Stoichiometry for guanine nucleotide binding to tubulin under polymerizing and nonpolymerizing conditions

The maximal stoichiometry for [³H]GTP binding to depolymerized tubulin with saturating amounts of added [³H]GTP is 0.4 mol/110,000 g protein. In contrast, 1 mol of radioactive nucleotide is incorporated into microtubules as a result of polymerization with [³H]GTP. The different stoichiometries result from a difference in the nucleotide binding properties of ring protein under polymerizing and nonpolymerizing conditions: ring protein at 0 °C is devoid of binding activity but binds added radioactive guanine nucleotide during microtubule assembly. The radioactive nucleotide which is incorporated into rings during microtubule assembly is not displaced by excess GDP, although it is at a site which is distinct from the N site.     

Effects of GTP on binding of (3H) glucagon to receptors in rat hepatic plasma membranes.

In this study, we report the preparation of [3H]glucagon and its characteristics of binding to receptors in the rat liver plasma membrane. Binding of the labeled hormone is optimal at pH 7.0. In the absence of GTP, [3H]glucagon binding to receptors is slow and the time of equilibration is inversely proportional to the hormone concentration. In the presence of GTP, equilibrium is reached within 30 s regardless of hormone levels, and the kinetics of binding are in accord with the kinetics of activation of adenylate cyclase by native glucagon in the presence of the nucleotide. Equilibrium binding measurements indicate that, in the absence of GTP, the binding isotherm is sigmoidal with an apparent Kd of 2 nM. The addition of GTP results in a complex binding isotherm with about 90% of the binding sites having a considerably lower apparent dissociation constant (greater than 10 nM) and a small population of sites having high affinity for the hormone. The binding properties of [3H]glucagon are compared with those of 125I-glucagon, and the implications of the actions of GTP on glucagon binding are discussed in relation to the overall regulation of adenylate cyclase by hormone and the nucleotide.     

Guanine Nucleotide Effects on 8-Cyclopentyl-1,3-[3H]Dipropylxanthine Binding to Membrane-Bound and Solubilized A1 Adenosine Receptors of Rat Brain

The effects of guanine nucleotides on binding of 8-cyclopentyl-1,3-[3H]dipropylxanthine ([3H]DPCPX), a highly selective A1 adenosine receptor antagonist, have been investigated in rat brain membranes and solubilized A1 receptors. GTP, which induces uncoupling of receptors from guanine nucleotide binding proteins, increased binding of [3H]DPCPX in a concentration-dependent manner. The rank order of potency for different guanine nucleotides for increasing [3H]DPCPX binding was the same as for guanine nucleotide-induced inhibition of agonist binding. Therefore, a role for a guanine nucleotide binding protein, e.g., Gi, in the regulation of antagonist binding is suggested. This was confirmed by inactivation of Gi by N-ethylmaleimide (NEM) treatment of membranes, which resulted in an increase in [3H]DPCPX binding similar to that seen with addition of GTP. Kinetic and equilibrium binding studies showed that the GTP- or NEM-induced increase in antagonist binding was not caused by an affinity change of A1 receptors for [3H]DPCPX but by an increased Bmax value. Guanine nucleotides had similar effects on membrane-bound and solubilized receptors, with the effects in the solubilized system being more pronounced. In the absence of GTP, when most receptors are in a high-affinity state for agonists, only a few receptors are labeled by [3H]DPCPX. It is suggested that [3H]DPCPX binding is inhibited when receptors are coupled to Gi. Therefore, uncoupling of A1 receptors from Gi by guanine nucleotides or by inactivation of Gi with NEM results in an increased antagonist binding.     

Metabolism of 2-deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose in yeast and chick-embryo cells.

2-Deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose have been prepared by tritiation of the corresponding unlabeled 2-fluoro sugars. The tritiated 2-fluoro sugars are phosphorylated and activated by UTP and by GTP to yield UDP-2-deoxy-2-fluoro-D-[3H]glucose, UDP-2-deoxy-2-fluoro-D-[3H]mannose, GDP-2-deoxy-2-fluoro-D-[3H]glucose and GDP-2-deoxy-2-fluoro-D-[3H]mannose in both cell types. The nucleotide derivatives could also be labeled in the nucleotide moiety by feeding the cells with [14C]uridine or [14C]guanosine in the presence of unlabeled 2-fluoro sugar. No evidence was obtained for metabolic steps in which the six-carbon chain of 2-fluoro sugars was not preserved. No epimerisation of the label to 2-deoxy-2-fluoro-D-[3H]galactose could be observed by radioactive gas-liquid chromatography of the enzymatic cleavage products of the different 2-fluoro sugar metabolites isolated from either cell type. Yeast and chick embryo cells both incorporate 2-deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose specifically into glycoproteins, although this incorporation is very low when compared to the incorporation of 2-deoxy-D-[3H]glucose.     

Characterization of [3H]Guanine Nucleotide Binding Sites in Brain Membranes

[3H]GTP [guanosine triphosphate] and [3H]GMP-PNP [guanosine 5'-(beta, 8-imino)triphosphate, a nonmetabolized analog of GTP] have been utilized as ligands to characterize binding sites of guanine nucleotides to rat brain membranes. Binding of both [3H]GTP and [3H]GMP-PNP is saturable, with respective KD values of 0.76 and 0.42 microM. The number of binding sites for GMP-PNP (4 nmol/g) is three times greater than for GTP (1.5 nmol/g). This discrepancy is caused by rapid degradation of GTP to guanosine by brain membranes, which can be partially prevented by addition of 100 microM-ATP. The binding of [3H]guanine nucleotides is selective, with approximately equipotent inhibition by GTP, GDP, and GMP-PNP (at 0.2--1.0 microM), but no inhibition by other nucleotides at 100 microM concentrations. The bindings sites for guanine nucleotides in brain membranes appear not to be associated with microtubules, since treatments that reduce [3H]colchicine binding by 65% have no effect on [3H]GTP binding. [3H]Guanine nucleotide binding is widely distributed in various organs, with highest levels in liver and brain and lowest levels in skeletal muscle. The characteristics of these binding sites in brain show specificity properties of sites that regulate neurotransmitter receptors and adenylate cyclase.     

Modulation of 5-Hydroxytryptamine1A Receptor Density by Nonhydrolyzable GTP Analogues

Co-incubation of rat cortical membranes with 10(-4) M GTP results in a competitive inhibition of 5-hydroxytryptamine1A (5-HT1A) receptor binding sites labeled by [3H]8-hydroxy-2-(di-n-propylamino)tetralin [( 3H]8-OH-DPAT). Preincubation of cortical membranes with 10(-4) M GTP does not significantly change either KD or Bmax values, indicating that the effect of GTP is reversible. By contrast, GTP gamma S and 5'-guanylylimidodiphosphate (GppNHp) are nonhydrolyzable analogues of GTP which lengthen the time course of guanine nucleotide activation of guanine nucleotide binding proteins (G proteins) and thereby alter G protein-receptor interactions. These nonhydrolyzable GTP analogues were used to characterize the effects of persistent alterations in G proteins on [3H]8-OH-DPAT binding to 5-HT1A receptors. Co-incubation of rat cortical membranes with either 10(-4) M GTP gamma S or GppNHp results in a decrease in both the affinity and apparent density of 5-HT1A binding sites. Co-incubation with the nonhydrolyzable nucleotides reduces the affinity of [3H]8-OH-DPAT binding by 65-70% and lowers the density of the binding site by 53-61%. Similarly, preincubation of membranes with a 10(-4) M concentration of either GTP gamma S or GppNHp significantly increases the KD value and reduces the Bmax value of [3H]8-OH-DPAT binding. These results indicate that GTP gamma S and GppNHp induce persistent changes in 5-HT1A receptor-G protein interactions that are reflected as a decrease in the density of binding sites labeled by [3H]8-OH-DPAT.     

Role of GTP hydrolysis in microtubule polymerization: evidence for a coupled hydrolysis mechanism

The relationship between GTP hydrolysis and microtubule assembly has been investigated by using a rapid filtration method. Microtubules assembled from phosphocellulose-purified tubulin, double-labeled with [gamma-32P]- and [3H]GTP, were trapped and washed free of unbound nucleotide on glass fiber filters. The transient accumulation of microtubule-bound GTP predicted by uncoupled GTP hydrolysis models [Carlier & Pantaloni (1981) Biochemistry 20, 1918-1924; Carlier et al. (1987) Biochemistry 26, 4428-4437] during the rapid assembly of microtubules was not detectable under our experimental conditions. By calculating hypothetical time courses for the transient accumulation of microtubule-bound GTP, we demonstrate that microtubule-bound GTP would have been detectable even if the first-order rate constant for GTP hydrolysis were 4-5 times greater than the pseudo-first-order rate constant for tubulin subunit addition to microtubules. In a similar manner, we demonstrate that if GTP hydrolysis were uncoupled from microtubule assembly but were limited to the interface between GTP subunits and GDP subunits (uncoupled vectorial hydrolysis), then microtubule-bound GTP would have been detectable if GTP hydrolysis became uncoupled from microtubule assembly at less than 50 microM free tubulin, 5 times the steady-state tubulin concentration of our experimental conditions. In addition, during rapid microtubule assembly, we have not detected any microtubule-bound Pi, which has been proposed to form a stabilizing cap at the ends of microtubules [Carlier et al. (1988) Biochemistry 27, 3555-3559]. Also, several conditions that could be expected to increase the degree of potential uncoupling between GTP hydrolysis and microtubule assembly were examined, and no evidence of uncoupling was found. Our results are consistent with models that propose cooperative mechanisms that limit GTP hydrolysis to the terminal ring of tubulin subunits [e.g., O'Brien et al. (1987) Biochemistry 26, 4148-4156]. The results are also consistent with the hypothesis that a slow conformational change in tubulin subunits after GTP hydrolysis and Pi release occurs that results in destabilized microtubule ends when such subunits become exposed at the ends.     

Dynamics of Antarctic fish microtubules at low temperatures

The tubulins of Antarctic fishes, purified from brain tissue and depleted of microtubule-associated proteins (MAPs), polymerized efficiently in vitro to yield microtubules at near-physiological and supraphysiological temperatures (5, 10, and 20 degrees C). The dynamics of the microtubules at these temperatures were examined through the use of labeled guanosine 5'-triphosphate (GTP) as a marker for the incorporation, retention, and loss of tubulin dimers. Following attainment of a steady state in microtubule mass at 20 degrees C, the rate of incorporation of [3H]GTP (i.e., tubulin dimers) during pulses of constant duration decreased asymptotically toward a constant, nonzero value as the interval prior to label addition to the microtubule solution increased. Concomitant with the decreasing rate of label incorporation, the average length of the microtubules increased, and the number concentration of microtubules decreased. Thus, redistribution of microtubule lengths (probably via dynamic instability and/or microtubule annealing) appears to be responsible for the time-dependent decrease in the rate of tubulin uptake. When the microtubules had attained both a steady state in mass and a constant length distribution, linear incorporation of labeled tubulin dimers over time occurred at rates of 1.45 s-1 at 5 degrees C, 0.48 s-1 at 10 degrees C, and 0.18 s-1 at 20 degrees C. Thus, the microtubules displayed greater rates of subunit flux, or treadmilling, at lower, near-physiological temperatures. At each temperature, most of the incorporated label was retained by the microtubules during a subsequent chase with excess unlabeled GTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Concerning the chemical nature of tubulin subunits that cap and stabilize microtubules

There is no definitive evidence on the nature of the cap at microtubule ends that is responsible for dynamic instability behavior. It was, therefore, of interest that steady-state microtubules assembled in 20 mM P(i) buffer and pulsed for 15-60 min with [gamma-(32)P]GTP contained approximately 26 [(32)P]P(i)/microtubule [Panda et al. (2002) Biochemistry 41, 1609-1617]. It was concluded that microtubules are capped with a tubulin-GDP-P(i) subunit at the end of each its 13 protofilaments and that this is responsible for stabilizing microtubules in the growth phase. Also, because microtubules with [(32)P]P(i) were isolated despite the presence of 20 mM P(i), it was concluded that P(i) in terminal tubulin-GDP-P(i) subunits does not exchange with solvent. These observations are inconsistent with our finding that tubulin-GDP-P(i) subunits do not stabilize microtubules and with evidence that the nucleotide, and presumably also P(i), in subunits at microtubule ends exchanges with solvent. We have resolved this discrepancy by finding that during the pulse period the added [(32)P]GTP was almost quantitatively hydrolyzed. The so-formed [(32)P]P(i) labeled the 20 mM P(i) buffer, and this exchanged into tubulin-GDP subunits in the core of the microtubule. Evidence for this was our finding of virtually identical [(32)P]P(i) in microtubules pulsed with [(32)P]GTP with a specific activity that varied 11-fold by using either 100 or 1,100 microM GTP in the reaction. Label uptake was insensitive to the [(32)P]GTP specific activity because in both cases hydrolysis generated 20 mM [(32)P]P(i) with a virtually identical specific activity. Also, approximately 0.4 mol of [(32)P]P(i) /tubulin dimer was found in microtubules when steady-state microtubules in 20 mM P(i) were pulsed with a trace amount of [(32)P]P(i). This stoichiometry is consistent with a 25 mM K(d) previously reported for P(i) binding to tubulin-GDP subunits in microtubules. It is concluded that, under the conditions used for the [(32)P]GTP pulse labeling, (32)P was incorporated into the entire microtubule from [(32)P]P(i) released into the solution, rather than into a tubulin-GDP-P(i) cap, from [(32)P]GTP. Thus, there is no evidence that tubulin-GDP-P(i) subunits accumulate in and stabilize microtubule ends.     

Identification of the prostacyclin receptor by use of [15-3H1]19-(3-azidophenyl)-20-norisocarbacyclin, an irreversible specific photoaffinity probe.

The prostaglandin I (PGI2) receptor of mouse mastocytoma P-815 cells was characterized by photo-affinity labeling with the stable PGI2 analogue [15-3H1]-19-(3-azidophenyl)-20-norisocarbacyclin ([3H] APNIC) used as a potential photoaffinity probe for the receptor. [3H]APNIC bound to the mastocytoma membrane with high affinity and in a saturable manner. Scatchard plot analysis indicated a single binding site with a Kd of 4.7 nM and a Bmax of 0.58 pmol/mg protein. The binding of [3H]APNIC was dose dependently inhibited by APNIC and iloprost, another stable PGI2 agonist, and to a much lesser extent by PGE2. The binding of the radioligand showed sensitivity to the guanine nucleotide guanosine 5'-O-(3-thio-triphosphate) (GTP gamma S). Photolysis of [3H]APNIC-prelabeled membranes resulted in incorporation of radiolabel into a protein of approximately 43 kDa. Photolabeling was inhibited by PGI2 agonists and other prostaglandins with specificity for the PGI2 receptor and was modulated by GTP gamma S. A protein of approximately 45 kDa was also labeled by [3H]APNIC in the membrane of porcine platelets, membranes that are known to be abundant in PGI2 receptors. These results demonstrate that [3H]APNIC specifically labels a protein that may represent the PGI2 receptor and that this radioprobe will be a useful reagent for further characterization and purification of the PGI2 receptor.     

Direct photoaffinity labeling of tubulin with guanosine 5'-triphosphate

Irradiation of tubulin in the presence of [3H]GTP or [3H]GDP at 254 nm led to the covalent incorporation of nucleotide into the protein. The specific nature of the labeling was shown in the following manner: with tubulin depleted of exchangeable nucleotide, the amount of labeling increased to a plateau value as the [3H]GTP concentration was increased, with saturation being reached at a ratio of approximately 1.5; the same amount of labeling was obtained with GTP/tubulin ratios of 1 and 100; [3H]GMP was not incorporated into the dimer, nor did GMP inhibit the incorporation of [3H]GTP; [3H]ATP was not incorporated; [3H]GTP incorporation did not occur into denatured tubulin or into serum albumin. When [alpha-32P]GTP was used in the irradiation experiments, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the carboxymethylated protein demonstrated that the incorporated label was associated with the beta subunit. The radiation treatment did cause changes in the tubulin molecule resulting in a decrease in assembly competence and in sulfhydryl groups, but these effects were minimized when a large excess of GTP was present during irradiation. Labeling of tubulin in the assembled state was much less than that observed in the free state.     

Autoradiographic Visualization of A1 Adenosine Receptors in Rat Brain with [3H]8-Cyclopentyl-1,3-Dipropylxanthine

A1 adenosine receptors were labeled in rat brain sections with the antagonist [3H]8-cyclopentyl-1,3-dipropylxanthine ([3H]DPCPX) and visualized at the light microscopic level using autoradiography. The specific binding of [3H]DPCPX to the sections showed the pharmacological characteristics of A1 adenosine receptors and was accompanied by very low levels of nonspecific binding. Whereas GTP had no significant effect on [3H]DPCPX binding to rat brain membranes, the addition of 100 microM GTP increased the apparent affinity of [3H]DPCPX to tissue sections fivefold (from 1.83 to 0.35 nM), enhancing it to the affinity measured in membranes. However, GTP altered neither the binding capacity nor the distribution of binding sites in tissue sections. It is suggested that a competitive antagonism with endogenous adenosine explains the lower affinity of [3H]DPCPX in the absence of GTP. The autoradiographic pattern of [3H]DPCPX binding was characteristic for A1 adenosine receptors. Distinct labeling of the different layers of the cerebellar cortex was shown by photomicrographs generated with the coverslip technique. In addition, several fiber tracts were found to be labeled. The high selectivity for A1 adenosine receptors and low nonspecific binding of [3H]DPCPX, the ability to produce high-resolution autoradiograms, together with the fact that the effects of endogenous adenosine can be eliminated by the addition of GTP make [3H]DPCPX a very useful tool in the autoradiographic study of A1 adenosine receptors.     

Ca2+-Guanine Nucleotide Interactions in Brain Membranes. II. Characteristics of [3H]Guanosine Triphosphate and [3H]β, γ-Imidoguanosine 5'-Triphosphate Binding and Catabolism in the Rat Hippocampus and Striatum

Abstract: With [³H]guanosine triphosphate ([³H]GTP) and [³H]β, γ -imidoguanosine 5′-triphosphate ([³H]GppNHp) as the labelled substrates, both the binding and the catabolism of guanine nucleotides have been studied in various brain membrane preparations. Both labelled nucleotides bound to a single class of noninteracting sites (K_D= 0.1-0.5 μm ) in membranes from various brain regions (hippocampus, striatum, cerebral cortex). Unlabelled GTP, GppNHp, and guanosine diphosphate (GDP) but not guanosine monophosphate (GMP) and guanosine competitively inhibited the specific binding of [³H]guanine nucleotides. Calcium (0.1–5 mm ) partially prevented the binding of [³H]GTP and [³H]GppNHp to hippocampal and striatal membranes. This resulted from both an increased catabolism of [³H]GTP (into [³H]guanosine) and the likely formation of Ca-guanine nucleotide^2- complexes. The blockade of guanine nucleotide catabolism was responsible for the enhanced binding of [³H]GTP to hippocampal membranes in the presence of 0.1 mm -ATP or 0.1 mm -GMP. Striatal lesions with kainic acid produced both a 50% reduction of the number of specific guanine nucleotide binding sites and an acceleration of [³H]GTP and [³H]GppNHp catabolism (into [³H]guanosine) in membranes from the lesioned striatum. This suggests that guanine nucleotide binding sites were associated (at least in part) with intrinsic neurones whereas the catabolising enzyme(s) would be (mainly) located to glial cells (which proliferate after kainic acid lesion). The characteristics of the [³H]guanine nucleotide binding sites strongly suggest that they may correspond to the GTP subunits regulating neurotransmitter receptors including those labelled with [³H]5-hydroxytryptamine ([³H]5-HT) in the rat brain.     

Phosphoinositide synthesis in bovine rod outer segments

Phosphoinositide turnover has been implicated in signal transduction in a variety of cells, including photoreceptors. We demonstrate here the presence of a complete pathway for rapid synthesis of phosphoinositides in isolated bovine retinal rod outer segments (ROS) free of microsomal contaminants. Synthesis was measured by the incorporation of label from radioactive precursors, [gamma-32P]ATP and [3H]inositol. [gamma-32P]ATP also produced large amounts of labeled phosphatidic acid. Incorporation of [3H]inositol required CTP and Mn2+. Mn2+ increased 32P incorporation into phosphatidylinositol 4-phosphate, while spermine increased phosphoinositide labeling generally. ROS that had been washed to remove soluble and peripheral proteins incorporated less label than unwashed ROS into phosphatidic acid and phosphatidylinositol. No effects of light were detected. Inhibitory effects of high concentrations of nonhydrolyzable GTP analogues were probably due to competition with ATP.     

Use of 5′-[<Emphasis Type="Italic">p</Emphasis>-(Fluorosulfonyl)benzoyl] Guanosine as an Affinity Probe for the Guanine Nucleotide-Binding Site of Transducin

Transducin (T) mediates vision in retinal rods by transmitting light signals detected by rhodopsin to a cGMP phosphodiesterase. The flow of information relies on a subunit association/dissociation cycle of T regulated by a guanine nucleotide exchange/hydrolysis reaction. 5′-[p-(Fluorosulfonyl)benzoyl] guanosine (FSBG) was synthesized and examined here as an affinity label for the guanine nucleotide binding site of T. Although the relative binding affinity of FSBG to T was much lower than for GTP and β,γ-imido-guanosine 5′-triphosphate (GMPPNP), the incorporation of FSBG to T inhibited its light-dependent [³H] GMPPNP binding activity in a concentration dependent manner. Additionally, GDP, GTP and GTP analogs hindered the binding of [³H] FSBG to T. These results demonstrated that FSBG could be used to specifically modify the active site of T. In addition, FSBG was not capable of dissociating T from T:photoactivated rhodopsin complexes, suggesting that in this case FSBG is acting as a GDP analog.     

An endogenous Ca2+-sensitive proteinase converts the hepatic alpha 1-adrenergic receptor to guanine nucleotide-insensitive forms

An iodoazido[125I]prazosin analogue was employed to photoaffinity label alpha 1-adrenergic receptors in rat liver plasma membranes. Labeled proteins were separated by gradient polyacrylamide gel electrophoresis in sodium dodecyl sulfate, and (-)-epinephrine displacement of [3H]prazosin binding was concurrently measured in the presence or absence of guanosine 5'-O-(gamma-thiotriphosphate) (GTP[gamma S]). Inclusion of EGTA and/or proteinase inhibitors during membrane preparation and incubation increased the effect of GTP[gamma S] on alpha 1-adrenergic agonist binding and this could be correlated with increased concentrations of a 78 kDa photoaffinity labeled protein. In contrast, omission of EGTA or addition of exogenous Ca2+ diminished or abolished the effect of GTP[gamma S] on binding and caused loss of the 78 kDa form and the appearance of lower molecular weight labeled proteins. Age-dependent differences in GTP[gamma S] effects on alpha 1-adrenergic agonist binding were abolished when membranes were prepared and incubated in the presence of EGTA and proteinase inhibitors. However, the 78 kDa photoaffinity labeled protein observed in adult rats (over 225 g body weight) was not apparent in membranes from younger rats (50-75 g), even when the membranes were prepared and incubated in the presence of EGTA and proteinase inhibitors. Instead, a 68 kDa species was the major labeled protein. These data suggest that GTP effects on alpha 1-adrenergic agonist binding in rat liver membranes require the presence of either a 68 or 78 kDa alpha 1-adrenergic binding protein. Failure to inhibit proteolysis in the membranes leads to the generation of lower-molecular-weight binding proteins and the loss of GTP effects on alpha 1-adrenergic agonist binding, although [3H]prazosin binding characteristics are not changed. It is suggested that either the proteolyzed forms of the alpha 1-adrenergic receptor are unable to couple to a putative guanine nucleotide-binding regulatory protein, or that such a protein is concurrently proteolyzed and is thus unable to couple to the receptor.     

Characterization of 3H-labelled platelet activating factor receptor complex solubilized from rabbit platelet membranes

Rabbit platelet membranes, preincubated with 3H-labeled platelet activating factor ([3H]PAF), were solubilized with 2% digitonin. Sedimentation of the detergent extract in a sucrose density gradient revealed a major labeled component with a sedimentation coefficient (s20,omega) of 10.5 S, which was substantially diminished when an excess of unlabeled PAF or L-652,731, (trans-2,5-bis(3,4,5-trimethoxyphenyl)tetrahydrofuran), (PAF antagonist) was present in the preincubation mixture, suggesting that the 10.5 S component is a specific receptor-bound [3H]PAF complex. Gel filtration of the [3H]PAF-receptor complex on Sephacryl S-300 revealed a single radiolabeled fraction with an apparent Stokes' radius of 4.9 nm. The apparent molecular weight and the frictional ratio of the agonist-receptor complex were computed to be 220,000 and 1.13, respectively. Dissociation of [3H]PAF from the radioligand-receptor complex was facilitated by Na+ and Li+, whereas K+ and Cs+ were ineffective. The guanine nucleotide, GTP, was also found to promote the dissociation in a manner that is additive with the effect of Na+, suggestive of the coupling of a guanine nucleotide binding protein to the solubilized PAF-receptor complex.     

Mechanism of the nucleotide exchange reaction in eukaryotic polypeptide chain initiation. Characterization of the guanine nucleotide exchange factor as a GTP-binding protein

Polypeptide chain initiation in mammalian systems is regulated at the level of the guanine nucleotide exchange factor (GEF). This multisubunit protein catalyzes the exchange of GDP bound to eukaryotic initiation factor 2 (eIF-2) for GTP. Although various models have been proposed for its mode of action, the exact sequence of events involved in nucleotide exchange is still uncertain. We have studied this reaction by three different experimental techniques: (a) membrane filtration assays to measure the release of [3H]GDP from the eIF-2.[3H]GDP binary complex, (b) changes in the steady-state polarization of fluorescamine-GDP during the nucleotide exchange reaction, and (c) sucrose gradient analysis of the total reaction. The results obtained do not support the reaction as written: eIF-2.GDP + GEF in equilibrium eIF-2.GEF + GDP. The addition of GEF alone does not result in the displacement of eIF-2-bound GDP. The release of bound GDP is dependent on the presence of both GTP and GEF, and this argues against the possibility of a substituted enzyme (ping-pong) mechanism for the guanine nucleotide exchange reaction. An important finding of the present study is the observation that GTP binds to GEF. The Kd value of 4 microM for GTP was estimated (a) by the extent of quenching of tryptophan fluorescence of GEF in the presence of GTP and (b) by the binding of [3H]GTP to GEF as measured on nitrocellulose membranes. The GEF-dependent release of eIF-2-bound GDP was studied at several constant concentrations of one substrate (GTP or eIF-2.GDP) while varying the second substrate concentration, and the results were then plotted according to the Lineweaver-Burk method. Taken together, the results of GTP and eIF-2.GDP binding to GEF and the pattern of the double-reciprocal plots strongly suggest that the guanine nucleotide exchange reaction follows a sequential mechanism.     

Unique guanine nucleotide binding properties of the human placental GTP-binding protein Gp

Gp is a major GTP-binding protein of human placenta and platelets [Evans, T., Brown, M. L., Fraser, E. D., & Northup, J. K. (1986) J. Biol. Chem. 261, 7052-7059]. High-affinity guanine nucleotide binding is associated with a polypeptide migrating identically with H-ras on SDS-PAGE. We have characterized the interactions of preparations of purified human placental Gp with guanine nucleotides in detergent solution. Equilibrium binding studies with [35S]GTP gamma S, [3H]Gpp(NH)p, and [3H]GTP identified a single class of sites with a dissociation constant of 10 +/- 1, 153 +/- 61, and 125 +/- 77 nM for the ligands, respectively. These three ligands were mutually competitive with Ki values consistent with the Kd values from direct binding experiments. Competition for the binding of [3H]Gpp(NH)p was used to determine the specificity of the site. Ki values determined from this assay were 14 nM for GTP gamma S, 143 nM for Gpp(NH)p, 3.3 microM for GDP beta S, 69 nM for GTP, and 64 nM for GDP. ATP, ADP, cAMP, cGMP, and NAD+ had no detectable affinity for this site. While the equilibrium binding data fit well to a single class of sites, association kinetics of these ligands were better fit to two rate constants. Dissociation kinetics, however, were not clearly resolved into two rates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chemotactic peptide, calcium and guanine nucleotide regulation of phospholipase C activity in membranes from DMSO-differentiated HL60 cells

Membranes prepared from DMSO-differentiated HL60 cells labeled with [3H]inositol hydrolyze polyphosphoinositides in a Ca2+-dependent manner, generating inositol 1,4-bisphosphate (IP2) and inositol 1,4,5-trisphosphate (IP3). Incubation of membranes with GTP or GTP gamma S reduces the concentration of Ca2+ required for activation. This nucleotide effect is potentiated by formyl-Met-Leu-Phe (FMLP). Pertussis toxin inhibits FMLP-induced augmentation, but not the induction of IP2/IP3 formation by GTP or GTP gamma S. These results suggest that differentiated HL60 cells contain a membrane-associated phospholipase C that degrades polyphosphoinositides and that activation of this enzyme is mediated by at least two guanine nucleotide binding proteins, one of which is linked to FMLP receptors and is pertussis toxin sensitive.