Paul J. Silver

Biochemical aspects of inhibition of cardiovascular low (Km) cyclic adenosine monophosphate phosphodiesterase

Multiple isozymes of cyclic nucleotide phosphodiesterase (PDE) exist in mammalian cells. At least 5 major types of PDE isozymes have been identified; they differ by substrate affinity, maximal activity, intracellular regulation or mechanism of pharmacologic inhibition. A low Michaelis constant (Km) cyclic adenosine monophosphate (cAMP) PDE, whose activity is inhibited by submicromolar concentrations of cyclic guanosine monophosphate and stimulated by cAMP-mediated phosphorylation, is present in both cardiac muscle and vascular smooth muscle. This PDE isozyme (referred to as peak IIIc PDE) is sensitive to selective inhibition by amrinone, milrinone, imazodan, CI-930, piroximone, and numerous other PDE inhibitors. The subcellular distribution of cardiac PDE IIIc varies according to species; it is found in the soluble fraction of guinea pig myocardium, in the particulate fraction of canine myocardium, and in both fractions of primate (simian and human) myocardium. Another PDE isozyme, which is sensitive to inhibition by rolipram and is less sensitive to inhibition by PDE IIIc inhibitors, is found in cardiac muscle of some species (i.e., soluble fractions of rat and canine myocardium) and is apparently not related to direct regulation of positive inotropy. Both positive inotropy and vasorelaxation by milrinone and other PDE IIIc inhibitors can be linked to inhibition of PDE IIIc and activation of the cAMP system. These significant relations are similar to those obtained for other cAMP-related positive inotrope/vasodilators (such as beta-adrenoreceptor agonists). Moreover, an increased rate of ventricular relaxation (lusitropy), which is apparent with PDE IIIc inhibitors, may also be attributable to activation of the cAMP system.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of a specific radioligand for the cardiac rapidly activating delayed rectifier K+ channel.

Class III antiarrhythmic drugs show promise as effective treatments for the suppression of potentially lethal cardiac arrhythmias. Dofetilide (UK-68,798), is a potent class III antiarrhythmic agent that is presently under clinical investigation. The objective of this study was to determine whether [3H]dofetilide could be used as a specific radioligand for the rapidly activating delayed rectifier K+ channel of the heart. We find that [3H]dofetilide binds to high-affinity sites on guinea pig cardiac myocytes. Competition studies using unlabeled dofetilide indicate that binding is characterized by an IC50 of 100 +/- 30 nM (mean +/- SD, n = 13). Scatchard analyses of binding indicate a Kd of 70 +/- 6 nM and a maximal binding capacity of 0.30 +/- 0.02 pmol/mg protein. [3H]Dofetilide is displaced from guinea pig myocytes by dofetilide, clofilium, quinidine, sotalol, and sematilide with a rank order of potency that correlates with functional blockade of the rapidly activating delayed rectifier K+ current (correlation coefficient, 0.951; slope, 0.99 +/- 0.19; p = 0.014). High-affinity [3H]dofetilide binding is not detected in rat myocytes, which are devoid of delayed rectifier K+ current. We conclude that [3H]dofetilide specifically binds to sites associated with the rapidly activating delayed rectifier K+ channel of guinea pig myocardium.

Differential Vasorelaxant Effects of Milrinone and Amrinone on Contractile Responses of Canine Coronary, Cerebral, and Renal Arteries

The vasorelaxant effects of milrinone and amrinone in canine coronary, cerebral, and renal arterial rings or strips contracted by either K+-depolarization, U46619 (a thromboxane mimetic), or prostaglandin F2α (PGF2α) were quantitated. Milrinone was more potent as a vasorelaxant in coronary arteries relative to cerebral or renal arteries regardless of the mode of contraction; amrinone was coronary selective with K+ contraction only. When comparing potency in arteries contracted by different agonists, milrinone was significantly more potent as a vasorelaxant in all three arteries contracted by either U46619 or PGF2α than in arteries contracted by K+ depolarization, whereas amrinone was only selective for U46619-induced contractions in cerebral arteries. This profile of activity for milrinone was similar to that of sodium nitrite and isoproterenol and dissimilar from the calcium entry blocking agents nimodipine and nifedipine. In conclusion, this study shows that coronary vascular selectivity exists for milrinone and amrinone. Moreover, the relaxant profiles of milrinone and amrinone, with different sources of vascular smooth muscle, are unlike those of calcium entry blocking agents and more similar to the profiles of agents that modulate cyclic nucleotide levels.

Modulation of vascular and cardiac contractile protein regulatory mechanisms by calmodulin inhibitors and related compounds

The abilities of several calmodulin antagonists and other compounds belonging to different pharmacological classes to modulate Ca2+ X calmodulin mediated arterial myosin light chain phosphorylation and Ca2+-troponin C regulated cardiac myofibrillar ATPase activity have been quantitated in Triton X-100 purified preparations of bovine aortic actomyosin and canine ventricular myofibrils. At submaximal free Ca2+ concentrations, all calmodulin antagonists inhibited myosin phosphorylation; however, some (calmidazolium, trifluoperazine, chlorpromazine, pimozide) stimulated myofibrillar ATPase activity, some (compound 48/80, W-5) had no effect on activity, while others (W-7, haloperidol, mastoparan) inhibited ATPase activity. The relative order of potency for several agents in both preparations was the same, as IC50 values for inhibition of arterial myosin phosphorylation were: calmidazolium, 0.5 microM; trifluoperazine, 22 microM; perhexiline, 35 microM; and concentrations which stimulated cardiac myofibrillar ATPase activity by 50% were: calmidazolium, 9 microM; trifluoperazine, 45 microM; perhexiline, 90 microM. A common feature of stimulation of cardiac ATPase activity by these agents was a leftward shift in the pCa relationship, although different shape changes in the pCa curves were also apparent. Maximum ATPase activity was either not affected or inhibited (trifluoperazine). Several other agents belonging to diverse pharmacological classes also had differential effects on myosin phosphorylation and ATPase activity. These results show that structurally-distinct calmodulin antagonists and other compounds differentially affect cardiac myofibrillar ATPase activity. Moreover, several agents have been identified which inhibit arterial, and stimulate cardiac, contractile protein regulatory mechanisms. Thus, it may be possible to develop mechanistically novel cardiotonic/vasodilator agents, Ca2+ binding protein modulators, which function primarily by altering the Ca2+ sensitivity of contractile protein interactions.

Protein kinase inhibitors and blood pressure control in spontaneously hypertensive rats.

Considerable evidence suggests that protein kinase C activation participates in the regulation of vascular smooth muscle tone. The objective of the current study was to examine the relations between inhibition of protein kinase C (PKC) and myosin light-chain kinase (MLCK) and vasorelaxation and blood pressure regulation in spontaneously hypertensive rats (SHR). Putative PKC inhibitors from two chemical classes, staurosporinelike (staurosporine and K252A) and isoquinolinesulfonamides (H7 and HA1004), were tested for their ability to 1) inhibit PKC and MLCK from SHR aorta, 2) relax isolated SHR aorta, and 3) lower blood pressure in conscious SHR. A rank order of potency for the inhibition of PKC and MLCK was established, with the staurosporinelike compounds (staurosporine PKC IC50 = 54 nM) clearly more potent than the isoquinolinesulfonamides (H7 PKC IC50 = 128 microM). The rank order of potency for inhibition of PKC was retained for inhibition of MLCK for all compounds. Staurosporine (EC50 = 75 nM) and H7 (EC50 = 2 microM) caused concentration-dependent relaxation of SHR aorta, but only staurosporine produced vasorelaxation at concentrations consistent with the inhibition of PKC or MLCK. Dose-dependent reductions in arterial pressure of SHR were demonstrated after intravenous injection of staurosporine and HA1004. A single intravenous injection of staurosporine (0.3 mg/kg) lowered blood pressure for more than 10 hours. Staurosporine also lowered blood pressure after oral administration. The depressor response to staurosporine was unaffected by sympathetic beta-adrenergic blockade. In conclusion, the vasorelaxant and antihypertensive actions of staurosporine in SHR are consistent with the inhibition of PKC but could also be equally related to inhibition of MLCK. Not all PKC inhibitors produce vasorelaxation and lower blood pressure. Moreover, the lack of correlation between in vitro vasodilation and PKC or MLCK inhibition for the isoquinolinesulfonamide protein kinase inhibitors H7 and HA1004 suggests that these agents do not cause vasorelaxation in SHR by inhibition of these enzymes.

Inhibition of low Km cyclic GMP phosphodiesterases and potentiation of guanylate cyclase activators by cicletanine.

Cicletanine is an antihypertensive/vasorelaxant/natriuretic agent of unknown mechanism. We wished (a) to determine if cicletanine interacts with guanylate cyclase activators that modulate vasomotor tone and sodium balance [i.e., atriopeptin II (AP II), endothelium-derived relaxing factor (EDRF), and sodium nitroprusside (SNP)], and (b) to define the subcellular basis for this interaction by quantitating the effects of cicletanine on low Km cyclic GMP phosphodiesterase (PDE) activity. In phenylephrine-contracted rat aortic smooth muscle, the vasorelaxant potency of cicletanine was increased twofold in the presence of a threshold-relaxant concentration of AP II, and functional cyclic GMP PDE inhibition was also evident from the three- to sixfold potentiation by cicletanine of AP II- or SNP-induced vasorelaxation. Vasorelaxation produced by cicletanine was not endothelium dependent, however. In further studies, intravenous (i.v.) administration of cicletanine or the low Km cyclic GMP PDE inhibitor, zaprinast, decreased blood pressure (BP) ≤20% in conscious spontaneously hypertensive rats (SHR). These results are consistent with the additional finding that cicletanine inhibited Ca2+ -calmodulin (CaM) cyclic GMP PDE and zaprinast-sensitive cyclic GMP specific PDE over a concentration range (10–600 μM) similar to that for vasorelaxation. Thus, inhibition of low Km cyclic GMP PDEs by cicletanine may be partly responsible for the vasorelaxant effect of cicletanine as well as the potentiation by cicletanine of the vasorelaxant actions of guanylate cyclase activators. The extent to which this mechanism contributes to the antihypertensive efficacy of cicletanine has not yet been fully determined.

Antidepressants and protein kinases: inhibition of Ca2+-regulated myosin phosphorylation by fluoxetine and iprindole

The effects of several antidepressant and antipsychotic agents on Ca2+-calmodulin-regulated myosin light chain phosphorylation were evaluated. At a concentration of 100 microM, the antidepressant agents buproprion, mianserin and maprotiline were ineffective; zimelidine, desipramine and imipramine produced 40-50% inhibition; and iprindole and fluoxetine produced 75-90% inhibition. The efficacies of iprindole and fluoxetine were similar to the phenothiazine antipsychotics chlorpromazine and trifluoperazine. Clozapine, an atypical antipsychotic and the butyrophenone haloperidol were relatively ineffective as myosin light chain phosphorylation inhibitors. IC50 values of the most effective agents were: trifluoperazine 16 microM, fluoxetine 28 microM, chlorpromazine and iprindole 56 microM. As with trifluoperazine, inhibition of myosin phosphorylation by iprindole was completely attenuated in the presence of exogenous calmodulin. However, a significant component (30%) of the inhibitory effect of fluoxetine was not reversible with calmodulin. These results show that some antidepressant agents, most notably iprindole and fluoxetine, are capable of antagonizing a calmodulin-regulated protein kinase through calmodulin inhibition; and in the case of fluoxetine, through an additional calmodulin-independent mechanism.

Protein kinase C activity and reactivity to phorbol ester in vascular smooth muscle from spontaneously hypertensive rats (SHR) and normotensive Wistar Kyoto rats (WKY)

Protein kinase C (PKC) activity in aortic and renal arterial smooth muscle from SHR (20-23 wk male; mean arterial pressure = 178 mm Hg) and WKY (age/sex matched; mean arterial pressure = 126 mm Hg) was quantitated. Activity was greatest in the particulate fractions relative to the soluble fractions in all sources. The only difference between SHR and WKY was in the soluble fraction from SHR renal arteries, which had 2 fold more activity (255 pmol/mg/min) when compared with WKY (136 pmol/mg/min). This difference was not apparently related to force modulation, since the magnitude of isometric force development in renal arteries in response to phorbol 12,13-dibutyrate was not different between SHR and WKY. The magnitude of force developed in response to phorbol 12,13-dibutyrate and PKC activity in the particulate fraction was greatest in aorta vs. renal arteries in both WKY and SHR. These results suggest that regional vascular differences in the amount of PKC activity may exist which are not apparently related to a disease state (i.e., hypertension). These differences may be related to differential sensitivity to phorbol ester-mediated contractions in isolated smooth muscle.

Cardiovascular cyclic nucleotide phosphodiesterases and their role in regulating cardiovascular function

We have described five phosphodiesterase (PDE) isozymes that can be found in cardiac and vascular smooth muscle of animals and humans. Much of the evidence for the role that these isozymes have in the regulation of cellular processes has been generated through, or awaits, the identification of selective and potent PDE inhibitors. While selective inhibitors of the cGMP-inhibitable (cGi)-PDE isozyme have been approved for use in the acute treatment of heart failure, selective inhibitors of the cGMP-PDE have not been extensively explored as potential candidates for the treatment of cardiovascular diseases. More potent selective inhibitors of the cGMP-PDE isozyme are needed to determine whether these pharmacological potentiators of EDRF and ANP will be useful in the therapy of angina, hypertension or heart failure.

Sodium nitroprusside potentiates the depressor response to the phosphodiesterase inhibitor zaprinast in rats

To determine if the presence of an activator of guanylate cyclase alters the depressor response to a selective inhibitor of low Km cyclic GMP (cGMP) phosphodiesterase (PDE), zaprinast (3-30 mg/kg) was given i.v. to conscious, spontaneously hypertensive rats during a steady state of i.v. infusion of sodium nitroprusside (15 micrograms/kg per min). Sodium nitroprusside significantly increased the magnitude of the depressor response to zaprinast. In contrast, fenoldopam (20 micrograms/kg per min), an activator of adenylate cyclase, did not affect the depressor response to zaprinast. Zaprinast (10 mg/kg) significantly decreased mean arterial pressure (MAP) in rats given an infusion of sodium nitroprusside, an activator of soluble guanylate cyclase, at doses of 15 and 25 micrograms/kg per min but not at a dose of 5 micrograms/kg per min. However, in rats given atrial natriuretic peptide (ANP; 0.5, 1 and 2 micrograms/kg per min), an activator of particulate guanylate cyclase, zaprinast (10 mg/kg) did not affect MAP. In contrast to the potentiation of the depressor response to zaprinast, sodium nitroprusside (15 micrograms/kg per min) significantly attenuated the reductions in MAP produced by CI-930, a selective inhibitor of low Km cAMP PDE. It is concluded that sodium nitroprusside, but not ANP or fenoldopam, potentiates the depressor response to zaprinast. Furthermore, the potentiation of the depressor response to zaprinast is dependent upon the dose of sodium nitroprusside and is selective for zaprinast; the depressor response to CI-930 is attenuated by sodium nitroprusside.