Regulation of intracellular acetyl-CoA carboxylase by ATP depletors mimics the action of the 5'-AMP-activated protein kinase.

Acetyl-CoA carboxylase (ACC) can be regulated in vitro via phosphorylation by a 5'-AMP-activated protein kinase. A potential intracellular role for this kinase has been studied in the Fao hepatoma cell by manipulating the intracellular adenine nucleotide pool with ATP-depleting agents. Three different ATP depletors, antimycin A, dinitrophenol, and sodium azide, all promote the rapid loss of ACC activity characterized by a marked reduction in enzyme Vmax, abolition of citrate-independent activity, an increase in the Ka for citrate and a reduction in the mass of a complex between the two major ACC isozymes. These effects persist through enzyme purification on monomeric avidin-Sepharose and are accompanied by an increase in 32P-content, both consistent with depletor-induced covalent enzyme modification. The effects of ATP depletors in intact cells are mimicked in vitro on phosphorylation of ACC by the 5'-AMP-activated protein kinase and are reversible on dephosphorylation. These data indicate that ACC activity is sensitive to the intracellular adenylate charge, but that changes in the state of enzyme phosphorylation, rather than direct allosteric regulation by adenine nucleotides, underly this mode of enzyme control. This kinase-mediated modulation provides a mechanism for altering the rate of fatty acid synthesis and, secondarily, fatty acid oxidation, depending on the rate of ATP generation from carbohydrate-derived precursors in several tissues in vivo.     

Regulation of ribonucleotide reductase activity in intact mammalian cells

An intact cell assay system based upon Tween-80 permeabilization was used to investigate the regulation of ribonucleotide reductase activity in Chinese hamster ovary cells. Models used to explain the regulation of the enzyme have been based upon work carried out with cell-free extracts, although there is concern that the properties of such a complex enzyme would be modified by extraction procedures. We have used the intact cell assay system to evaluate, within whole cells, the current model of ribonucleotide reductase regulation. While some of the results agree with the proposals of the model, others do not. Most significantly, it was found that ribonucleotide reductase within the intact cell could simultaneously bind the nucleoside triphosphate activators for both CDP and ADP reductions. According to the model based upon studies with cell-free preparations, the binding of one of these nucleotides should exclude the binding of others. Also, studies on intracellular enzyme activity in the presence of combinations of nucleotide effectors indicate that GTP and perhaps dCTP should be included in a model for ribonucleotide reductase regulation. For example, GTP has the unique ability to modify through activation both ADP and CDP reductions, and synergistic effects were obtained for the reduction of CDP by various combinations of ATP and dCTP. In general, studies with intact cells suggest that the in vivo regulation of ribonucleotide reductase is more complex than predicted from enzyme work with cell-free preparations. A possible mechanism for the in vivo regulation of ribonucleotide reductase, which combines observations of enzyme activity in intact cells and recent reports of independent substrate-binding subunits in mammalian cells is discussed.     

Multiple inhibitory and activating effects of nucleotides and magnesium on adrenal adenylate cyclase.

Adenylate cyclase in particulate fractions from rat adrenal glands is subject to regulation by purine nucleotides, particularly guanine nucleotides. While GTP activates the enzyme, this effect is not evident in all particulate fractions. Following dialysis of the refractory fractions activation by GTP is observed, an indication that endogenous nucleotides may obscure the effects of added GTP. The analog, guanyl-5'-yl imidodiphosphate (Gpp(NH)p gives considerable more activity than does GTP. GDP, on the other hand, is inhibitory, an effect revealed only in the absence of a nucleotide-regenerating solution. GDP blocks the action of both GTP and Gpp(NH)p. These results show that the gamma-phosphate of the nucleotide is required for but need not be metabolized in the activation process. At low substrate concentration (0.1 mM ATP or adenyl-5'-yl imidodiphosphate) stimulation of the enzyme by ACTH occurs only in the presence of added guanine nucleotide (GTP or Gpp(NH)p); the hormone and nucleotide act synergistically. While both GTP and Gpp(NH)p inhibit fluoride-stimulated activity, the level of fluoride required to demonstrate such inhibition appears not to be related to the level of fluoride required for activation of the enzyme. In the presence of GTP, or GTP plus ACTH, the enzyme exhibits normal Michaelis-Menten kinetics with respect to substrate utilization (K-m equal to 0.16 mM). In the activated state, produced with ACTH plus GTP, the enzyme is less susceptible to inhibition by a species of ATP uncomplexed with Mg2+, but is more susceptible to inhibition by Mg2+. These results demonstrate that fundamental differences exist between different states of the adenylate cyclase. The difficulties in describing kinetically the regulation of adenylate cyclase systems in view of the multiple actions of nucleotides and magnesium are discussed.     

Involvement of guanine nucleotides in superoxide release by fluoride-treated neutrophils. Implications for a role of a guanine nucleotide regulatory protein

Previous studies demonstrating hydrolysis of phosphatidylinositol bisphosphate (PIP2) and generation of inositol phosphates in neutrophils exposed to 20.0 mM NaF provide indirect evidence that activation of phospholipase-associated guanine nucleotide regulatory protein, a guanine nucleotide binding protein which regulates the activation of a membrane inositol-specific phospholipase C, is an early event in the neutrophil stimulus-response pathway triggered by fluoride. Consistent with this hypothesis, exposure of a plasma membrane rich preparation isolated from 32P labeled neutrophils to 20.0 mM NaF resulted in hydrolysis of labeled PIP2. Levels of other phospholipids were not affected. Inositol bisphosphate and inositol trisphosphate were detected in extracts of neutrophil plasma membranes exposed to fluoride. To further explore the involvement of guanine nucleotides in functional responses of intact neutrophils triggered by fluoride, we preincubated cells with 2-beta-D-ribofuranosylthiazole-4-carboxamide (tiazofurin), a selective inhibitor of inosine monophosphate dehydrogenase, to diminish guanine nucleotide synthesis and then compared superoxide generation induced by FMLP, PMA, digitonin, and 20.0 mM NaF to intracellular levels of guanine nucleotides. Preincubation of neutrophils for 2.5 h at 37 degrees C with tiazofurin resulted in dose-dependent depletion of GTP and GDP. Maximal depletion of guanine nucleotides required relatively high levels of tiazofurin (200 to 400 microM) and resulted in a 55 to 60% reduction of GTP and GDP. The effects of tiazofurin on guanine nucleotides levels were not observed when neutrophils were preincubated at 4 degrees C. AT 37 degrees C, tiazofurin also decreased intracellular ATP and ADP levels but adenine nucleotide depletion was less pronounced than guanine nucleotide depletion for each concentration of tiazofurin used. When tiazofurin was removed by washing cells after incubation, adenine nucleotide quickly returned to preincubation values but guanine nucleotide levels remained depressed. Addition of exogenous guanosine (200 microM) prevented tiazofurin-dependent depletion of guanine nucleotides but had no influence on adenine nucleotide depletion. Superoxide released triggered by FMLP and F- was inhibited to an extent similar to that of guanine nucleotide depletion under different conditions of preincubation. Inhibition of superoxide release was not observed if cells were preincubated at 4 degrees C, was not rapidly reversible, and was not observed when guanosine was added with tiazofurin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin activation of acetyl-CoA carboxylase accompanied by inhibition of the 5'-AMP-activated protein kinase.

The activity of acetyl-CoA carboxylase (ACC), a rate-limiting enzyme of fatty acid biosynthesis and malonyl-CoA production, can be regulated by several mechanisms, including multisite covalent phosphorylation, both in vitro and in intact cells. Evidence has been presented by others to indicate that a 5'-AMP-activated protein kinase (AMPK) is likely the major regulatory kinase active on ACC. While insulin is known to activate ACC in several cell types, accompanied by changes in ACC phosphorylation, the mechanism underlying this activation has been obscure. In the present study, we have examined, in Fao hepatoma cells, the effects of insulin on ACC and AMPK activity, the latter measured with a synthetic peptide corresponding to one of the phosphorylation sites on ACC for AMPK. Our results show that insulin leads to inhibition of kinase activity prior to the onset of ACC activation; the peak of maximal kinase inhibition (approximately 35% at 10 min) is seen to precede the onset of ACC activation (20 min). The inhibition of kinase activity due to insulin is observed both in the absence and presence of varying stimulating concentrations of added 5'-AMP. Both kinase inhibition and ACC activation display similar insulin sensitivity (A50 0.3 nM). Preservation of this insulin-induced kinase inhibition requires the presence of protein phosphatase inhibitors in the cell lysis buffer, suggesting that AMPK itself might be regulated by insulin-stimulated changes in kinase phosphorylation. Taken together, these data are consistent with the hypothesis that the 5'-AMP-activated protein kinase is a regulated component of the insulin signal transduction pathway and may be the major target for insulin regulation of ACC.     

Activation of solubilized liver membrane adenylate cyclase by guanyl nucleotides.

Liver plasma membranes of hypophysectomized rats were purified, treated with 0.1 m Lubrol-PX and centrifuged at 165,000g for 1 h. The detergent solubilized 50% of the membrane protein; adenylate cyclase activity was present in the supernatant fraction. Optimal substrate concentration of the soluble enzyme was 0.32 mm ATP. Basal activity of 25 preparations of the solubilized enzyme ranged from 124 to 39 pmol cyclic AMP/mg protein/10 min. The solubilized enzyme retained the same sensitivity to activation by guanyl nucleotides as was present in the membrane preparation from which it was derived. Relative sensitivity of the solubilized enzyme with 0.1 mm nucleotides or -side was GDP > GTP > GMP > guanosine; GMP-PNP = GMP-PCP > ITP > GTP. GTP, GMP-PCP, GMP-PNP and other nucleotides were hydrolyzed by phosphohydrolases present in liver membranes that were solubilized with Lubrol-PX along with adenylate cyclase. The presence of the ATP regenerating system in the adenylate cyclase assay also aided in maintaining guanyl nucleotide concentrations. The degree of adenylate cyclase activation by guanyl nucleotides was not related to the sparing effects of nucleotides on substrate ATP hydrolysis. These findings demonstrate that activation of adenylate cyclase by nucleotides is a consequence of a nucleotide-enzyme interaction that is independent of membrane integrity.     

Irreversible stimulation of adenylate cyclase activity of fat cell membranes of phosphoramidate and phosphonate analogs of GTP.

The ability of 5'-guanylylimidodiphosphate (Gpp(NH)p) to stimulate irreversibly the adenylate cyclease activity of fat cell membranes has been studied by preincubating the membranes with this or related analogs followed by assaying after thoroughly washing the membranes. Activation can occur in a simple Tris-HCl buffer, in the absence of added divalent cations and in the presence of EDTA. Dithiothreitol enhances the apparent degree of activation, perhaps by stabilization. The importance of utilizing optimal conditions for stabilizing enzyme activity, and of measuring the simultaneous changes in the control enzyme, is illustrated. The organomercurial, p-aminophenylmercuric acetate, inhibits profoundly the activity of the native as well as the Gpp(NH)p-stimulated adenylate cyclase, but in both cases subsequent exposure to dithiothreitol restores fully the original enzyme activity. However, the mercurial-inactivated enzyme does not react with Gpp(NP)p, as evidenced by the subsequent restoration of only the control enzyme activity upon exposure to dithiothreitol. Thus, reaction with Gpp(NH)p requires intact sulfhydryl groups, but the activated state is not irreversibly destroyed by the inactivation caused by sulfhydryl blockade. GTP and, less effectively, GDP and ATP inhibit activation by Gpp(NH)p, but interpretations are complicated by the facts that this inhibition is overcome with time and that GTP and ATP can protect potently from spontaneous inactivation. These two nucleotides can be used in the Gpp(NH)p preincubation to stabilize the enzyme. The Gpp(NH)p-activated enzyme cannot be reversed spontaneously during prolonged incubation at 30 degrees C in the absence or presence of GTP, ATP, MgCl2, glycine, dithiothreitol, NaF or EDTA. The strong nucleophile, neutral hydroxylamine, decreases the Gpp(NH)p-activated enzyme activity and no subsequent activation is detected upon re-exposure to the nucleotide.     

Acetyl-CoA carboxylase in Reuber hepatoma cells: variation in enzyme activity, insulin regulation, and cellular lipid content.

Reuber hepatoma cells are useful cultured lines for the study of insulin action, lipid and lipoprotein metabolism, and the regulation of acetyl-CoA carboxylase (ACC), the rate-limiting enzyme of fatty acid biosynthesis. During investigations in different clonal lines of these cells, we have uncovered marked intercellular variability in the activity, enzyme content, and insulin regulation of ACC paralleled by differences in cellular neutral lipid (triglyceride) content. Two contrasting clonal lines, Fao and H356A-1, have been studied in detail. Several features distinguish these two lines, including differences in ACC activity and enzyme kinetics, the content of the two major hepatic ACC isozymes (Mr 280,000 and 265,000 Da) and their heteroisozymic complex, the extent of ACC phosphorylation, and the ability of ACC to be activated on stimulation by insulin and insulinomimetic agonists. As studied by Nile Red staining and fluorescence-activated cell sorting, these two lines also display marked differences in neutral lipid content, which correlates with both basal levels of ACC activity and inhibition of ACC by the fatty acid analog, 5-(tetradecyloxy)-2-furoic acid (TOFA). These results emphasize the importance of characterization of any particular clonal line of Reuber cells for studies of enzyme regulation, substrate metabolism, and hormone action. With respect to ACC, studies in contrasting clonal lines of Reuber cells could provide valuable clues to understanding both the complex mechanisms of intracellular ACC regulation in the absence and presence of hormones and its regulatory role(s) in overall hepatic lipid metabolism.     

The effect of nucleotides on glutamate dehydrogenase from the mealworm fat body

The effect of nucleotides: AMP, cAMP, ADP, ATP, GDP and GTP, on glutamate dehydrogenase (GDH) purified from the mealworm fat body was studied. Guanine nucleotides and ATP inhibited the enzyme strongly in both directions. GDH was partially protected from the inhibition by the addition of ADP to an assay medium. AMP and cAMP activated the enzyme slightly. The concerted effects of ADP and ATP indicate the importance of adenylate energy charge in the regulation of fat body GDH. It is suggested that GDH may play amphibolic role in the fat body and that the direction of GDH catalysed reaction is under strong influence of nucleotides. The enzyme may synthesize glutamate at high energy charge, but when the energy reserves are low, it oxidizes glutamate.     

Separate processes mediate nucleotide-induced inhibition and stimulation of the ATP-regulated K(+)-channels in mouse pancreatic beta-cells.

The mechanisms by which nucleotides stimulate the activity of the ATP-regulated K(+)-channel (KATP-channel) were investigated using inside-out patches from mouse pancreatic beta-cells. ATP produces a concentration-dependent inhibition of channel activity with a Ki of 18 microns. The inhibitory action of ATP was counteracted by ADP (0.1 mM) and GDP (0.2 mM) but not GTP (1 mM). Stimulation of channel activity was also observed when ADP, GDP and GTP were applied in the absence of ATP. The ability of ADP and GDP to reactivate KATP-channels blocked by ATP declined with time following patch excision and after 30-60 min these nucleotides were without effect. During the same time period the ability of ADP and GTP to stimulate the channel in the absence of ATP was lost. In fact, ADP now blocked channel activity with 50% inhibition being observed at approximately 0.1 mM. By contrast, GDP remained a stimulator in the absence of ATP even when its ability to evoke channel activity in the presence of ATP was lost. These observations show that nucleotide-induced activation of the KATP-channel does not involve competition with ATP for a common inhibitory site but involves other processes. The data are consistent with the idea that nucleotides modulate KATP-channel activity by a number of different mechanisms that may include both regulation of cytosolic constituents and direct interaction with the channel and associated control proteins.     

Specific enzymatic determinations of adenosine triphosphate.

The well-known soluble kinases are not specific for ATP (1). All these enzymes convert ATP as well as GTP, ITP, CTP, and UTP, although at different rates. The only exception is adenylate kinase (1). However, with this enzyme, a direct determination of ATP in tissue extracts which contain both the di- and mononucleotides is not possible.Phosphoglycerate kinase from various sources is specific for ATP, GTP, and ITP and does not react with the pyrimidine nucleotides (2), Now, however, it was found that phosphoglycerate kinase from the blue alga Spirulina platensis does not convert GTP and ITP. With this enzyme, therefore, it is possible to specifically determine ATP in tissue extracts or in mixtures of nucleotides. In the same test, GTP and ITP can be determined by adding phosphoglycerate kinase from yeast or from other sources (2).     

Phospholipase D activation in a cell-free system from human neutrophils by phorbol 12-myristate 13-acetate and guanosine 5'-O-(3-thiotriphosphate). Activation is calcium dependent and requires protein factors in both the plasma membrane and cytosol

Receptor-linked activation of phospholipase D has been demonstrated recently in a variety of intact cell types including granulocytes, but little is known about the enzyme, its cofactor requirements, and regulation. Using [3H]alkyllysophosphatidylcholine to prelable an endogenous phosphatidylcholine substrate pool in conjunction with transphosphatidylation using ethanol to generate labeled phosphatidylethanol, we demonstrated a novel phospholipase D activity in neutrophil subcellular fractions. Guanosine 5'-O-3-(thiotriphosphate) (GTP gamma S) and phorbol 12-myristate 13-acetate (PMA) activated both phosphatidic acid generation and transphosphatidylation. Activity using both activators required the presence of not only plasma membrane but also cytosol, and proteolytic and thermal inactivation demonstrated the requirement for protein factors in both fractions. Using both stimuli, activity increased with increasing cytosol concentration. Product formation was approximately linear for about 10 min with PMA and 30 min with GTP gamma S, and both activators resulted in the total hydrolysis of up to 10% of the labeled phosphatidylcholine. The activity using both activators showed similar broad neutral pH optima, and both required the presence of micromolar levels of calcium, which by itself failed to activate at concentrations up to 1 mM. At low micromolar concentrations of nucleotides, activation was specific for guanine nucleotides and showed a specificity of GTP gamma S greater than guanyl-5'-yl imidodiphosphate greater than GTP, with no effect of GDP and GMP or adenine nucleotides, consistent with the participation of a guanine nucleotide regulatory protein. PMA activation was dependent on the presence of ATP, in particular when dialyzed cytosol was used, and was inhibited by about 50% by staurosporine, supporting a role for protein kinase C. However, purified protein kinase C failed to substitute for cytosol, implicating an additional cytosolic factor(s) in this response. These results indicate that the granulocytic phospholipase D pathway is a complex system that is regulated by at least two activation pathways, each comprised of components in two subcellular compartments.     

Regulation of phospholipase D from human hepatocarcinoma cell line by purine nucleotides and protein kinase A

The regulation of phosphatidylcholine-specific phospholipase D by purine nucleotides and protein kinase A were studied in vitro using an enzyme preparation partially purified from the membranous fraction of 7721 hepatocarcinoma cells. It was found that the enzyme activity was elevated by low concentrations of some purine nucleotides, but the activating effects were decreased when the concentrations of the nucleotides were higher. The optimal concentrations of GTP, GTP[S] , GDP and ATP for maximal activation were 0.1mM, 5M,1 mM and 1 mM respectively. The activation caused by 1mM ADP was lower. The enzyme was not activated by 1mM AMP, but significant activation was observed by the addition of 1mM cAMP. The latter was mediated by protein kinase A, as a specific inhibitor of protein kinase A ablished the activation. There were synergic effects between ATP and GTP, ATP and PIP₂, but not between ATP and GTP[S] , or PIP₂ and GTP[S]. The activating effects of GTP and ATP were abolished by neomycin, a PIP₂ scavenger. These results suggest that phospholipase D is regulated by GTP-binding protein and the presence of PIP₂ is required for the activation induced by GTP. Protein kinase A may be another protein kinase in addition to protein kinase C and protein tyrosine kinase which regulate the activity of phospholipase D, when the intracellular concentration of cAMP is increased.     

Guanine nucleotides can activate the insulin-stimulated phosphodiesterase in liver plasma membranes

The insulin-stimulated cyclic AMP phosphodiesterase from liver plasma membranes is shown to be activated upon incubation with guanine nucleotides in the presence of ATP. The non-hydrolysable analogue of ATP, adenylyl imidodiphosphate failed to substitute for ATP in achieving activation. GTP, its non-hydrolysable analogues p[NH]ppG and GTP-gamma-S, as well as GDP, all elicited activation. It is suggested that guanine nucleotides, and probably insulin, exert their effect on this enzyme through a distinct species of guanine nucleotide regulatory protein.     

P2-purinergic agonists activate phospholipase C in a guanine nucleotide- and Ca2+-dependent manner in FRTL-5 thyroid cell membranes

Various adenine nucleotides activated phospholipase C of FRTL-5 cell membranes in the following order of activity, ATP gamma S greater than ATP greater than AppNp greater than AppCp = ADP greater than MeSATP. This order was well consistent with that observed in intact cells. Such activation occurred only in the presence of appropriate concentrations of GTP gamma S and Ca2+, in a way similar to the norepinephrine-induced activation. NaF, a non-specific GTP-binding protein (G-protein) activator, also stimulated the enzyme. These adenine nucleotides, norepinephrine and NaF-induced activations were inhibited by GDP beta S. We conclude that a G-protein is involved in the adenine nucleotides-induced activation of phospholipase C via P2-purinergic receptor in FRTL-5 cells.     

IMP dehydrogenase inhibitors reduce intracellular tetrahydrobiopterin levels through reduction of intracellular GTP levels. Indications of the regulation of GTP cyclohydrolase I activity by restriction of GTP availability in the cells.

GTP cyclohydrolase I exhibits a positive homotropic cooperative binding to GTP, which raises the possibility of a role for GTP in regulating the enzyme reaction (Hatakeyama, K., Harada, T., Suzuki, S., Watanabe, Y., and Kagamiyama, H. (1989) J. Biol. Chem. 264, 21660-21664). We examined whether or not the intracellular GTP level is within the range of affecting GTP cyclohydrolase I activity, using PC-12 rat pheochromocytoma and IMR-32 human neuroblastoma cells. Since GTP cyclohydrolase I was the rate-limiting enzyme for the biosynthesis of tetrahydrobiopterin in these cell lines, the intracellular activities of this enzyme were reflected in the tetrahydrobiopterin contents. We found that the addition of guanine or guanosine increased GTP but not tetrahydrobiopterin in these cells. On the other hand, three IMP dehydrogenase inhibitors, tiazofurin, 2-amino-1,3,4-thiadiazole, and mycophenolic acid, decreased both GTP and tetrahydrobiopterin in a parallel and dose-dependent manner, and these effects were reversed by the simultaneous addition of guanine or guanosine. There was no evidence suggesting that these inhibitors inhibited other enzymes involved in the biosynthesis and regeneration of tetrahydrobiopterin. Comparing intracellular activities of GTP cyclohydrolase I in the inhibitor-treated cells with its substrate-velocity curve, we estimated that the intracellular concentration of free GTP is 150 microM at which point the activity of GTP cyclohydrolase I is elicited at its maximum velocity. Below this GTP concentration, GTP cyclohydrolase I activity is rapidly decreased. Therefore GTP can be a regulator for tetrahydrobiopterin biosynthesis.     

Stimulation of human fat cell adenylate cyclase by GDP and guanosine 5'-O-(2-thiodiphosphate)

GDP regulation of basal and receptor-mediated catecholamine-sensitive human fat cell adenylate cyclase was studied using purified plasma membrane preparations and assay conditions selected to minimize conversion of GDP to GTP. Under ordinary assay conditions (low NaCl concentration) and with App(NH)p as substrate to prevent GDP conversion to GTP, basal enzyme activity was stimulated up to 2-fold by GDP (0.1 mM) while addition of epinephrine (0.1 mM) eliminated stimulation by GDP and reduced basal adenylate cyclase activity. With ATP as substrate, the enzyme was not responsive to hormone in the absence of guanyl nucleotides and GDP augmentation of basal activity was small (0-1.5-fold) while stimulatory effects of epinephrine and isoproterenol were minimally but definitely exhibited (1.5-fold over basal). Guanosine 5'-O-(2-thiodiphosphate) (GDP beta S), a GDP analog resistant to phosphorylation and hydrolysis and an antagonist of GTP, stimulated enzyme activity more than did GDP but did not promote epinephrine action. Rather, inhibition of GDP beta S-stimulated adenylate cyclase activity was seen with both epinephrine and isoproterenol and also with GTP. In the presence of NaCl (200 mM), which alone produced 2-3-fold increase in basal enzyme activity, GDP (0.1 mM) and GDP beta S (50 microM) produced 8- and 15-fold increases of activity, respectively. Addition of UDP, to prevent possible conversion of GDP to GTP, had no effect on NaCl-enhanced activation by GDP. The results indicate that the human fat cell adenylate cyclase system is unique in responding to GDP and its analog GDP beta S by stimulation in the absence of hormone but suggest that as in other systems catecholamine-mediated stimulation is normally dependent on GTP. Salts (Na+) appear to stimulate the enzyme by facilitating the interaction of the guanyl nucleotide regulatory protein (N8) with the catalytic unit.     

Regulation of the interaction of inosine monophosphate dehydrogenase with mycophenolic Acid by GTP

Inosine monophosphate dehydrogenase (IMPDH), a rate-limiting enzyme in the de novo synthesis of guanine nucleotides, is a major therapeutic target. A prototypic uncompetitive inhibitor of IMPDH, mycophenolic acid (MPA), is the active form of mycophenolate mofeteil (CellCept), a widely used immunosuppressive drug. We have found that MPA interacts with intracellular IMPDH in vivo to alter its mobility on SDS-polyacrylamide gels. MPA also induces a striking conformational change in IMPDH protein in intact cells, resulting in the formation of annular aggregates of protein with concomitant inhibition of IMPDH activity. These aggregates are not associated with any known intracellular organelles and are reversible by incubating cells with guanosine, which repletes intracellular GTP, or with GTPgammaS. GTP also restores IMPDH activity. Treatment of highly purified IMPDH with MPA also results in the formation of large aggregates of protein, a process that is both prevented and reversed by the addition of GTP. Finally, GTP binds to IMPDH at physiologic concentrations, induces the formation of linear arrays of tetrameric protein, and prevents the aggregation of protein induced by MPA. We conclude that intracellular GTP acts as an antagonist to MPA by directly binding to IMPDH and reversing the conformational changes in the protein.     

Evidence for receptor-regulated phosphotransfer reactions involved in activation of the adenylate cyclase inhibitory G protein in human platelet membranes

The activity of the adenylate cyclase inhibitory guanine-nucleotide-binding regulatory protein (Gi), measured as inhibition of forskolin-stimulated cyclic AMP formation, and its regulation by various nucleotides and the inhibitory alpha 2-adrenoreceptor agonist epinephrine was studied in membranes of human platelets. When adenylate cyclase activity was measured with ATP as substrate and in the absence of a nucleoside-triphosphate-regenerating system, GTP (0.1-10 microM) by itself potently and efficiently inhibited the enzyme. GDP was almost as potent and as effective as GTP. In the additional presence of epinephrine, the potencies of both GTP and GDP were increased about threefold, while maximal inhibition by these nucleotides was only slightly increased by the receptor agonist. In contrast to GTP and GDP, the metabolically stable GDP analog, guanosine 5'-[beta-thio]diphosphate, had only a very small effect, suggesting that GDP but not its stable analog is converted to the active GTP. Addition of UDP (1 mM), used to block the GDP to GTP conversion reaction, completely suppressed the inhibitory effect of GDP, while that caused by GTP was not affected. Most important, the inhibitory receptor agonist epinephrine counteracted the suppressive effect of UDP on GDP's action, suggesting that, while UDP inhibits the formation of GTP from GDP, the activated receptor stimulates this conversion reaction. In the presence of a complete nucleoside-triphosphate-regenerating system, which by itself had no influence on control forskolin-stimulated adenylate cyclase activity, GTP alone, at concentrations up to 10 microM, did not decrease enzyme activity, but required the presence of an inhibitory receptor agonist (epinephrine) to activate the Gi protein. Addition of the regenerating system creatine phosphate plus creatine kinase not only abolished adenylate cyclase inhibition by GTP alone, but also largely reduced both the potency and efficiency of epinephrine to activate the Gi protein in the presence of GTP. Furthermore, the nucleoside-triphosphate-regenerating system also largely delayed the onset of adenylate cyclase inhibition by the GTP analog, guanosine-5'-[beta-thio]triphosphate (10 nM), which was accelerated by epinephrine, and it also decreased the final enzyme inhibition caused by this GTP analog.(ABSTRACT TRUNCATED AT 400 WORDS)