Effects of calcium and chelating agents on the ability of various agonists to increase cyclic GMP in pancreatic acinar cells.

In dispersed acinar cells from guinea pig pancreas we found that chelating extracellular calcium with EDTA did not alter cellular cyclic GMP but caused a 50% reduction in the increase in cyclic GMP caused by the synthetic C-terminal octapeptide of porcine cholecystokinin (cholecystokinin octapeptide). This effect was maximal within 2 min and preincubating the cells with EDTA for as long as 30 min caused no further reduction in the action of cholecystokinin octapeptide. In acinar cells preincubated without calcium, adding calcium caused a time dependent increase in the action of cholecystokinin octapeptide and this increase was maximal after 10 min of incubation. An effect of extracellular calcium on the action of cholecystokinin octapeptide could be detected with 0.5 mM calcium and was maximal with 2.0 mM calcium. Magnesium alone or with calcium did not alter the action of cholecystokinin octapeptide. Extracellular calcium did not alter the time course or the configuration of the dose vs. response curve for the action of cholecystokinin octapeptide on cellular cyclic GMP. Low concentrations of EGTA (0.1 mM) decreased the effect of cholecystokinin octapeptide on cellular cyclic GMP to the same extent as did EDTA or preincubating acinar cells without calcium. Increasing EGTA above 0.1 mM caused progressive augmentation of the action of cholecystokinin octapeptide on cellular cyclic GMP and this augmentation did not require extracellular calcium or magnesium. Results similar to those obtained with cholecystokinin octapeptide were also obtained with bombesin, carbamylcholine, litorin and eledoisin. In contrast, the action of sodium nitroprusside on cyclic GMP in pancreatic acinar cells was not altered by adding EDTA or EGTA. These results indicate that the ability of extracellular calcium to influence the action of cholecystokinin octapeptide and other agents on cyclic GMP results from changes in cellular calcium and not from effects of extracellular calcium per se. The action of low concentrations of EGTA on the increase in cyclic GMP caused by various agents reflects the ability of EGTA to chelate extracellular calcium. The actions of high concentrations of EGTA were independent of extracellular calcium or magnesium and appear to reflect a direct action of EGTA on pancreatic acinar cells.     

Action of cholecystokinin, cholinergic agents, and A-23187 on accumulation of guanosine 3':5'-monophosphate in dispersed guinea pig pancreatic acinar cells.

The COOH-terminal octapeptide of cholecystokinin (CCK-OP) and carbamylcholine each increased calcium outflux, cellular cyclic GMP and amylase secretion in dispersed guinea pig pancreatic acinar cells. Following addition of CCK-OP or carbamylcholine, cellular cyclic GMP increased as early as 15 s, became maximal after 1 to 2 min, and then decreased steadily during the subsequent incubation. For both CCK-OP and carbamylcholine there was close agreement between the dose-response curve for stimulation of calcium outflux and that for increase of cellular cyclic GMP. With CCK-OP an effect on both functions could be detected at 10(-10) M and maximal stimulation occurred at 3 X 10(-8) M. With carbamylcholine an effect on both functions could be detected at 10(-5) M and maximal stimulation occurred at 3 X 10(-3) M. Atropine inhibited stimulation of both cyclic GMP and calcium outflux by carbamylcholine but not by CCK-OP. Stimulation of calcium outflux or cellular cyclic GMP by CCK-OP or carbamylcholine did not require extracellular calcium since stimulation occurred in a calcium-free, ethylene glycol bis(beta, beta-aminoethyl ether) N,N'-tetraacetic acid (EGTA)-containing solution. The divalent cation ionophore A-23187 increased bidirectional fluxes of calcium, cellular cyclic GMP and secretion of amylase from dispersed pancreatic acinar cells. Like CCK-OP and carbamylcholine, the ionophore stimulated calcium outflux and cellular cyclic GMP in a calcium-free, EGTA-containing solution. These results suggest that in pancreatic acinar cells the initial step in the sequence of events mediating the action of ionophore as well as that of CCK-OP and carbamylcholine is stimulation of calcium outflux, and that this stimulation then increases cellular cyclic GMP.     

Evidence against cyclic GMP as a mediator of the actions of secretagogues on amylase release from guinea-pig pancreas

In dispersed acini from guinea-pig pancrease several pancreatic secretagogues increased calcium outflux, cyclic GMP and amylase secretion, whereas nitroprusside and hydroxylamide increased cyclic GMP but did not increase calcium outflux or amylase secretion and did not alter the action of secretagogues on calcium outflux or amylase secretion. Secretin and vasoactive intestinal peptide increased cyclic AMP and increased secretion but did not alter cyclic GMP. Nitroprusside and hydroxylamine did not alter cyclic AMP or the action of secretin or vasoactive intestinal peptide on cyclic AMP and enzyme secretion. Agents that increased cyclic GMP also caused release of the nucleotide into the extracellular medium; however, this release did not correlate with secretion of amylase into the extracellular medium. 8-Bromo cyclic AMP as well as 8-bromo cyclic GMP increased enzyme secretion and potentiated the increase in enzyme secretion caused by cholecystokinin or carbachol. The increase in amylase secretion caused by vasoactive intestinal peptide or secretin plus either of the cyclic nucleotide derivatives was the same as that caused by the peptide alone. These results indicate that cyclic GMP does not mediate the action of secretagogues on pancreatic enzyme secretion, that the release of cyclic GMP into the extracellular medium does not occur by exocytosis and that the increase in enzyme secretion caused by 8-bromo cyclic GMP results from its stability to mimic the action of endogenous cyclic AMP.     

Secretagogue-induced membrane alterations in dispersed acini from rat pancreas

Dispersed acini from rat pancreas were used to examine the effects of various pancreatic secretagogues on the fine structure of the acinar cell plasma membrane. With the C-terminal octapeptide of cholecystokinin, the C-terminal tetrapeptide of cholecystokinin, carbamylcholine, bombesin, A23187, vasoactive intestinal peptide or 8-bromo cyclic adenosine monophosphate, concentrations of the secretagogues that caused maximal stimulation of enzyme secretion did not produce alterations of the acinar cell plasma membrane. Supramaximal concentrations of the C-terminal octapeptide of cholecystokinin, the C-terminal tetrapeptide of cholecystokinin or carbamylcholine induced the formation of cytoplasmic protrusions at the basolateral plasma membrane of the pancreatic acinar cell, whereas supramaximal concentration of bombesin, A23187, vasoactive intestinal peptide or 8-bromo cyclic AMP did not alter the morphology of the acinar cell. Effects of the C-terminal octapeptide of cholecystokinin could be detected as early as after two minutes of incubation and these effects progressed for up to 30 minutes of incubation.     

Action of cholera toxin on dispersed acini from guinea pig pancreas

In dispersed acini from guinea pig pancreas cholera toxin bound reversibly to specific membrane binding sites to increase cellular cyclic AMP and amylase secretion. Cholera toxin did not alter outflux of ⁴⁵Ca or cellular cyclic AMP. Binding of ¹²⁵I-labeled cholera toxin could be detected within 5 min; however, cholera toxin did not increase cyclic AMP or amylase release until after 40 min of incubation. There was a close correlation between the dose vs. response curve for inhibition of bindind of ¹²⁵I-labeled cholera toxin by native toxin and the action of native toxin on cellular cyclic AMP. With different concentrations of cholera toxin, maximal stimulation of amylase release occurred when the increase in cellular cyclic AMP was approximately 35% of maximal. Cholera toxin did not alter the increase in ⁴⁵Ca outflux or cellular cyclic GMP caused by cholecystokinin or carbachol but significantly augmented the increase in cellular cyclic AMP caused by secretion or vasoactive intestinal peptide. The increase in amylase secretion caused by cholera toxin plus secretin or vasoactive intestinal peptide was the same as that with cholera toxin alone. On the other hand, the increase in amylase secretion caused by cholera toxin plus cholecystokinin or carbachol was significantly greater than the sum of the increases caused by each agent alone.     

Action of cholera toxin on dispersed acini from guinea pig pancreas.

In dispersed acini from guinea pig pancreas cholera toxin bound reversibly to specific membrane binding sites to increase cellular cyclic AMP and amylase secretion. Cholera toxin did not alter outflux of 45Ca or cellular cyclic AMP. Binding of 125I-labeled cholera toxin could be detected within 5 min; however, cholera toxin did not increase cyclic AMP or amylase release until after 40 min of incubation. There was a close correlation between the dose vs. response curve for inhibition of binding of 125I-labeled cholera toxin by native toxin and the action of native toxin on cellular cyclic AMP. With different concentrations of cholera toxin, maximal stimulation of amylase release occurred when the increase in cellular cyclic AMP was approximately 35% of maximal. Cholera toxin did not alter the increase in 45Ca outflux or cellular cyclic GMP caused by cholecystokinin or carbachol but significantly augmented the increase in cellular cyclic AMP caused by secretin or vasoactive intestinal peptide. The increase in amylase secretion caused by cholera toxin plus secretin or vasoactive intestinal peptide was the same as that with cholera toxin alone. On the other hand, the increase in amylase secretion caused by cholera toxin plus cholecystokinin or carbachol was significantly greater than the sum of the increases caused by each agent alone.     

Action of cholera toxin on dispersed acini from rat pancreas: Post-receptor modulation involving cyclic AMP and calcium

In dispersed acini from rat pancreas, cholera toxin caused a significant increase in cellular cyclic AMP but little or no change in amylase secretion. The presence of a secretagogue that causes mobilization of cellular calcium (e.g., cholecystokinin, carbamylcholine, bombesin or ionophore A23187) caused a substantial increase in the effect of cholera toxin on enzyme secretion. Cholera toxin did not alter calcium transport or the changes in calcium transport caused by other secretagogues, and secretagogues that mobilize cellular calcium did not alter cellular cyclic AMP or the increase in cyclic AMP caused by cholera toxin. These results indicate that in dispersed acini from rat pancreas there is post-receptor modulation of the action of cholera toxin by secretagogues that mobilize cellular calcium and that this modulation is a major determinant of the effect of the toxin on enzyme secretion.     

Potassium transport in dispersed mucosal cells from guinea pig stomach

Dispersed mucosal cells (approx. 70% parietal cells) prepared from guinea pig stomach maintained their cellular concentration of potassium (65--80 nmol potassium/10(6) cells) for at least 5 h in vitro. Uptake of 42K by dispersed gastric mucosal cells depended on temperature, H+ concentration and oxidative metabolism. Carbachol and, in some instances, gastrin caused a 40--50% increase in cellular uptake of 42K as a consequence of the ability of these agents to increase 42K influx. Ouabain reduced uptake of 42K by 70% but did not alter the effect of carbachol. Cellular uptake of 42K was not altered by histamine, prostaglandin, E1, glucagon, secretin, vasoactive intestinal peptide or C-terminal octapeptide of cholecystokinin. Uptake of 42K was also increased by dibutyryl cyclic AMP or dibutyryl cyclic GMP but not by cyclic AMP, cyclic GMP or their 8-bromo derivatives. Theophylline caused a small (10--15%) increase in 42K uptake and potentiated the increase caused by submaximal concentrations of carbachol. The increase in 42K uptake caused by either dibutyryl cyclic nucleotide and carbachol was additive.     

BAY-K-8644-stimulated amylase secretion from pancreatic acinar cells

Pancreatic acinar cells do not contain depolarization-sensitive calcium channels. Nonetheless, in the current study, the calcium channel activator, BAY-K-8644, was found to stimulate a time- and concentration-dependent increase in the spontaneous release of amylase. Secretion was dependent on the presence of extracellular calcium in the incubation medium. Racemic BAY-K-8644 and (or) its S(-)optical isomer did not enhance the secretory response to either carbachol or cholecystokinin octapeptide; however, when co-applied with either phorbol ester, vasoactive intestinal peptide, or forskolin, they potentiated amylase secretion. Nifedipine and the R(+)isomer of BAY-K-8644, which are both calcium channel antagonists, did not alter basal or forskolin-stimulated amylase secretion, and [3H]nitrendipine did not bind to acinar cell membranes. Neither atropine nor dibutyryl cGMP, inhibitors of cholinergic and cholecystokininergic receptors, respectively, affected BAY-K-8644-induced amylase secretion. While BAY-K-8644 stimulated concentration-dependent cGMP synthesis in acinar cells, it had no effect on basal or forskolin-stimulated cAMP formation. The data suggest that BAY-K-8644 may bind to acinar cell sites that are not functional calcium channel proteins but are coupled nevertheless to the secretory response, and that calcium channel antagonists do not bind to these sites. The mechanism of the secretagogue action of BAY-K-8644 remains to be elucidated.     

Effects of calcium chelators, divalent cations and sulfhydryl reagents on calcium uptake and motility of bovine spermatozoa

Addition of 1 mM Ca/EGTA complex (1:1 ratio) to an incubation medium containing 1.5 mM Ca2+ produced a notable increase in the Ca2+ cycling in ejaculated bovine spermatozoa. Similar results were also obtained with the Ca/EDTA and Ca/EDTA complexes or with the heavy metal chelator DTPA (50 microM). Ba2+, Ni2+ or Co2+ added at 0.1 mM concentration abolished the stimulatory effect of the Ca/EGTA complex on Ca2+ cycling, whereas it did not affect the calcium movement in the absence of the calcium chelator complex. It is concluded that small amounts of these cations should be bound to the plasma membrane of bovine spermatozoa and inhibit the cellular calcium influx. 0.1 mM Cd2+ and NEM or 1 mM diamide produced a calcium efflux from the spermatozoa together with an inhibition of cellular motility and an increase in glutamate-oxaloacetate transaminase release. Conversely the impermeant sulfhydryl reagent mersalyl caused a net calcium efflux but did not alter the cellular motility nor the transaminase release. It is suggested that the permeant thiol reagents could decrease the spermatozoal mobility by impairing the mitochondrial ATP-synthesis.     

A possible role for guanosine 3′,5′-monophosphate in the stimulus-secretion coupling in exocrine pancreas

Carbamylcholine, caerulein and cholecystokinin octapeptide rapidly increased the cyclic GMP concentration and amylase secretion in isolated guinea pig pancreatic slices. The cyclic GMP concentration was increased eight-fold over the basal concentration in 30 s, with concomitant increase in the rate of amylase secretion. The tissue concentration of cyclic GMP then rapidly declined to a plateau value of approx. 16% of the peak level within 10 min and was maintained at that concentration for the duration of the experiment. We have shown earlier (Kapoor, C.L. and Krishna, G. (1977) Science 196, 1003–1005) that the decrease of tissue cyclic GMP was due mainly to the secretion of cyclic GMP into the medium. The cyclic AMP concentration in the tissue was not changed, nor was it secreted into the medium.There was a correlation between the concentration response to various agents for the increase in cyclic GMP concentration and amylase secretion in pancreatic slices. Carbamylcholine increased both the cyclic GMP concentration and amylase secretion; the half-maximal effect was achieved at 1.5 μM concentration. Caerulein and cholecystokinin octapeptide were 5000 times more potent than carbamylcholine in increasing cyclic GMP concentration and amylase secretion; the half-maximal effect was achieved at 0.3 nM concentration. Atropine, which completely inhibited the increase in cyclic GMP and amylase secretion induced by carbamylcholine, did not block the effects of caerulein or cholecystokinin octapeptide. These results suggest that various secretagogues induced amylase secretion by increasing the cyclic GMP concentration, but the mechanism by which cyclic GMP caused amylase secretion remains to be elucidated.     

Action of cholera toxin on dispersed acini from rat pancreas. Post-receptor modulation involving cyclic AMP and calcium

In dispersed acini from rat pancreas, cholera toxin caused a significant increase in cellular cyclic AMP but little or no change in amylase secretion. The presence of a secretagogue that causes mobilization of cellular calcium (e.g., cholecystokinin, carbamylcholine, bombesin or ionophore A23187) caused a substantial increase in the effect of cholera toxin on enzyme secretion. Cholera toxin did not alter calcium transport or the changes in calcium transport caused by other secretagogues, and secretagogues that mobilize cellular calcium did not alter cellular cyclic AMP or the increase in cyclic AMP caused by cholera toxin. These results indicate that in dispersed acini from rat pancreas there is post-receptor modulation of the action of cholera toxin by secretagogues that mobilize cellular calcium and that this modulation is a major determinant of the effect of the toxin on enzyme secretion.     

Cellular cyclic AMP in dispersed mucosal cells from guinea pig stomach.

In dispersed mucosal cells from guinea pig stomach cyclic AMP was increased 4-fold by theophylline, 5-fold by prostaglandin E2, and 10- to 15-fold by histamine. Theophylline augmented the increase in cellular cyclic AMP caused by histamine or prostaglandin E1 and the actions of histamine and prostaglandin E1 were additive. Cellular cyclic AMP was not altered by carbachol, gastrin, secretin, vasoactive intestinal peptide, glucagon, insulin or the octapeptide of cholecystokinin. Metiamide or diphenhydramine but not atropine inhibited the increase in cellular cyclic AMP caused by histamine, but did not alter the concentration of cyclic AMP in control cells or in cells incubated with theophylline or prostaglandin E1.     

Cholecystokinin-induced residual stimulation of enzyme secretion from mouse pancreatic acini

When dispersed acini from mouse pancreas are first incubated with cholecystokinin octapeptide, washed and then reincubated with no additions there is significant stimulation of amylase secretion during the second incubation (residual stimulation of enzyme secretion). Cholecystokinin-induced residual stimulation of enzyme secretion is modified, but not abolished, by reducing the temperature of the first incubation from 37°C to 4°C. Measurement of binding of ¹²⁵I-labeled cholecystokinin octapeptide indicated that maximal cholecystokinin induced residual stimulation of enzyme secretion occurs when 12–20% of cholecystokinin receptors are occupied by cholecystokinin octapeptide. Moreover, maximal cholecystokinin-induced residual stimulation of amylase secretion is 25% greater than maximal cholecystokinin-induced direct stimulation of amylase secretion. Cholecystokinin tetrapeptide, which causes the same maximal direct stimulation of amylase secretion as does cholecystokinin octapeptide, causes a maximal residual stimulation of enzyme secretion that is only 30% of that caused by a maximally effective concentration of cholecystokinin octapeptide. Adding dibutyryl cyclic GMP to the second incubation can reverse the residual stimulation caused by adding cholecystokinin to the first incubation. The pattern and extent of the dibutyryl cyclic GMP-induced reversal of residual stimulation varies, depending on the temperature and concentration of cholecystokinin octapeptide in the first incubation. The present results are compatible with the hypothesis that mouse pancreatic acini possess two classes of cholecystokinin receptors. One class has a relatively high affinity for cholecystokinin and produces stimulation of enzyme secretion; the other class has a relatively low affinity for cholecystokinin and produces inhibition of enzyme secretion.     

Cholecystokinin-induced residual stimulation of enzyme secretion from mouse pancreatic acini

When dispersed acini from mouse pancreas are first incubated with cholecystokinin octapeptide, washed and then reincubated with no additions there is significant stimulation of amylase secretion during the second incubation (residual stimulation of enzyme secretion). Cholecystokinin-induced residual stimulation of enzyme secretion is modified, but not abolished, by reducing the temperature of the first incubation from 37 degrees C to 4 degrees C. Measurement of binding of 125I-labeled cholecystokinin octapeptide indicated that maximal cholecystokinin induced residual stimulation of enzyme secretion occurs when 12-20% of cholecystokinin receptors are occupied by cholecystokinin octapeptide. Moreover, maximal cholecystokinin-induced residual stimulation of amylase secretion is 25% greater than maximal cholecystokinin-induced direct stimulation of amylase secretion. Cholecystokinin tetrapeptide, which causes the same maximal direct stimulation of amylase secretion as does cholecystokinin octapeptide, causes a maximal residual stimulation of enzyme secretion that is only 30% of that caused by a maximally effective concentration of cholecystokinin octapeptide. Adding dibutyryl cyclic GMP to the second incubation can reverse the residual stimulation caused by adding cholecystokinin to the first incubation. The pattern and extent of the dibutyryl cyclic GMP-induced reversal of residual stimulation varies, depending on the temperature and concentration of cholecystokinin octapeptide in the first incubation. The present results are compatible with the hypothesis that mouse pancreatic acini possess two classes of cholecystokinin receptors. One class has a relatively high affinity for cholecystokinin and produces stimulation of enzyme secretion; the other class has a relatively low affinity for cholecystokinin and produces inhibition of enzyme secretion.     

A possible role for guanosine 3',5'-monophosphate in the stimulus-secretion coupling in exocrine pancreas.

Carbamylcholine, caerulein and cholecystokinin octapeptide rapidly increased the cyclic GMP concentration and amylase secretion in isolated guinea pig pancreatic slices. The cyclic GMP concentration was increased eight-fold over the basal concentration in 30 s, with concomitant increase in the rate of amylase secretion. The tissue concentration of cyclic GMP then rapidly declined to a plateau value of approx. 16% of the peak level within 10 min and was maintained at that concentration for the duration of the experiment. We have shown earlier (Kapoor, CL. and Krishna, G. (1977) Science 196, 1003--1005) that the decrease of tissue cyclic GMP was due mainly to the secretion of cyclic GMP into the medium. The cyclic AMP concentration in the tissue was not changed, nor was it secreted into the medium. There was a correlation between the concentration response to various agents for the increase in cyclic GMP concentration and amylase secretion in pancreatic slices. Carbamylcholine increased both the cyclic GMP concentration and amylase secretion; the half-maximal effect was achieved at 1.5 micrometer concentration. Caerulein and cholecystokinin octapeptide were 5000 times more potent than carbamylcholine in increasing cyclic GMP concentration and amylase secretion; the half-maximal effect was achieved at 0.3 nM concentration. Atropine, which completely inhibited the increase in cyclic GMP and amylase secretion induced by carbamylcholine, did not block the effects of caerulein or cholecystokinin octapeptide. These results suggest that various secretagogues induced amylase secretion by increasing the cyclic GMP concentration, but the mechanism by which cyclic GMP caused amylase secretion remains to be elucidated.     

Endothelium-derived NO, but not cyclic GMP, is required for hypoxic augmentation in isolated porcine coronary arteries

The present study investigated the mechanism underlying the transient potentiation of vasoconstriction by hypoxia in isolated porcine coronary arteries. Isometric tension was measured in rings with or without endothelium. Hypoxia (Po(2) <30 mmHg) caused a transient further increase in tension (hypoxic augmentation) in contracted (with U46619) preparations. The hypoxic response was endothelium dependent and abolished by inhibitors of nitric oxide synthase [N(ω)-nitro-L-arginine methyl ester (L-NAME)] or soluble guanylyl cyclase (ODQ and NS2028). The addition of DETA NONOate (nitric oxide donor) in the presence of L-NAME restored the hypoxic augmentation, suggesting the involvement of the nitric oxide pathway. However, the same was not observed after incubation with 8-bromo-cyclic GMP, atrial natriuretic peptide, or isoproterenol. Assay of the cyclic GMP content showed no change upon exposure to hypoxia in preparations with and without endothelium. Incubation with protein kinase G and protein kinase A inhibitors did not inhibit the hypoxic augmentation. Thus the hypoxic augmentation is dependent on nitric oxide and soluble guanylyl cyclase but independent of cyclic GMP. The hypoxic augmentation persisted in calcium-free buffer and in the presence of nifedipine, ruling out a role for extracellular calcium influx. Hypoxia did not alter the intracellular calcium concentration, as measured by confocal fluorescence microscopy. This observation and the findings that hypoxic augmentation is enhanced by thapsigargin (sarco/endoplasmic reticulum calcium ATPase inhibitor) and inhibited by HA1077 or Y27632 (Rho kinase inhibitors) demonstrate the involvement of calcium sensitization in the phenomenon.     

The actions of tetraethylammonium on dispersed acini from guinea pig pancreas

In dispersed acini from guinea pig pancreas, replacing extracellular sodium by tetraethylammonium (1) abolished carbamylcholine-stimulated amylase secretion but did not alter the increase in amylase secretion caused by the C-terminal octapeptide of cholecystokinin, bombesin, ionophore A23187, vasoactive intestinal peptide or 8-bromoadenosine 3':5' monophosphate, (2) caused a parallel rightward shift in the dose-response curve for carbamylcholine-stimulated amylase secretion and (3) inhibited binding of N-[3H]methyl scopolamine to muscarinic cholinergic receptors. Detectable inhibition of carbamylcholine-stimulated amylase secretion and binding of N-[3H]methyl scopolamine occurred with 300 microM tetraethylammonium, and half-maximal inhibition of these functions occurred with 1-2 mM tetraethylammonium. Replacing extracellular sodium by Tris did not alter the stimulation of enzyme secretion caused by any secretagogue tested. These results indicate that the tetraethylammonium is a muscarinic cholinergic receptor antagonist and that enzyme secretion from pancreatic acini does not depend on extracellular sodium.     

Dissociation of cyclic GMP synthesis from cholinergic-stimulated secretion of protein from rat exocrine pancreas.

The phosphodiesterase inhibitors RO-201724/1 and 1-methyl-3-isobutylxanthine (MIX) stimulate a rapid increase in cyclic GMP content in rat pancreas; the latter agent also potentiates the stimulatory effect of carbachol on cyclic GMP synthesis. However, neither RO-201724/1 nor MIX alter basal secretion of 3H-labeled protein, nor do they affect the secretory response to carbachol used in either suboptimal or optimal concentrations. MIX as well does not alter the rate at which carbachol stimulates pancreatic enzyme release. The ability of carbachol to increase cyclic GMP synthesis is lost if extracellular calcium concentration is lowered to 0.05 mM; at this calcium concentration, however, the muscarinic agent still elicits a marked secretory effect. The dissociation between cyclic GMP synthesis and the secretory response suggests that the cyclic nucleotide does not play a major role in the stimulus--enzyme secretion coupling phenomenon of the exocrine pancreas.     

Cyclic nucleotide phosphodiesterase activities of pig coronary arteries.

Most (85% or more) of the cyclic nucleotide phosphodiesterase (3' :5' -cyclic-AMP 5'-nucleotidohydrolase, EC 3.1.4.17) activity of pig coronary arteries was found in the 40 000 times g supernatant fraction of homogenates of the intima plus media layer. Chromatography of the soluble fraction of this layer on DEAE-cellulose resolved two phosphodiesterase activities and a heat stable, non-dializable activator. Peak I activity had apparent Km values of 2-4 muM for cyclic GMP and 40-100 muM for cyclic AMP. Peak II activity was relatively specific for cyclic AMP and exhibited apparent negatively cooperative behavior. Peak I but not peak II activity could be stimulated 3-8-fold by the addition of the boiled activator fraction or a boiled crude supernatant fraction. Cyclic AMP hydrolysis by peak I or peak II was more rapid in the presence of Mn-2+ than Mg-2+, but the latter promoted hydrolysis of cyclic GMP by peak I more effectively than did Mn-2+ in the presence of activator. In the absence of added metals, ethylene bis(oxyethylenenitriol)tetra-acetic acid (EGTA) and EDTA both inhibited hydrolysis of cyclic AMP and cyclic GMP by phosphodiesterase activities in the supernatant fraction and in peak I, but EDTA produced more complete inhibition at lower concentrations than did EGTA. Imidazole (1 muM to 10 mM) had virtually no effect on the hydrolysis of cyclic AMP or cyclic GMP catalyzed by either of the two separated peaks or by total phosphodiesterase activities in crude supernatant or particulate fractions.