Forskolin Potentiates the Stimulation of Rat Striatal Adenylate Cyclase Mediated by D-1 Dopamine Receptors, Guanine Nucleotides, and Sodium Fluoride

We report here that forskolin acts in a synergistic manner with dopaminergic agonists, guanine nucleotides, or sodium fluoride to potentiate the stimulation of rat striatal adenylate cyclase mediated by these reagents. In the presence of 100 microM GTP, 100 microM guanyl-5'-yl imidodiphosphate [Gpp(NH)p], or 10 mM NaF, there is a greater than additive increase in forskolin-stimulated enzyme activity as well as a concomitant decrease (two- to fourfold) in the EC50 value for forskolin stimulation of striatal enzyme activity. In the presence of various concentrations of forskolin (10 nM-100 microM), the stimulation of adenylate cyclase elicited by GTP, Gpp(NH)p, and NaF is potentiated 194-1,825%, 122-1,141%, and 208-938%, respectively, compared with the stimulation by these agents above basal activity in the absence of forskolin. With respect to 3,4-dihydroxyphenylethylamine (dopamine) receptor-mediated stimulation of striatal enzyme activity, the stimulation of enzyme activity by dopaminergic agonists, in the absence or presence of forskolin, was GTP-dependent and could be antagonized by the selective D-1 antagonist SCH23390 (100 nM), indicating that these effects are mediated by D-1 dopamine receptors. In the presence of 100 microM GTP, forskolin at various concentrations markedly potentiates the stimulation elicited by submaximal as well as a maximally effective concentrations of dopamine (100 microM) and SKF38393 (1 microM). At higher concentrations of forskolin (10-100 microM) the stimulation elicited by the partial agonist SKF38393 is comparable to that of the full agonist dopamine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative effects of forskolin and isoproterenol on the cyclic AMP content of human adipocytes

Alterations in adipocyte cyclic AMP concentrations in response to 100 microM forskolin and 10 microM isoproterenol over a 4 hour period were found to be similar; with each agent, a peak response was noted within 30 minutes. In general, the greater the magnitude of peak response, the more rapid the decline of cyclic AMP concentration during the ensuing 3 1/2 hours. Alpha-2 adrenergic activation, achieved with 10 microM clonidine or 10 microM epinephrine, substantially reduced the cyclic AMP concentrations in cells stimulated by 100 microM forskolin or 10 microM isoproterenol. Isoproterenol-stimulated cells appeared to be more sensitive to alpha adrenergic inhibition than did forskolin-stimulated cells. Cells preincubated for 3 hours with 100 microM forskolin were markedly less responsive to a second exposure to the diterpine. Cells exposed to forskolin for 3 hours also had a reduced response when incubated with isoproterenol; thus, desensitization to forskolin appears to be heterologous. Forskolin desensitization did not appear to be dependent on cellular ATP depletion since cells mildly stimulated during preincubation were as severely desensitized as those adipocytes strongly stimulated. Maximum desensitization required a preincubation time of 1-2 hours with either isoproterenol or forskolin.     

Role of calcium in acetylcholine-induced desensitization in dog thyroid slices

Incubation of dog thyroid slices with 1 microM acetylcholine (ACH) for 3 h followed by a second 2-h incubation without it induces a diminution of stimulation of glucose oxidation by ACH during a third incubation of 45 min. Using a calcium-free medium during all incubations prevents the desensitization and reduces, but does not abolish, ACH stimulation of glucose oxidation. EGTA [ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid] (2 mM) added to the calcium-free medium in all incubations prevents both refractoriness and stimulation of glucose oxidation induced by ACH. Calcium depletion during the first incubation only, achieved by using EGTA and a calcium-free medium, also prevents refractoriness but not the augmentation of glucose oxidation caused by ACH. Incubation of thyroid slices with 1 microM ionophore A23817 during the 3-h first incubation decreases the stimulation of glucose oxidation induced by its readdition or by 1 microM ACH added for the first time in the third incubation. Ionophore-induced desensitization is not related to a cholinergic muscarinic receptor effect. Initial incubation of dog thyroid slices with 1 microM ACH diminishes the subsequent stimulation of glucose oxidation by 0.5 microM ionophore. However, the ACH-induced desensitization to ionophore can be overcome by a 10-fold increase in the amount of ionophore in the third incubation. Ionophore (1 microM) in the first incubation also induces refractoriness to thyroid-stimulating hormone (TSH) (10 mU/ml)-stimulated glucose oxidation in the third incubation. In contrast, initial incubation of thyroid slices with TSH (25 mU/ml) does not affect the stimulation of glucose oxidation by 0.5 microM ionophore added during the third incubation. These results suggest that increased intracellular calcium plays a major role in, or even mediates, ACH-induced desensitization in the thyroid gland.     

Regulation of adenosine 3':5'-monophosphate-dependent protein kinase in cerebral cortex

Alterations in the cyclic AMP-dependent protein kinase activity ratio in response to putative neurotransmitters and other cyclic AMP-elevating agents in intact cerebral cortical slices and Krebs-Ringer particulate preparations from cerebral cortex were examined. Both norepinephrine (30 microM) and forskolin (20 microM) produced a time-dependent increase in intracellular levels of cyclic AMP in cerebral cortical slices which was paralleled by an increase in both cyclic AMP and the protein kinase activity ratio. The increases were maximal at 5 min. and remained elevated for at least 15 min. Forskolin, norepinephrine, adenosine and isoproterenol produced a concentration-dependent increase in both cyclic AMP and the protein kinase activity ratio, however, the degree of increase observed was dissimilar. Thus, a 5-fold change in intracellular cyclic AMP resulted in only a 2-fold increase in the activity ratio. Of the agents examined, forskolin produced the most marked change in the activity ratio (from 0.23 to 0.78 at 100 microM) while isoproterenol at 100 microM produced only a 50% increase in the activity ratio. The half-time for the decline in forskolin elicited elevations of either the activity ratio or cyclic AMP was about 4-6 min. In the presence of the phosphodiesterase inhibitor, Ro 20-1724, both were significantly prolonged being 60-70% of the maximum observed immediately after forskolin stimulation, at 15 min. Potentiation of forskolin elicited increases in the activity ratio by Ro 20-1724 were also observed but the increase in the activity ratio was maximal at 7.5 min. while cyclic AMP accumulations continued to rise during the entire 15 min. incubation. Particulate preparations from cerebral cortex were found to contain a cyclic AMP-dependent protein kinase which could be activated 2 to 3-fold with either forskolin, norepinephrine, or adenosine. Unlike the intact brain slice the changes in protein kinase activity ratio and intracellular levels of cyclic AMP in cell-free particulate preparations were similar in both time and degree.     

Role of cell contractions in cAMP-induced cardiomyocyte atrial natriuretic peptide release

Incubation of spontaneously beating ventricular cardiomyocytes from neonatal rats with prostaglandin E(2) (0.1 microM) or forskolin (0.1 microM) simultaneously increased the rate of cellular contraction and atrial natriuretic peptide (ANP) secretion. Both responses were maximal within 10-20 min of application and were accompanied by three- to fourfold increases in cAMP formation. By contrast, a higher regimen of forskolin (10 microM) promoted a 20- to 30-fold increase in basal cAMP production, which was accompanied by the abolition of contractile activity and ANP release. Low regimens of forskolin (0.1 microM) doubled the occurrence of cytosolic Ca(2+) transients associated with monolayer contraction, whereas higher regimens of forskolin (10 microM) completely suppressed Ca(2+) transients. Moreover, in quiescent cultures that were pretreated with ryanodine, tetrodotoxin, nifedipine, or butanedione monoxime, prostaglandin E(2) (0.1 microM) and forskolin (0.1 microM) failed to elicit significant ANP secretion, suggesting that cAMP-elevating agents promote ANP secretion to a great extent via an increase in cellular contraction frequency in ventricular cardiomyocytes.     

Isoproterenol-induced desensitization of mucin release in isolated rat submandibular acini

Release of [14C]glucosamine-labelled mucins was studied in vitro using well-characterised preparations of rat submandibular acini. Mucin release was stimulated by forskolin, an activator of the catalytic subunit of adenylate cyclase, and 3-isobutyl-1-methylxanthine (IBMX), a cyclic nucleotide phosphodiesterase inhibitor. Both stimulated in a dose-dependent manner to the same maximum as that seen with isoproterenol. Neither forskolin nor IBMX added in the presence of isoproterenol increased secretion above the maximum in response to isoproterenol alone, suggesting a similar mechanism of action, mediated by cyclic AMP. Prior exposure of acini to isoproterenol (10 microM) for 45 min, followed by washout resulted in (a) persistent increase in basal secretion which was abolished by propranolol and (b) reduced stimulation of mucin secretion in response to either a second isoproterenol challenge, noradrenaline or forskolin. Thus, exposure of rat submandibular acini in vitro desensitizes the cells to subsequent stimulation. Although this mimics the decreased beta-adrenergic secretory responses seen in submandibular cells from cystic fibrosis patients, results suggest that the isoproterenol-induced desensitization is at the level of beta-receptor and adenylate cyclase, rather than distal to cyclic AMP.     

A dose-response study of forskolin, stimulatory hormone, and guanosine triphosphate analog on adenylate cyclase from several sources

We have described relationships involving forskolin stimulation of adenylate cyclase (AC) from a variety of sources and the potentiation of forskolin effects by stimulatory hormones (glucagon, ACTH, and epinephrine) and beta, gamma-imidoguanosine 5'-triphosphate (Gpp(NH)p). The effects on AC were examined using membrane preparations of rabbit adipocytes, rat adipocytes, rat erythrocytes, and rat liver. Also examined was the AC of liver membranes of rat pretreated with pertussis toxin as well as that solubilized from rat liver membranes. Maximal forskolin stimulation of AC in all preparations studied revealed a consistent 10-fold increase in AC activity. The EC50 for forskolin was 10 microM for rat liver, 15 microM for rabbit and rat adipocytes and 17 microM for rat erythrocyte AC stimulation. In all cases the AC activity attained by forskolin stimulation was further enhanced by stimulatory hormones in a dose-dependent manner. Furthermore, a combination of all three activators (forskolin, stimulatory hormone, and Gpp(NH)p) resulted in an even greater overall stimulation to levels ranging from 25- to 30-fold over unstimulated activity levels. In the presence of saturating levels of each stimulatory hormone and Gpp(NH)p, the EC50 for forskolin diminished markedly to the range of 0.5 to 4.0 microM. In the absence of any apparent tissue specificity for forskolin stimulation, the general pattern of these results further implicates the catalytic site of the AC complex as the site of forskolin activation. Furthermore, activation of additional components of the complex by Gpp(NH)p and tissue specific hormones may further influence the AC activity and thereby potentiate the stimulation by forskolin.     

Effects of insulin and norepinephrine on glucose transport and metabolism in rat brown adipocytes. Potentiation by insulin of norepinephrine-induced glucose oxidation

Glucose is an important fuel for rat brown adipose tissue in vivo and its utilization is highly sensitive to insulin. In this study, the different glucose metabolic pathways and their regulation by insulin and norepinephrine were examined in isolated rat brown adipocytes, using [6-14C]glucose as a tracer. Glucose utilization was stimulated for insulin concentrations in the range of 40-1000 microU/ml. Furthermore, the addition of adenosine deaminase (200 mU/ml) or adenosine (10 microM) did not alter insulin sensitivity of glucose metabolism. The major effect of insulin (1 mU/ml) was a respective 7-fold and 5-fold stimulation of lipogenesis and lactate synthesis, whereas glucose oxidation remained very low. The 5-fold stimulation of total glucose metabolism by 1 mU/ml of insulin was accompanied by an 8-fold increase in glucose transport. In the presence of norepinephrine (8 microM), total glucose metabolism was increased 2-fold. This was linked to a 7-fold increase of glucose oxidation, whereas lipogenesis was greatly inhibited (by 72%). In addition, norepinephrine alone did not modify glucose transport. The addition of insulin to adipocytes incubated with norepinephrine, induced a potentiation of glucose oxidation, while lipogenesis remained very low. In conclusion, in the presence of insulin and norepinephrine glucose is a oxidative substrate for brown adipose tissue. However the quantitative importance of glucose as oxidative fuel remains to be determined.     

Chymotrypsin selectively decreases forskolin stimulation of adenylate cyclase

We studied the effects of chymotrypsin on turkey erythrocyte membrane adenylate cyclase activity. Proteolysis with chymotrypsin led to a concentration- and time-dependent increase in activation of adenylate cyclase by isoproterenol + guanine nucleotides, and fluoride, and to a decrease in activation by forskolin. Maximal effects (up to 10-fold increases in fluoride- and isoproterenol + guanine nucleotide-stimulated activity, and up to 100% inhibition of forskolin-stimulated activity) occurred under similar conditions (10-20 micrograms/ml chymotrypsin for 10-15 min at 30 degrees C). Augmentation of isoproterenol + guanosine-3'-O-thiotriphosphate (GTP-gamma-S)-stimulated activity by chymotrypsin occurred only if proteolysis preceded stimulation with isoproterenol + GTP-gamma-S. Addition of isoproterenol + GTP-gamma-S to membranes before proteolysis, however, did not prevent chymotrypsin from augmenting subsequent stimulation by these agents. In contrast, addition of forskolin during proteolysis with chymotrypsin prevented the time- and concentration-dependent decline in forskolin stimulation observed with chymotrypsin. Proteolysis decreased the magnitude of stimulation at any concentration of forskolin, but did not alter the concentration dependence of forskolin stimulation (apparent half-maximum = 3 microM). The data are consistent with the existence of a chymotrypsin-sensitive site essential for forskolin stimulation of adenylate cyclase. In view of the simultaneous effect of chymotrypsin to augment fluoride- and isoproterenol + guanine nucleotide-stimulated activities, it is highly unlikely that the site is on the stimulatory guanine nucleotide binding protein. Since forskolin is thought to act directly on the catalytic unit of adenylate cyclase, and since forskolin can protect against the effect of proteolysis with chymotrypsin, the site involved may be on the catalytic unit itself.     

Acute and chronic effects of glucose and carbachol on insulin secretion and phospholipase C activation: studies with diazoxide and atropine

The acute and chronic effects of 20 mM glucose and 10 microM carbachol on beta-cell responses were investigated. Acute exposure of rat islets to 20 mM glucose increased glucose usage rates and resulted in a large insulin-secretory response during a dynamic perifusion. The secretory, but not the metabolic, effect of 20 mM glucose was abolished by simultaneous exposure to 100 microM diazoxide. Glucose (20 mM) significantly increased inositol phosphate (IP) accumulation, an index of phospholipase C (PLC) activation, from [(3)H]inositol-prelabeled islets. Diazoxide, but not atropine, abolished this effect as well. Unlike 20 mM glucose, 10 microM carbachol (in the presence of 5 mM glucose) increased IP accumulation but had no effect on insulin secretion or glucose (5 mM) metabolism. The IP effect was abolished by 50 microM atropine but not by diazoxide. Chronic 3-h exposure of islets to 20 mM glucose or 10 microM carbachol profoundly reduced both the insulin-secretory and PLC responses to a subsequent 20 mM glucose stimulus. The adverse effects of chronic glucose exposure were abolished by diazoxide but not by atropine. In contrast, the adverse effects of carbachol were abolished by atropine but not by diazoxide. Prior 3 h of exposure to 20 mM glucose or carbachol had no inhibitory effect on glucose metabolism. Significant secretory responses could be evoked from 20 mM glucose- or carbachol-pretreated islets by the inclusion of forskolin. These findings support the concept that an early event in the evolution of beta-cell desensitization is the impaired activation of islet PLC.     

Acetylcholine receptor channel properties in rat myotubes exposed to forskolin

Rat myotubes exposed to forskolin were studied by patch-clamp technique in cell-attached single channel recording configuration. Channel open time and opening frequency of the main class of acetylcholine receptor- (AChR-) channels (accounting for more than 90% of all unitary events) decreased in the presence of forskolin (20-100 microM). The forskolin-induced action on the AChR function fully developed with a delay of 30-60 minutes from the peak of cytosolic cyclic AMP (cAMPi) concentration. Both cAMP (1 mM), applied intracellularly for 10 min, and dibutyryl cAMP (0.5 mM), applied extracellularly for 90 min, did not accelerate the rate of desensitization of myotubes studied in whole-cell patch-clamp recording configuration. It was concluded that the action of forskolin on AChR-channel function of rat myotubes could be not associated with the cAMPi-dependent phosphorylation of AChR.     

The regulation of glucose transport by cAMP stimulators via three different mechanisms in rat and human adipocytes

The regulation of glucose transport by a beta-adrenergic agonist and other cAMP stimulators was assessed by kinetic analyses of 3-O-methylglucose (MG) transport in rat and human adipocytes and in isolated rat plasma membrane vesicles. Basal MG transport was biphasically affected by L-isoproterenol in rat adipocytes: lower concentrations (10-25 nM) of L-isoproterenol stimulated the basal rate by increasing the Vmax, but higher concentrations (0.5-2 microM) of L-isoproterenol inhibited the basal rate. On the other hand, the maximum insulin-stimulated MG transport rate was not affected by 25 nM L-isoproterenol, but was suppressed by 2 microM L-isoproterenol in rat adipocytes. In the presence of adenosine deaminase plus L-isoproterenol (25 nM and 2 microM), dibutyryl cyclic AMP (Bt2cAMP), 3-isobutyl-1-methylxanthine, or forskolin, both basal and the maximum rates of MG transport were suppressed in rat adipocytes. However, from kinetic experiments, both L-isoproterenol plus adenosine deaminase and Bt2cAMP decreased the Vmax. On the other hand, isobutymethylxanthine and forskolin decreased the Vmax as well as increased the K8. MG transport in plasma membrane vesicles was directly inhibited by either forskolin or isobutylmethylxanthine. In contrast, both 25 nM and 2 microM L-isoproterenol with or without adenosine deaminase, Bt2cAMP, or cAMP had no effect on MG transport in rat plasma membrane vesicles. In human adipocytes, L-isoproterenol always stimulated basal MG transport and did not suppress the maximum rate of MG transport, even though cAMP production was maximally stimulated by L-isoproterenol. Both adenosine deaminase plus L-isoproterenol and Bt2cAMP did not suppress the basal rate, but did show a modest suppression (40%) of the maximum insulin effect on MG transport in human adipocytes. However, both isobutylmethylxanthine and forskolin remarkably suppressed (85%) both the basal and the maximum rate of MG transport by both increasing the K8 and decreasing the Vmax. These results indicate MG transport in both rat and human adipocytes is regulated by 3 different mechanisms: (I) L-isoproterenol, a beta-adrenergic agonist, stimulates basal MG transport by increasing the Vmax, (II) cAMP mediates a decrease in MG transport by decreasing the Vmax, and (III) both forskolin and isobutylmethylxanthine also decrease MG transport by directly inhibiting the binding of MG molecules to transporters, resulting in a decrease in the Vmax and an increase in the K8.     

Stimulation of bile acid active transport related to increased mucosal cyclic AMP content in rat ileum in vitro

The regulation of bile acid transport in rat ileum was studied in vitro using the adenylate cyclase stimulator forskolin, or 3-isobutyl-1-methylxanthine (IBMX), a phosphodiesterase inhibitor. Forskolin 20 microM as well as 100 microM IBMX enhanced mucosal cyclic AMP to 3-fold the control levels. As a physiological response, net fluid absorption in everted ileal sacs was reduced. Taurocholate (10-500 microM) transfer in everted perfused segments of rat ileum was measured using a three compartment dual label method suitable for measuring active transport. Transport asymmetry with absorption exceeding its counterflux by 26-fold, was measured at 500 microM taurocholate. Forskolin increased absorption of taurocholate still further, by 68%, and reduced the serosal to mucosal flux. Enhanced intracellular accumulation of taurocholate indicated a stimulatory action of forskolin on active transport at the mucosal brush-border membrane. In uptake studies, accumulation of taurocholate was enhanced by 100 microM IBMX also. Forskolin-induced uptake stimulation could also be shown for chenodeoxycholate and cholate. In the presence of the neuronal blocker tetrodotoxin, uptake stimulation was still effective. Results indicate that the ileal bile acid transporter is included within the group of sodium-dependent cotransporters of the rat small intestine which are subject to a cyclic AMP-related stimulation at the mucosal cellular level.     

Interactions of insulin, catecholamines and adenosine in the regulation of glucose transport in isolated rat cardiac myocytes

The regulation of the glucose transport system by catecholamines and insulin has been studied in isolated rat cardiomyocytes. In the basal state, 1-isoproterenol exhibited a biphasic concentration-dependent regulation of 3-O-methylglucose transport. At low concentrations (less than 10 nM), isoproterenol induced a maximal inhibition of 65-70% of the basal rates, while at higher concentrations (greater than 10 nM) a 25-70% stimulation of transport was observed. In the presence of adenosine deaminase, the inhibition of isoproterenol at low doses was attenuated. No effect of adenosine deaminase was observed on the stimulation of transport at high doses of isoproterenol. The inhibitory effect of isoproterenol returned when N6-phenylisopropyladenosine (a non-metabolizable analog of adenosine) was included along with adenosine deaminase. Dibutyryl cAMP and forskolin both inhibited basal transport rates. In the presence of maximally stimulating concentrations of insulin, cardiomyocyte 3-O-methylglucose transport was generally elevated 200-300% above basal levels. In the presence of isoproterenol, insulin stimulation was inhibited at both high and low concentrations of catecholamine, with maximum inhibition occurring at the lowest concentrations tested. When cells were incubated with both adenosine deaminase and isoproterenol, the inhibition of the insulin response was greater at all concentrations of catecholamine and was almost completely blocked at isoproterenol concentrations of 10 nM or less. Dibutyryl cAMP inhibited the insulin response to within 10% of basal transport levels, while forskolin completely inhibited all transport activity in the presence of insulin. These results suggest that catecholamines regulate basal and insulin-stimulated glucose transport via both cAMP-dependent and cAMP-independent mechanisms and that this regulation is modulated in the presence of extracellular adenosine.     

Inhibition of 3-O-methylglucose transport in human erythrocytes by forskolin

The effect of forskolin, an activator of adenylate cyclase, was investigated on glucose transport in human erythrocytes. Forskolin was found to be a potent inhibitor of 3-O-methylglucose (3-O-MG) influx in human erythrocytes. The inhibition of 3-O-MG transport was instantaneous and reversible. The inhibitory effect of forskolin was concentration-dependent, having an IC50 value of 7.5 microM. Forskolin caused a decrease in Vmax of carrier-mediated 3-O-MG transport from 35.32 to 1.56 mumol/ml of cell X min in the presence of 50 microM forskolin. Inhibition of influx was not reversed at high concentrations of 3-O-MG. In addition, forskolin inhibited the influx of other carbohydrates including galactose, ribose, and fructose. In contrast, forskolin was without effect on adenosine transport. To unravel the underlying mechanism responsible for the inhibitory action of forskolin, the possible involvement of cyclic AMP in controlling glucose transport was examined. Erythrocytes treated with 50 microM forskolin exhibited an increase in cyclic AMP content from the basal levels of 258 fmol/ml of cell to 334 fmol/ml of cell within 10 s after forskolin exposure. However, erythrocytes in which cyclic AMP was allowed to accumulate in excess of 10,000 times the basal level, by means of preincubation with exogenous cyclic AMP, displayed 3-O-MG transport indistinguishable from that of cyclic AMP-poor control cells. In view of the finding that cyclic AMP plays no discernible role in the erythrocyte 3-O-MG transport, it is suggested that the forskolin inhibition is mediated by a mechanism other than by stimulating adenylate cyclase activity. Moreover, forskolin appears to directly inactivate the 3-O-MG transport system since glucose-sensitive cytochalasin B binding to erythrocyte membranes is virtually abolished by 50 microM forskolin.     

Stimulation by insulin of glycolysis in cultured hepatocytes is attenuated by extracellular ATP and puromycin through purine-dependent inhibition of phosphofructokinase 2 activation

Activation of glycolysis by insulin in cultured rat hepatocytes is preceded by an activation of phosphofructokinase 2 (PFK 2) and subsequent rise of the fructose 2,6-bisphosphate [Fru(2,6)P2] level. Extracellular addition of ATP or puromycin prevented the hormonal effect on glycolysis. The mechanism through which the purines abolished glycolytic stimulation was investigated. 1. 50 microM ATP completely prevented the 3-5-fold insulin-dependent increase of glycolysis, irrespective of whether the cells initially possessed a low or a high Fru(2,6)P2 content. 50 microM puromycin prevented the stimulation of glycolysis by insulin only in cells whose initial Fru(2,6)P2 levels were low and had to be increased by insulin prior to the increase in glycolysis. It did not antagonize the action of insulin cells with initial high Fru(2,6)P2 content. 2. ATP exerted effects on its own; it decreased initially high Fru(2,6)P2 levels by 95% within 10 min and decreased the basal glycolytic rate by 60%. Half-maximal effects on the Fru(2,6)P2 level were obtained with about 25 microM ATP or 15 microM adenosine 5'[beta, gamma-methylene]triphosphate. ADP and adenosine-5-[gamma-thio]triphosphate were as effective as ATP, whereas 100 microM adenosine 5'[alpha, beta-methylene]triphosphate elicited no effect. Puromycin neither decreased high Fru(2,6)P2 levels nor inhibited basal glycolysis. 3. Extracellular ATP (100 microM) led to inhibition of the active form of PFK 2. Intracellular levels of Glc6P, citrate, ATP, ADP and AMP were increased by extracellular ATP, the phosphoenolpyruvate content was decreased, Fru6P and glycerol 3-phosphate levels stayed constant. Puromycin did not inhibit PFK 2. 4. Both puromycin and ATP prevented the insulin-dependent rise of the Fru(2,6)P2 level, they abolished the activation of PFK 2 by the hormone. Puromycin did not block the accumulation of Fru(2,6)P2 provoked by glucose addition; ATP also antagonized the glucose-dependent increase. 5. 100 microM ATP elevated the cAMP-dependent protein kinase activity ratio from 0.1 to 0.38 and increased the level of inositol trisphosphate by 16-fold within 5 min, whereas puromycin was without effect on either level. It is concluded that the two purines block the insulin effect on glycolysis by preventing the hormone increasing the Fru(2,6)P2 level. The mode of action, however, seems to be different: ATP antagonizes insulin action in that it leads to increased inhibition of PFK 2 whereas puromycin prevents the activation of PFK 2 by insulin.     

Mass measurements of inositol 1,4,5-trisphosphate and inositol 1,3,4,5-tetrakisphosphate in a neuronal cell line stimulated with bradykinin: inositolphosphate response shows desensitization.

In a neuronal cell line (108CC15, NG108-15) the levels of inositol 1,4,5-trisphosphate (InsP3) and inositol 1,3,4,5-tetrakisphosphate (InsP4), as measured by receptor binding assays, rise transiently after stimulation with bradykinin (EC50 approx. 150 nM). Maximal InsP3 level of 354 pmol/mg protein (15-fold basal level) is obtained at 10-15 s after addition of bradykinin, the InsP4 level rises maximally to 78 pmol/mg protein (14-fold basal level) at 20-30 s. In a rat glioma cell line, bradykinin (2 microM) causes a fast 6-fold increase in InsP3 and InsP4 levels. In the neuronal cells the bradykinin-dependent rise of the inositolphosphate levels is diminished with reduced extracellular Ca2+ concentration. However, depletion of internal Ca2+ stores does not affect the bradykinin-induced rise in InsP3 and InsP4 levels. Homologous desensitization to bradykinin occurs in the signal transduction pathway already at the production of inositolphosphates, since after a 2 min stimulation with bradykinin the rise in cellular masses of InsP3 and InsP4, inducible by a following second bradykinin stimulus, is substantially reduced.     

Effect of stimulation frequency on contraction-induced glucose transport in rat skeletal muscle

Previous studies have indicated that frequency of stimulation is a major determinant of glucose transport in contracting muscle. We have now studied whether this is so also when total force development or metabolic rate is kept constant. Incubated soleus muscles were electrically stimulated to perform repeated tetanic contractions at four different frequencies (0.25, 0.5, 1, and 2 Hz) for 10 min. Resting length was adjusted to achieve identical total force development or metabolic rate (glycogen depletion and lactate accumulation). Overall, at constant total force development, glucose transport (2-deoxyglucose uptake) increased with stimulation frequency (P < 0.05; basal: 25 +/- 2, 0.25 Hz: 50 +/- 4, 0.5 Hz: 50 +/- 3, 1 Hz: 81 +/- 5, 2 Hz: 79 +/- 3 nmol. g(-1). 5 min(-1)). However, glucose transport was identical (P > 0.05) at the two lower (0.25 and 0.5 Hz) as well as at the two higher (1 and 2 Hz) frequencies. Glycogen decreased (P < 0.05; basal: 19 +/- 1, 0.25 Hz: 13 +/- 1, 0.5 Hz: 12 +/- 2, 1 Hz: 7 +/- 1, 2 Hz: 7 +/- 1 mmol/kg) and 5'-AMP-activated protein kinase (AMPK) activity increased (P < 0. 05; basal: 1.7 +/- 0.4, 0.25 Hz: 32.4 +/- 7.0, 0.5 Hz: 36.5 +/- 2.1, 1 Hz: 63.4 +/- 8.0, 2 Hz: 67.0 +/- 13.4 pmol. mg(-1). min(-1)) when glucose transport increased. Experiments with constant metabolic rate were carried out in soleus, flexor digitorum brevis, and epitrochlearis muscles. In all muscles, glucose transport was identical at 0.5 and 2 Hz (P > 0.05); also, AMPK activity did not increase with stimulation frequency. In conclusion, muscle glucose transport increases with stimulation frequency but only in the face of energy depletion and increase in AMPK activity. This indicates that contraction-induced glucose transport is elicited by metabolic demands rather than by events occurring early during the excitation-contraction coupling.