Lipid modifications of G protein subunits

Reciprocal regulation of Gs alpha by palmitate and the beta gamma subunit

Hormonal activation of Gs, the stimulatory regulator of adenylyl cyclase, promotes dissociation of alpha s from G beta gamma, accelerates removal of covalently attached palmitate from the G alpha subunit, and triggers release of a fraction of alpha s from the plasma membrane into the cytosol. To elucidate relations among these three events, we assessed biochemical effects in vitro of attached palmitate on recombinant alpha s prepared from Sf9 cells. In comparison to the unpalmitoylated protein (obtained from cytosol of Sf9 cells, treated with a palmitoyl esterase, or expressed as a mutant protein lacking the site for palmitoylation), palmitoylated alpha s (from Sf9 membranes, 50% palmitoylated) was more hydrophobic, as indicated by partitioning into TX-114, and bound beta gamma with 5-fold higher affinity. beta gamma protected GDP-bound alpha s, but not alpha s-GTP[gamma S], from depalmitoylation by a recombinant esterase. We conclude that beta gamma binding and palmitoylation reciprocally potentiate each other in promoting membrane attachment of alpha s and that dissociation of alpha s.GTP from beta gamma is likely to mediate receptor-induced alpha s depalmitoylation and translocation of the protein to cytosol in intact cells.

Partial constitutive activation of pheromone responses by a palmitoylation-site mutant of a G protein alpha subunit in yeast

G protein alpha subunits are often myristoylated and/or palmitoylated near their amino terminus. The G protein alpha subunit in the yeast Saccharomyces cerevisiae (GPA1 gene product, Gpa1p) is known to be myristoylated, and this modification is essential for G protein activity in vivo. Here we examined whether Gpa1p is palmitoylated and determined the functional consequences of this modification. [3H]-Palmitic acid was incorporated into Gpa1p in cells expressing myc-tagged Gpa1p or Gpa1p-Gst. The label was released upon hydroxylamine treatment. Substitution of the conserved Cys 3 for Ser blocked incorporation of the label (Gpa1pC3S). Palmitoylation was also blocked by a mutation that prevents myristoylation (Gly2Ala), whereas the palmitoylation-site mutation had no effect on myristoylation of Gpa1p. Gpa1pC3S complemented the gpa1 delta mutation in vivo and formed a complex with G beta gamma that was able to undergo nucleotide exchange in vitro. However, basal and pheromone-induced FUSl-lacZ transcription were 2-5-fold higher in the C3S mutant. Pheromone-induced growth arrest was also enhanced by the mutation, but recovery from arrest was not affected. Like wild-type Gpa1p, the C3S mutant was predominantly membrane-associated. Upon Triton X-114 partitioning or high pH treatment, no difference in the membrane-binding properties of the wild-type Gpa1p and the C3S mutant was detected. By sucrose density gradient centrifugation of membranes, however, most of the mutant protein was mislocalized to a non-plasma membrane compartment, whereas G beta gamma localization was unaltered. Taken together, our data suggest that Gpa1p is palmitoylated via a thioester bond at Cys 3 and that palmitoylation plays a role in modulating Gpa1p signaling and membrane localization.

Autoacylation of G protein alpha subunits

The palmitoylation or S-acylation of at least some G protein alpha subunits is a dynamic process that is regulated in vivo by the activation of associated receptors. Highly purified, myristoylated Gialpha1 and other G protein alpha subunits react spontaneously with palmitoyl-CoA in vitro to form thioesterified proteins. This reaction requires native Gialpha1 and occurs exclusively at Cys3, the same residue that is palmitoylated in vivo. The reaction proceeds to completion, and its rate is roughly equal to the rate of loss of palmitate observed in pulse-chase experiments in vivo. The rate of autoacylation is significantly enhanced by the G protein betagamma subunit complex. Autoacylation may play a role in the dynamic thioesterification of some cellular proteins.

RGS family members: GTPase-activating proteins for heterotrimeric G-protein alpha-subunits

Signaling pathways using heterotrimeric guanine-nucleotide-binding-proteins (G proteins) trigger physiological responses elicited by hormones, neurotransmitters and sensory stimuli. GTP binding activates G proteins by dissociating G alpha from G beta gamma subunits, and GTP hydrolysis by G alpha subunits deactivates G proteins by allowing heterotrimers to reform. However, deactivation of G-protein signalling pathways in vivo can occur 10- to 100-fold faster than the rate of GTP hydrolysis of G alpha subunits in vitro, suggesting that GTPase-activating proteins (GAPs) deactivate G alpha subunits. Here we report that RGS (for regulator of G-protein signalling) proteins are GAPs for G alpha subunits. RGS1, RGS4 and GAIP (for G alpha-interacting protein) bind specifically and tightly to G alphai and G alpha0 in cell membranes treated with GDP and AlF4(-), and are GAPs for G alphai, G alpha0 and transducin alpha-subunits, but not for G alphas. Thus, these RGS proteins are likely to regulate a subset of the G-protein signalling pathways in mammalian cells. Our results provide insight into the mechanisms that govern the duration and specificity of physiological responses elicited by G-protein-mediated signalling pathways.

Regulation of cellular signalling by fatty acid acylation and prenylation of signal transduction proteins

Covalent modification by fatty acylation and prenylation occurs on a wide variety of cellular signalling proteins. The enzymes that catalyze attachment of these lipophilic moieties to proteins have recently been identified and characterized. Each lipophilic group confers unique properties to the modified protein, resulting in alterations in protein/protein interactions, membrane binding and targeting, and intracellular signalling. The biochemistry and cell biology of protein myristoylation, farnesylation and geranylgeranylation is reviewed here, with emphasis on the Src family of tyrosine kinases, Ras proteins and G protein coupled signalling systems.

The role of prenylation in G-protein assembly and function

Heterotrimeric guanine nucleotide-binding regulatory proteins (G-proteins) are vital components of numerous signal transduction pathways, including sensory and hormonal response systems. G-proteins transduce signals from heptahelical transmembrane receptors to downstream effectors. The localization of a G-protein to the plasma membrane, as well as its interaction with the appropriate receptor and effector, are essential for its function. In addition, the association of a G-protein's subunits to form its trimer is required for interaction with its receptor. The G-protein gamma subunits (G gamma) are subject to a set of carboxyl-terminal processing events that include prenylation of a cysteine, proteolysis, and methylation. Recent advances which elucidate the contributions that the post-translational modifications of the G gamma subunit have on the assembly, membrane association, and function of the G-protein trimer reveal that these modifications are required for important protein-protein, in addition to membrane-protein, interactions.

Regulation of membrane and subunit interactions by N-myristoylation of a G protein alpha subunit in yeast

Initiation of the mating process in yeast Saccharomyces cerevisiae requires the action of secreted pheromones and G protein-coupled receptors. As in other eukaryotes, the yeast G protein alpha subunit undergoes N-myristoylation (GPA1 gene product, Gpa1p). This modification appears to be essential for function, since a myristoylation site mutation exhibits the null phenotype in vivo (gpa1(G2A)). Here we examine how myristoylation affects Gpa1p activity in vitro. We show that the G2A mutant of Gpa1p, when fused with glutathione S-transferase, can still form a complex with the G protein betagamma subunits. The complex is stabilized by GDP and is dissociated upon treatment with guanosine 5'-O-(thiotriphosphate). In addition, there is no apparent difference in the relative binding affinity of Gbetagamma for mutant and wild-type Gpa1p. Using sucrose density gradient fractionation of cell membranes, Gpa1p associates normally with the plasma membrane whereas Gpa1pG2A is mislocalized to a microsomal membrane fraction. A portion of Gbetagamma is also mislocalized in these cells, as it is in a gpa1Delta strain. In contrast, wild-type Gpa1p reaches the plasma membrane in cells that do not express Gbetagamma or cell surface receptors. These findings indicate that mislocalization of Gpa1pG2A is not caused by a redistribution of Gbetagamma, nor is it the result of any difference in Gbetagamma binding affinity. These data suggest that myristoylation is required for specific targeting of Gpa1p to the plasma membrane, where it is needed to interact with the receptor and to regulate the release of Gbetagamma.

Role of myristoylation in membrane attachment and function of G alpha i-3 on Golgi membranes

Heterotrimeric G protein alpha-subunits localized on the cytoplasmic face of Golgi membranes are involved in regulating vesicle trafficking and protein secretion. We investigated the role of myristoylation in attachment of the G alpha i-3 subunit to Golgi membranes. G alpha i-3 was epitope-tagged by insertion of a FLAG sequence at an NH2-terminal site predicted to interfere with myristoylation, and the resulting NT-alpha i-3 construct was stably transfected and expressed in polarized epithelial LLC-PK1 cells. Metabolic labeling confirmed that the translation product of NT-alpha i-3 was not myristoylated. In contrast to endogenous G alpha 1-3, which is tightly bound to Golgi membranes, the unmyristoylated FLAG-tagged NT-alpha i-3 did not attach to membranes; it was localized by immunofluorescence in the cytoplasm of LLC-PK1 cells and was detected only in the cytosol fraction of cell homogenates. Pertussis toxin-dependent ADP-ribosylation was used to test the ability of NT-alpha i-3 to interact with membrane-bound beta gamma-subunits. In both in vitro and in vivo assays, cytosolic NT-alpha i-3 alone was not ADP-ribosylated, although in the presence of membranes it could interact with G beta gamma-subunits to form heterotrimers. The expression of NT-alpha i-3 in LLC-PK1 cells altered the rate of basolateral secretion of sulfated proteoglycans, consistent with the demonstrated function of endogenous G alpha i-3. These data are consistent with a model in which G alpha i-3 utilizes NH2-terminal myristoylation to bind to Golgi membranes and to maximize its interaction with G beta gamma-subunits. Furthermore, our results show that stable attachment of G alpha i-3 to Golgi membranes is not required for it to participate as a regulatory element in vesicle trafficking in the secretory pathway.

A novel Ca2+-binding protein, p22, is required for constitutive membrane traffic

We have identified a novel protein, p22, required for "constitutive" exocytic membrane traffic. p22 belongs to the EF-hand superfamily of Ca2+-binding proteins and shows extensive similarity to the regulatory subunit of protein phosphatase 2B, calcineurin B. p22 is a cytosolic N-myristoylated protein that undergoes conformational changes upon binding of Ca2+. Antibodies against a p22 peptide block the targeting/fusion of transcytotic vesicles with the apical plasma membrane, but recombinant wild-type p22 overcomes that inhibition. Nonmyristoylated p22, or p22 incapable of undergoing Ca2+-induced conformational changes, cannot reverse the antibody-mediated inhibition. The data suggest that p22 may act by transducing cellular Ca2+ signals to downstream effectors. p22 is ubiquitously expressed, and we propose that its function is required for membrane trafficking events common to many cells.

Inhibition of an inwardly rectifying K+ channel by G-protein alpha-subunits

Cholinergic muscarinic, serotonergic, opioid and several other G-protein-coupled neurotransmitter receptors activate inwardly rectifying K+ channels of the GIRK family, slowing the heartbeat and decreasing the excitability of neuronal cells. Inhibitory modulation of GIRKs by G-protein-coupled receptors may have important implications in cardiac and brain physiology. Previously G alpha and G beta gamma subunits of heterotrimeric G proteins have both been implicated in channel opening, but recent studies attribute this role primarily to the G beta gamma dimer that activates GIRKs in a membrane-delimited fashion, probably by direct binding to the channel protein. We report here that free GTP gamma S-activated G alpha i 1, but not G alpha i 2 or G alpha i 3, potently inhibits G beta 1 gamma 2-induced GIRK activity in excised membrane patches of Xenopus oocytes expressing GIRK1. High-affinity but partial inhibition is produced by G alpha s-GTP gamma S. G alpha i 1-GTP gamma S also inhibits G beta 1 gamma 2-activated GIRK in atrial myocytes. Antagonistic interactions between G alpha and G beta gamma may be among the mechanisms determining specificity of G protein coupling to GIRKs.

G-protein palmitoyltransferase activity is enriched in plasma membranes

Heterotrimeric G proteins are covalently modified by lipids. Myristoylation of G-protein alpha subunits and prenylation of gamma subunits are stable modifications. In contrast, palmitoylation of alpha subunits is dynamic and thus has the potential for regulating protein function. Indeed, receptor activation of Gs increases palmitate turnover on the alpha subunit, presumably by stimulating deacylation. The enzymes that catalyze reversible palmitoylation of G-protein alpha subunits have not been characterized. Here we report the identification of a palmitoyl-CoA:protein S-palmitoyltransferase activity that acylates G-protein alpha subunits in vitro. Palmitoyltransferase activity is membrane-associated and requires detergent for solubilization. The preferred G-protein substrate for the enzyme activity is the alpha subunit in the context of the heterotrimer. Both myristoylated and nonmyristoylated G-protein alpha subunits are recognized as substrates. The palmitoyltransferase activity demonstrates a modest preference for palmitoyl-CoA over other fatty acyl-CoA substrates. Palmitoyltransferase activity is high in plasma membrane and present at low or undetectable levels in Golgi, endoplasmic reticulum, and mitochondria of rat liver. The subcellular localization of this enzyme activity is consistent with a role for regulated cycles of acylation and deacylation accompanying activation of G-protein signal transduction pathways.

Thioesterification of platelet proteins with saturated and polyunsaturated fatty acids

We have demonstrated that more than 20 platelet proteins can be acylated with fatty acids via thioester linkages. These include the glycoprotein IX beta chain of glycoprotein Ib, components of the von Willebrand factor receptor on the platelet surface, P-selectin, and alpha subunits of Gz, Gq, and Gi. Our studies have shown that platelet proteins can be posttranslationally acylated in thioester linkages not only with palmitate but with myristate and also with the eicosanoid precursor fatty acids arachidonate and eicosapentaenoate. Thioesterification of platelet proteins with fatty acids other than palmitate may have significant functional consequences for reversible binding of proteins to membranes.

Partial G protein activation by fluorescent guanine nucleotide analogs. Evidence for a triphosphate-bound but inactive state

N-methyl-3'-O-anthranoyl (MANT) guanine nucleotide analogs are useful environmentally sensitive fluorescent probes for studying G protein mechanisms. Previously, we showed that MANT fluorescence intensity when bound to G protein was related to the degree of G protein activation where MANT-guanosine-5'-O-(3-thiotriphosphate) (mGTP gammaS) had the highest fluorescence followed by mGTP and mGDP, respectively (Remmers, A. E., Posner, R., and Neubig, R. R. (1994) J. Biol. Chem. 269, 13771-13778). To directly examine G protein conformations with nucleotide triphosphates bound, we synthesized several nonhydrolyzable MANT-labeled guanine nucleotides. The relative maximal fluorescence levels observed upon binding to recombinant myristoylated Goalpha (myrGoalpha) and myrGialpha1 were: mGTPgammaS > MANT-5'-guanylyl-imidodiphosphate > MANT-guanylyl-(beta,gamma-methylene)-diphosphonate > MANT-guanosine 5'-O-2-(thio)diphosphate. Using protection against tryptic digestion as a measure of the activated conformation, the ability of the MANT guanine nucleotides to maximally activate myrGo alpha correlated with maximal fluorescence. Biphasic dissociation kinetics were observed for all of the MANT guanine nucleotides. The data were consistent with the following model, [formula: see text] where G protein activation (G*-GXP) is determined by a conformational equilibrium between two triphosphate bound states as well as by the balance between binding and hydrolysis of the nucleotide triphosphate. Compared with myrGialpha1, maximal mGTP fluorescence was only 2-fold higher for the myrGialpha1 Q204L mutant, a mutant with greatly reduced GTPase activity, and only 24% that of mGTPgammaS, indicating that partial activation by mGTP was not just due to hydrolysis of mGTP. These results extend our previous conclusion that GTP analogs do not fully activate G protein.

Biosynthesis of the unsaturated 14-carbon fatty acids found on the N termini of photoreceptor-specific proteins

In the vertebrate retina, a number of proteins involved in signal transduction are known to be N-terminal acylated with the unusual 14 carbon fatty acids 14:1n-9 and 14:2n-6. We have explored possible pathways for producing these fatty acids in the frog retina by incubation in vitro with candidate precursor fatty acids bearing radiolabels, including [3H]14:0, [3H]18:1n-9, [3H]18:2n-6, and [3H]18:3n-3. Rod outer segments were prepared from the radiolabeled retinas for analysis of protein-linked fatty acids, and total lipids were extracted from the remaining retinal pellet. Following saponification of extracted lipids, fatty acid phenacyl esters were prepared and analyzed by high pressure liquid chromatography (HPLC) with detection by continuous scintillation counting. Transducin, whose alpha-subunit (Gt alpha) is known to bear N-terminal acyl chains, was extracted from the rod outer segments and subjected to SDS-polyacrylamide gel electrophoresis and fluorography to detect radiolabeled proteins. Gt alpha was also subjected to methanolysis, and the resulting fatty acyl methyl esters were analyzed by HPLC. The identities of HPLC peaks coinciding with unsaturated species of both phenacyl esters and methyl esters were confirmed by reanalyzing them after catalytic hydrogenation. The results showed that 14:1n-9 can be derived in the retina from 18:1n-9 and 14:2n-6 from 18:2n-6, most likely by two rounds of beta-oxidation, but that neither is produced in detectable amounts from 14:0. Retroconversion of unsaturated 18 carbon fatty acids to the corresponding 14 carbon species showed specificity, in that 18:3n-3 was not converted to 14 carbon fatty acids in detectable amounts. Myristic acid (14:0), 14:1n-9, and 14:2n-6 were all incorporated into Gt alpha. A much less efficient incorporation of 18:1n-9 into Gt alpha was also observed, but no radiolabeling of Gt alpha was observed in retinas incubated with 18:3n-3. Thus, retroconversion by limited beta-oxidation of longer chain unsaturated fatty acids appears to be the most likely metabolic source of the unusual fatty acids found on the N termini of signal transducing proteins in the retina.

The 2.0 A crystal structure of a heterotrimeric G protein

The structure of a heterotrimeric G protein reveals the mechanism of the nucleotide-dependent engagement of the alpha and beta gamma subunits that regulates their interaction with receptor and effector molecules. The interaction involves two distinct interfaces and dramatically alters the conformation of the alpha but not of the beta gamma subunits. The location of the known sites for post-translational modification and receptor coupling suggest a plausible orientation with respect to the membrane surface and an activated heptahelical receptor.

Functional importance of the amino terminus of Gq alpha

Gq alpha is palmitoylated at residues Cys9 and Cys10. Removal of palmitate from purified Gq alpha with palmitoylthioesterase in vitro failed to alter interactions of Gq alpha with phospholipase C-beta 1, the G protein beta gamma subunit complex, or m1 muscarinic cholinergic receptors. Mutants C9A, C10A, C9A/C10A, C9S/C10S, and truncated Gq alpha (removal of residues 1-6) were synthesized in Sf9 cells and purified. Loss of both Cys residues or truncation prevented palmitoylation of Gq alpha. However, truncated Gq alpha and the single Cys mutants activated phospholipase C-beta 1 normally, while the double Cys mutants were poor activators. Loss of both Cys residues impaired but did not abolish interaction of Gq alpha with m1 receptors. These Cys residues are thus important regardless of their state of palmitoylation. When expressed in HEK-293 or Sf9 cells, all of the proteins studied associated entirely or predominantly with membranes, although a minor fraction of nonpalmitoylated Gq alpha proteins accumulated in the cytosol of HEK-293 cells. When subjected to TX-114 phase partitioning, a significant fraction of all of the proteins, including those with no palmitate, was found in the detergent-rich phase. Removal of residues 1-34 of Gq alpha caused a loss of surface hydrophobicity as evidenced by complete partitioning into the aqueous phase. The Cys residues at the amino terminus of Gq alpha are thus important for its interactions with effector and receptor, and the amino terminus conveys a hydrophobic character to the protein distinct from that contributed by palmitate.

Effect of thyroid deficiency on Go alpha-subunit isoforms in developing rat cerebral cortex

Postnatal development of G alpha o isoforms in rat cerebral cortex was studied by SDS-PAGE and immunoblotting. When rat cerebral cortical membranes were resolved on separating gels containing 9% acrylamide and 8 M urea, three electrophoretically distinct G alpha o-immunoreactive proteins were evident. Comparison of their electrophoretic mobilities and partial tryptic digest pattern with recombinant G alpha o1 or G alpha o1-specific antibody revealed that the slowest and intermediate-migrating bands represent unmodified and fatty acylated forms of G alpha o1 protein, respectively. The fastest-migrating band corresponds to G alpha o2. While the fatty acylated form of G alpha o1 is the predominant species, its appearance paralleled that observed for G alpha o2 in developing rat cortex. Perinatal hypothyroidism induced by methimazole treatment did not significantly alter the appearance of cerebral cortical G alpha o1 and G alpha o2 between days 1 and 22 postpartum. Our findings support the earlier idea that heterogeneity of G alpha o proteins in mammalian brain is likely the result of different co- or post-translational processings of each splice variant of G alpha o. While the appearance of G alpha o isoforms is developmentally regulated, they likely do not play an obligatory role in neonatal brain development. Alternatively, the expression of G alpha o isoforms in developing rat cortex may be controlled by an intrinsic signal(s) that is independent of the thyroid status.

Phosphorylation of Gz alpha by protein kinase C blocks interaction with the beta gamma complex

Gz alpha is a G protein alpha subunit with biochemical properties that distinguish it from other members of the G protein alpha subunit family. One such property is its ability to be stoichiometrically phosphorylated by protein kinase C (PKC), both in vitro and in intact cells. The site of this phosphorylation has been mapped to a region near the N terminus of Gz alpha, but no functional significance of the modification has been established. To investigate this question, we have developed a baculovirus/Sf9 cell expression system to produce Gz alpha. The protein purified from Sf9 cells is functional as assessed by its ability both to bind guanine nucleotide in a Mg(2+)-sensitive fashion and to serve as a substrate for phosphorylation by PKC. Furthermore, addition of the G protein beta gamma complex purified from bovine brain inhibits phosphorylation of Gz alpha in a dose-dependent manner. Conversely, phosphorylation of Gz alpha inhibits its ability to interact with beta gamma subunits. These results establish a functional consequence for PKC-catalyzed phosphorylation of Gz alpha and suggest a mechanism for regulation of signaling through Gz by preventing reassociation of its subunits.

Acylation of adenylyl cyclase catalyst is important for enzymic activity

Incubation of human thrombocytes in the presence of [3H]palmitic acid leads to incorporation of this fatty acid into the alpha subunit of Gs as described [Linder et al., Proc. Natl. Acad. Sci. USA 90 (1993) 3675-3679; Degtyarev et al., Biochemistry 32 (1993) 8057-8061] but also into the catalyst of adenylyl cyclase which has not been recognized before. Treatment of labeled membranes with hydroxylamine released the label from both components. Label incorporated into the catalyst could be identified as [3H]palmitate. At the same time chemical deacylation caused partial loss of adenylyl cyclase activity.

The myristoyl moiety of myristoylated alanine-rich C kinase substrate (MARCKS) and MARCKS-related protein is embedded in the membrane

Members of the myristoylated alanine-rich protein kinase C substrate (MARCKS) family are involved in several cellular processes such as secretion, motility, mitosis, and transformation. In addition to their ability to bind calmodulin and to cross-link actin filaments, reversible binding to the plasma membrane is most certainly an important component of the so far unknown functions of these proteins. We have therefore investigated the binding of murine MARCKS-related protein (MRP) to lipid vesicles. The partition coefficient, Kp, describing the affinity of myristoylated MRP for acidic lipid vesicles (20% phosphatidylserine, 80% phosphatidylcholine) is 5-8 x 10(3) M-1, which is only 2-4 times larger than the partition coefficient for the unmyristoylated protein. Interestingly, the affinity of MRP for acidic lipid membranes is 20-30-fold smaller than reported for murine MARCKS (Kim, J., Shishido, T., Jiang, X., Aderem, A. A., and McLaughlin, S. (1994) J. Biol. Chem. 269, 28214-28219). Since only a marginal binding could be observed with neutral phosphatidylcholine vesicles, we propose that electrostatic interactions are the major determinant of the binding of MRP to pure lipid membranes. Although the myristoyl moiety does not contribute drastically to the binding of MRP to vesicles, photolabeling experiments with a photoreactive phospholipid probe show that the fatty acid is embedded in the bilayer. The same membrane topology was found for bovine brain MARCKS. Since the relatively low affinity of MRP for vesicles is insufficient to account for a stable anchoring of the protein to cellular membranes, insertion of the myristoyl moiety into the bilayer might favor the interaction of MRP with additional factors required for the binding of the protein to intracellular membranes.

Hydrophobicity and subunit interactions of rod outer segment proteins investigated using Triton X-114 phase partitioning

Triton X-114 phase partitioning, a procedure used for purifying integral membrane proteins, was used to study protein components of the mammalian visual transduction cascade. An integral membrane protein, rhodopsin, and two isoprenylated protein complexes, cyclic GMP phosphodiesterase and Gt beta gamma, partitioned into the detergent-rich phase. Arrestin, a soluble protein, accumulated in the aqueous phase. Gt alpha distributed about equally between phases whether GDP (Gt alpha.GDP) or GTP (Gt alpha.GTP) was bound. Gt beta gamma increased recovery of Gt alpha.GDP but not Gt alpha.GTP in the detergent phase. Trypsin-treated Gt alpha, which lacks the fatty acylated amino-terminal 2-kDa region, accumulated to a greater extent in the aqueous phase than did intact Gt alpha. Trypsinized cGMP phosphodiesterase, which lacks the isoprenyl group, partitioned into the aqueous phase. A carboxyl-terminal truncated mutant (Val-331 stop) of Gt alpha accumulated more in the aqueous phase then did recombinant full-length Gt alpha, supporting the role of the carboxyl terminus in increasing its hydrophobicity. N-Myristoylated recombinant Go alpha was more hydrophobic than recombinant Go alpha without myristate. ADP-ribosylation of Gt alpha catalyzed by NAD:arginine ADP-ribosyltransferase, but not by pertussis toxin, increased hydrophilicity. Triton X-114 phase partitioning can thus semiquantify the hydrophobic nature of proteins and protein domains. It may aid in evaluating changes associated with post-translational protein modification and protein-protein interactions in a defined system.

The dynamic role of palmitoylation in signal transduction

Guanine nucleotide binding protein (G protein)-linked receptors, the alpha-subunits of heterotrimeric G proteins and members of the Src family of nonreceptor tyrosine kinases are among many polypeptides that are posttranslationally modified by the addition of palmitate, a long-chain fatty acid. Attachment of palmitate to these proteins is dynamic and may be regulated by their activation. The presence of palmitate appears to play a key role in the membrane localization of either the entire polypeptide or parts of it, and may regulate the interactions of these polypeptides with other proteins.

Fatty acylation of alpha z. Effects of palmitoylation and myristoylation on alpha z signaling

As the first step in an investigation of roles played by fatty acylation of G protein alpha chains in membrane targeting and signal transmission, we inserted monoclonal antibody epitopes, hemagglutinin (HA) or Glu-Glu (EE), at two internal sites in three alpha subunits. At site I, only HA-tagged alpha q and alpha z functioned normally. alpha s, alpha q, and alpha z subunits tagged at site II with the EE epitope showed normal expression, membrane localization, and signaling activity. Using epitope-tagged alpha z, we investigated effects of mutations in sites for fatty acylation. Mutational substitution of Ala for Gly2 (G2A) prevented incorporation of myristate and decreased but did not abolish incorporation of palmitate. Substitution of Ala for Cys3 (C3A) prevented incorporation of palmitate but had no effect on incorporation of myristate. Substitution of Ala for both Gly2 and Cys3 (G2AC3A) prevented incorporation of both myristate and palmitate. All three mutations substantially disrupted association of alpha z with the particulate fraction. Gz-mediated inhibition of adenylyl cyclase, triggered by activation of the D2-dopamine receptor, was, respectively, abolished (G2AC3A), impaired (G2A), and enhanced (C3A). Constitutive inhibition of adenylyl cyclase by alpha z was unchanged (G2AC3A), strongly diminished (G2A), or strongly enhanced (C3A). A nonacylated, mutationally activated alpha z mutant inhibited adenylyl cyclase, although less potently than normally acylated, mutationally activated alpha z. From these findings we conclude: (a) fatty acylations of alpha z increase its association with membranes; (b) myristoylation is not required for palmitoylation of alpha z or for its productive interactions with adenylyl cyclase; (c) palmitoylation is not required for, but may instead inhibit, signaling by alpha z.

Protein lipidation in cell signaling

The ability of cells to communicate with and respond to their external environment is critical for their continued existence. A universal feature of this communication is that the external signal must in some way penetrate the lipid bilayer surrounding the cell. In most cases of such signal acquisition, the signaling entity itself does not directly enter the cell but rather transmits its information to specific proteins present on the surface of the cell membrane. These proteins then communicate with additional proteins associated with the intracellular face of the membrane. Membrane localization and function of many of these proteins are dependent on their covalent modification by specific lipids, and it is the processes involved that form the focus of this article.

Nobel Lecture. G proteins and regulation of adenylyl cyclase

The function and structures of G proteins and their role in the regulation of adenylyl cyclase is reviewed.

Involvement of N-myristoylation in monoclonal antibody recognition sites on chimeric G protein alpha subunits

Monoclonal antibody, LAS-2, directed against the alpha subunit of transducin (Gt alpha), inhibited Gt beta gamma-dependent, pertussis toxin-catalyzed ADP ribosylation of Gt alpha and was specific for Gt alpha. Immunoblotting studies on proteolytic fragments of Gt alpha were consistent with an amino-terminal epitope. To define the antibody recognition site, recombinant Gt alpha was synthesized in Escherichia coli cotransfected with or without yeast N-myristoyl-transferase. Amino-terminal fatty acylation of Gt alpha, verified by use of radiolabeled fatty acid, was required for immunoreactivity. LAS-2 did not react with a chimeric protein consisting of residues 1-9 of Gt alpha and the remainder Go alpha, regardless of its myristoylation. Immunoreactivity was observed when amino acids 1-17 of Gt alpha were present in a Go alpha chimera and the protein was amino-terminally myristoylated; there was no reactivity without myristoylation. It appears that the LAS-2 epitope requires both Gt alpha-specific sequence in amino acids 10-17 and a fatty acyl group in proximity to these residues. These results are consistent with the hypothesis that the myristoyl group is essential for protein structure; conceivably it "folds back" on and stabilizes the amino-terminal structure of Gt alpha as opposed to protruding from an amino-terminal alpha-helix and serving as an amino-terminal membrane anchor.

Modulation of serotonin-controlled behaviors by Go in Caenorhabditis elegans

Seven transmembrane receptors and their associated heterotrimeric guanine nucleotide-binding proteins (G proteins) have been proposed to play a key role in modulating the activities of neurons and muscles. The physiological function of the Caenorhabditis elegans G protein Go has been genetically characterized. Mutations in the goa-1 gene, which encodes an alpha subunit of Go (G alpha o), cause behavioral defects similar to those observed in mutants that lack the neurotransmitter serotonin (5-HT), and goa-1 mutants are partially resistant to exogenous 5-HT. Mutant animals that lack G alpha o and transgenic animals that overexpress G alpha o [goa-1(xs) animals] have reciprocal defects in locomotion, feeding, and egg laying behaviors. In normal animals, all of these behaviors are regulated by 5-HT. These results demonstrate that the level of Go activity is a critical determinant of several C. elegans behaviors and suggest that Go mediates many of the behavioral effects of 5-HT.

Lipid modifications of trimeric G proteins

G protein alpha subunits and beta gamma dimers are covalently modified by lipids. The emerging picture is one in which attached lipids provide more than just a nonspecific "glue" for sticking G proteins to membranes. We are only beginning to understand how different lipid modifications of different G protein subunits affect specific protein-protein interactions and localization to specific cellular sites. In addition, regulation of these modifications, particularly palmitoylation, can provide new ways to regulate signals transmitted by G proteins.

Mutational analysis of Saccharomyces cerevisiae ARF1

Wild type and eight point mutants of Saccharomyces cerevisiae ARF1 were expressed in yeast and bacteria to determine the roles of specific residues in in vivo and in vitro activities. Mutations at either Gly2 or Asp26 resulted in recessive loss of function. It was concluded that N-myristoylation is required for Arf action in cells but not for either nucleotide exchange or cofactor activities in vitro. Asp26 (homologous to Gly12 of p21ras) was essential for the binding of the activating nucleotide, guanosine 5'-3-O-(thio)triphosphate. This is in marked contrast to results obtained after mutagenesis of the homologous residue in p21ras or Gs alpha, and suggests a fundamental difference in the guanine nucleotide binding site of Arf with respect to these other GTP-binding proteins. Two dominant alleles were also identified, one activating dominant ([Q71L]Arf1) and the other ([N126I]) a negative dominant. A conditional allele, [W66R]Arf1, was characterized and shown to have approximately 300-fold lower specific activity in an in vitro Arf assay. Two high-copy suppressors of this conditional phenotype were cloned and sequenced. One of these suppressors, SFS4, was found to be identical to PBS2/HOG4, recently shown to encode a microtubule-associated protein kinase kinase in yeast.

Signal transduction by G proteins: 1994 edition

Findings from the last two years in signal transduction research, including the elucidation of the crystal structure of alpha1, the uncovering of multiple roles for lipidation, the mimicry of receptor action with peptides, and both the in vitro reconstitution of inhibition of adenylyl cyclase and the in cell reconstitution of receptor-G protein coupling in transient and stable expression studies, are integrated into a "current" view of the receptor --> G protein --> effector pathway. The question is raised whether receptor or betagamma is the nucleotide exchange factor, and the central participation of Mg2+ in G protein activation and the change in affinity of the G protein for Mg2+ during receptor-stimulated activation are stressed.

Roles of lipid modifications of transducin subunits in their GDP-dependent association and membrane binding

Transducin is an unusually soluble and dissociable heterotrimeric G-protein, although its T alpha and T beta gamma subunits are N-acylated and farnesylated, respectively. These lipid modifications have been suggested to contribute directly to the GDP-dependent T alpha-T beta gamma association, through specific lipid recognition sites on both protein subunits. We studied the dependence of subunit association on their bound lipids and on the presence of different lipidic environments. Association of native N-acylated (nT alpha) or acyl-free recombinant (rT alpha) T alpha with farnesylated and carboxymethylated (fcT beta gamma), farnesylated (fT beta gamma), or farnesyl-free (dfT beta gamma) T beta gamma was analyzed by gradient centrifugation and gel filtration in the presence of detergent or phospholipid-cholate micelles and by cosedimentation with phospholipid vesicles. Without detergent, nT alpha GDP and fcT beta gamma associate only weakly in solution. The loss of T alpha acyl or T beta gamma farnesyl residues induces total dissociation. With detergent or lipids, isolated fcT beta gamma binds tightly to micelles or vesicles, while dfT beta gamma does not; nT alpha GDP binds weakly, while deacylated rT alpha GDP does not bind at all; and nT alpha GDP binds cooperatively with fcT beta gamma, while rT alpha GDP does not. Thus (i) the T alpha acyl chain binds weakly, whereas the T beta gamma farnesyl chain binds strongly to membrane lipids; (ii) there is no evidence for binding of the T alpha acyl chain to a polypeptide site in T beta gamma, nor for binding of the T beta gamma farnesyl chain to a polypeptidic site in T alpha, but the T alpha acyl chain seems to bind cooperatively with the T beta gamma farnesyl chain in the membrane lipids; (iii) the insertion of the two protein-attached lipids into the same membrane could contribute to the association of both subunits by favoring collision coupling of the properly oriented protein moieties on the membrane surface.

GTP-dependent binding of Gi, G(o) and Gs to the gamma-subunit of the effector of Gt

The gamma-subunit of the cGMP-phosphodiesterase (PDE gamma) of retinal rods forms a tight complex with the activated alpha-subunit of transducin (Gt alpha GTP gamma S). We observe that while PDE gamma is not the physiological effector of other G alpha subtypes, it can still detectably interact with them. This interaction is strong with Gi1 alpha and Gi3 alpha (Kd approximately 10 nM) and weaker with Go alpha and Gs alpha (Kd approximately 1 microM). For all these G alpha subtypes, similar intrinsic fluorescence changes are observed upon PDE gamma binding. Moreover, similar relative decreases in affinity are obtained when the GDP forms of Gi1 alpha, Gi3 alpha or Gt alpha are used in lieu of the GTP forms. This points to a conserved GTP-dependent effector-interaction domain.

Lipid modifications of G proteins

Covalent attachment of lipids is a near-universal mechanism through which eukaryotic cells direct and, in some cases, control membrane localization of G proteins. Studies conducted over the past year have substantially advanced our understanding of both the molecular mechanisms and the functional consequences of these modifications. Of particular note are the processes of palmitoylation of the alpha-subunits of heterotrimeric G proteins, and prenylation of members of the Ras superfamily of monomeric G proteins, where recent findings point to unexpected roles for lipid modifications in signaling through these proteins.

Recombinant G-protein beta gamma-subunits activate the muscarinic-gated atrial potassium channel

Acetylcholine activates inwardly rectifying potassium channels (IK.ACh) in the heart through muscarinic receptor binding and activation of pertussis-toxin-sensitive G proteins. Experiments showing that only the beta gamma-subunit (G beta gamma) activates IK.ACh (ref. 4) were challenged by reports that only the activated alpha-subunit (G alpha) was effective. Here we examine IK.ACh regulation using purified brain and recombinant G-protein subunits. Six recombinant G beta gamma-subunits activated IK.ACh with apparent half-maximal activation concentrations of 3-30 nM. Activation of IK.ACh by recombinant G alpha-GTP gamma S was observed, but this was probably due to release of GTP gamma S from the protein. Importantly, IK.ACh activity elicited by GTP gamma S was inhibited by purified brain and recombinant G alpha-GDP, suggesting that native G beta gamma plays a major role in this pathway. We conclude that G beta gamma is a primary regulator of IK.ACh activity.

Activation of the retinal cGMP-specific phosphodiesterase by the GDP-loaded alpha-subunit of transducin

The interaction of the GDP-bound form of the alpha-subunit of transducin (T alpha GDP) with the cGMP-specific phosphodiesterase, the effector enzyme in the visual system, has been studied. T alpha GDP is demonstrated to be able to activate the phosphodiesterase: (a) the basal activity in suspensions of dark-adapted retinal rod outer segments, examined in the absence of GTP, was found to be inhibited by binding of transducin to activated rhodopsin (Rh*) and by the complex of the beta- and gamma-subunits of transducin (T beta gamma); (b) purified T alpha GDP is able to activate phosphodiesterase in the presence of membranes; (c) no activation is obtained either with holotransducin (T alpha GDP T beta gamma) or with T alpha GDP in the presence of excess T beta gamma to prevent dissociation of TGDP. The maximal level of phosphodiesterase activation reached with T alpha GDP (about 1500 mol cGMP/mol phosphodiesterase-1.s-1) is similar to that obtained through the 'classical' activation by T alpha GTP whereas the apparent affinity of T alpha GDP for phosphodiesterase (Kd about 50 microM) is much lower than that of T alpha GTP. Our data suggest that GTP hydrolysis itself does not inactivate T alpha. The role of T beta gamma to sequester T alpha is therefore of critical importance for phosphodiesterase inactivation. Our results support observations on the regulation of adenylyl cyclase by G-proteins, which suggested the ability of the free alpha-subunits loaded with GDP to activate their effectors.

The alpha-subunits of G-proteins G12 and G13 are palmitoylated, but not amidically myristoylated

The alpha-subunits of the G-proteins G12 and G13 were expressed with a baculovirus system in insect cells and analysed for acylation. Both proteins incorporated tritiated palmitic and to a lesser extent also tritiated myristic acid. Radiolabel from both fatty acids was sensitive to treatment with neutral hydroxylamine. This result supports a thioester-type fatty acid bond and argues against amidical N-myristoylation. Fatty acid analysis after labeling with [3H]palmitic acid showed that palmitate represents the predominant fatty acid linked to G alpha 12 and G alpha 13. Separation of cells into cytosolic and membranous fractions revealed that palmitoylated alpha-subunits of G12 were exclusively membrane-bound, whereas [35S]methionine-labeled proteins were detected in soluble and particulate fractions. Inhibition of protein synthesis with cycloheximide did not block palmitoylation of the alpha-subunits, which indicates that palmitoylation occurs independently of protein synthesis.