A truncated recombinant alpha subunit of Gi3 with a reduced affinity for beta gamma dimers and altered guanosine 5'-3-O-(thio)triphosphate binding

Disruption of the interaction between mutationally activated Gαq and Gβγ attenuates aberrant signaling

Heterotrimeric G protein stimulation via G protein-coupled receptors promotes downstream proliferative signaling. Mutations can occur in Gα proteins which prevent GTP hydrolysis; this allows the G proteins to signal independently of G protein-coupled receptors and can result in various cancers, such as uveal melanoma (UM). Most UM cases harbor Q209L, Q209P, or R183C mutations in Gα_q/11 proteins, rendering the proteins constitutively active (CA). Although it is generally thought that active, GTP-bound Gα subunits are dissociated from and signal independently of Gβγ, accumulating evidence indicates that some CA Gα mutants, such as Gα_q/11, retain binding to Gβγ, and this interaction is necessary for signaling. Here, we demonstrate that disrupting the interaction between Gβγ and Gα_q is sufficient to inhibit aberrant signaling driven by CA Gα_q. Introduction of the I25A point mutation in the N-terminal α helical domain of CA Gα_q to inhibit Gβγ binding, overexpression of the G protein Gα_o to sequester Gβγ, and siRNA depletion of Gβ subunits inhibited or abolished CA Gα_q signaling to the MAPK and YAP pathways. Moreover, in HEK 293 cells and in UM cell lines, we show that Gα_q-Q209P and Gα_q-R183C are more sensitive to the loss of Gβγ interaction than Gα_q-Q209L. Our study challenges the idea that CA Gα_q/11 signals independently of Gβγ and demonstrates differential sensitivity between the Gα_q-Q209L, Gα_q-Q209P, and Gα_q-R183C mutants.

Structural insights into G protein activation by D1 dopamine receptor

G protein-coupled receptors (GPCRs) comprise the largest family of membrane receptors and are the most important drug targets. An agonist-bound GPCR engages heterotrimeric G proteins and triggers the exchange of guanosine diphosphate (GDP) with guanosine triphosphate (GTP) to promote G protein activation. A complete understanding of molecular mechanisms of G protein activation has been hindered by a lack of structural information of GPCR-G protein complex in nucleotide-bound states. Here, we report the cryo-EM structures of the D1 dopamine receptor and mini-G_s complex in the nucleotide-free and nucleotide-bound states. These structures reveal major conformational changes in Gα such as structural rearrangements of the carboxyl- and amino-terminal α helices that account for the release of GDP and the GTP-dependent dissociation of Gα from Gβγ subunits. As validated by biochemical and cellular signaling studies, our structures shed light into the molecular basis of the entire signaling events of GPCR-mediated G protein activation.

Pancreatic stone protein - sepsis and the riddles of the exocrine pancreas

Pancreatic stone protein (PSP), discovered in the 1970ies, was first associated with stone formation during chronic pancreatitis. Later, the same protein was independently detected in islet preparations and named regenerating protein 1 (REG1). Additional isoforms of PSP, including pancreatitis-associated protein (PAP), belong to the same protein family. Although the names indicate a potential function in stone formation or islet regeneration, involvements in cellular processes were only suggestive and never unequivocally proven. We established an association between PSP levels in patient blood samples and the development of sepsis. In this review, written in connection with receiving the Lifetime Achievement Award of the European Pancreatic Club, the evolution of the sepsis aspect of PSP is described. We conclude that the true functional properties of this fascinating pancreatic protein still remain an enigma.

Specific inhibition of GPCR-independent G protein signaling by a rationally engineered protein

Activation of heterotrimeric G proteins by cytoplasmic nonreceptor proteins is an alternative to the classical mechanism via G protein-coupled receptors (GPCRs). A subset of nonreceptor G protein activators is characterized by a conserved sequence named the Gα-binding and activating (GBA) motif, which confers guanine nucleotide exchange factor (GEF) activity in vitro and promotes G protein-dependent signaling in cells. GBA proteins have important roles in physiology and disease but remain greatly understudied. This is due, in part, to the lack of efficient tools that specifically disrupt GBA motif function in the context of the large multifunctional proteins in which they are embedded. This hindrance to the study of alternative mechanisms of G protein activation contrasts with the wealth of convenient chemical and genetic tools to manipulate GPCR-dependent activation. Here, we describe the rational design and implementation of a genetically encoded protein that specifically inhibits GBA motifs: GBA inhibitor (GBAi). GBAi was engineered by introducing modifications in Gαi that preclude coupling to every known major binding partner [GPCRs, Gβγ, effectors, guanine nucleotide dissociation inhibitors (GDIs), GTPase-activating proteins (GAPs), or the chaperone/GEF Ric-8A], while favoring high-affinity binding to all known GBA motifs. We demonstrate that GBAi does not interfere with canonical GPCR-G protein signaling but blocks GBA-dependent signaling in cancer cells. Furthermore, by implementing GBAi in vivo, we show that GBA-dependent signaling modulates phenotypes during Xenopus laevis embryonic development. In summary, GBAi is a selective, efficient, and convenient tool to dissect the biological processes controlled by a GPCR-independent mechanism of G protein activation mediated by cytoplasmic factors.

Obligatory role in GTP hydrolysis for the amide carbonyl oxygen of the Mg(2+)-coordinating Thr of regulatory GTPases

When G-protein alpha subunits binds GTP and Mg(2+), they transition from their inactive to their active conformation. This transition is accompanied by completion of the coordination shell of Mg(2+) with electrons from six oxygens: two water molecules, the ss and gamma phosphoryls of GTP, a helix-alpha1 Ser, and a switch I domain (SWI) Thr, and the repositioning of SWI and SWII domains. SWII binds and regulates effector enzymes and facilitates GTP hydrolysis by repositioning the gamma-carbonyl of a Gln. Mutating the Ser generates regulatory GTPases that cannot lock Mg(2+) into its place and are locked in their inactive state with dominant negative properties. Curiously, mutating the Thr appears to reduce GTP hydrolysis. The reason for this difference is not known because it is also not known why removal of the Thr should affect the overall GTPase cycle differently than removal of the Ser. Working with recombinant Gsalpha, we report that mutating its SWI-Thr to either Ala, Glu, Gln, or Asp results not only in diminished GTPase activity but also in spontaneous activation of the SWII domain. Upon close examination of existing alpha subunit crystals, we noted the oxygen of the backbone carbonyl of SWI-Thr and of the gamma-carbonyl of SWII Gln to be roughly equidistant from the oxygen of the hydrolytic H(2)O. Our observations indicate that the Gln and Thr carbonyls play equihierarchical roles in the GTPase process and provide the mechanism that explains why mutating the Thr mimics mutating the Gln and not that of the Ser.

Receptor-mediated changes at the myristoylated amino terminus of Galpha(il) proteins

G protein-coupled receptors (GPCRs) catalyze nucleotide release in heterotrimeric G proteins, the slow step in G protein activation. G i/o family proteins are permanently, cotranslationally myristoylated at the extreme amino terminus. While myristoylation of the amino terminus has long been known to aid in anchoring G i proteins to the membrane, the role of myristoylation with regard to interaction with activated receptors is not known. Previous studies have characterized activation-dependent changes in the amino terminus of Galpha proteins in solution [Medkova, M. (2002) Biochemistry 41, 9963-9972; Preininger, A. M. (2003) Biochemistry 42, 7931-7941], but changes in the environment of specific residues within the Galpha i1 amino terminus during receptor-mediated G i activation have not been reported. Using site-specific fluorescence labeling of individual residues along a stretch of the Galpha il amino terminus, we found specific changes in the environment of these residues upon interaction with the activated receptor and following GTPgammaS binding. These changes map to a distinct surface of the amino-terminal helix opposite the Gbetagamma binding interface. The receptor-dependent fluorescence changes are consistent with a myristoylated amino terminus in the proximity of the membrane and/or receptor. Myristoylation affects both the rate and intensity of receptor activation-dependent changes detected at several residues along the amino terminus (with no significant effect on the rate of receptor-mediated GTPgammaS binding). This work demonstrates that the myristoylated amino terminus of Galpha il proteins undergoes receptor-mediated changes during the dynamic process of G protein signaling.

Signal Transfer from GPCRs to G Proteins

Catalysis of nucleotide exchange in heterotrimeric G proteins (Galphabetagamma) is a key step in cellular signal transduction mediated by G protein-coupled receptors. The Galpha N terminus with its helical stretch is thought to be crucial for G protein/activated receptor (R(*)) interaction. The N-terminal fatty acylation of Galpha is important for membrane targeting of G proteins. By applying biophysical techniques to the rhodopsin/transducin model system, we studied the effect of N-terminal truncations in Galpha. In Galphabetagamma, lack of the fatty acid and Galpha truncations up to 33 amino acids had little effect on R(*) binding and R(*)-catalyzed nucleotide exchange, implying that this region is not mandatory for R(*)/Galphabetagamma interaction. However, when the other hydrophobic modification of Galphabetagamma, the Ggamma C-terminal farnesyl moiety, is lacking, R(*) interaction requires the fatty acylated Galpha N terminus. This suggests that the two hydrophobic extensions can replace each other in the interaction of Galphabetagamma with R(*). We propose that in native Galphabetagamma, these two terminal regions are functionally redundant and form a microdomain that serves both to anchor the G protein to the membrane and to establish an initial docking complex with R(*). Accordingly, we find that the native fatty acylated Galpha is competent to interact with R(*) even in the absence of Gbetagamma, whereas nonacylated Galpha requires Gbetagamma for interaction. Experiments with N-terminally truncated Galpha subunits suggest that in the second step of the catalytic process, the receptor binds to the alphaN/beta1-loop region of Galpha to reduce nucleotide affinity and to make the Galpha C terminus available for subsequent interaction with R(*).

The carboxyl terminus of the Galpha-subunit is the latch for triggered activation of heterotrimeric G proteins

The receptor-mimetic peptide D2N, derived from the cytoplasmic domain of the D(2) dopamine receptor, activates G protein alpha-subunits (G(i) and G(o)) directly. Using D2N, we tested the current hypotheses on the mechanism of receptor-mediated G protein activation, which differ by the role assigned to the Gbetagamma-subunit: 1) a receptor-prompted movement of Gbetagamma is needed to open up the nucleotide exit pathway ("gear-shift" and "lever-arm" model) or 2) the receptor first engages Gbetagamma and then triggers GDP release by interacting with the carboxyl (C) terminus of Galpha (the "sequential-fit" model). Our results with D2N were compatible with the latter hypothesis. D2N bound to the extreme C terminus of the alpha-subunit and caused a conformational change that was transmitted to the switch regions. Hence, D2N led to a decline in the intrinsic tryptophan fluorescence, increased the guanine nucleotide exchange rate, and modulated the Mg(2+) control of nucleotide binding. A structural alteration in the outer portion of helix alpha5 (substitution of an isoleucine by proline) blunted the stimulatory action of D2N. This confirms that helix alpha5 links the guanine nucleotide binding pocket to the receptor contact site on the G protein. However, neither the alpha-subunit amino terminus (as a lever-arm) nor Gbetagamma was required for D2N-mediated activation; conversely, assembly of the Galphabetagamma heterotrimer stabilized the GDP-bound species and required an increased D2N concentration for activation. We propose that the receptor can engage the C terminus of the alpha-subunit to destabilize nucleotide binding from the "back side" of the nucleotide binding pocket.

The myristoylated amino terminus of Galpha(i)(1) plays a critical role in the structure and function of Galpha(i)(1) subunits in solution

To determine the role of the myristoylated amino terminus of Galpha in G protein activation, nine individual cysteine mutations along the myristoylated amino terminus of Galpha(i) were expressed in a functionally Cys-less background. Thiol reactive EPR and fluorescent probes were attached to each site as local reporters of mobility and conformational changes upon activation of Galpha(i)GDP by AlF(4)(-), as well as binding to Gbetagamma. EPR and steady state fluorescence anisotropy are consistent with a high degree of immobility for labeled residues in solution all along the amino terminus of myristoylated Galpha(i). This is in contrast to the high mobility of this region in nonmyristoylated Galpha(i) [Medkova, M., et al. (2002) Biochemistry 41, 9962-9972]. Steady state fluorescence measurements revealed pronounced increases in fluorescence upon activation for residues 14-17 and 21 located midway through the 30-amino acid stretch comprising the amino-terminal region. Collectively, the data suggest that myristoylation is an important structural determinant of the amino terminus of Galpha(i) proteins.

Dissociation of G-protein alpha from rhabdomeric membranes decreases its interaction with rhodopsin and increases its degradation by calpain

Photoactivation of invertebrate rhodopsin activates a GTP-binding protein, Gq, which in turn activates a phospholipase C (PLC) enzyme. Gqalpha is a membrane-associated protein that is progressively released from the membrane by washing with buffers containing increasing concentrations of beta-mercaptoethanol (beta-ME). Isolated, soluble Gqalpha showed a decreased ability to be activated by rhodopsin but was more active in stimulating PLC when compared with the membrane-associated form of Gqalpha. The calcium-activated protease, calpain, selectively cleaved the soluble but not the membrane-bound form of Gqalpha. Calpain cleaved a small peptide from the amino-terminus of Gqalpha reducing the ability of the G-protein to bind GTP. The uncoupling of Gqalpha from rhodopsin and subsequent calcium-dependent proteolysis to further inactivate the G-protein may therefore be a regulatory mechanism of light adaptation in rhabdomeric photoreceptors.

Interaction with Gbetagamma is required for membrane targeting and palmitoylation of Galpha(s) and Galpha(q)

Peripheral membrane proteins utilize a variety of mechanisms to attach tightly, and often reversibly, to cellular membranes. The covalent lipid modifications, myristoylation and palmitoylation, are critical for plasma membrane localization of heterotrimeric G protein alpha subunits. For alpha(s) and alpha(q), two subunits that are palmitoylated but not myristoylated, we examined the importance of interacting with the G protein betagamma dimer for their proper plasma membrane localization and palmitoylation. Conserved alpha subunit N-terminal amino acids predicted to mediate binding to betagamma were mutated to create a series of betagamma binding region mutants expressed in HEK293 cells. These alpha(s) and alpha(q) mutants were found in soluble rather than particulate fractions, and they no longer localized to plasma membranes as demonstrated by immunofluorescence microscopy. The mutations also inhibited incorporation of radiolabeled palmitate into the proteins and abrogated their signaling ability. Additional alpha(q) mutants, which contain these mutations but are modified by both myristate and palmitate, retained their localization to plasma membranes and ability to undergo palmitoylation. These findings identify binding to betagamma as a critical membrane attachment signal for alpha(s) and alpha(q) and as a prerequisite for their palmitoylation, while myristoylation can restore membrane localization and palmitoylation of betagamma binding-deficient alpha(q) subunits.

G protein mechanisms: insights from structural analysis

This review is concerned with the structures and mechanisms of a superfamily of regulatory GTP hydrolases (G proteins). G proteins include Ras and its close homologs, translation elongation factors, and heterotrimeric G proteins. These proteins share a common structural core, exemplified by that of p21ras (Ras), and significant sequence identity, suggesting a common evolutionary origin. Three-dimensional structures of members of the G protein superfamily are considered in light of other biochemical findings about the function of these proteins. Relationships among G protein structures are discussed, and factors contributing to their low intrinsic rate of GTP hydrolysis are considered. Comparison of GTP- and GDP-bound conformations of G proteins reveals how specific contacts between the gamma-phosphate of GTP and the switch II region stabilize potential effector-binding sites and how GTP hydrolysis results in collapse (or reordering) of these surfaces. A GTPase-activating protein probably binds to and stabilizes the conformation of its cognate G protein that recognizes the transition state for hydrolysis, and may insert a catalytic residue into the G protein active site. Inhibitors of nucleotide release, such as the beta gamma subunit of a heterotrimeric G protein, bind selectively to and stabilize the GDP-bound state. Release factors, such as the translation elongation factor, Ts, also recognize the switch regions and destabilize the Mg(2+)-binding site, thereby promoting GDP release. G protein-coupled receptors are expected to operate by a somewhat different mechanism, given that the GDP-bound form of many G protein alpha subunits does not contain bound Mg2+.

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.

Interaction of transducin with light-activated rhodopsin protects It from proteolytic digestion by trypsin

The tryptic cleavage pattern of transducin (Gt) in solution was compared with that in the presence of phospholipid vesicles, rod outer segment (ROS) membranes kept in the dark, or ROS membranes containing light-activated rhodopsin, metarhodopsin II (Rh*). When Gt was in the high affinity complex with Rh*, the alphat subunit was almost completely protected from proteolysis. The protection of alphat at Arg310 was complete, while Arg204 was substantially protected. The cleavage of alphat at Lys18 was protected in the presence of phospholipid vesicles, ROS membranes kept in the dark, or ROS membranes containing Rh*. The cleavage of betat was slower in the presence of ROS membranes or phospholipid vesicles. When the Rh*. Gt complex was incubated with guanyl-5'-yl thiophosphate, a guanine nucleotide analog known to release the high affinity interaction between Gt and Rh*, the protection at Arg310 and Arg204 was diminished. From our results, we propose that Rh* either physically blocks access of trypsin to Arg204 and Arg310 or maintains the heterotrimer in such a conformation that these cleavage sites are not available. Since Arg204 is involved in the switch interface with betagammat (Lambright, D. G., Sondek, J., Bohm, A., Skiba, N. P., Hamm, H. E., and Sigler, P. B. (1996) Nature 379, 311-319), it may be that betagammat is implicated in protecting this cleavage site in the receptor-bound, stabilized heterotrimer. Arg310 is not near the betagammat subunit, thus we believe that the high affinity binding of Gt to Rh* physically or sterically blocks access of trypsin to this site. Thus, Arg310, only a few angstroms away from the carboxyl terminus of alphat, which is known to directly bind to Rh*, is likely to also be a part of the Rh* binding site. This is in agreement with other studies and has implications for the mechanism by which receptors catalyze GDP release from G proteins. The protection of Lys18 in the presence of phospholipid vesicles suggests that the amino-terminal region is in contact with the membrane, consistent with the crystal structure of the heterotrimer (Lambright, D. G., Sondek, J., Bohm, A., Skiba, N. P., Hamm, H. E., and Sigler, P. B. (1996) Nature 379, 311-319).

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.

Altered Gs alpha N-terminus affects Gs activity and interaction with the G beta gamma subunit complex in cell membranes but not in solution

The stimulatory G protein (Gs) mediates activation of adenylylcyclase by a ligand-receptor complex. Gs is heterotrimeric (alpha beta gamma) and activation can be accomplished by dissociation of the alpha-subunit (Gs alpha) from the beta gamma-subunit complex (G beta gamma). Gs alpha is also a substrate for choleragen catalyzed ADP-ribosylation when it is associated with G beta gamma but not as free Gs alpha. Using recombinant DNA techniques we modified the cDNA for the 52,000 M(r) form of Gs alpha (Gs alpha 52) to produce a protein with a 2,400 M(r) N-terminal extension (Gs alpha 54.4). This N-terminal extension could be removed with the protease Factor Xa. In vitro transcription and translation of the recombinant plasmid containing the cDNA's for Gs alpha 52 and Gs alpha 54.4 produced a 52,000 M(r) and a 54,000 M(r) protein, respectively. In solution the properties of Gs alpha 52 and Gs alpha 54.4 were indistinguishable. Both proteins: (a) formed a heterotrimer with G beta gamma and their affinities for the subunit complex were the same; (b) could be ADP-ribosylated by choleragen in the presence but not in the absence of G beta gamma; (c) bound the non-hydrolyzable GTP analogue, GTP gamma S, and were protected from chymotryptic proteolysis by the guanine nucleotide; and (d) could activate in vitro translated type IV adenylylcyclase. Gs alpha 54.4 and Gs alpha 52 were incorporated into S49 cyc-membranes, which lack Gs alpha. After incorporation, both Gs alpha 52 and Gs alpha 54.4 were protected from chymotryptic proteolysis when GTP gamma S was present, revealing that both proteins were able to bind the nucleotide and undergo a conformational change characteristic of Gs alpha activation. When Gs alpha 52 was incorporated into cyc-membranes it could mediate both hormone and GTP gamma S stimulation of adenylylcyclase and could be ADP-ribosylated by choleragen, but Gs alpha 54.4 could do neither of these things, indicating that the properties of Gs alpha 54.4 were altered by the membrane. Deletion of the N-terminal extension by treatment with Factor Xa in solution converted Gs alpha 54.4 to Gs alpha 52, and upon incorporation into cyc-membranes it behaved like Gs alpha 52 in every regard, showing that the effect of the N-terminal extension was reversible. A lack of other differences in the functional properties of Gs alpha 52 and Gs alpha 54.4 suggests a correlation between the interaction of Gs alpha with G beta gamma and its ability to activate adenylylcyclase.

Tertiary and quaternary structural changes in Gi alpha 1 induced by GTP hydrolysis

Crystallographic analysis of 2.2 angstrom resolution shows that guanosine triphosphate (GTP) hydrolysis triggers conformational changes in the heterotrimeric G-protein alpha subunit, Gi alpha 1. The switch II and switch III segments become disordered, and linker II connecting the Ras and alpha helical domains moves, thus altering the structures of potential effector and beta gamma binding regions. Contacts between the alpha-helical and Ras domains are weakened, possibly facilitating the release of guanosine diphosphate (GDP). The amino and carboxyl termini, which contain receptor and beta gamma binding determinants, are disordered in the complex with GTP, but are organized into a compact microdomain on GDP hydrolysis. The amino terminus also forms extensive quaternary contacts with neighboring alpha subunits in the lattice, suggesting that multimers of alpha subunits or heterotrimers may play a role in signal transduction.

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.

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.

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.

Targeting of chimeric G alpha i proteins to specific membrane domains

Heterotrimeric guanine nucleotide-regulatory (G) proteins are associated with a variety of intracellular membranes and specific plasma membrane domains. In polarized epithelial LLC-PK1 cells we have shown previously that endogenous G alpha i-2 is localized on the basolateral plasma membrane, whereas G alpha i-3 is localized on Golgi membranes. The targeting of these highly homologous G alpha i proteins to distinct membrane domains was studied by the transfection and expression of chimeric G alpha i proteins in LLC-PK1 cells. Chimeric cDNAs were constructed from the cDNAs for G alpha i-3 and G alpha i-2 and introduced into a pMXX eukaryotic expression vector containing a mouse metallothionein-I promoter. Stably transfected cell lines were produced that expressed either G alpha i-2/3 or G alpha i-3/2 chimeric proteins. Chimeric and endogenous G alpha i proteins were detected in cells using specific carboxy-terminal peptide antibodies. Immunofluorescence staining was used to localize endogenous and chimeric G alpha i proteins in LLC-PK1 cells. The staining of chimeric proteins was detected as an increased intensity of staining on membranes containing endogenous G alpha i proteins. Using confocal microscopy and image analysis we localized G alpha i-2 to a specific sub-domain of the lateral membrane of polarized cells, the chimeric G alpha i-3/2 protein was then shown to colocalize with endogenous G alpha i-2 in the same lateral plasma membrane domain. The chimeric G alpha i-2/3 protein colocalized with endogenous G alpha i-3 on Golgi membranes in LLC-PK1 cells. These results show that chimeric G alpha i proteins were targeted to the same membrane domains as endogenous G alpha i proteins and the specificity of their membrane targeting was conferred by the carboxy-terminal end of the proteins. These data provide the first evidence for specific targeting information contained in the carboxy termini of G alpha i proteins, which appears to be independent of amino-terminal membrane attachment sites in these proteins.

G proteins: critical control points for transmembrane signals

Heterotrimeric GTP-binding proteins (G proteins) that are made up of alpha and beta gamma subunits couple many kinds of cell-surface receptors to intracellular effector enzymes or ion channels. Every cell contains several types of receptors, G proteins, and effectors. The specificity with which G protein subunits interact with receptors and effectors defines the range of responses a cell is able to make to an external signal. Thus, the G proteins act as a critical control point that determines whether a signal spreads through several pathways or is focused to a single pathway. In this review, I will summarize some features of the structure and function of mammalian G protein subunits, discuss the role of both alpha and beta gamma subunits in regulation of effectors, the role of the beta gamma subunit in macromolecular assembly, and the mechanisms that might make some responses extremely specific and others rather diffuse.