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.     

N-Myristoylation and betagamma play roles beyond anchorage in the palmitoylation of the G protein alpha(o) subunit

Many of the alpha subunits of heterotrimeric GTP-binding regulatory proteins (G proteins) are palmitoylated, a modification proposed to play a key role in the stable anchorage of the subunits to the plasma membrane. Palmitoylation of alpha subunits from the G(i) family is preceded by N-myristoylation, which alone or together with betagamma probably supports a reversible interaction of the alpha subunit with membrane as a prerequisite to the eventual incorporation of palmitate. Previous studies have not addressed, however, the question of whether membrane association alone, carried out through N-myristoylation, interaction with betagamma, or other events, is sufficient for palmitoylation. We report here for alpha(o) that it is not. We found that N-myristoylation is required for palmitoylation at least in part because it supports events subsequent to membrane attachment. Mutants of alpha(o) designed to target the subunit to membrane without an N-myristoyl group are unable to be palmitoylated as evaluated by incorporation of [(3)H]palmitate. Mutants of alpha(o) unable to interact normally with betagamma yet still attach to membrane demonstrate that betagamma, in contrast, is not required for palmitoylation. betagamma becomes necessary, however, when the N-myristoyl group is absent. Our results suggest that N-myristoylation and betagamma, while almost certainly relevant to the reversible interaction of alpha(o) with membrane, also play at least partly overlapping, post-anchorage roles in palmitoylation.     

Fluorescence analysis of receptor-G protein interactions in cell membranes

The dynamics of G protein heterotrimer complex formation and disassembly in response to nucleotide binding and receptor activation govern the rate of responses to external stimuli. We use a novel flow cytometry approach to study the effects of lipid modification, isoform specificity, lipid environment, and receptor stimulation on the affinity and kinetics of G protein subunit binding. Fluorescein-labeled myristoylated Galpha(i1) (F-alpha(i1)) was used as the ligand bound to Gbetagamma in competition binding studies with differently modified Galpha subunit isoforms. In detergent solutions, the binding affinity of Galpha(i) to betagamma was 2 orders of magnitude higher than for Galpha(o) and Galpha(s) (IC50 of 0.2 nM vs 17 and 27 nM, respectively), while in reconstituted bovine brain lipid vesicles, binding was slightly weaker. The effects of receptor on the G protein complex were assessed in alpha(2A)AR receptor expressing CHO cell membranes into which purified betagamma subunits and F-alpha(i1) were reconstituted. These cell membrane studies led to the following observations: (1) binding of alpha subunit to the betagamma was not enhanced by receptor in the presence or absence of agonist, indicating that betagamma contributed essentially all of the binding energy for alpha(i1) interaction with the membrane; (2) activation of the receptor facilitated GTPgammaS-stimulated detachment of F-alpha(i1) from betagamma and the membrane. Thus flow cytometry permits quantiatitive and real-time assessments of protein-protein interactions in complex membrane environments.     

A family of G protein βγ subunits translocate reversibly from the plasma membrane to endomembranes on receptor activation

The present model of G protein activation by G protein-coupled receptors exclusively localizes their activation and function to the plasma membrane (PM). Observation of the spatiotemporal response of G protein subunits in a living cell to receptor activation showed that 6 of the 12 members of the G protein gamma subunit family translocate specifically from the PM to endomembranes. The gamma subunits translocate as betagamma complexes, whereas the alpha subunit is retained on the PM. Depending on the gamma subunit, translocation occurs predominantly to the Golgi complex or the endoplasmic reticulum. The rate of translocation also varies with the gamma subunit type. Different gamma subunits, thus, confer distinct spatiotemporal properties to translocation. A striking relationship exists between the amino acid sequences of various gamma subunits and their translocation properties. gamma subunits with similar translocation properties are more closely related to each other. Consistent with this relationship, introducing residues conserved in translocating subunits into a non-translocating subunit results in a gain of function. Inhibitors of vesicle-mediated trafficking and palmitoylation suggest that translocation is diffusion-mediated and controlled by acylation similar to the shuttling of G protein subunits (Chisari, M., Saini, D. K., Kalyanaraman, V., and Gautam, N. (2007) J. Biol. Chem. 282, 24092-24098). These results suggest that the continual testing of cytosolic surfaces of cell membranes by G protein subunits facilitates an activated cell surface receptor to direct potentially active G protein betagamma subunits to intracellular membranes.     

Heterotrimer formation,together with isoprenylation,is required for plasma membrane targeting of Gbetagamma

Nascent beta and gamma subunits of heterotrimeric G proteins need to be targeted to the cytoplasmic face of the plasma membrane (PM) in order to transmit signals. We show that beta(1)gamma(2) is poorly targeted to the PM and predominantly localized to endoplasmic reticulum (ER) membranes when expressed in HEK293 cells, but co-expression of a G protein alpha subunit allows strong PM localization of the beta(1)gamma(2). Furthermore, C-terminal isoprenylation of the gamma subunit is necessary but not sufficient for PM localization of beta(1)gamma(2). Isoprenylation of gamma(2) and localization of beta(1)gamma(2) to the ER occurs independently of alpha expression. Efficient PM localization of beta(1)gamma(2) in the absence of co-expressed alpha is observed when a site for palmitoylation, a putative second membrane targeting signal, is introduced into gamma(2). When a mutant of alpha(s) is targeted to mitochondria, beta(1)gamma(2) follows, consistent with an important role for alpha in promoting subcellular localization of betagamma. Furthermore, we directly demonstrate the requirement for alpha by showing that disruption of heterotrimer formation by the introduction of alpha binding mutations into beta(1) impedes PM targeting of beta(1)gamma(2). The results indicate that two membrane targeting signals, lipid modification and alpha binding, make concerted contributions to PM localization of betagamma.     

Stimulation of cellular signaling and G protein subunit dissociation by G protein betagamma subunit-binding peptides

We previously developed peptides that bind to G protein betagamma subunits and selectively block interactions between betagamma subunits and a subset of effectors in vitro (Scott, J. K., Huang, S. F., Gangadhar, B. P., Samoriski, G. M., Clapp, P., Gross, R. A., Taussig, R., and Smrcka, A. V. (2001) EMBO J. 20, 767-776). Here, we created cell-permeating versions of some of these peptides by N-terminal modification with either myristate or the cell permeation sequence from human immunodeficiency virus TAT protein. The myristoylated betagamma-binding peptide (mSIRK) applied to primary rat arterial smooth muscle cells caused rapid activation of extracellular signal-regulated kinase 1/2 in the absence of an agonist. This activation did not occur if the peptide lacked a myristate at the N terminus, if the peptide had a single point mutation to eliminate betagamma subunit binding, or if the cells stably expressed the C terminus of betaARK1. A human immunodeficiency virus TAT-modified peptide (TAT-SIRK) and a myristoylated version of a second peptide (mSCAR) that binds to the same site on betagamma subunits as mSIRK, also caused extracellular signal-regulated kinase activation. mSIRK also stimulated Jun N-terminal kinase phosphorylation, p38 mitogen-activated protein kinase phosphorylation, and phospholipase C activity and caused Ca2+ release from internal stores. When tested with purified G protein subunits in vitro, SIRK promoted alpha subunit dissociation from betagamma subunits without stimulating nucleotide exchange. These data suggest a novel mechanism by which selective betagamma-binding peptides can release G protein betagamma subunits from heterotrimers to stimulate G protein pathways in cells.     

Lipid modifications of G protein subunits. Myristoylation of Go alpha increases its affinity for beta gamma

Myristoylated recombinant proteins can be synthesized in Escherichia coli by concurrent expression of the enzyme myristoyl-CoA:protein N-myristoyl-transferase with its protein substrates (Duronio, R.J., Jackson-Machelski, E., Heuckeroth, R.O., Olins, P. O., Devine, C.S., Yonemoto, W., Slice, L. W., Taylor, S. S., and Gordon, J. I. (1990) Proc. Natl. Acad. Sci. U. S.A. 87, 1506-1510). Expression of the G protein subunit Go alpha in this system results in the synthesis of two forms of the protein; these were separated on a column of heptylamine-Sepharose. Purification of the more abundant form of Go alpha yielded a product that has a blocked amino terminus. Chemical analysis of the fatty acids released by acid hydrolysis of the protein revealed myristic acid. The second form of the protein was not myristoylated. Myristoylated and nonmyristoylated recombinant Go alpha were compared with brain Go alpha (which is myristoylated) for their ability to interact with G protein beta gamma subunits. The nonmyristoylated recombinant protein clearly had a reduced affinity for beta gamma, while the myristoylated recombinant protein was indistinguishable from native Go alpha in its subunit interactions. Thus, myristoylation increases the affinity of alpha subunits for beta gamma. We propose that the function of myristoylation of G protein alpha subunits is, at least in part, to facilitate formation of the heterotrimer and the localization of alpha to the plasma membrane.     

The alpha2A-adrenergic receptor discriminates between Gi heterotrimers of different betagamma subunit composition in Sf9 insect cell membranes

In view of the expanding roles of the betagamma subunits of the G proteins in signaling, the possibility was raised that the rich diversity of betagamma subunit combinations might contribute to the specificity of signaling at the level of the receptor. To test this possibility, Sf9 cell membranes expressing the recombinant alpha2A-adrenergic receptor were used to assess the contribution of the betagamma subunit composition. Reconstituted coupling between the receptor and heterotrimeric Gi protein was assayed by high affinity, guanine nucleotide-sensitive binding of the alpha2-adrenergic agonist, [3H]UK-14,304. Supporting this hypothesis, the present study showed clear differences in the abilities of the various betagamma dimers, including those containing the beta3 subtype and the newly described gamma4, gamma10, and gamma11 subtypes, to promote interaction of the same alphai subunit with the alpha2A-adrenergic receptor.     

Differential distribution of alpha subunits and beta gamma subunits of heterotrimeric G proteins on Golgi membranes of the exocrine pancreas

Heterotrimeric G proteins are well known to be involved in signaling via plasma membrane (PM) receptors. Recent data indicate that heterotrimeric G proteins are also present on intracellular membranes and may regulate vesicular transport along the exocytic pathway. We have used subcellular fractionation and immunocytochemical localization to investigate the distribution of G alpha and G beta gamma subunits in the rat exocrine pancreas which is highly specialized for protein secretion. We show that G alpha s, G alpha i3 and G alpha q/11 are present in Golgi fractions which are > 95% devoid of PM. Removal of residual PM by absorption on wheat germ agglutinin (WGA) did not deplete G alpha subunits. G alpha s was largely restricted to TGN- enriched fractions by immunoblotting, whereas G alpha i3 and G alpha q/11 were broadly distributed across Golgi fractions. G alpha s did not colocalize with TGN38 or caveolin, suggesting that G alpha s is associated with a distinct population of membranes. G beta subunits were barely detectable in purified Golgi fractions. By immunofluorescence and immunogold labeling, G beta subunits were detected on PM but not on Golgi membranes, whereas G alpha s and G alpha i3 were readily detected on both Golgi and PM. G alpha and G beta subunits were not found on membranes of zymogen granules. These data indicate that G alpha s, G alpha q/11, and G alpha i3 associate with Golgi membranes independent of G beta subunits and have distinctive distributions within the Golgi stack. G beta subunits are thought to lock G alpha in the GDP-bound form, prevent it from activating its effector, and assist in anchoring it to the PM. Therefore the presence of free G alpha subunits on Golgi membranes has several important functional implications: it suggests that G alpha subunits associated with Golgi membranes are in the active, GTP-bound form or are bound to some other unidentified protein(s) which can substitute for G beta gamma subunits. It further implies that G alpha subunits are tethered to Golgi membranes by posttranslational modifications (e.g., palmitoylation) or by binding to another protein(s).     

Visualization of G protein betagamma dimers using bimolecular fluorescence complementation demonstrates roles for both beta and gamma in subcellular targeting

To investigate the role of subcellular localization in regulating the specificity of G protein betagamma signaling, we have applied the strategy of bimolecular fluorescence complementation (BiFC) to visualize betagamma dimers in vivo. We fused an amino-terminal yellow fluorescent protein fragment to beta and a carboxyl-terminal yellow fluorescent protein fragment to gamma. When expressed together, these two proteins produced a fluorescent signal in human embryonic kidney 293 cells that was not obtained with either subunit alone. Fluorescence was dependent on betagamma assembly in that it was not obtained using beta2 and gamma1, which do not form a functional dimer. In addition to assembly, BiFC betagamma complexes were functional as demonstrated by more specific plasma membrane labeling than was obtained with individually tagged fluorescent beta and gamma subunits and by their abilities to potentiate activation of adenylyl cyclase by alpha(s) in COS-7 cells. To investigate isoform-dependent targeting specificity, the localization patterns of dimers formed by pair-wise combinations of three different beta subunits with three different gamma subunits were compared. BiFC betagamma complexes containing either beta1 or beta2 localized to the plasma membrane, whereas those containing beta5 accumulated in the cytosol or on intracellular membranes. These results indicate that the beta subunit can direct trafficking of the gamma subunit. Taken together with previous observations, these results show that the G protein alpha, beta, and gamma subunits all play roles in targeting each other. This method of specifically visualizing betagamma dimers will have many applications in sorting out roles for particular betagamma complexes in a wide variety of cell types.     

Involvement of betagamma subunits of G(q/11) in muscarinic M(1) receptor potentiation of corticotropin-releasing hormone-stimulated adenylyl cyclase activity in rat frontal cortex

In the present study, we investigated the involvement of betagamma subunits of G(q/11) in the muscarinic M(1) receptor-induced potentiation of corticotropin-releasing hormone (CRH)-stimulated adenylyl cyclase activity in membranes of rat frontal cortex. Tissue exposure to either one of two betagamma scavengers, the QEHA fragment type II adenylyl cyclase and the GDP-bound form of the alpha subunit of transducin, inhibited the muscarinic M(1) facilitatory effect. Moreover, like acetylcholine (ACh), exogenously added betagamma subunits of transducin potentiated the CRH-stimulated adenylyl cyclase activity, and this effect was not additive with that elicited by ACh. Western blot analysis indicated the expression in frontal cortex of both type II and type IV adenylyl cyclases, two isoforms stimulated by betagamma subunits in synergism with activated G(s). The M(1) receptor-induced enhancement of the adenylyl cyclase response to CRH was counteracted by the G(q/11) antagonist GpAnt-2A but not by GpAnt-2, a preferential G(i/o) antagonist. In addition, the muscarinic facilitatory effect was inhibited by membrane preincubation with antiserum directed against the C terminus of the alpha subunit of G(q/11), whereas the same treatment with antiserum against either G(i1/2) or G(o) was without effect. These data indicate that in membranes of rat frontal cortex, activation of muscarinic M(1) receptors potentiates CRH-stimulated adenylyl cyclase activity through betagamma subunits of G(q/11).     

Formation of the alpha-bungarotoxin binding site and assembly of the nicotinic acetylcholine receptor subunits occur in the endoplasmic reticulum

During the process by which newly synthesized subunits of the nicotinic acetylcholine receptor (stoichiometry = alpha 2 beta gamma delta) mature and acquire the properties of the fully functional cell surface receptor, they undergo numerous covalent and noncovalent modifications. Using ligand-mediated and subunit-specific immunoprecipitation, four forms in the maturation of the alpha subunit can be detected: the primary translation product; alpha subunit that can bind alpha-bungarotoxin; alpha subunit assembled with the other subunits; and surface receptor. The alpha subunit acquires the ability to bind alpha-bungarotoxin with a t1/2 of approximately 40 min after translation and becomes assembled with a t1/2 of 80 min after translation. Using metabolic labeling and sucrose gradient fractionation, we have determined the subcellular location of alpha subunit when it acquires the ability to bind alpha-bungarotoxin and when it is assembled. Golgi membranes were identified across the gradient by the enzymatic activities UDP-galactose:N-acetylglucosamine galactosyltransferase and alpha-mannosidase. Endoplasmic reticulum membranes were identified by the enzymatic activity glucose-6-phosphatase and by the presence of newly synthesized alpha and beta subunits. Pulse-labeled alpha subunit that bound alpha-bungarotoxin was first detected co-migrating in the gradient with the glucose-6-phosphatase activity. Therefore, the capacity to bind alpha-bungarotoxin was acquired while the alpha subunit was in the endoplasmic reticulum. Assembled alpha subunit was detected by immunoprecipitating with an anti-beta subunit-specific monoclonal antibody. By this method, assembled receptor was first detected 15 min after translation in both the endoplasmic and Golgi portions of the gradient. To validate this method of detecting assembled receptor, we determined the sedimentation coefficient of the receptor subunits in the endoplasmic reticulum. Both unassembled subunits with sedimentation coefficients of 5 S and assembled receptor with a sedimentation coefficient of 9 S were recovered from the endoplasmic reticulum portion of the gradient. Thus, our data concerning the subcellular site of assembly are consistent with assembly occurring in the endoplasmic reticulum followed by rapid transport to the Golgi.     

Gbeta gamma isoforms selectively rescue plasma membrane localization and palmitoylation of mutant Galphas and Galphaq

Mutation of Galpha(q) or Galpha(s) N-terminal contact sites for Gbetagamma resulted in alpha subunits that failed to localize at the plasma membrane or undergo palmitoylation when expressed in HEK293 cells. We now show that overexpression of specific betagamma subunits can recover plasma membrane localization and palmitoylation of the betagamma-binding-deficient mutants of alpha(s) or alpha(q). Thus, the betagamma-binding-defective alpha is completely dependent on co-expression of exogenous betagamma for proper membrane localization. In this report, we examined the ability of beta(1-5) in combination with gamma(2) or gamma(3) to promote proper localization and palmitoylation of mutant alpha(s) or alpha(q). Immunofluorescence localization, cellular fractionation, and palmitate labeling revealed distinct subtype-specific differences in betagamma interactions with alpha subunits. These studies demonstrate that 1) alpha and betagamma reciprocally promote the plasma membrane targeting of the other subunit; 2) beta(5), when co-expressed with gamma(2) or gamma(3), fails to localize to the plasma membrane or promote plasma membrane localization of mutant alpha(s) or alpha(q); 3) beta(3) is deficient in promoting plasma membrane localization of mutant alpha(s) and alpha(q), whereas beta(4) is deficient in promoting plasma membrane localization of mutant alpha(q); 4) both palmitoylation and interactions with betagamma are required for plasma membrane localization of alpha.     

The carboxy-terminal domain of Gs alpha is necessary for anchorage of the activated form in the plasma membrane

GTP-binding proteins which participate in signal transduction share a common heterotrimeric structure of the alpha beta gamma-type. In the activated state, the alpha subunit dissociates from the beta gamma complex but remains anchored in the membrane. The alpha subunits of several GTP-binding proteins, such as Go and Gi, are myristoylated at the amino terminus (Buss, J. E., S. M. Mumby, P. J. Casey, A. G. Gilman, and B. M. Sefton. 1987. Proc. Natl. Acad. Sci. USA. 84:7493-7497). This hydrophobic modification is crucial for their membrane attachment. The absence of fatty acid on the alpha subunit of Gs (Gs alpha), the protein involved in adenylate cyclase activation, suggests a different mode of anchorage. To characterize the anchoring domain of Gs alpha, we used a reconstitution model in which posttranslational addition of in vitro-translated Gs alpha to cyc- membranes (obtained from a mutant of S49 cell line which does not express Gs alpha) restores the coupling between the beta-adrenergic receptor and adenylate cyclase. The consequence of deletions generated by proteolytic removal of amino acid sequences or introduced by genetic removal of coding sequences was determined by analyzing membrane association of the proteolyzed or mutated alpha chains. Proteolytic removal of a 9-kD amino-terminal domain or genetic deletion of 28 amino-terminal amino acids did not modify the anchorage of Gs alpha whereas proteolytic removal of a 1-kD carboxyterminal domain abolished membrane interaction. Thus, in contrast to the myristoylated alpha subunits which are tethered through their amino terminus, the carboxy-terminal residues of Gs alpha are required for association of this protein with the membrane.     

Insulin induces translocation of the alpha 2 and beta 1 subunits of the Na+/K(+)-ATPase from intracellular compartments to the plasma membrane in mammalian skeletal muscle.

Unlike glucose transport, where translocation of the insulin-responsive glucose transporter (GLUT4) from an intracellular compartment to the plasma membrane is the principal mechanism underlying insulin stimulation, no consensus exists presently for the mechanism by which insulin activates the Na+/K(+)-ATPase. We have investigated (i) the subunit isoforms expressed and (ii) the effect of insulin on the subcellular distribution of the alpha beta isoforms of the Na+/K(+)-ATPase in plasma membranes (PM) and internal membranes (IM) from rat skeletal muscle. Western blot analysis, using isoform-specific antibodies to the various subunits of the Na+/K(+)-ATPase, revealed that skeletal muscle PM contains the alpha 1 and alpha 2 catalytic subunits and the beta 1 and beta 2 subunits of the Na+ pump. Skeletal muscle IM were enriched in alpha 2, beta 1, and beta 2; alpha 1 was barely detectable in this fraction. After insulin treatment, alpha 2 content in the PM increased, with a parallel decrease in its abundance in the IM pool; insulin did not have any effect on alpha 1 isoform amount or subcellular distribution. The beta 1 subunit, but not beta 2, was also elevated in the PM after insulin treatment, but this increase originated from a sucrose gradient fraction different from that of the alpha 2 subunit. Our findings suggest that insulin induces an isoform-specific translocation of Na+ pump subunits from different intracellular sources to the PM and that the hormone-responsive enzyme in rat skeletal muscle is an alpha 2:beta 1 dimer.     

BIP associates with newly synthesized subunits of the mouse muscle nicotinic receptor

A slow conformational change in newly synthesized acetylcholine receptor subunits is thought to be a requisite step in the biogenesis of this multi-subunit transmembrane glycoprotein. Previously, we demonstrated that this early conformational change within the alpha-subunit was inefficient and dependent upon disulfide bond formation (Blount, P. and J.P. Merlie. 1990. J. Cell Biol. 111:2613-2622). Here we show that newly synthesized acetylcholine receptor subunits and subunit complexes in the muscle-like cell line, BC3H-1, are associated with Bip, a ubiquitous binding protein of the endoplasmic reticulum. Characterization of the Bip/alpha-subunit complex in stably transfected fibroblasts revealed that Bip associates with newly synthesized unassembled alpha-subunit and some alpha gamma and alpha delta subunit complexes. Significantly, Bip does not associate well with the more mature form of the alpha-subunit containing an intramolecular disulfide bridge. Hence, Bip may play an important role in the conformational maturation and/or editing of unassembled AChR subunits and subunit complexes in vivo.     

Loss of association between activated Galpha q and Gbetagamma disrupts receptor-dependent and receptor-independent signaling

The G protein subunit, betagamma, plays an important role in targeting alpha subunits to the plasma membrane and is essential for binding and activation of the heterotrimer by heptahelical receptors. Mutation of residues in the N-terminal alpha-helix of alpha s and alpha q that contact betagamma in the crystal structure of alpha i reduces binding between alpha and betagamma, inhibits plasma membrane targeting and palmitoylation of the alpha subunit, and results in G proteins that fail to couple receptor activation to stimulation of effector. Overexpression of betagamma can recover this loss of signaling through Gs but not Gq. In fact, a single mutation (I25A) in alpha q can block alpha q-mediated generation of inositol phosphates. Function is not recovered by betagamma overexpression nor myristoylation directed plasma membrane localization. Introduction of a Q209L activating mutation with I25A results in a constitutively active alpha q as expected, but surprisingly a R183C activating mutation does not result in constitutive activity when present with I25A. Examination of binding between alpha and betagamma via a pull down assay shows that the N-terminal betagamma-binding mutations inhibit alpha-betagamma binding significantly more than the R183C or Q209L activating mutations do. Moreover, introduction of the I25A mutation into alpha q RC disrupts co-immunoprecipitation with PLCbeta1. Taken together, results presented here suggest that alpha-betagamma binding is necessary at a point downstream from receptor activation of the heterotrimeric G protein for signal transduction by alpha q.     

Pmel17 Initiates Premelanosome Morphogenesis within Multivesicular Bodies

Melanosomes are tissue-specific organelles within which melanin is synthesized and stored. The melanocyte-specific glycoprotein Pmel17 is enriched in the lumen of premelanosomes, where it associates with characteristic striations of unknown composition upon which melanin is deposited. However, Pmel17 is synthesized as an integral membrane protein. To clarify its physical linkage to premelanosomes, we analyzed the posttranslational processing of human Pmel17 in pigmented and transfected nonpigmented cells. We show that Pmel17 is cleaved in a post-Golgi compartment into two disulfide-linked subunits: a large lumenal subunit, M alpha, and an integral membrane subunit, M beta. The two subunits remain associated intracellularly, indicating that detectable M alpha remains membrane bound. We have previously shown that Pmel17 accumulates on intralumenal membrane vesicles and striations of premelanosomes in pigmented cells. In transfected nonpigmented cells Pmel17 associates with the intralumenal membrane vesicles of multivesicular bodies; cells overexpressing Pmel17 also display structures resembling premelanosomal striations within these compartments. These results suggest that Pmel17 is sufficient to drive the formation of striations from within multivesicular bodies and is thus directly involved in the biogenesis of premelanosomes.     

The role of electrostatic interactions in the regulation of the membrane association of G protein beta gamma heterodimers

In this paper we report calculations of electrostatic interactions between the transducin (G(t)) betagamma heterodimer (G(t)betagamma) and phospholipid membranes. Although membrane association of G(t)betagamma is due primarily to the hydrophobic penetration into the membrane interior of a farnesyl chain attached to the gamma subunit, structural studies have revealed that there is a prominent patch of basic residues on the surface of the beta subunit surrounding the site of farnesylation that is exposed upon dissociation from the G(t)alpha subunit. Moreover, phosducin, which produces dissociation of G(t)betagamma from membranes, interacts directly with G(t)betagamma and introduces a cluster of acidic residues into this region. The calculations, which are based on the finite difference Poisson-Boltzmann method, account for a number of experimental observations and suggest that charged residues play a role in mediating protein-membrane interactions. Specifically, the calculations predict the following. 1) Favorable electrostatic interactions enhance the membrane partitioning due to the farnesyl group by an order of magnitude although G(t)betagamma has a large net negative charge (-12). 2) This electrostatic attraction positions G(t)betagamma so that residues implicated in mediating the interaction of G(t)betagamma with its membrane-bound effectors are close to the membrane surface. 3) The binding of phosducin to G(t)betagamma diminishes the membrane partitioning of G(t)betagamma by an order of magnitude. 4) Lowering the ionic strength of the solution converts the electrostatic attraction into a repulsion. Sequence analysis and homology model building suggest that our conclusions may be generalized to other Gbetagamma and phosducin isoforms as well.     

Over-expression of a truncated Arabidopsis thaliana heterotrimeric G protein gamma subunit results in a phenotype similar to alpha and beta subunit knockouts

Heterotrimeric G proteins (G-proteins) are a diverse class of signal transducing proteins which have been implicated in a variety of important roles in plants. When G-proteins are activated, they dissociate into two functional subunits (alpha and the betagamma dimer) that effectively relay the signal to a multitude of effectors. In animal systems, the betagamma dimer is anchored to the plasma membrane by a prenyl group present in the gamma subunit and membrane localization has proven vital for heterotrimer function. A semi-dominant negative strategy was designed aiming to disrupt heterotrimer function in Arabidopsis thaliana (ecotype Columbia) plants by over-expressing a truncated gamma subunit lacking the isoprenylation motif (gamma()). Northern analysis shows that the levels of expression of the mutant gamma subunit in several transgenic lines (35S-gamma()) are orders of magnitude higher than that of the native subunits. In-depth characterization of the 35S-gamma() lines has been carried out, specifically focusing on a number of developmental characteristics and responses to several stimuli previously shown to be affected in alpha- and beta-deficient mutants. In all cases, the transgenic lines expressing the mutant gamma subunit behave in the same way as the alpha- and/or the beta-deficient mutants, albeit with reduced severity of the phenotype. Our data indicates that signaling from both functional subunits, alpha and the beta/gamma dimer, is disrupted in the transgenic plants. Even though physical association of the subunits has been previously reported, our research provides evidence of the functional association of alpha and beta with the gamma subunits in Arabidopsis, while also suggesting that plasma membrane localization may be critical for function of plant heterotrimeric G proteins.