptor. In addition, the two GTPase domains of the heterodimer are brought to contact with each other, but without causing any conformational change of the Gtr1p subunit. These features explain how the nucleotide-bound statuses of the two GTPases subunits switch the Raptor binding affinity on and off.     

Purification and characterization from bovine brain cytosol of proteins that regulate the GDP/GTP exchange reaction of smg p21s, ras p21-like GTP-binding proteins

Novel regulatory proteins for smg p21A and -B, ras p21-like GTP-binding proteins (G proteins) having the same putative effector domain as ras p21s, were purified to near homogeneity from bovine brain cytosol and characterized. These regulatory proteins, designated as GDP dissociation stimulator (GDS) 1 and -2, stimulated the dissociation of both [3H]GDP and [35S] guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) from smg p21s to the same extent. smg p21 GDS1 and -2 also stimulated the binding of [35S]GTP gamma S to the GDP-bound form of smg p21s but not that to the guanine nucleotide-free form. These actions of smg p21 GDS1 and -2 were specific for smg p21s and inactive for other ras p21/ras p21-like G proteins including c-Ha-ras p21, rhoB p20, and smg p25A. Neither smg p21 GDS1 nor -2 stimulated the GTPase activity of smg p21s and by itself showed [35S]GTP gamma S-binding or GTPase activity. smg p21 GDS1 and -2 showed very similar physical and kinetic properties and were indistinguishable by peptide map analysis. The Mr values of smg p21 GDS1 and -2 were estimated to be about 53,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and from the S values, indicating that smg p21 GDS1 and -2 are composed of a single polypeptide without a subunit structure. smg p21 GDS1 and -2 were distinguishable from GTPase activating proteins (GAPs) for the ras and rho proteins, and smg p21B, and GDP dissociation inhibitors for smg p25A and the rho proteins previously identified in bovine brain cytosol. These results indicate that bovine brain contains regulatory proteins for smg p21s that stimulate the dissociation of GDP from and thereby the subsequent binding of GTP to smg p21s in addition to smg p21 GAP. It is likely that the conversion from the GDP-bound inactive form of smg p21s to the GTP-bound active form is regulated by smg p21 GDS and that its reverse reaction is regulated by smg p21 GAP.     

Saccharomyces cerevisiae GTPase complex: Gtr1p-Gtr2p regulates cell-proliferation through Saccharomyces cerevisiae Ran-binding protein, Yrb2p

A Gtr1p GTPase, the GDP mutant of which suppresses both temperature-sensitive mutants of Saccharomyces cerevisiae RanGEF/Prp20p and RanGAP/Rna1p, was presently found to interact with Yrb2p, the S. cerevisiae homologue of mammalian Ran-binding protein 3. Gtr1p bound the Ran-binding domain of Yrb2p. In contrast, Gtr2p, a partner of Gtr1p, did not bind Yrb2p, although it bound Gtr1p. A triple mutant: yrb2delta gtr1delta gtr2delta was lethal, while a double mutant: gtr1delta gtr2delta survived well, indicating that Yrb2p protected cells from the killing effect of gtr1delta gtr2delta. Recombinant Gtr1p and Gtr2p were purified as a complex from Escherichia coli. The resulting Gtr1p-Gtr2p complex was comprised of an equal amount of Gtr1p and Gtr2p, which inhibited the Rna1p/Yrb2 dependent RanGAP activity. Thus, the Gtr1p-Gtr2p cycle was suggested to regulate the Ran cycle through Yrb2p.     

Rom1p and Rom2p are GDP/GTP exchange proteins (GEPs) for the Rho1p small GTP binding protein in Saccharomyces cerevisiae.

The RHO1 gene encodes a homolog of the mammalian RhoA small GTP binding protein in the yeast Saccharomyces cerevisiae. Rho1p is localized at the growth site and is required for bud formation. Multicopy suppressors of a temperature-sensitive, dominant negative mutant allele of RHO1, RHO1(G22S, D125N), were isolated and named ROM (RHO1 multicopy suppressor). Rom1p and Rom2p were found to contain a DH (Dbl homologous) domain and a PH (pleckstrin homologous) domain, both of which are conserved among the GDP/GTP exchange proteins (GEPs) for the Rho family small GTP binding proteins. Disruption of ROM2 resulted in a temperature-sensitive growth phenotype, whereas disruption of both ROM1 and ROM2 resulted in lethality. The phenotypes of deltarom1deltarom2 cells were similar to those of deltarho1 cells, including growth arrest with a small bud and cell lysis. Moreover, the temperature-sensitive growth phenotype of deltarom2 was suppressed by overexpression of RHO1 or RHO2, but not of CDC42. The glutathione-S-transferase (GST) fusion protein containing the DH domain of Rom2p showed the lipid-modified Rholp-specific GDP/GTP exchange activity which was sensitive to Rho GDP dissociation inhibitor. These results indicate that Rom1p and Rom2p are GEPs that activate Rho1p in S.cerevisiae.     

Both stimulatory and inhibitory GDP/GTP exchange proteins, smg GDS and rho GDI, are active on multiple small GTP-binding proteins.

Six peaks of small GTP-binding proteins (G proteins) were separated by column chromatographies from the cytosol fraction of the differentiated HL-60 cells: two peaks of rho p21, one peak of smg/rap1 p21, two peaks of rac1 p21, and one peak of an unidentified small G protein with a Mr of about 20,000 (20 KG). smg GDS, previously thought to be a stimulatory GDP/GTP exchange protein for smg p21, Ki-ras p21, and rho p21, but not for Ha-ras p21 or smg p25A, was also active on rac1 p21. rho GDI, previously thought to be an inhibitory GDP/GTP exchange protein specific for rho p21, was also active on rac1 p21. These results indicate that both smg GDS and rho GDI are active on multiple small G proteins.     

Binding and hydrolysis of guanine nucleotides by Sec4p, a yeast protein involved in the regulation of vesicular traffic

The 23.5-kDa Sec4 protein is required for vesicular transport between the Golgi apparatus and the plasma membrane in Saccharomyces cerevisiae. In order to analyze its biochemical properties, we have purified the soluble pool of the wild-type protein from an overproducing yeast strain. At 30 degrees C, Sec4p bound [35S] guanosine 5'-O-(thiotriphosphate) (GTP gamma S) with a rate of 0.18 min-1 in a reaction requiring micromolar concentration of free magnesium ions. The protein had high affinity for guanine nucleotides with Kd values for GTP gamma S and GTP of 3.7 nM and 3.5 nM, respectively, and that for GDP of 77 nM. The dissociation of [3H] GDP from Sec4p occurred with a rate of 0.21 min-1 suggesting that the association of GTP gamma S was the result of exchange for prebound GDP. The release of GTP from Sec4p was slow and correlated with a low inherent GTPase activity of 0.0012 min-1. By analogy with other classes of GTP binding proteins, both the nucleotide exchange and hydrolysis activities of Sec4p may be modulated in vivo to facilitate its role in the regulation of intercompartmental membrane traffic.     

Dynamic relocation of the TORC1–Gtr1/2–Ego1/2/3 complex is regulated by Gtr1 and Gtr2

TORC1 regulates cellular growth, metabolism, and autophagy by integrating various signals, including nutrient availability, through the small GTPases RagA/B/C/D in mammals and Gtr1/2 in budding yeast. Rag/Gtr is anchored to the lysosomal/vacuolar membrane by the scaffold protein complex Ragulator/Ego. Here we show that Ego consists of Ego1 and Ego3, and novel subunit Ego2. The ∆ego2 mutant exhibited only partial defects both in Gtr1-dependent TORC1 activation and Gtr1 localization on the vacuole. Ego1/2/3, Gtr1/2, and Tor1/Tco89 were colocalized on the vacuole and associated puncta. When Gtr1 was in its GTP-bound form and TORC1 was active, these proteins were preferentially localized on the vacuolar membrane, whereas when Gtr1 was in its GDP-bound form, they were mostly localized on the puncta. The localization of TORC1 to puncta was further facilitated by direct binding to Gtr2, which is involved in suppression of TORC1 activity. Thus regulation of TORC1 activity through Gtr1/Gtr2 is tightly coupled to the dynamic relocation of these proteins.     

Association of the GTP-binding protein Gtr1p with Rpc19p, a shared subunit of RNA polymerase I and III in yeast Saccharomyces cerevisiae

Yeast Gtr1p and its human homolog RRAG A belong to the Ras-like small G-protein superfamily and genetically interact with RCC1, a guanine nucleotide exchange factor for Ran GTPase. Little is known regarding the function of Gtr1p. We performed yeast two-hybrid screening using Gtr1p as the bait to find interacting proteins. Rpc19p, a shared subunit of RNA polymerases I and III, associated with Gtr1p. The association of Gtr1p with Rpc19p occurred in a GTP-form-specific manner. RRAG A associated with RPA16 (human Rpc19p homolog) in a GTP-form-specific manner, suggesting that the association is conserved during evolution. Ribosomal RNA and tRNA synthesis were reduced in the gtr1Delta strain expressing the GDP form of Gtr1p, but not the GTP form of Gtr1p. Gel-filtration studies revealed an accumulation of the smaller Rpc19p-containing complex, but not of A135, in the gtr1Delta strain. Here, we propose that Gtr1p is involved in RNA polymerase I and III assembly by its association with Rpc19p and could be a mediator that links growth regulatory signals with ribosome biogenesis.     

Role of GDP in formyl-peptide-receptor-induced activation of guanine-nucleotide-binding proteins in membranes of HL 60 cells.

Membranes of myeloid differentiated human leukemia (HL 60) cells contain receptors for the chemotactic peptide, fMet-Leu-Phe (fMet, N-formylmethionine), interacting with pertussis-toxin-sensitive guanine-nucleotide-binding proteins (G proteins). Agonist activation of the receptors increases binding of the GTP analog, guanosine 5'-[gamma-thio]triphosphate (GTP[S]), to membrane G proteins, at 30 degrees C only in the presence of exogenous GDP. In contrast, at 0 degrees C fMet-Leu-Phe stimulated binding of GTP[S] to G proteins maximally without addition of GDP. Under conditions resulting in marked degradation of membrane-bound GDP, control binding of GTP[S] measured at 0 degrees C was significantly increased, whereas the extent of agonist-stimulated binding was reduced. Furthermore, there was a rapid spontaneous release of membrane-bound GDP at 30 degrees C, but not at 0 degrees C. The data suggest that in intact membranes of HL 60 cells G proteins are initially in a GDP-liganded form, which state allows the receptor-induced exchange of bound GDP for GTP[S] at low temperature. In contrast, at or near physiological temperature, bound GDP is rapidly released (and degraded), resulting in unligated G proteins to which GTP[S] will bind independently of agonist-activated receptors.     

Nitrogen Source Activates TOR (Target of Rapamycin) Complex 1 via Glutamine and Independently of Gtr/Rag Proteins

The evolutionary conserved TOR complex 1 (TORC1) activates cell growth in response to nutrients. In yeast, TORC1 responds to the nitrogen source via a poorly understood mechanism. Leucine, and perhaps other amino acids, activates TORC1 via the small GTPases Gtr1 and Gtr2, orthologs of the mammalian Rag GTPases. Here we investigate the activation of TORC1 by the nitrogen source and how this might be related to TORC1 activation by Gtr/Rag. The quality of the nitrogen source, as defined by its ability to promote growth and glutamine accumulation, directly correlates with its ability to activate TORC1 as measured by Sch9 phosphorylation. Preferred nitrogen sources stimulate rapid, sustained Sch9 phosphorylation and glutamine accumulation. Inhibition of glutamine synthesis reduces TORC1 activity and growth. Poor nitrogen sources stimulate rapid but transient Sch9 phosphorylation. A Gtr1 deficiency prevents the transient stimulation of TORC1 but does not affect the sustained TORC1 activity in response to good nitrogen sources. These findings suggest that the nitrogen source must be converted to glutamine, the preferred nitrogen source in yeast, to sustain TORC1 activity. Furthermore, sustained TORC1 activity is independent of Gtr/Rag. Thus, the nitrogen source and Gtr/Rag activate TORC1 via different mechanisms.     

Crystal structure of the Ego1-Ego2-Ego3 complex and its role in promoting Rag GTPase-dependent TORC1 signaling

The target of rapamycin complex 1 (TORC1) integrates various hormonal and nutrient signals to regulate cell growth, proliferation, and differentiation. Amino acid-dependent activation of TORC1 is mediated via the yeast EGO complex (EGOC) consisting of Gtr1, Gtr2, Ego1, and Ego3. Here, we identify the previously uncharacterized Ycr075w-a/Ego2 protein as an additional EGOC component that is required for the integrity and localization of the heterodimeric Gtr1-Gtr2 GTPases, equivalent to mammalian Rag GTPases. We also report the crystal structure of the Ego1-Ego2-Ego3 ternary complex (EGO-TC) at 2.4 Å resolution, in which Ego2 and Ego3 form a heterodimer flanked along one side by Ego1. Structural data also reveal the structural conservation of protein components between the yeast EGO-TC and the human Ragulator, which acts as a GEF for Rag GTPases. Interestingly, however, artificial tethering of Gtr1-Gtr2 to the vacuolar membrane is sufficient to activate TORC1 in response to amino acids even in the absence of the EGO-TC. Our structural and functional data therefore support a model in which the EGO-TC acts as a scaffold for Rag GTPases in TORC1 signaling.     

The Rag GTPase-Ragulator complex attenuates TOR complex 1 signaling in fission yeast

Target of rapamycin complex 1 (TORC1) is an evolutionarily conserved protein kinase complex, whose activation in response to nutrients suppresses autophagy. In mammalian cells, amino-acid stimuli induce lysosomal translocation and activation of MTORC1 through the RRAG GTPase heterodimer, which is tethered to the surface of lysosomes by the Ragulator complex. Our recent study demonstrated that the fission yeast Schizosaccharomyces pombe also has a Ragulator complex that anchors the Gtr1-Gtr2 Rag GTPase heterodimer to the vacuole, a lysosome-like organelle. Unexpectedly, however, neither vacuolar localization nor activation of TORC1 is dependent on the Rag-Ragulator complex, which instead plays a critical role in attenuating TORC1 signaling. Our findings suggest dual functionality of the Rag GTPase in both activation and inactivation of TORC1.     

New insights into the role of conserved, essential residues in the GTP binding/GTP hydrolytic cycle of large G proteins

The GTP hydrolytic (GTPase) reaction terminates signaling by both large (heterotrimeric) and small (Ras-related) GTP-binding proteins (G proteins). Two residues that are necessary for GTPase activity are an arginine (often called the "arginine finger") found either in the Switch I domains of the alpha subunits of large G proteins or contributed by the GTPase-activating proteins of small G proteins, and a glutamine that is highly conserved in the Switch II domains of Galpha subunits and small G proteins. However, questions still exist regarding the mechanism of the GTPase reaction and the exact role played by the Switch II glutamine. Here, we have characterized the GTP binding and GTPase activities of mutants in which the essential arginine or glutamine residue has been changed within the background of a Galpha chimera (designated alpha(T)*), comprised mainly of the alpha subunit of retinal transducin (alpha(T)) and the Switch III region from the alpha subunit of G(i1). As expected, both the alpha(T)*(R174C) and alpha(T)*(Q200L) mutants exhibited severely compromised GTPase activity. Neither mutant was capable of responding to aluminum fluoride when monitoring changes in the fluorescence of Trp-207 in Switch II, although both stimulated effector activity in the absence of rhodopsin and Gbetagamma. Surprisingly, each mutant also showed some capability for being activated by rhodopsin and Gbetagamma to undergo GDP-[(35)S]GTPgammaS exchange. The ability of the mutants to couple to rhodopsin was not consistent with the assumption that they contained only bound GTP, prompting us to examine their nucleotide-bound states following their expression and purification from Escherichia coli. Indeed, both mutants contained bound GDP as well as GTP, with 35-45% of each mutant being isolated as GDP-P(i) complexes. Overall, these findings suggest that the R174C and Q200L mutations reveal Galpha subunit states that occur subsequent to GTP hydrolysis but are still capable of fully stimulating effector activity.     

Partial purification and characterization of GDP dissociation stimulator (GDS) for the rho proteins from bovine brain cytosol

A novel type of regulatory proteins for the rho proteins (rhoA p21 and rhoB p20), ras p21-like small GTP-binding proteins (G proteins), are partially purified from bovine brain cytosol. These regulatory proteins, named rho GDP dissociation stimulator (GDS) 1 and -2, stimulate the dissociation of GDP from rhoA p21 and rhoB p20. rho GDS1 and -2 are inactive for other ras p21/ras p21-like small G proteins including c-Ha-ras p21, smg p21B, and smg p25A. Since we have previously shown that the rate limiting step for the GDP/GTP exchange reaction of the rho proteins is the dissociation of GDP from these proteins, the present results suggest that rho GDS1 and -2 stimulate the GDP/GTP exchange reaction of the rho proteins. rho GDS1 and -2 are distinct from the GAP- and GDI-types of regulatory proteins for the rho proteins previously purified from bovine brain cytosol. rho GAP stimulates the GTPase activity of the rho proteins and rho GDI inhibits the GDP/GTP exchange reaction of the rho proteins. The present results together with these earlier observations indicate that the rho proteins are regulated by at least three different types of regulatory proteins, GDS, GDI, and GAP.     

Membrane interactions of G proteins and other related proteins

Guanine nucleotide-binding proteins, G proteins, propagate incoming messages from receptors to effector proteins. They switch from an inactive to active state by exchanging a GDP molecule for GTP, and they return to the inactive form by hydrolyzing GTP to GDP. Small monomeric G proteins, such as Ras, are involved in controlling cell proliferation, differentiation and apoptosis, and they interact with membranes through isoprenyl moieties, fatty acyl moieties, and electrostatic interactions. This protein-lipid binding facilitates productive encounters of Ras and Raf proteins in defined membrane regions, so that signals can subsequently proceed through MEK and ERK kinases, which constitute the canonical MAP kinase signaling cassette. On the other hand, heterotrimeric G proteins undergo co/post-translational modifications in the alpha (myristic and/or palmitic acid) and the gamma (farnesol or geranylgeraniol) subunits. These modifications not only assist the G protein to localize to the membrane but they also help distribute the heterotrimer (Galphabetagamma) and the subunits generated upon activation (Galpha and Gbetagamma) to appropriate membrane microdomains. These proteins transduce messages from ubiquitous serpentine receptors, which control important functions such as taste, vision, blood pressure, body weight, cell proliferation, mood, etc. Moreover, the exchange of GDP by GTP is triggered by nucleotide exchange factors. Membrane receptors that activate G proteins can be considered as such, but other cytosolic, membranal or amphitropic proteins can accelerate the rate of G protein exchange or even activate this process in the absence of receptor-mediated activation. These and other protein-protein interactions of G proteins with other signaling proteins are regulated by their lipid preferences. Thus, G protein-lipid interactions control the features of messages and cell physiology.     

Identification of guanine nucleotides bound to ras-encoded proteins in growing yeast cells

We have analyzed the guanine nucleotides bound to mammalian ras and yeast RAS proteins overexpressed in [32P]orthophosphate-labeled cultures of exponentially growing Saccharomyces cerevisiae cells. Whereas S. cerevisiae RAS1 and RAS2 proteins were immunoprecipitated bound entirely to GDP, mammalian Harvey ras was isolated with GTP and GDP bound in near-equimolar proportions. In a strain overexpressing a RAS2 variant where the RAS unique C-terminal domain was deleted, both GTP and GDP were detected in a ratio of 3:97. Increased amounts of GTP (16-75% of total guanine nucleotide) were observed bound to all ras proteins containing mutations that inhibit GTP hydrolytic activity. Increasing proportions of GTP bound to the various ras proteins correlated with increasing biological potency to bypass cdc25 lethality in yeast.     

Stimulated D(1) dopamine receptors couple to multiple Galpha proteins in different brain regions

Previous studies have revealed that activation of rat striatal D(1) dopamine receptors stimulates both adenylyl cyclase and phospholipase C via G(s) and G(q), respectively. The differential distribution of these systems in brain supports the existence of distinct receptor systems. The present communication extends the study by examining other brain regions: hippocampus, amygdala, and frontal cortex. In membrane preparations of these brain regions, selective stimulation of D(1) dopamine receptors increases the hydrolysis of phosphatidylinositol/phosphatidylinositol 4,5-biphosphate. In these brain regions, D(1) dopamine receptors couple differentially to multiple Galpha protein subunits. Antisera against Galpha(q) blocks dopamine-stimulated PIP(2) hydrolysis in hippocampal and in striatal membranes. The binding of [(35)S]GTPgammaS or [alpha-(32)P]GTP to Galpha(i) was enhanced in all brain regions. Dopamine also increased the binding of [(35)S]GTPgammaS or [alpha-(32)P]GTP to Galpha(q) in these brain regions: hippocampus = amygdala > frontal cortex. However, dopamine-stimulated binding of [(35)S]GTPgammaS to Galphas only in the frontal cortex and striatum. This differential coupling profile in the brain regions was not related to a differential regional distribution of the Galpha proteins. Dopamine induced increases in GTPgammaS binding to Galpha(s) and Galpha(q) was blocked by the D(1) antagonist SCH23390 but not by D(2) receptor antagonist l-sulpiride, suggesting that D(1) dopamine receptors couple to both Galpha(s) and Galpha(q) proteins. Co-immunoprecipitation of Galpha proteins with receptor-binding sites indicate that in the frontal cortex, D(1) dopamine-binding sites are associated with both Galpha(s) and Galpha(q) and, in hippocampus or amygdala, D(1) dopamine receptors couple solely to Galpha(q). The results indicate that in addition to the D(1)/G(s)/adenylyl cyclase system, brain D(1)-like dopamine receptor sites activate phospholipase C through Galpha(q) protein.     

Biochemical characterization of rab proteins from Bombyx mori

The small GTPases known as Rab proteins are key regulators of membrane trafficking. We used RT-PCR to isolate cDNA clones of insect-specific Rab proteins (BRabN1 and BRabN2) showing low homology with known Rab proteins from other animals, from mRNA of Bombyx mori. These 2 Rabs were produced in Escherichia coli and purified. BRabN1 bound [(3)H]-GDP and [(35)S]-GTPgammaS with dissociation constants of 0.087 x 10(-6) M and 1.02 x 10(-6) M, respectively, whereas those of BRabN2 were 0.546 x 10(-6) M and 1.02 x 10(-6) M, respectively. Binding of [(35)S]-GTPgammaS to BRabN1 and N2 was inhibited by GDP and GTP. The GTP-hydrolysis activities of BRabN1 and N2 were 154 and 35.5 mmol/min/mole, respectively, and bound [(35)S]-GTPgammaS was exchanged efficiently with GTP. BRabN1 also showed ATPase activity and exchange of [(35)S]-GTPgammaS with ATP. Monoclonal antibodies against BRabN1 and N2 did not recognize any other Rab proteins, and Western blotting using the anti-BRabN1 antibody revealed a single band in the testis of B. mori. These results suggest that BRabN1 and N2 of B. mori bind GTP, convert from the GTP-bound state to the GDP-bound state by intrinsic GTP hydrolysis activity, and return to the GTP-bound state with the exchange, and that BRabN1 is specifically expressed in testis. Arch. Insect Biochem. Physiol. 2008. (c) 2008 Wiley-Liss, Inc.