Mechanism of endogenous phosphorylation of microtubule proteins during GTP-induced microtubule assembly and implications for stability of the assembled structures

Cycle-purified microtubule protein from mammalian brain incorporated [32P]Pi upon incubation with [gamma-32P]GTP under the conditions used to promote assembly. This phosphorylation also occurred in the same proteins when phosphorylated with [gamma-32P]ATP and was only slightly stimulated by cAMP. GTP was a much less effective substrate than ATP. The transfer of phosphoryl groups from [gamma-32P]GTP to endogenous proteins followed a linear time-course and was stimulated by low concentrations of ATP and, more efficiently, by ADP. These data are in agreement with the predictions derived from a mechanism of phosphorylation by which [gamma-32P]GTP does not act as a phosphoryl donor for the protein kinase activity but, instead, only as a repository of high group transfer potential phosphoryl groups used to make [gamma-32P]ATP, from contaminating ADP, by means of the nucleoside diphosphate kinase activity. Using 100 mM fluoride, which suppressed protein phosphorylation without inhibiting the nucleoside diphosphate kinase activity, formation of [gamma-32P]ATP was detected. Fluoride was also able to protect microtubules from a slow depolymerization which was found to occur during long-term incubation of microtubules. This indicates that the phosphorylation observed in the presence of GTP is sufficient to destabilize microtubules.     

The role of nucleoside-diphosphate kinase reactions in G protein activation of NADPH oxidase by guanine and adenine nucleotides

NADPH-oxidase-catalyzed superoxide (O2-) formation in membranes of HL-60 leukemic cells was activated by arachidonic acid in the presence of Mg2+ and HL-60 cytosol. The GTP analogues, guanosine 5'-[gamma-thio]triphosphate (GTP[gamma S] and guanosine 5'-[beta,gamma-imido]triphosphate, being potent activators of guanine-nucleotide-binding proteins (G proteins), stimulated O2- formation up to 3.5-fold. The adenine analogue of GTP[gamma S], adenosine 5'-[gamma-thio]triphosphate (ATP[gamma S]), which can serve as donor of thiophosphoryl groups in kinase-mediated reactions, stimulated O2- formation up to 2.5-fold, whereas the non-phosphorylating adenosine 5'-[beta,gamma-imido]triphosphate was inactive. The effect of ATP[gamma S] was half-maximal at a concentration of 2 microM, was observed in the absence of added GDP and occurred with a lag period two times longer than the one with GTP[gamma S]. HL-60 membranes exhibited nucleoside-diphosphate kinase activity, catalyzing the thiophosphorylation of GDP to GTP[gamma S] by ATP[gamma S]. GTP[gamma S] formation was half-maximal at a concentration of 3-4 microM ATP[gamma S] and was suppressed by removal of GDP by creatine kinase/creatine phosphate (CK/CP). The stimulatory effect of ATP[gamma S] on O2- formation was abolished by the nucleoside-diphosphate kinase inhibitor UDP. Mg2+ chelation with EDTA and removal of endogenous GDP by CK/CP abolished NADPH oxidase activation by ATP[gamma S] and considerably diminished stimulation by GTP[gamma S]. GTP[gamma S] also served as a thiophosphoryl group donor to GDP, with an even higher efficiency than ATP[gamma S]. Transthiophosphorylation of GDP to GTP[gamma S] was only partially inhibited by CK/CP. Our results suggest that NADPH oxidase is regulated by a G protein, which may be activated either by exchange of bound GDP by guanosine triphosphate or by thiophosphoryl group transfer to endogenous GDP by nucleoside-diphosphate kinase.     

Binding of ATP to eukaryotic initiation factor 2. Differential modulation of mRNA-binding activity and GTP-dependent binding of methionyl-tRNAMetf

Eukaryotic initiation factor 2 (eIF-2) is shown to bind ATP with high affinity. Binding of ATP to eIF-2 induces loss of the ability to form a ternary complex with Met-tRNAf and GTP, while still allowing, and even stimulating, the binding of mRNA. Ternary complex formation between eIF-2, GTP, and Met-tRNAf is inhibited effectively by ATP, but not by CTP or UTP. Hydrolysis of ATP is not required for inhibition, for adenyl-5'-yl imidodiphosphate (AMP-PNP), a nonhydrolyzable analogue of ATP, is as active an inhibitor; adenosine 5'-O-(thiotriphosphate) (ATP gamma S) inhibits far more weakly. Ternary complex formation is inhibited effectively by ATP, dATP, or ADP, but not by AMP and adenosine. Hence, the gamma-phosphate of ATP and its 3'-OH group are not required for inhibition, but the beta-phosphate is indispensible. Specific complex formation between ATP and eIF-2 is shown 1) by effective retention of Met-tRNAf- and mRNA-binding activities on ATP-agarose and by the ability of free ATP, but not GTP, CTP, or UTP, to effect elution of eIF-2 from this substrate; 2) by eIF-2-dependent retention of [alpha-32P]ATP or dATP on nitrocellulose filters and its inhibition by excess ATP, but not by GTP, CTP, or UTP. Upon elution from ATP-agarose by high salt concentrations, eIF-2 recovers its ability to form a ternary complex with Met-tRNAf and GTP. ATP-induced inhibition of ternary complex formation is relieved by excess Met-tRNAf, but not by excess GTP or guanyl-5'-yl imidodiphosphate (GMP-PNP). Thus, ATP does not act by inhibiting binding of GTP to eIF-2. Instead, ATP causes Met-tRNAf in ternary complex to dissociate from eIF-2. Conversely, affinity of eIF-2 for ATP is high in the absence of GTP and Met-tRNAf (Kd less than or equal to 10(-12) M), but decreases greatly in conditions of ternary complex formation. These results support the concept that eIF-2 assumes distinct conformations for ternary complex formation and for binding of mRNA, and that these are affected differently by ATP. Interaction of ATP with an eIF-2 molecule in ternary complex with Met-tRNAf and GTP promotes displacement of Met-tRNAf from eIF-2, inducing a state favorable for binding of mRNA. ATP may thus regulate the dual binding activities of eIF-2 during initiation of translation.     

Assembly of the 26 S complex that degrades proteins ligated to ubiquitin is accompanied by the formation of ATPase activity

In the ubiquitin pathway for intracellular protein breakdown, proteins ligated to ubiquitin are degraded by a large (26 S) ATP-dependent protease complex. It was found previously that the 26 S complex is assembled from three different enzyme components by a process that requires MgATP. In addition, MgATP is also required for the continued action of the 26 S complex in the breakdown of ubiquitin-protein conjugates. In the present study we have tried to gain some insight into the mode of action of ATP by following ATP hydrolysis by the 26 S complex and its three components. It was found that none of the three unassembled components had significant ATPase activity, but such activity appeared following their entry into the 26 S complex. The presence of all three components and of MgATP was required for the formation of complex-associated ATPase activity. GTP and UTP cannot replace ATP for complex assembly, but these nucleotides can substitute for ATP in the stimulation of the conjugate-degrading activity of the 26 S complex. Unlabeled GTP and UTP inhibit the hydrolysis of [gamma-32P] ATP by complex-associated ATPase, indicating that this activity is related to the latter site of ATP action in this system.     

Nucleotide interconversions in microtubule protein preparations, a significant complication for accurate measurement of GTP hydrolysis in the presence of adenosine 5'-(beta, gamma-imidotriphosphate)

Pursuing the observation of Carlier and Pantaloni [Carlier, M.-F., & Pantaloni, D. (1982) Biochemistry 21, 1215-1224] that adenosine 5'-(beta, gamma-imidotriphosphate) (pNHppA) strongly inhibited tubulin-independent phosphatases in microtubule protein preparations, we observed with a number of commercial preparations of pNHppA that a major proportion of the terminal phosphate of [gamma-32P]GTP added to microtubule protein preparations was rapidly converted into ATP. Initially postulating degradation of pNHppA to AMP followed by stepwise conversion of AMP to ATP, we isolated two nucleoside monophosphate kinase activities from microtubule protein capable of generating ATP from AMP + GTP. The amounts of these enzymes in microtubule protein preparations, however, are probably too low to account for rapid ATP formation. Instead, ATP formation most likely is caused by nucleoside diphosphate kinase acting on ADP contaminating commercial pNHppA preparations. Such ADP contamination was demonstrated by high-performance liquid chromatography, with the amount of ATP formed with different pNHppA preparations proportional to the amount of ADP contamination. Repurification of commercial pNHppA until it was free of contaminating ADP also resulted in the elimination of ATP formation. The repurified pNHppA potently inhibited GTP hydrolysis in microtubule protein preparations. In addition, especially when supplemented with equimolar Mg2+, the repurified pNHppA strongly inhibited GTP hydrolysis and microtubule assembly in reaction mixtures containing purified tubulin and heat-treated microtubule-associated proteins (which contain negligible amounts of tubulin-independent phosphatase activity). We conclude that studies of microtubule-dependent GTP hydrolysis which make use of pNHppA must be interpreted with extreme caution.     

Studies on the synthesis of CDP-diacylglycerol: Stimulation by GTP and inhibition by ATP and fluoride

The rat liver microsomal enzyme CTP: phosphatidate cytidylyltransferase (EC 2.7.7.41) which catalyzes the formation of CDP-diacylglycerol has been found to be markedly stimulated by GTP. The requirement for GTP is absolute, the novel GTP analogues such as guanosine 5′-[β,γ-methylene]-triphosphate, guanosine 5′-[α,β-methylene]-triphosphate, guanosine 5′-[β,γ-imido]-triphosphate and guanosine 3′-diphosphate 5′-diphosphate are without significant effect. Maximal stimulation occurs at 1 mM GTP. ATP at a concentration of 5 mM totally inhibits the formation of CDP-diacylglycerol even in the presence of optimal GTP concentration. Analogues of ATP such as adenosine 5′-[α,β-methylene]-triphosphate, adenosine 5′-[β,γ-methylene]-triphosphate and adenosine 5′-[β,γ-imido]-triphosphate are without effect on the reaction. The addition of fluoride (8 mM) likewise abolishes the stimulatory effect of GTP.     

Association of microtubules and neurofilaments in vitro is not mediated by ATP

Runge et al. [Runge, M.S., Laue, T.M., Yphantis, D.A., Lifsics, M.R., Saito, A., Altin, M., Reinke, K., & Williams, R.C., Jr. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 1431-1435] found that mixtures of microtubules and neurofilaments formed a viscous, sedimentable complex when incubated at 37 degrees C for 20 min in the presence of ATP. They did not observe the high viscosities associated with the complex when the incubation was carried out in the absence of ATP. This paper reports an investigation of the roles of time and ATP in the formation of the complex. Microtubules assembled in a mixture containing GTP and neurofilaments prepared from bovine brain remained assembled for a shorter period of time than they did in similar solutions containing no neurofilaments. Adding ATP to the neurofilament-containing solutions, or doubling their GTP concentration, extended the time during which the microtubules remained assembled. These mixtures then became highly viscous. These phenomena resulted from the action of at least two enzymes present in the neurofilament preparation. A GTPase raised the GDP/GTP ratio, in the mixtures in which ATP was absent, to levels sufficient to cause disassembly of the microtubules. When ATP was present, a nucleotide diphosphokinase catalyzed regeneration of GTP from GDP while converting ATP to ADP. This process kept the GDP/GTP ratio low and delayed the disassembly of the microtubules. These results show that the apparent ATP dependence of formation of the microtubule-neurofilament complex observed by Runge et al. is attributable to a GDP-induced disassembly of microtubules rather than to a disruption of microtubule-neurofilament contacts. Those contacts can form in the absence of ATP.     

Mechanism of adenine toxicity in Escherichia coli

The mechanism of adenine toxicity in an hpt gpt strain of Escherichia coli that is extremely sensitive to adenine inhibition was investigated. Adenine-resistant derivatives had secondary mutations in adeninephosphoribosyltransferase or the purR repressor. Growth studies with various purine salvage pathway mutants and the ability of guanosine to prevent adenine toxicity indicated that adenine exerts its toxic effects by depleting guanine nucleotide pools. In the presence of adenine, ATP pools increased twofold in wild-type cells and stabilized after 5 min. In contrast, ATP pools continued to rise in hpt gpt cells up to 25 min and increased sevenfold after adenine addition. hpt gpt cells were shown to have higher levels of adeninephosphoribosyltransferase than did the wild-type cells. In response to adenine addition, GTP pools dropped three- to fourfold in all strains tested. Although GTP levels returned to near normal values in wild-type cells after 35 min, no restoration of GTP pools was observed in the hpt gpt strain during this period. Measurements of guanine pools before and after the addition of adenine indicated that guaninephosphoribosyltransferase plays an important role in maintaining GTP pools by converting the free guanine to GMP during guanine nucleotide depletion.     

The ATP requirement for initiation of eukaryotic translation varies according to the mRNA species

The requirement for ATP for initiation of eukaryotic mRNA translation was tested using gel-filtered rabbit reticulocyte lysates incubated with labelled Met-tRNAfMet and exogenous RNA templates, and assaying the formation of labelled 80S initiation complexes in the presence of GTP, or labelled 40S initiation complexes in the presence of a non-hydrolysable analogue of GTP. Initiation complex formation on globin mRNA, or on capped viral RNAs such as papaya mosaic virus RNA and tobacco mosaic virus RNA, was strongly stimulated by ATP. In contrast, initiation complex formation on (uncapped) encephalomyocarditis virus RNA was uninfluenced by the presence or absence of ATP, which may be correlated with the recent evidence for scanning-independent internal initiation on this viral RNA. In addition, initiation complex formation on uncapped cowpea mosaic virus RNA and on poly(A,U,G) was only slightly stimulated by ATP, much less than in the case of the capped RNAs. These results suggest that most of the ATP hydrolysed during translation initiation is consumed in cap-dependent processes, probably in unwinding the mRNA, and relatively little in the actual migration or scanning of 40S subunits along the mRNA.     

Activation of protease-constitutive recA proteins of Escherichia coli by all of the common nucleoside triphosphates.

To understand why the RecA proteins of the protease-constitutive recA1202 and recA1211 mutants show very high protease activities in vivo without the usual need for DNA damage (E. S. Tessman and P. Peterson, J. Bacteriol. 163:677-687, 1985), we examined the activation of the mutant proteins by nucleoside triphosphates (NTPs) in vitro. In vivo, the mutant protease activities are resistant to inhibition by cytidine plus guanosine (C + G) in the growth medium, in contrast to the activities of weaker mutants, such as recA441, which are sensitive to C + G inhibition. We found that RecA1202 and RecA1211 proteins, in contrast to RecA+, can use natural NTPs other than ATP and dATP as cofactors in the cleavage of LexA repressor. The effectiveness of NTPs in promoting LexA cleavage by RecA1202 and RecA1211 proteins decreased in roughly the following order: dATP greater than ATP greater than UTP greater than ATP-gamma S greater than dCTP greater than CTP greater than dGTP greater than GTP greater than TTP. These mutant proteins showed higher affinities for ATP and single-stranded DNA and higher repressor cleavage activities than RecA+ protein. With the various effectors (single-stranded DNA or NTPs), the RecA1202 protein always showed more activity than RecA1211 in the cleavage of LexA repressor in vitro, which is consistent with the greater activity of the recA1202 mutant in vivo. The results explain, in part, why some recA mutants have unusually high constitutive RecA protease activity and why that activity is more or less resistant to C + G inhibition.     

Differential phosphorylation by GTP and ATP in isolated rod outer segments of the retina.

Isolated bovine rod outer segment protein is phosphorylated with GTP-gamma-32P and ATP-gamma 32P and to a much lesser extent by CTP-gamma-32P and UTP-gamma-32P. Phosphorylation with both GTP (GTP-kinase activity) and ATP (ATP-kinase activity) is markedly stimulated by light; phosphorylation with GTP is lower in dark-adapted and higher in light-adapted rod outer segments than is phosphorylation with ATP. Km values of 20 and 200 muM and Vmax values of 2.1 and 5.9 nmol/(mg min(-1)) were calculated using ATP and GTP, respectively, in light-adapted outer segments. When outer segments are incubated with GTP-gamma-32P under the usual conditions employed in these experiments, no formation of ATP-gamma-32P was detected by the techniques of high-pressure liquid chromatography and thin-layer chromatography. In intact, light-bleached outer segments, GTP appears to specifically phosphorylate rhodopsin. Histone and phosvitin are not phosphorylated to any appreciable extent by GTP. Histone appears to block rhodopsin phosphorylation by GTP while histone and, to some extent, phosvitin, both act as substrates for ATP-kinase activity. Cyclic AMP and other adenine derivates have a marked inhibitory effect on GTP-kinase activity. Phosphate also inhibits GTP-kinase activity but stimulates ATP-kinase activity. Such differences in phosphorylation with GTP and ATP indicate that these activities are either due to separate enzyme systems or, if only one enzyme is involved, the activities are under separate physiological control in the photoreceptor unit.     

Roles of GTP and GDP in the regulation of the thyroid adenylate cyclase system

Effects of guanine nucleotides on the adenylate cyclase activity of thyroid plasma membranes were investigated by monitoring metabolism of the radiolabeled nucleotides by thin-layer chromatography (TLC). When ATP was used as substrate with a nucleotide-regeneratign system, TSH stimulated the adenylate cyclase activity in the absence of exogenous guanine nucleotide. Addition of GTP and GDP equally enhanced the TSH stimulation. Effects of GTP and GDP were indistinguishable in regard to their inhibitory effects on NaF-stimulated activities. The results from TLC suggested that GDP could be converted to GTP by a nucleotide-regenerating system. Even in the absence of nucleotide-regenerating system, addition of GDP to the adenylate cyclase assay mixture int he parallel decrease in ATP levels and formation of GTP indicating that thyroid plasma membrane preparatiosn possessed a transphosphorylating activity. When an ATP analog, App[NH]p, was used as substrate without a nucleotide-regenerating system, no conversion of GDP to GTP was observed. Under such conditions, TSH did not stimulate the adenylate cyclase activity unless exogenous GTP or Gpp[NH]p was added. GDP no longer supported TSH stimulation and caused a slight decrease in the activity. GDP was less inhibitory than Gpp(NH)p to the NaF-stimulated adenylate cyclase activity. These results suggest: (1) TSH stimulation of thyroid adenylate cyclase is absolutely dependent on the regulatory nucleotides. (2) In contrst to GTP, GDP cannot support the coupling of the receptor-TSH complex to the catalytic componenet of adenylate cyclase. (3) The nucleotide regulatory site is more inhibitory to the stimulation of the enzyme by NaF when occupied by Gpp[NH]p than GDP.     

Regulation of secretion from the adrenal medulla. Evidence for adenylate cyclase activity in secretory vesicle membranes.

Adenylate cyclase activity has been found in purified secretory vesicle membranes from the adrenal medulla. Activity was detected both by formation of radioactive cAMP from [alpha-32P]ATP and by the competitive protein binding assay for cAMP. Activity was highest at pH 8.0 to 8.5, and was stimulated by sodium fluoride and GppNHp, a GTP analogue known to stimulate adenylate cyclase activity in plasma membrane preparations. The reaction rate was strongly dependent on the molar ratio of Mg2+:ATP in the system. This is the first demonstration of adenylate cyclase in a secretory vesicle membrane.     

A wheat embryo cell‐free protein synthesis system not requiring an exogenous supply of GTP

Most in vitro protein synthesis systems require a supply of GTP for the formation of translation initiation complexes, with two GTP molecules per amino acid needed as an energy source for a peptide elongation reaction. In order to optimize protein synthesis reactions in a continuous‐flow wheat embryo cell‐free system, we have examined the influence of adding GTP and found that the system does not require any supply of GTP. We report here the preparation of a wheat embryo extract from which endogenous GTP was removed by gel filtration, and the influence of adding GTP to the system on protein synthesis reactions. Using Green Fluorescent Protein (GFP) as a reporter, higher levels of production were observed at lower concentrations of GTP, with the optimal level of production obtained with no supply of GTP. A HPLC‐based analysis of the extract and the translation mixture containing only ATP as an energy source revealed that GTP was not detectable in the extract, however, 35 μM of GTP was found in the translation mixture. This result suggests that GTP could be generated from other compounds, such as GDP and GMP, using ATP. A similar experiment with a C‐terminally truncated form of human protein tyrosine phosphatase 1B (hPTP1B_1‐320) gave almost the same result. The wheat embryo cell‐free translation system worked most efficiently without exogenous GTP, producing 3.5 mg/mL of translation mixture over a 48‐h period at 26°C. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Localization of the ATP binding site on alpha-tubulin

The binding site for ATP to tubulin was established by use of the photoaffinity label [gamma-32P]N3ATP. Photolysis of the analog in the presence of tubulin resulted in covalent modification of the protein as revealed by autoradiography of electropherograms. Scanning the autoradiograms showed that the ATP analog was bound mainly to the alpha subunit of the tubulin dimer; the alpha subunit was two to three times more radioactive than was the beta subunit. The location of a particular site on the alpha subunit was further defined by peptide maps. The alpha and beta subunits from affinity-labeled tubulin were separated and digested with Staphylococcus protease. Radioactivity was found predominantly in one peptide band from the alpha subunit. The location of the [gamma-32P]N3ATP binding site on the alpha subunit distinguishes it from the previously known exchangeable GTP binding site which is on the beta subunit. Moreover, excess GTP did not compete with [gamma-32P]N3ATP binding. The ATP binding site is distinct from the nonexchangeable GTP binding site. The GTP content of tubulin was the same after dialysis in 0.5 mM ATP as it was following dialysis against ATP-free buffer. Proof that the binding site for [gamma-32P]N3ATP is the same as that for ATP was obtained by competition experiments. In the presence of ATP, photolysis of the affinity analog did not label the alpha subunit preferentially.     

GTPase-mediated activation of ATP sulfurylase.

GTP stimulates the synthesis of APS (adenosine 5'-phosphosulfate) by the enzyme ATP sulfurylase (ATP:sulfate adenylyltransferase, EC 2.7.7.4) via a GTPase mechanism. The activation of the enzyme, purified from Escherichia coli, is titratable with GTP. The initial rate of APS formation is increased 116-fold at a saturating concentration of GTP. The enzyme exhibits a GTPase activity that is stimulated by ATP and further enhanced by SO4; however, SO4 alone does not significantly stimulate GTP hydrolysis. The larger subunit of ATP sulfurylase, encoded by cysN, contains a GTP-binding consensus sequence common to other known GTP-binding proteins. This is the first evidence that the sulfate activation pathway is a metabolic target for regulation by a GTPase.     

Protein synthesis in rabbit reticulocytes: requirements for Met-tRNAf . 40S preinitiation complex formation with AUG-codon and physiological mRNAs

Under standard conditions, in the presence of GTP, highly purified eIF-2 and Co-eIF-2 factor preparations efficiently stimulated AUG-codon dependent but not physiological mRNA-dependent Met-tRNAf binding to 40S ribosomes. Replacement of GTP by a nonhydrolyzable GTP analog, GMP-PNP, in the above system, gave significant stimulation of Met-tRNAf binding to 40S ribosomes dependent on physiological mRNAs. Lower but significant stimulation of Met-tRNAf binding to 40S ribosomes was also observed when GTP was used in the presence of nucleoside 5'-diphosphate kinase (NDK) and ATP. ATP alone in the absence of NDK had no significant effect. This is the first report on the formation of a stable Met-tRNAf . 40S initiation complex dependent on physiological mRNAs and the factor requirements for such complex formation.     

The mechanism of guanosine triphosphate depletion in the liver after a fructose load. The role of fructokinase.

A Sephadex G-25 filtrate of a 100 000g supernatant of rat liver homogenate was shown to be able to phosphorylate fructose, with GTP as the phosphate donor. Attempts to separate ATP- and GTP-dependent fructokinase activities failed, indicating that there is a single enzyme able to use both nucleotides. With a partially purified enzyme, Km values for fructose of 0.83 and 0.56 mM were found with ATP and GTP as substrates respectively. Km values of 1.53 and 1.43 mM were found for GTP and ATP respectively. Both ADP and GDP inhibited the GTP- and ATP-dependent fructokinase activity. We conclude that the depletion of hepatic GTP caused by intravenous administration of fructose to mice and rats can be explained simply by the utilization of the nucleotide by fructokinase.     

5-Hydroxytryptamine stimulates inositol phosphate production in a cell-free system from blowfly salivary glands. Evidence for a role of GTP in coupling receptor activation to phosphoinositide breakdown

Phosphoinositide breakdown has been linked to the receptor mechanism involved in the elevation of cytosolic Ca2+. In a cell-free system prepared from [3H] inositol-labeled blowfly salivary glands, 5-hydroxytryptamine stimulated the rapid production of inositol phosphates. Within 30 s of hormone addition, there was a 100% increase in inositol trisphosphate formation, a 70% increase in inositol bisphosphate formation, and a 90% increase in inositol monophosphate formation as compared to control homogenates incubated for the same length of time. 5-Hydroxytryptamine did not stimulate inositol or glycerol phosphoinositol formation. Half-maximal activation of inositol phosphate production was obtained with 0.33 microM 5-hydroxytryptamine. Ethylene glycol bis(beta-aminoethyl ether)-N',N',N',N'-tetraacetic acid, (EGTA) (0.3 mM) inhibited the basal formation of inositol phosphates and decreased the net accumulation of inositol bisphosphate and inositol trisphosphate due to hormone as compared to homogenates incubated in the absence of added Ca2+. EGTA, however, had little effect on the per cent stimulation of inositol phosphate production due to hormone. In homogenates, ATP, GTP or guanyl-5'-yl imidodiphosphate (Gpp(NH)p) was required for a hormone effect. Gpp(NH)p, unlike ATP or GTP, increased the basal formation of inositol phosphates. In membranes, GTP, Gpp(NH)p, or guanosine 5'-(3-O-thio)trisphosphate (GTP gamma S) sustained a hormone effect whereas ATP was ineffective. GTP did not affect production while Gpp(NH)p and GTP gamma S increased inositol phosphate production. Half-maximal effects of Gpp(NH)p and GTP gamma S on hormone-stimulated inositol phosphate formation occurred at 10 microM and 100 nM, respectively. In the presence of 1 microM GTP gamma S, 5-methyltryptamine stimulated inositol phosphate formation within 2 s in membranes. These results indicate that in a cell-free system, GTP is involved in mediating the effects of Ca2+-mobilizing hormones on phosphoinositide breakdown.     

Activation by GTP of liver adenylate cyclase in the presence of high concentrations of ATP

Effect of GTP on adenylate cyclase of liver plasma membrane was examined using ATP which was extensively purified by DEAE-cellulose column chromatography. In the incubation containing 2mM purified ATP as substrate, GTP enhanced basal and glucagon- or fluoride-stimulated activities. When the unpurified ATP at 2mM was used, all the activities were high and the stimulatory effect of GTP was not detected. The substance(s) which was recovered from a small but significant peak on DEAE-cellulose column was equivalent to 10–100μM GTP in stimulating adenylate cyclase. These results indicate that, if highly purified ATP is used as substrate, GTP can enhance adenylate cyclase activity in the presence of millimolar concentration of ATP and that GTP enhances not only the glucagon-stimulated adenylate cyclase but also the basal as well as fluoride-stimulated adenylate cyclase activities.