The complex regulation of receptor-coupled G-proteins.

Heterotrimeric G-proteins are associated with the cytoplasmic surface of the cell membrane as oligomeric structures. The oligomeric structures were deduced from a variety of studies including target (irradiation) analysis, hydrodynamic evaluation of detergent extracted material, and cross-linking of G-proteins in their membrane environment. From the functional mass determined by target analysis, it was estimated that one receptor (for glucagon) is associated with 8-10 units of Gs, the heterotrimeric G-protein that stimulates adenylyl cyclase. It is proposed that the receptor associates with each monomer of the chain via weak and strong binding forces that are dictated according to whether either GTP or GDP is bound to the alpha-subunits (weak forces) or, due to the hormone-induced release of the nucleotides during the exchange reaction, these subunits become transiently devoid of nucleotides (strong forces). The hormone-induced changes in type and degree of nucleotide binding allow for movement of the receptor along the oligomeric chain and filling of the nucleotide binding sites with the activating nucleotide, GTP. In this manner, the receptor catalytically activates Gs. It is suggested that the dynamic instability of the oligomeric chain produced by the asymmetric distribution of GTP and GDP along the chain results in release of a GTP-monomer from one end and association of a GDP-monomer at the opposite end. Adenylyl cyclase associates with the released GTP-monomer inducing a transient state of the coupled proteins. In a Mg-dependent fashion, hydrolysis of GTP occurs resulting in re-organization of the coupled proteins such that alpha and beta gamma interact with distinct domains of the cyclase molecule. The final state of the coupled process determines the degree of cyclase activity. Release of Pi from its binding site restores association of alpha and beta gamma to the GDP-bound form of the heterotrimer. The latter associates with the oligomeric structure of G-proteins to complete the cycle of events in the overall process of hormonal activation of the system.

G proteins: out of the cytoskeletal closet.

This article contains a brief review of GTP-binding proteins (G protein) signaling mechanism with emphasis on accumulated information which suggests that G proteins are multimeric proteins structured such that one receptor can catalytically activate each of the monomers as it moves in an oscillatory fashion along the multimeric chain. Movement is dictated by the binding of GTP or GDP controlled by the exchange reaction induced by agonist binding to the receptor. Based on the dynamic instability model for the interactions of myosin and F-actin, the hypothesis is presented that a GTP-bound monomer is released from one end of the multimer allowing it to interact with effectors such as adenylyl cyclase embedded in the plasma membrane. Association with the enzyme results in a transition, state of the enzyme-G protein complex. In the presence of magnesium, the GTPase on the alpha-subunit of Gs (which stimulates adenylyl cyclase is activated, resulting in the interaction of the alpha- and beta gamma-subunits of Gs with different domains of adenylyl cyclase. In this fashion, the GTPase is not simply a turn off mechanism, but induces a new configuration of the G protein cyclase complex allowing for greatly enhanced cyclic AMP formation. Dissociation of bound Pi may be one of the rate-limiting steps allowing for cycling of G proteins between the multimer receptor complex and adenylyl cyclase.

The disaggregation theory of signal transduction revisited: further evidence that G proteins are multimeric and disaggregate to monomers when activated.

We have compared the sedimentation rates on sucrose gradients of the heterotrimeric GTP-binding regulatory (G) proteins Gs, G(o), Gi, and Gq extracted from rat brain synaptoneurosomes with Lubrol and digitonin. The individual alpha and beta subunits were monitored with specific antisera. In all cases, both subunits cosedimented, indicating that the subunits are likely complexed as heterotrimers. When extracted with Lubrol all of the G proteins sedimented with rates of about 4.5 S (consistent with heterotrimers) whereas digitonin extracted 60% of the G proteins with peaks at 11 S; 40% pelleted as larger structures. Digitonin-extracted Gi was cross-linked by p-phenylenedimaleimide, yielding structures too large to enter polyacrylamide gels. No cross-linking of Lubrol-extracted Gi occurred. Treatment of the membranes with guanosine 5'-[gamma-thio]triphosphate and Mg2+ yielded digitonin-extracted structures with peak sedimentation values of 8.5 S--i.e., comparable to that of purified G(o) in digitonin and considerably larger than the Lubrol-extracted 2S structures representing the separated alpha and beta gamma subunits formed by the actions of guanosine 5'-[gamma-thio]triphosphate. It is concluded that the multimeric structures of G proteins in brain membranes are at least partially preserved in digitonin and that activation of these structures in membranes yields monomers of G proteins rather than the disaggregated products (alpha and beta gamma complexes) observed in Lubrol. It is proposed that hormones and GTP affect the dynamic interplay between multimeric G proteins and receptors in a fashion analogous to the actions of ATP on the dynamic interactions between myosin and actin filaments. Signal transduction is mediated by activated monomers released from the multimers during the activation process.

Heterotrimeric G proteins in synaptoneurosome membranes are crosslinked by p-phenylenedimaleimide, yielding structures comparable in size to crosslinked tubulin and F-actin.

We have treated rat brain synaptoneurosomes with the crosslinking agent N,N'-1,4-phenylenedimaleimide under conditions that cause extensive crosslinking of tubulin, F-actin, and the alpha and beta subunits of three major types of heterotrimeric GTP-binding regulatory proteins (G(o), Gs, Gi) present in brain membranes. The major crosslinked products are coeluted from Bio-Gel sizing columns as very large structures that do not penetrate stacking gels during SDS/PAGE. The alpha subunits but not the beta subunits of Gs, G(o) and Gi also yield crosslinked products of intermediate sizes. None of the products are as small as the heterotrimeric G proteins extracted from brain by cholate or Lubrol. However, the large and intermediate crosslinked structures are strikingly similar to the large, polydisperse structures of the alpha subunits of Gs, Gi, and G(o) extracted from synaptoneurosomes by the detergent octyl glucoside, which have sedimentation properties of multimeric proteins. Several ways in which multimeric forms of G proteins can explain the dynamic and pleiotropic actions of hormones and GTP on signal-transducing systems are discussed.

Glucagon induces disaggregation of polymer-like structures of the alpha subunit of the stimulatory G protein in liver membranes.

The hydrodynamic behavior of G alpha s, the alpha subunit of the stimulatory guanine nucleotide-binding regulatory protein (G protein), in octyl glucoside extracts of rat liver membranes was investigated. As was previously shown for G proteins similarly extracted from brain synaptoneurosomes, G alpha s behaved as polydisperse structures with S values higher than that of heterotrimeric G proteins. At concentrations of guanosine 5'-[gamma-thio]triphosphate (GTP[gamma S]) greater than 100 microM, incubation with membranes led to smaller structures having S values in the range of 4-5 S. Incubation of liver membranes with glucagon also caused a marked increase in structures having these S values; glucagon action required the presence of low concentrations of GTP[gamma S] (maximal, 10 microM), was rapid (within 10 sec), and was not observed with vasopressin, angiotensin II, or glucagon-(19-29). When G alpha s in its membrane-bound form was [32P]ADP-ribosylated by cholera toxin and the treated membranes were extracted with octyl glucoside, greater than 35% of the labeled G alpha s was found in material that sedimented through sucrose gradients and contained relatively low levels of immunoreactive G alpha s. Glucagon selectively converted the apparently large molecular weight structures to the 4-5 S structures in the presence of GTP[gamma S], even at 1 mM (the maximal effect of the nucleotide alone), when incubated with the toxin-treated membranes. These findings suggest that the glucagon receptor selectively interacts with polymer-like structures of G alpha s and that activation by GTP[gamma S] results in disaggregation. The role of the beta and gamma subunits of G proteins in the hormone-induced process is not clear since the polymer-like structures extracted with octyl glucoside are devoid of beta and gamma subunits.

Carbachol-activated muscarinic (M1 and M3) receptors transfected into Chinese hamster ovary cells inhibit trafficking of endosomes.

We examined the effects of isoproterenol and carbachol on fluid-phase endocytosis by Chinese hamster ovary (CHO) cells transfected with beta-adrenergic, M1, or M3 cholinergic receptors. Isoproterenol increased cAMP production and carbachol increased intracellular Ca, indicating successful expression of the receptor genes and coupling to typical signal transduction pathways. Carbachol inhibited the uptake of horseradish peroxidase (HRP) or Lucifer yellow (markers of fluid-phase endocytosis) in both M1- and M3-containing cells but not in wild-type cells, whereas isoproterenol did not affect pinocytosis in cells transfected with beta-adrenergic receptors. Carbachol inhibited the transit of HRP from an exchangeable pool to a nonexchangeable pool by a latent process requiring minimally 5 min of incubation. During the latent period, only one peak of low-density HRP-containing vesicles was found on Percoll gradients; after 5 min, HRP appeared in both high- and low-density vesicles. Carbachol-treated cells contained less HRP in the high-density fraction enriched in lysosomal markers. Early endosomes from CHO cells labeled for 5 min with HRP underwent fusion to make a more dense population of vesicles in the presence of ATP and KCl at 37 degrees C but not at 4 degrees C. The fused material contained increased levels of G proteins as detected either by ADP ribosylation with appropriate toxins or by immunoblotting with specific antibodies. These findings suggest that GTP binding proteins are internalized in endocytic vesicles and enter into a complex trafficking process involving fusion with other vesicular compartments. Trafficking of endosomes to these compartments is inhibited by activated M1 and M3 muscarinic receptors in CHO cells.

Microsomal and cytosolic fractions of guinea pig hepatocytes contain 100-kilodalton GTP-binding proteins reactive with antisera against alpha subunits of stimulatory and inhibitory heterotrimeric GTP-binding proteins.

Guinea pig hepatocytes fractionated by differential centrifugation into plasma membrane-enriched, microsomal, and cytosolic fractions were examined for their content of alpha and beta subunits of heterotrimeric GTP-binding proteins (G proteins) involved in signal transduction. alpha subunits of stimulatory (Gs) and inhibitory (Gi) proteins were detected by immunoblots with antisera reactive with the carboxyl-terminal decapeptide regions of these proteins. Unexpectedly, antisera (including immunopurified) to the alpha subunit but not the beta subunit reacted with a band of 100-kDa proteins in both the microsomal and cytosolic fractions. The immunoreactive 100-kDa proteins are not substrates for ADP-ribosylation catalyzed by pertussis toxin, cholera toxin, or diptheria toxin. Protease digests of the 100-kDa proteins yielded immunoreactive peptides that are distinctly different from those obtained from protease digests of alpha subunits of heterotrimeric G proteins. The 100-kDa protein(s) reactive with antisera to Gi alpha subunit bind to GTP-agarose but not to ATP-agarose. It is concluded that the immunoreactive 100-kDa proteins in microsomal and cytosolic fractions are structurally distinct G proteins from those linked to receptors in the plasma membrane and other G proteins such as elongation factor 2. Conceivably, the 100-kDa proteins represent a new class of G proteins.

Octyl glucoside extracts GTP-binding regulatory proteins from rat brain "synaptoneurosomes" as large, polydisperse structures devoid of beta gamma complexes and sensitive to disaggregation by guanine nucleotides.

GTP-binding regulatory proteins are generally purified from cholate-extracted membranes in the form of heterotrimers (G proteins) consisting of a GTP-binding subunit (alpha protein) complexed with a tightly interacted heterodimer termed beta gamma. In this study we extracted the proteins from rat brain "synaptoneurosomes" using the neutral detergent 1-octyl beta-D-glucopyranoside (octyl glucoside). Using specific antibodies for detection by immunoblotting and sucrose gradients for analyzing hydrodynamic properties, we found that each species of alpha protein (alpha subunits of stimulatory, inhibitory, and brain GTP-binding proteins) exhibited a broad range (4 S to greater than 12 S) of polydisperse structures with peak values (5 S to 7 S) considerably greater than that of heterotrimeric G proteins. The beta subunit proteins, for example, appeared as a homogeneous peak at 4.4 S within which only a fraction of the total alpha proteins can be associated. Incubation of octyl glucose extracts at 30 degrees C rapidly sedimented the alpha proteins but not the beta proteins. Incubation at 30 degrees C with guanosine 5'[gamma-thio]triphosphate (10-100 microM) prevented rapid sedimentation. Hydrodynamic analysis revealed that all alpha proteins were converted to approximately 4 S structures by the actions of guanosine 5'-[gamma-thio]triphosphate without change in the hydrodynamic properties of the beta proteins. Extraction of the membranes with sodium cholate instead of octyl glucoside resulted in complete loss of the large, polydisperse structures of the alpha proteins; the S values were approximately 4 S, in the range for beta proteins. These findings suggest that the transducing GTP-binding proteins in synaptoneurosomes exist as polydisperse, possibly multimer, structures of various size that are stable in octyl glucoside but destroyed by cholate. The polydisperse structures are not associated with beta gamma complexes and are sensitive to the disaggregating effects of guanosine 5'-[gamma-thio]triphosphate.

Isoproterenol stimulates shift of G proteins from plasma membrane to pinocytotic vesicles in rat adipocytes: a possible means of signal dissemination.

Guanine nucleotide-binding regulatory proteins (G proteins) are linked to a large number of surface membrane receptors and appear to regulate a variety of effector systems located both in the plasma membrane and in other parts of the cell. The mechanism of the disseminative actions of G proteins remains obscure. During an investigation of the fate of two types of G proteins, Gs and Gi, in rat adipocytes, we unexpectedly found that isoproterenol, which stimulates cAMP levels and lipolysis in these cells, induces parallel increases in both Gs and Gi in a low-density microsomal fraction rich in endosomes and Golgi bodies. Two plasma membrane constitutive enzymes, adenylyl cyclase and 5'-nucleotidase, are also elevated in this fraction. NaF and NaN3, metabolic inhibitors, block the redistribution process. The isoproterenol-stimulated shifts are completely reversible after removal of the hormone, indicating a recycling, endocytic process. The endocytic process seems to be fluid phase endocytosis, or pinocytosis, since isoproterenol stimulates the uptake of both fluorescent-labeled dextran and horseradish peroxidase into the same vesicles containing Gs. However, the vesicles that accumulate in response to isoproterenol seem heterogenous in properties that may reflect the lipolytic process induced by isoproterenol. It is speculated that the "pinosomes" formed in response to lipolytic hormones may continually produce signals within the cellular interior during their processing and cycling. Hence, signal production in response to hormones need not be confined to the cell membrane; circulating pinosomes may be responsible for some of the disseminative effects of hormones.

Pertussis toxin induces structural changes in G alpha proteins independently of ADP-ribosylation.

Pertussis toxin catalyzes ADP-ribosylation of a family of GTP-binding proteins (G alpha proteins) involved in signal transduction. It is thought that this activity is responsible for the attenuating effects of the toxin on the actions of a number of hormones and neurotransmitters. By utilizing specific antisera for detecting on electrophoretic transfer blots (Western blots) alpha proteins that are subject to ADP-ribosylation, it was found that treatment of these proteins with pertussis toxin resulted in shifts in their electrophoretic mobility and marked enhancement of their immunoreactivity compared to untreated proteins. No changes in mobility or immunoreactivity with specific antisera were observed with beta subunits of G proteins. Both effects on alpha proteins required the same ingredients, including detergents, ATP, and sulfhydryl reducing agents, that other studies have shown are required for activation of the ADP-ribosylating activity of pertussis toxin. However, NAD+, the substrate for ADP-ribosylating activity, was not required. Moreover, inhibition of the ADP-ribosylating activity by 50 mM nicotinamide failed to block the NAD-independent effects of the toxin. These findings indicate that the toxin induces structural changes in alpha proteins independently of its ADP-ribosylating activity and raise the possibility that these structural changes are primary to ADP-ribosylation and causative of many of the biological effects of pertussis toxin.

Photoaffinity labeling of the glucagon receptor with a new glucagon analog.

The preparation, purification and characterization of N epsilon-4- azidophenylamidinoglucagon are described. This photoreactive peptide was found to be 50% as potent as native glucagon in competing with 125I-labeled glucagon for binding to glucagon receptors on rat liver plasma membranes. Similarly, the analog was 50% as potent as native glucagon in its ability to stimulate adenylate cyclase. The photoreactive glucagon analog was radioiodinated to high specific activity with iodine-125 and was used to label rat liver plasma membrane proteins. Analysis of labeled membrane proteins by sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed covalent incorporation predominantly into a protein of relative molecular mass, Mr, of 50 000-60 000. Occasionally a protein of Mr 170 000-180 000 was also labeled. Irradiation of membranes in the presence of unlabeled glucagon or GTP selectively inhibited the labeling of the 50 000-60 000-Mr protein(s). As a result of these studies we suggest that the sodium-dodecyl-sulfate-dissociated glucagon receptor is a 50 000-60 000-Mr protein.

Identification and characterization of the rat adipocyte glucose transporter by photoaffinity crosslinking.

The photoaffinity crosslinking agent hydroxysuccinimidyl-4-azidobenzoate has been used to attach [3H]cytochalasin B to a rat adipocyte low-density microsomal membrane protein of 45-50 kDa. The characteristics of the [3H]cytochalasin B-labeled protein are consistent with those of the adipocyte glucose transporter. The low-density microsomes from cells incubated without insulin incorporate twice the amount of radioactivity per mg membrane protein than low-density microsomes derived from insulin-stimulated cells. This value agrees with the distribution of glucose transporters measured in this intracellular membrane fraction prepared from basal and insulin-treated cells by [3H]cytochalasin B binding. Preincubation of membranes with 500 mM D-glucose reduces the photoaffinity crosslinking by 48% relative to that observed with 500 mM L-glucose. Isoelectric focusing of low-density microsomes containing the photoaffinity crosslinked transporter yields three bands of radioactivity focusing at pH values of 5.5, 4.5, and 4.2 respectively. Following isolation from the isoelectric focusing gel and SDS-polyacrylamide gel electrophoresis, all three peaks can be shown to contain a band of 45-50 kDa which crossreacts with an antiserum raised against the purified human erythrocyte glucose transporter. These results suggest that the identification, isolation and purification of the adipocyte glucose transporter is now possible using the techniques described above.

Proposed mechanism of insulin-resistant glucose transport in the isolated guinea pig adipocyte. Small intracellular pool of glucose transporters.

A marked resistance to the stimulatory action of insulin on glucose metabolism has previously been shown in guinea pig, compared to rat, adipose tissue and isolated adipocytes. The mechanism of insulin resistance in isolated guinea pig adipocytes has, therefore, been examined by measuring 125I-insulin binding, the stimulatory effect of insulin on 3-0-methylglucose transport and on lipogenesis from [3-3H]glucose, the inhibitory effect of insulin on glucagon-stimulated glycerol release, and the translocation of glucose transporters in response to insulin. The translocation of glucose transporters was assessed by measuring the distribution of specific D-glucose-inhibitable [3H]cytochalasin B binding sites among the plasma, and high and low density microsomal membrane fractions prepared by differential centrifugation from basal and insulin-stimulated cells. At a glucose concentration (0.5 mM) where transport is thought to be rate-limiting for metabolism, insulin stimulates lipogenesis from 30 to 80 fmol/cell/90 min in guinea pig cells and from 25 to 380 fmol/cell/90 min in rat cells with half-maximal effects at approximately 100 pM in both cell types. Insulin similarly stimulates 3-O-methylglucose transport from 0.40 to 0.70 fmol/cell/min and from 0.24 to 3.60 fmol/cell/min in guinea pig and rat fat cells, respectively. Nevertheless, guinea pig cells bind more insulin per cell than rat cells, and insulin fully inhibits glucagon-stimulated glycerol release. In addition, the differences between guinea pig and rat cells in the stimulatory effect of insulin on lipogenesis and 3-O-methylglucose transport cannot be explained by the greater cell size of the former compared to the latter (0.18 and 0.09 micrograms of lipid/cell, respectively). However, the number of glucose transporters in the low density microsomal membrane fraction prepared from basal guinea pig cells is markedly reduced compared to that from rat fat cells (12 and 70 pmol/mg of membrane protein, respectively) and the translocation of intracellular glucose transporters to the plasma membrane fraction in response to insulin is correspondingly reduced. These results suggest that guinea pig adipocytes are markedly resistant to the stimulatory action of insulin on glucose transport and that this resistance is the consequence of a relative depletion in the number of intracellular glucose transporters.