Lipid modifications of G proteins

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.

Rin, a neuron-specific and calmodulin-binding small G-protein, and Rit define a novel subfamily of ras proteins

cDNAs encoding two novel 25 kDa Ras-like proteins, Rit and Rin, were isolated from mouse retina using a degenerate PCR-based cloning strategy. Using the expressed sequence tag database, human orthologs were also obtained and sequenced. The protein sequences of Rit and Rin, which are 64% identical, are more similar to each other than to any known Ras protein. Their closest homologs in the databases are Mucor racemosus Ras2 and Ras3, to which they show approximately 48% identity. Rit and Rin both bind GTP in vitro. An unusual feature of their structure is that they lack a known recognition signal for C-terminal lipidation, a modification that is generally necessary for plasma membrane association among the Ras subfamily of proteins. Nonetheless, transiently expressed Rit and Rin are plasma membrane-localized. Both proteins contain a C-terminal cluster of basic amino acids, which could provide a mechanism for membrane association. Deletion analysis suggested that this region is important for Rit membrane binding but is not necessary for Rin. Rit, like most Ras-related proteins, is ubiquitously expressed. Rin, however, is unusual in that it is expressed only in neurons. In addition, Rin binds calmodulin through a C-terminal binding motif. These results suggest that Rit and Rin define a novel subfamily of Ras-related proteins, perhaps using a new mechanism of membrane association, and that Rin may be involved in calcium-mediated signaling within neurons.

A novel form of the G protein beta subunit Gbeta5 is specifically expressed in the vertebrate retina

The G protein beta subunit, Gbeta5, is predominantly expressed in the central nervous system. In rodent brain, Gbeta5 is expressed as a protein with an apparent molecular mass of 39,000 daltons (39 kDa). We have identified an additional Gbeta5 immunoreactive protein of apparent size 44 kDa in the vertebrate retina. Molecular cloning and sequencing of polymerase chain reaction products revealed that the cDNA encoding the larger species of Gbeta5 (Gbeta5L) was identical to the shorter form with the addition of 126 base pairs of 5' DNA sequence potentially encoding an in-frame 42-amino acid extension. Sequencing of mouse Gbeta5 genomic clones demonstrated that the 126-base pair of retinal-specific coding material is derived from a hitherto undetected 5' exon. During sucrose density gradient fractionation of bovine retinas, the 44-kDa Gbeta5L protein co-purified with rod outer segment membranes. Incubation of rod outer segment membranes with the nonhydrolyzable guanine nucleotide, GTPgammaS (guanosine 5'-3-O-(thio)triphosphate), which released the Gbeta subunit of transducin (Gbeta1), failed to remove Gbeta5L. The 39-kDa Gbeta5 protein displayed differential association with retinal and brain membranes. In the retina, Gbeta5 was present as a soluble protein and was undetectable in the membrane fraction, whereas in the brain approximately 70% of Gbeta5 was associated with cellular membranes. In transient COS-7 cell expression experiments, Gbeta5L formed functional Gbetagamma dimers and Galphabetagamma heterotrimers, and activated phosphoinositide-specific phospholipase Cbeta2 in a manner indistinguishable from the 39-kDa Gbeta5 protein. The cloning of the retinal-specific Gbeta5L cDNA suggests the existence of potentially novel G protein-mediated signaling cascades in photoreception.

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.

Cytoplasmic tail length influences fatty acid selection for acylation of viral glycoproteins

We report remarkable differences in the fatty acid content of thioester-type acylated glycoproteins of enveloped viruses from mammalian cells. The E2 glycoprotein of Semliki Forest virus contains mainly palmitic acid like most other palmitoylated proteins analysed so far. However, the other glycoprotein (E1) of the same virus, as well as the HEF (haemagglutinin esterase fusion) glycoprotein of influenza C virus, are unique in this respect because they are acylated primarily with stearic acid. Comparative radiolabelling of uninfected cells with different fatty acids suggests that stearate may also be the prevailing fatty acid in some cellular acylproteins. To look for further differences between palmitoylated and stearoylated glycoproteins we characterized stearoylation in more detail. We identified the acylation site of HEF as a cysteine residue located at the boundary between the transmembrane region and the cytoplasmic tail. The attachment of stearate to HEF and E1 occurs post-translationally in a pre-Golgi compartment. Thus, stearoylated and palmitoylated proteins cannot be discriminated on the basis of the fatty acid linkage site or the intracellular compartment, where acylation occurs. However, stearoylated acylproteins contain a very short, positively charged cytoplasmic tail, whereas in palmitoylated proteins this molecular region is longer. Replacing the short cytoplasmic tail of stearoylated HEF with the long influenza A virus haemagglutinin (HA) tail in an HEF-HA chimera, and subsequent vaccinia T7 expression in CV-1 cells, yielded proteins with largely palmitic acid bound. The reverse chimera, HA-HEF with a short cytoplasmic tail was not fatty acylated at all during expression, indicating that conformational or topological constraints control fatty acid transfer.

Aberrant mitosis in fission yeast mutants defective in fatty acid synthetase and acetyl CoA carboxylase

Two fission yeast temperature-sensitive mutants, cut6 and lsd1, show a defect in nuclear division. The daughter nuclei differ dramatically in size (the phenotype designated lsd, large and small daughter). Fluorescence in situ hybridization (FISH) revealed that sister chromatids were separated in the lsd cells, but appeared highly compact in one of the two daughter nuclei. EM showed asymmetric nuclear elongation followed by unequal separation of nonchromosomal nuclear structures in these mutant nuclei. The small nuclei lacked electron-dense nuclear materials and contained highly compacted chromatin. The cut6+ and lsd1+ genes are essential for viability and encode, respectively, acetyl CoA carboxylase and fatty acid synthetase, the key enzymes for fatty acid synthesis. Gene disruption of lsd1+ led to the lsd phenotype. Palmitate in medium fully suppressed the phenotypes of lsd1. Cerulenin, an inhibitor for fatty acid synthesis, produced the lsd phenotype in wild type. The drug caused cell inviability during mitosis but not during the G2-arrest induced by the cdc25 mutation. A reduced level of fatty acid thus led to impaired separation of non-chromosomal nuclear components. We propose that fatty acid is directly or indirectly required for separating the mother nucleus into two equal daughters.

Activation of G protein-coupled inward rectifier K+ channels in brain neurons requires association of G protein beta gamma subunits with cell membrane

In cultured noradrenergic neurons from the rat locus coeruleus, application of recombinant G protein beta 1 gamma 2 subunits (30 nM) to the cytoplasmic side induced single channel activity similar to the somatostatin-induced single channel activity of G protein-coupled inward rectifier potassium channels (Kir (G)). In contrast, recombinant GTP gamma S-activated, myristoylated alpha i2 (100 nM) did not activate this brain Kir (G). Application of beta 1 gamma 2 C68S (30 nM or 150 nM), in which the cysteine residue fourth from the carboxyl terminus of gamma 2 was replaced by serine, failed to activate the brain Kir(G). This mutant lacks prenylation which is required for the association of beta gamma subunit with the cell membrane. Thus, our results suggest that the association of beta gamma subunit with the cell membrane is a prerequisite for activating Kir(G) channels.

The association between glycosylphosphatidylinositol-anchored proteins and heterotrimeric G protein alpha subunits in lymphocytes

Glycosylphosphatidylinositol (GPI)-anchored proteins are nonmembrane spanning cell surface proteins that have been demonstrated to be signal transduction molecules. Because these proteins do not extend into the cytoplasm, the mechanism by which cross-linking of these molecules leads to intracellular signal transduction events is obscure. Previous analysis has indicated that these proteins are associated with src family member tyrosine kinases; however, the role this interaction plays in the generation of intracellular signals is not clear. Here we show that GPI-anchored proteins are associated with alpha subunits of heterotrimeric GTP binding proteins (G proteins) in both human and murine lymphocytes. When the GPI-anchored proteins CD59, CD48, and Thy-1 were immunoprecipitated from various cell lines or freshly isolated lymphocytes, all were found to be associated with a 41-kDa phosphoprotein that we have identified, by using specific antisera, as a mixture of tyrosine phosphorylated G protein alpha subunits: a small amount of Gialpha1, and substantial amounts of Gialpha2 and Gialpha3. GTP binding assays performed with immunoprecipitations of CD59 indicated that there was GTP-binding activity associated with this molecule. Thus, we have shown by both immunochemical and functional criteria that GPI-anchored proteins are physically associated with G proteins. These experiments suggest a potential role of G proteins in the transduction of signals generated by GPI-anchored molecules expressed on lymphocytes of both mouse and human.

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.

Chemical biology of protein isoprenylation/methylation

Isoprenylation/methylation is an important dual hydrophobic post-translational modification which occurs at or near a carboxyl terminal cysteine residue. All known G proteins are modified in this way, making the pathway of central interest for an understanding of signal transduction. In this review, aspects of the molecular enzymology of isoprenylation/methylation are reviewed. The functional significance of these modifications is discussed, with special reference to the signal transducing G proteins. Of further interest is the possible regulatory role of methylation, since this step is the only reversible one in the pathway. The biochemical and functional consequences of isoprenylation/methylation are of especial interest. Isoprenylation/methylation is generally assumed to enhance the abilities of modified proteins to associate with membranes. This can be due either to hydrophobic lipid-lipid or lipid-protein interactions. Available evidence, taken largely from studies on visual signal transduction and ras signalling pathways, strongly points to enhanced membrane binding being a consequence of hydrophobic lipid-lipid interactions. An exciting possibility that also emerges is concerned with whether isoprenylation may also have additional roles, in addition to enhancing the membrane partitioning ability of the modified protein. In a simple mechanism of this type, the isoprenylated/methylated cysteine residue would be specifically recognized by another protein. While no compelling case can yet be made for an effector role for the isoprenylated/methylated cysteine moiety mediating protein-protein interactions, recent studies on the pharmacology of isoprenylated cysteine analogs suggests the possibility of such a role.

Post-translational modification of H-Ras is required for activation of, but not for association with, B-Raf

B-Raf is regulated by Ras protein and acts as a mitogen-activated protein (MAP) kinase kinase kinase in PC12 cells and brain. Ras protein undergoes a series of post-translational modifications on its C-terminal CAAX motif, and the modifications are critical for its function. To elucidate the role of the post-translational modifications in interaction with, and activation of, B-Raf, we have analyzed a direct association between H-Ras and B-Raf, and constructed an in vitro system for B-Raf activation by H-Ras. By using methods based on inhibition of yeast adenylyl cyclase or RasGAP activity and by in vitro binding assays, we have shown that the segment of B-Raf corresponding to amino acid 1-326 binds directly to H-Ras with a dissociation constant (Kd) comparable to that of Raf-1 and that the binding is not significantly affected by the post-translational modifications. However, when the activity of B-Raf to stimulate MAP kinase was measured by using a cell-free system derived from rat brain cytosol, we observed that the unmodified form of H-Ras possesses an almost negligible activity to activate B-Raf in vitro compared to the fully modified form. H-RasSer-181,184 mutant, which was farnesylated but not palmitoylated, was equally active as the fully modified form. These results indicate that the post-translational modifications, especially farnesylation, are required for H-Ras to activate B-Raf even though they have no apparent effect on the binding properties of H-Ras to B-Raf.

Mechanism of digeranylgeranylation of Rab proteins. Formation of a complex between monogeranylgeranyl-Rab and Rab escort protein

Rab proteins are Ras-related small GTPases that are digeranylgeranylated at carboxyl-terminal cysteines, a modification essential for their action as molecular switches regulating intracellular vesicular transport. Geranylgeranylation of Rabs is a complex reaction that requires a catalytic Rab geranylgeranyl transferase (GGTase) and a Rab escort protein (REP). REP binds unprenylated Rab and presents it to Rab GGTase. After GG transfer, REP remains associated with diGG-Rab, which leads to insertion of the Rab into a specific membrane. We used recombinant Rab1a single cysteine mutants that accept only one GG group to study the mechanism of the digeranylgeranylation reaction. Using the prenylation assay, gel filtration chromatography, and density ultracentrifugation, we show that REP, but not Rab GGTase, forms a stable complex with unprenylated, monoGG- and diGG-Rab1a. The REP.monoGG-Rab1a complex is stable in the presence of detergents or phospholipids, whereas the REP.diGG-Rab1a complex partially dissociates under these conditions. The stoichiometry of the REP.Rab complex appears to be 1:1 before prenylation. Prenylation induces a change in complex stoichiometry, with the formation of a 2:2 or 2:1 REP.Rab complex. A possible mechanism by which Rab proteins are digeranylgeranylated is suggested by the current studies. We propose that each geranylgeranyl addition is an independent reaction that leads to the production of monoGG-Rab and diGG-Rab, respectively. The stability of the REP.monoGG-Rab complex prevents monoGG-Rab from dissociating from REP prior to the second geranylgeranylation reaction, ensuring efficient digeranylgeranylation of Rab substrates.

Intersubunit surfaces in G protein alpha beta gamma heterotrimers. Analysis by cross-linking and mutagenesis of beta gamma

Heterotrimeric guanine nucleotide binding proteins (G proteins) are made up of alpha, beta, and gamma subunits, the last two forming a very tight complex. Stimulation of cell surface receptors promotes dissociation of alpha from the beta gamma dimer, which, in turn, allows both components to interact with intracellular enzymes or ion channels and modulate their activity. At present, little is known about the conformation of the beta gamma dimer or about the areas of beta gamma that interact with alpha. Direct information on the orientation of protein surfaces can be obtained from the analysis of chemically cross-linked products. Previous work in this laboratory showed that 1,6-bismaleimidohexane, which reacts with cysteine residues, specifically cross-links alpha to beta and beta to gamma (Yi, F., Denker, B. M., and Neer, E. J. (1991) J. Biol. Chem. 266, 3900-3906). To identify the residues in beta and gamma involved in cross-linking to each other or to alpha, we have mutated the cysteines in beta 1, gamma 2, and gamma 3 and analyzed the mutated proteins by in vitro translation in a rabbit reticulocyte lysate. All the mutants were able to form beta gamma dimers that could interact with the alpha subunit. We found that 1,6-bismaleimidohexane can cross-link beta 1 to gamma 3 but not to gamma 2. The cross-link goes from Cys25 in beta 1 to Cys30 in gamma 3. This cysteine is absent from any of the other known gamma isoforms and therefore confers a distinctive property to gamma 3. The beta subunit in the beta 1 gamma 2 dimer can be cross-linked to an unidentified protein in the rabbit reticulocyte lysate, generating a product slightly larger than cross-linked beta 1 gamma 3. The beta subunit can also be cross-linked to alpha, giving rise to two products on SDS-polyacrylamide gel electrophoresis, both of which were previously shown to be formed by cross-linking beta to Cys215 in alpha o (Thomas, T. C., Schmidt, C. J., and Neer, E. J. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 10295-10299). Mutation of Cys204 in beta 1 abolished one of these two products, whereas mutation of Cys271 abolished the other. Because both alpha-beta cross-linked products are formed in approximately equal amounts, Cys204 and Cys271 in beta are equally accessible from Cys215 in alpha o. Our findings begin to define intersubunit surfaces, and they pose structural constraints upon any model of the beta gamma dimer.

Protein farnesyltransferase in plants

The occurrence of protein farnesyltransferase has been demonstrated in spinach. The enzyme transferred different prenyl groups to the nonapeptide acceptor. All-trans isoprenoid diphosphates were utilized most efficiently in contrast to long-chain mainly cis-polyprenyl diphosphates and dolichyl diphosphates. The activity of the enzyme was stimulated by divalent cations. The presence of protein farnesyltransferase activity in several plant species has been confirmed.

Squid photoreceptor phospholipase C is stimulated by membrane Gq alpha but not by soluble Gq alpha

Phospholipase C (PLC) was purified from squid retina. Soluble Gq alpha, membrane Gq alpha and G beta gamma were isolated from GTP gamma S-treated and light-illuminated photoreceptor membranes. The membrane Gq alpha stimulated phosphatidyl inositol-phospholipase C (PI-PLC) activity in a dose-dependent manner. Soluble Gq alpha and membrane G beta gamma showed no stimulating effects on PLC. GTP gamma S-binding was found exclusively in membrane fraction, with very little present in the KCl-soluble fraction which contained soluble Gq alpha. These results indicate that light-activated rhodopsin activates PLC through membrane-bound Gq alpha and suggest that the rhodopsin/Gq/PLC cascade might be the pathway of phototransduction in squid photoreceptors.

Myristoylation of calcineurin B is not required for function or interaction with immunophilin-immunosuppressant complexes in the yeast Saccharomyces cerevisiae

Calcineurin is a heterodimeric Ca2+/calmodulin-dependent protein phosphatase that regulates signal transduction and is the target of immunophilin-immunosuppressive drug complexes in T-lymphocytes and in yeast. Calcineurin is composed of a catalytic A subunit and a regulatory B subunit that is myristoylated at its amino terminus. We employed genetic and biochemical approaches to investigate the functional roles of myristoylation of calcineurin B (CNB1) in Saccharomyces cerevisiae. A calcineurin B mutant in which glycine 2 was substituted by alanine (CNB1-G2A) did not incorporate [3H]myristate when expressed in yeast. Both wild-type calcineurin B and the CNB1-G2A mutant protein are partially associated with membranes and cytoskeletal structures; hence, myristoylation is not required for these associations. In several independent genetic assays of calcineurin functions (recovery from alpha-factor arrest, survival during cation stress, and viability of a calcineurin-dependent strain), the nonmyristoylated CNB1-G2A mutant protein exhibited full biological activity. In vitro, both wild-type and CNB1-G2A mutant proteins formed complexes with both cyclophilin A-cyclosporin A (CsA) and FKBP12-FK506 that contained calcineurin A. Interestingly, expression of the nonmyristoylated CNB1-G2A mutant protein rendered yeast cells partially resistant to the immunosuppressant CsA, but not to FK506. This study demonstrates that calcineurin B myristoylation is not required for function, but may participate in inhibition by the cyclophilin A-CsA complex.

Transmembrane Ca2+ gradient and function of membrane proteins

This review will focus on the recent advance in the study of effect of transmembrane Ca2+ gradient on the function of membrane proteins. It consits of two parts: 1. Transmembrane Ca2+ gradient and sarcoplasmic reticulum Ca(2+)-ATPase; 2. Effect of transmembrane Ca2+ gradient on the components and coupling of cAMP signal transduction pathway. The results obtained indicate that a proper transmembrane Ca2+ gradient may play an important role in modulating the conformation and activity of SR Ca(2+)-ATPase and the function of membrane proteins involved in the cAMP signal transduction by mediating the physical state change of the membrane phospholipids.

ADP-ribosylation factor translocation correlates with potentiation of GTP gamma S-stimulated phospholipase D activity in membrane fractions of HL-60 cells

Phospholipase D (PLD) activation by guanine nucleotides requires protein cofactors from both the membrane and the cytosol. The small GTP-binding protein ADP-ribosylation factor (ARF) has been established as one important component of PLD activation. By stimulating HL-60 cells with various agonists and then isolating the membrane fraction and assaying PLD activity in the presence and absence of GTP gamma S, we observed that fMet-Leu-Phe (fMLP) and phorbol esters induced a potentiation of GTP gamma S-stimulated PLD activity in the membrane fractions of these cells. Inactive phorbol esters induced no such potentiation. Both fMLP and active phorbol esters induced a 2-3-fold increase in GTP gamma S-stimulated PLD in HL-60 membranes. Membranes derived from stimulated HL-60 cells contained 60-70% more ARF as compared with membranes derived from control cells. Membrane contents of ARF were assessed by Western blotting with the anti-ARF monoclonal antibody 1D9 followed by densitometric evaluation. Therefore, ARF translocation correlates with the potentiation of the GTP gamma S-stimulated PLD activity. The effect on PLD activity and ARF membrane content achieved through fMLP stimulation was greatly enhanced by prior treatment of the cells with cytochalasin B. Membranes derived from control and fMLP-stimulated cells were assayed for PLD activity in the presence of exogenous ARF and a 50-kDa fraction known to contain elements implicated in PLD activation. The ability of ARF and the 50-kDa fraction to enhance GTP gamma S-sensitive PLD activity was significantly reduced when the membranes were derived from fMLP-stimulated cells. The data indicate that, in addition to ARF, elements of the 50-kDa PLD-inducing factors were likely already translocated to the membranes upon stimulation. We propose that ARF, upon stimulation with agonists such as fMLP or phorbol esters, is translocated to the membrane and in concert with other protein components of the 50-kDa fraction enhances PLD 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.

Apical release of base-labile fatty acyl groups commensurate with stimulation of glycoprotein sialosyl Lewis(a) secretion in colorectal carcinoma cells

The rate of polarized secretion of a putative adhesion ligand, sialosyl Lewis(a) (19-9), by SW1116 colorectal carcinoma cells is stimulated at least 20-fold after pre-incubation with, and the incorporation of, retinoic acid (RA). In order to investigate the possible involvement of fatty acylation in the export of the epitope, purified ligands from carcinoma-cell membranes, membrane subfractions and media were analyzed during RA-induced secretion. Incorporation of radioactivity from (3H)palmitate into membrane subfractions and purified sialosyl Lewis(a) antigenic molecular species of M(r) > 150,000 (SiaLeams) was stimulated by RA treatment. Most of the intracellular lipid radioactivity which bound to solid-phase 19-9 antibody behaved chromatographically, either like ganglioside or like NH2 OH-labile acyl groups, but most of the (3H) bound to SiaLeams of post-incubation media behaved like base-labile fatty acyl groups, or free fatty acid. Release of base-labile lipid radioactivity after 3 hr (associated with antigen) was almost exclusively into the apical media of membrane inserts. Gas-liquid chromatography/mass spec. analyses of purified Sialeams revealed the presence of palmitate (16:0), as well as stearate (18:0) and oleate (18:1) fatty acyl groups. Our results suggest that fatty acylation of SiaLeams may be co-ordinated with alterations in glycosylation and participate in directing these molecules to the apical surface. Lipid analyses were consistent with ganglioside chaperonage of SiaLeams to the apical surface, where N-fatty-acylated gangliosides remain for the most part integrated into the bilayer, but some oxyester or thioester bonds may be cleaved to permit release of SiaLeams to the apical medium.

Protein farnesyltransferase: kinetics of farnesyl pyrophosphate binding and product release

Protein farnesyltransferase (FTase) catalyzes the prenylation of Ras and several other key proteins involved in cell regulation. The mechanism of the FTase reaction was elucidated by pre-steady-state and steady-state kinetic analysis. FTase catalyzed the farnesylation of biotinylated peptide substrate (BiopepSH) by farnesyl pyrophosphate (FPP) to an S-farnesylated peptide (BiopepS-C15). The steady-state kinetic mechanism was ordered. FTase bound FPP in a two-step process with an effective dissociation rate constant of 0.013 s-1 and an overall Kd of 2.8 nM. BiopepSH reacted with FTase.FPP irreversibly, with a second-order rate constant of 2.2 x 10(5) M-1 s-1, to form FTase.BiopepS-C15. Because most of the FPP in FTase.FPP was trapped as FTase.BiopepS-C15 at high concentrations of BiopepSH, FPP dissociated slowly from the ternary complex relative to catalysis, so that the commitment to catalysis was high. The maximal rate constant for formation of FTase.BiopepS-C15 (enzyme-bound product) is much larger than kcat (0.06 s-1), indicating that product release is the rate-determining step in the reaction mechanism.

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.

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.

Receptors and G proteins as primary components of transmembrane signal transduction. Part 2. G proteins: structure and function

Seven-transmembrane receptors signal through nucleotide-binding proteins (G proteins) into the cell. G proteins are membrane-associated proteins composed of three subunits termed alpha, beta and gamma, of which the G alpha subunit classifies the heterotrimer. So far, 23 different mammalian G alpha subunits are known, which are grouped in four subfamilies (Gs, Gi, Gq, G12) on the basis of their amino acid similarity. They carry an endogenous GTPase activity allowing reversible functional coupling between ligand-bound receptors and effectors such as enzymes and ion channels. In addition, five G beta and seven G gamma subunits have been identified which form tightly associated beta gamma heterodimers. Upon activation by a ligand-bound receptor the G protein dissociates into G alpha and G beta gamma, which both transmit signal by interacting with effectors. On the G protein level, specificity and selectivity of the incoming signal is accomplished by G protein trimers composed of distinct subunits. On the other hand, many receptors have been shown to activate different G proteins, thereby regulating diverse signal transduction pathways.

Agonist-modulated palmitoylation of endothelial nitric oxide synthase

The nitric oxide synthases (NOS) comprise a family of enzymes which differ in primary structure, biological roles, subcellular distribution, and post-translational modifications. The endothelial nitric oxide synthase (ec-NOS) is unique among the NOS isoforms in being modified by N-terminal myristoylation, which is necessary for its targeting to the endothelial cell membrane. The subcellular localization of the ecNOS, but not enzyme myristoylation, is dynamically regulated by agonists such as bradykinin, which promote ecNOS translocation from membrane to cytosol, as well as enhancing enzyme phosphorylation. Using transiently transfected endothelial cells, we now show that a myristoylation-deficient mutant ecNOS undergoes phosphorylation despite restriction to the cytosol, suggesting that phosphorylation may be a consequence rather than a cause of ecNOS translocation. We therefore explored whether other post-translational modifications might regulate ecNOS targeting and now report that ecNOS is reversibly palmitoylated. Biosynthetic labeling of endothelial cells with [3H]palmitic acid followed by immunoprecipitation of ecNOS revealed that the enzyme is palmitoylated; the label is released by hydroxylamine, consistent with formation of a fatty acyl thioester, and authentic palmitate can be recovered from labeled ecNOS following acid hydrolysis. Importantly, pulse-chase experiments in endothelial cells biosynthetically labeled with [3H]palmitate show that bradykinin treatment promotes ecNOS depalmitoylation. We conclude that ecNOS palmitoylation is dynamically regulated by bradykinin and propose that depalmitoylation of the enzyme may result in its cytosolic translocation and subsequent phosphorylation.

Effect of transmembrane Ca2+ gradient on Gs function

Gs and adenylate cyclase from bovine brain cortices were co-reconstituted into asolectin liposomes with or without 1000-fold transmembrane Ca2+ gradient. Obtained results showed that Gs activities of both binding GTP gamma S and stimulating adenylate cyclase were the highest in proteoliposomes, with a transmembrane Ca2+ gradient similar to the physiological situation and the lowest while the transmembrane Ca2+ gradient was in the inverse direction. Such a difference could be diminished following the dissipation of the transmembrane Ca2+ gradient by A23187. Time-resolved fluorescence anisotropy of diphenylhexatriene (DPH) has been used to compare the physical state of phospholipids among those proteoliposomes. It is suggested that a proper transmembrane Ca2+ gradient is essential for higher membrane fluidity, which may favor Gs function with higher GTP-binding activity and stimulation of adenylate cyclase.

Palmitoylation but not the extreme amino-terminus of Gq alpha is required for coupling to the NK2 receptor

Gq alpha and G11 alpha differ from other G protein alpha subunits in that they have unique, conserved 6 residue amino-terminal extensions. Wild-type and amino-terminal mutants of Gq alpha expressed in COS cells were analyzed for their ability to functionally couple with co-expressed neurokinin NK2 receptor. Wild-type, T2A and delta 2-7 Gq alpha were able to stimulate agonist driven phospholipase C (PLC) activity in identical manners. Other activities of these two amino-terminal mutants including aluminum fluoride stimulated PLC activity, palmitoylation, interaction with G beta gamma subunits and GTP gamma S-induced trypsin resistance are also similar to the wild-type alpha subunit. This demonstrates that the NK2 receptor is able to functionally interact with the alpha subunit of Gq and that the first seven amino-acids of Gq alpha are not required for any of the alpha subunit functions tested. In contrast to the T2A and delta 2-7 mutants, a C9,10A Gq alpha mutant was not able to couple to either the NK2 receptor or PLC, as assessed by high-affinity agonist binding and activation of PLC either in intact cells or in vitro. The C9,10A protein was able to assume a GTP gamma S-induced trypsin-resistant conformation and partitioned primarily to the pelletable fraction in a manner similar to the wild-type protein. However, it was not labeled with [3H]palmitic acid. This suggests that blocking palmitoylation at the amino-terminus of Gq alpha results in a loss of functional activity which reflects an inability to interact with both the receptor and downstream signaling targets.

Complex information processing by the transmembrane signaling system involving G proteins

Much of the information cells receive is transduced by a membranous signaling system that uses heterotrimeric guanine nucleotide binding proteins (G proteins) to functionally couple cell surface receptors to a variety of effectors. During recent years it has been shown that receptors, G protein alpha, beta and gamma subunits as well as effectors involved in this signaling system exhibit a remarkable structural diversity and that the interactions of these components display a bewildering complexity. Even though many questions remain to be answered, it is becoming obvious that G proteins form the basis of a complex membranous signaling network which allows the cell to coordinate and to process incoming signals already on the level of the plasma membrane.