Membrane curvature and the control of GTP hydrolysis in Arf1 during COPI vesicle formation.

The GTP switch of the small G-protein Arf1 (ADP-ribosylation factor 1) on lipid membranes promotes the polymerization of the COPI (coat protein complex I) coat, which acts as a membrane deforming shell to form transport vesicles. Real-time measurements for coat assembly on liposomes gives insights into how the GTPase cycle of Arf1 is coupled in time with the polymerization of the COPI coat and the resulting membrane deformation. One key parameter seems to be the membrane curvature. Arf-GAP1 (where GAP stands for GTPase-activating protein), which promotes GTP hydrolysis in the Arf1-COPI complex is highly sensitive to lipid packing. Its activity on Arf1-GTP increases by two orders of magnitude as the diameter of the liposomes approaches that of authentic transport vesicles (60 nm). This suggests that during membrane budding, Arf1-GTP molecules are progressively eliminated from the coated area where the membrane curvature is positive, but are protected from Arf-GAP1 at the bud neck due to the negative curvature of this region. As a result, the coat should be stable as long as the bud remains attached and should disassemble as soon as membrane fission occurs.

Role of protein-phospholipid interactions in the activation of ARF1 by the guanine nucleotide exchange factor Arno.

Arno is a 47-kDa human protein recently identified as a guanine nucleotide exchange factor for ADP ribosylation factor 1 (ARF1) with a central Sec7 domain responsible for the exchange activity and a carboxyl-terminal pleckstrin homology (PH) domain (Chardin, P., Paris, S., Antonny, B., Robineau, S., Béraud-Dufour, S., Jackson, C. L., and Chabre, M. (1996) Nature 384, 481-484). Binding of the PH domain to phosphatidylinositol 4,5-bisphosphate (PIP2) greatly enhances Arno-mediated activation of myristoylated ARF1. We show here that in the absence of phospholipids, Arno promotes nucleotide exchange on [Delta17]ARF1, a soluble mutant of ARF1 lacking the first 17 amino acids. This reaction is unaffected by PIP2, which suggests that the PIP2-PH domain interaction does not directly regulate the catalytic activity of Arno but rather serves to recruit Arno to membranes. Arno catalyzes the release of GDP more efficiently than that of GTP from [Delta17]ARF1, and a stable complex between Arno Sec7 domain and nucleotide-free [Delta17]ARF1 can be isolated. In contrast to [Delta17]ARF1, full-length unmyristoylated ARF1 is not readily activated by Arno in solution. Its activation requires the presence of phospholipids and a reduction of ionic strength and Mg2+ concentration. PIP2 is strongly stimulatory, indicating that binding of Arno to phospholipids is involved, but in addition, electrostatic interactions between phospholipids and the amino-terminal portion of unmyristoylated ARF1GDP seem to be important. We conclude that efficient activation of full-length ARF1 by Arno requires a membrane surface and two distinct protein-phospholipid interactions: one between the PH domain of Arno and PIP2, and the other between amino-terminal cationic residues of ARF1 and anionic phospholipids. The latter interaction is normally induced by insertion of the amino-terminal myristate into the bilayer but can also be artificially facilitated by decreasing Mg2+ and salt concentrations.

G-protein beta gamma subunits mediate specific phosphorylation of the protein-tyrosine phosphatase SH-PTP1 induced by lysophosphatidic acid.

SH-PTP1 is a protein-tyrosine phosphatase preferentially expressed in hematopoietic cells and bearing two SH2 (src homology-2) domains. In the human megakaryocytic cell line Dami, lysophosphatidic acid (LPA) promoted a rapid increase in SH-PTP1 phosphorylation on both serine and tyrosine residues. Only tyrosine phosphorylation was significantly inhibited by pertussis toxin and by the protein kinase C inhibitor GF109203X. Moreover, SH-PTP1 was phosphorylated upon challenge with other agonists acting via G-protein-coupled receptors such as alpha-thrombin, epinephrine, and ADP, whereas the closely related protein-tyrosine phosphatase SH-PTP2 failed to share such a regulation in Dami cells. We developed an in vitro assay that reproduced LPA-dependent phosphorylation of SH-PTP1 in a cell-free system. The fusion protein glutathione S-transferase-beta-adrenergic receptor kinase 1-(495-689) or the transducin subunit Galphat-GDP, which act as specific antagonists of Gbetagamma, inhibited SH-PTP1 phosphorylation. Moreover, purified transducin Gbetagamma subunits mimicked the effect of LPA. Finally, stable expression of beta-adrenergic receptor kinase 1-(495-689) in Dami cells resulted in the inhibition of SH-PTP1 as a specific target of protein kinases linked to G-protein-coupled receptors via Gbetagamma subunits.

Heterologous multimeric assembly is essential for K+ channel activity of neuronal and cardiac G-protein-activated inward rectifiers.

The family of G-protein-activated inward-rectifiers K+ channels presently comprise at least 3 cloned members called GIRK1, GIRK2 and GIRK3. A close structural parent of GIRK channels has recently been described as being an ATP-sensitive K+ channel. This paper shows that Xenopus expression of this new channel that we call GIRK4 does not produce an ATP-inhibitable activity with a pharmacological activation by pinacidil as previously described but instead a G-protein activated inward-rectifier. While oocyte expression of single subunits is infrequent and relatively modest in intensity, expression of GIRK1,2, GIRK1,4 and GIRK2,4 mixtures leads to routine and robust expression of K+ channels indicating that heterologous subunit assembly is necessary for activity. Activity of GIRK1,2, GIRK1,4 and GIRK2,4 channels required the presence of ATP acting as an activator at the cytoplasmic face and is further activated by the beta gamma subunits.

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

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

The mechanism of aluminum-independent G-protein activation by fluoride and magnesium. 31P NMR spectroscopy and fluorescence kinetic studies.

With magnesium present, fluoride and aluminum ions activate heterotrimeric G-proteins by forming AlFx complexes that mimic the gamma phosphate of a GTP. We report compelling evidence for a newly proposed process of G-protein activation by fluoride and magnesium, without Al3+. With millimolar Mg2+ and F-, Gs and Gt activate adenylylcyclase and cGMP-phosphodiesterase, respectively. In 31P NMR, addition of magnesium to Gi1 alpha GDP or Gt alpha GDP solutions containing fluoride, but no Al3+, modifies the chemical shift of the GDP beta phosphorus, suggesting that magnesium interacts with the beta phosphate. Titration of this effect indicates that two Mg2+ are bound per G alpha. Biphasic activation kinetics, monitored by G alpha tryptophan fluorescence, suggests the rapid binding of one Mg2+ to G alpha GDP and the slow association of another Mg2+, in correlation with fluoride binding and G alpha activation. The deactivation rate upon fluoride dilution shows a second order dependence with respect to the residual F- concentration, suggesting the sequential release of at least three F-/G alpha. Thus, in millimolar Mg2+ and F-, and without Al3+, two Mg2+ and three F- bind sequentially to G alpha GDP and induce the switch to an active G alpha (GDP-MgF3)Mg state, which is structurally analogous to G alpha (GDP-AlFx)Mg and to G alpha (GTP)Mg.

Functional modifications of transducin induced by cholera or pertussis-toxin-catalyzed ADP-ribosylation.

Transducin (T alpha beta gamma), the heterotrimeric GTP-binding protein that interacts with photoexcited rhodopsin (Rh*) and the cGMP-phosphodiesterase (PDE) in retinal rod cells, is sensitive to cholera (CTx) and pertussis toxins (PTx), which catalyze the binding of an ADP-ribose to the alpha subunit at Arg174 and Cys347, respectively. These two types of ADP-ribosylations are investigated with transducin in vitro or with reconstituted retinal rod outer-segment membranes. Several functional perturbations inflicted on T alpha by the resulting covalent modifications are studied such as: the binding of T alpha to T beta gamma to the membrane and to Rh*; the spontaneous or Rh*-catalysed exchange of GDP for GTP or guanosine 5-[gamma-thio]triphosphate (GTP[gamma S]), the conformational switch and activation undergone by transducin upon this exchange, the activation of T alpha GDP by fluoride complexes and the activation of the PDE by T alpha GTP. ADP-ribosylation of transducin by CTx requires the GTP-dependent activation of ADP-ribosylation factors (ARF), takes place only on the high-affinity, nucleotide-free complex, Rh*-T alpha empty-T beta gamma and does not activate T alpha. Subsequent to CTx-catalyzed ADP-ribosylation the following occurs: (a) addition of GDP induces the release from Rh* of inactive CTxT alpha GDP (CTxT alpha, ADP-ribosylated alpha subunit of transducin) which remains associated to T beta gamma; (b) CTxT alpha GDP-T beta gamma exhibits the usual slow kinetics of spontaneous exchange of GDP for GTP[gamma S] in the absence of Rh*, but the association and dissociation of fluoride complexes, which act as gamma-phosphate analogs, are kinetically modified, suggesting that the ADP-ribose on Arg174 specifically perturbs binding of the gamma-phosphate in the nucleotide site; (c) CTxT alpha GDP-T beta gamma can still couple to Rh* and undergo fast nucleotide exchange; (d) CTxT alpha GTP[gamma S] and CTxT alpha GDP-AlFx (AlFx, Aluminofluoride complex) activate retinal cGMP-phosphodiesterase (PDE) with the same efficiency as their unmodified counterparts, but the kinetics and affinities of fluoride activation are changed; (e) CTxT alpha GTP hydrolyses GTP more slowly than unmodified T alpha GTP, which entirely accounts for the prolonged action of CTxT alpha GTP on the PDE; (f) after GTP hydrolysis, CTxT alpha GDP reassociates to T beta gamma and becomes inactive. Thus, CTx catalyzed ADP-ribosylation only perturbs in T alpha the GTP-binding domain, but not the conformational switch nor the domains of contact with the T beta gamma subunit, with Rh* and with the PDE.(ABSTRACT TRUNCATED AT 400 WORDS)

A novel magnesium-dependent mechanism for the activation of transducin by fluoride.

Activation of transducin-GDP by NaF is mainly mediated by aluminofluorde or beryllofluoride complexes acting as GTP gamma-phosphate analogs. In millimolar magnesium, NaF at concentrations above 3 mM is active even in the absence of aluminium or beryllium. This activation has a Hill coefficient of 3 with respect to F-, and its rate is linear with respect to Mg2+ concentrations above 2 mM. Upon fluoride dilution, inactivation rate is hundreds of times faster than for aluminofluoride-activated T alpha GDP. We propose that at high NaF concentrations, 3 hydrogen-bonded fluorides in the gamma-phosphate site of T alpha GDP entrap a magnesium counterion and this induces the transconformation to the T alpha GTP form.

cGMP phosphodiesterase of retinal rods is regulated by two inhibitory subunits.

The cGMP phosphodiesterase (PDE) of cattle retinal rod outer segments comprises three types of subunits: the two heavy catalytic ones, PDE alpha and PDE beta, each around 85 kDa, and the light inhibitory one, PDE gamma or I (11 kDa). The relative stoichiometry is usually assumed to be 1:1:1. PDE activation in the visual transduction cascade results from removal of the inhibitor by the alpha subunit of transducin (T alpha). The stoichiometric complex T alpha-I, separated from activated PDE, has been isolated and characterized. Analyzing now the activated PDE, we find that it still contains some inhibitor and is resolvable into two species, one with 50% of the inhibitor content of the native enzyme and the other totally devoid of it. The same two species are observed upon activation of PDE by very short tryptic proteolysis, which specifically degrades the inhibitor. This leads us to conclude that the composition of the native enzyme is PDE alpha beta-I2. The two inhibitory subunits are differentially bound, sequentially removable, and exchangeable between the native complex PDE alpha beta-I2 and the fully active PDE alpha beta. The possibility of this exchange precludes as yet an unambiguous estimate of the actual activity of the intermediate complex PDE alpha beta-I. The differential binding and the exchangeability of the inhibitors raises the possibility of a fast, diffusion controlled, switch-off mechanism of PDE activity after a flash, which would shortcut the inactivation resulting from the slow GTPase rate of transducin.

Fluoride complexes of aluminium or beryllium act on G-proteins as reversibly bound analogues of the gamma phosphate of GTP.

Fluoride activation of G proteins requires the presence of aluminium or beryllium and it has been suggested that AIF4- acts as an analogue of the gamma-phosphate of GTP in the nucleotide site. We have investigated the action of AIF4- or of BeF3- on transducin (T), the G protein of the retinal rods, either indirectly through the activation of cGMP phosphodiesterase, or more directly through their effects on the conformation of transducin itself. In the presence of AIF4- or BeF3-, purified T alpha subunit of transducin activates purified cyclic GMP phosphodiesterase (PDE) in the absence of photoactivated rhodopsin. Activation is totally reversed by elution of fluoride or partially reversed by addition of excess T beta gamma. Activation requires that GDP or a suitable analogue be bound to T alpha: T alpha-GDP and T alpha-GDP alpha S are activable by fluorides, but not T alpha-GDP beta S, nor T alpha that has released its nucleotide upon binding to photoexcited rhodopsin. Analysis of previous works on other G proteins and with other nucleotide analogues confirm that in all cases fluoride activation requires that a GDP unsubstituted at its beta phosphate be bound in T alpha. By contrast with alumino-fluoride complexes, which can adopt various coordination geometries, all beryllium fluoride complexes are tetracoordinated, with a Be-F bond length of 1.55 A, and strictly isomorphous to a phosphate group. Our study confirms that fluoride activation of transducin results from a reversible binding of the metal-fluoride complex in the nucleotide site of T alpha, next to the beta phosphate of GDP, as an analogue of the gamma phosphate.(ABSTRACT TRUNCATED AT 250 WORDS)

The retinal phototransduction process: enzymatic cascade and regulation.

Among cellular systems performing the transduction of an external stimulus, phototransduction in vertebrate rod cells is a unique case which allows convergent approaches to electrophysiological, biophysical and biochemical analyses. The framework of the molecular processes involved in the corresponding enzymatic cascade is now elucidated and can be considered as a model for G protein mediated transductions. We present here the main features of this cascade, its amplification and regulation properties. The mode of stimulation by the aluminofluoride ion is particularly addressed.

Activation of retinal rod cyclic GMP-phosphodiesterase by transducin: characterization of the complex formed by phosphodiesterase inhibitor and transducin alpha-subunit.

The GTP-binding subunit of transducin (T alpha) activates the cGMP phosphodiesterase (PDE) of bovine retinal rods by relieving the constraint imposed by the inhibitory subunit PDE gamma. We have isolated and characterized the complex T alpha.GTP gamma S-PDE gamma formed when T alpha is activated by the nonhydrolyzable analog GTP gamma S. Sedimentation and light-scattering techniques demonstrate that, in contrast to free T alpha.GTP gamma S, which is soluble, the T alpha.GTP gamma S-PDE gamma complex, as well as T alpha.GTP-PDE gamma, is membrane bound at cytosolic ionic strength. It is eluted from the membrane at low ionic strength as a monomeric and 1:1 stoichiometric complex. The relative affinities of PDE gamma for PDE alpha beta and for T alpha.GTP are discussed.

Fluoroaluminates activate transducin-GDP by mimicking the gamma-phosphate of GTP in its binding site.

Fluoride activation of the cGMP cascade of vision requires the presence of aluminum, and is shown to be mediated by the binding of one A1F-4 to the GDP/GTP-binding subunit of transducin. The presence of GDP in the site is required: A1F-4 is ineffective when the site is empty or when GDP beta S is substituted for GDP. This sensitivity to the sulfur of GDP beta S suggests that A1F-4 is in contact with the GDP. Striking structural similarities between A1F-4 and PO3-4 lead us to propose that A1F-4 mimics the role of the gamma-phosphate of GTP.

Tissue expression and phylogenetic appearance of the beta and gamma subunits of GTP binding proteins.

Antibodies raised against the T-beta gamma dimer of bovine retinal transducin specifically bind to the beta and gamma subunits of transducin in calf retina. Tissues from different vertebrates, but not from invertebrates, contained a band comigrating with the beta subunit of transducin (T-beta) which was immunostained. This protein most likely corresponds to the beta subunit of GTP binding proteins of hormonal systems (G-beta). In non-retinal vertebrate membranes, the antibodies did not recognize the gamma subunits of G proteins whereas a band comigrating with bovine T-gamma was detected in frog or rat retina. Although T-beta was precipitated by the T-beta gamma antiserum, we failed to immunoprecipitate the G-beta from calf brain.

Guanine nucleotides and magnesium dependence of the association states of the subunits of transducin.

When GTP gamma S is bound to transducin (T), the two subunits T alpha X GTP gamma S and T beta gamma dissociate, independently of the ionic environment. When GDP is bound, these subunits are associated as a monomeric T alpha X GDP-T beta gamma complex of 75 kDa when the ionic environment is comparable to that of the cytoplasm, but they dissociate in the presence of 10-100 mM Mg2+ or Ca2+. Using this property, the subunits could be separated and purified by a rapid one-step procedure on an ion-exchange column (FPLC), and their molecular masses were verified by neutron small angle scattering. The physiological relevances of the dissociating effect of Mg2+ are discussed.