Ronald E. Weishaar

Multiple molecular forms of cyclic nucleotide phosphodiesterase in cardiac and smooth muscle and in platelets. Isolation, characterization, and effects of various reference phosphodiesterase inhibitors and cardiotonic agents.

Multiple molecular forms of cyclic nucleotide phosphodiesterase have been identified previously in several tissues and cell types using a variety of different isolation methods. In the present study, the different molecular forms of phosphodiesterase (PDE) were isolated from cardiac muscle (guinea pig left ventricle), vascular smooth muscle (bovine coronary arteries) and human platelets using the same isolation procedure in each instance. These enzymes were then characterized kinetically, and the effects of various reference PDE inhibitors and cardiotonic agents on each form were examined. A low Km, low Vmax form of phosphodiesterase (PDE I) was found in all three tissue/cell types. PDE I activity was stimulated by calmodulin in cardiac and smooth muscle, but not in platelets. In smooth muscle and platelets, PDE I preferentially hydrolyzed cyclic GMP, whereas cardiac muscle PDE I hydrolyzed cyclic AMP and cyclic GMP equally. A high Km, high Vmax form of phosphodiesterase (PDE II) was found in cardiac muscle and platelets, but not in smooth muscle. PDE II activity was not stimulated by calmodulin and there was no substrate specificity. A low Km, low Vmax cyclic AMP-specific form of phosphodiesterase (PDE III) was found in all three tissue/cell types. The activity of PDE III was not stimulated by calmodulin. The reference inhibitors theophylline and papaverine exerted non-specific inhibitory effects on all forms of phosphodiesterase. Other reference inhibitors (M & B 22,948 and dipyridamole) and several cardiotonic agents (AR-L 57, CI-914, CI-930, amrinone, and MDL 17,043) exerted selective inhibitory effects on only one molecular form of phosphodiesterase. The degree of selectivity was often dependent upon the tissue or cell from which the molecular form of phosphodiesterase was isolated. These studies demonstrate that there is heterogeneity regarding the number of phosphodiesterases present in various tissue/cell types, as well as their substrate specificity and their ability to be stimulated by calmodulin, and these different molecular forms of phosphodiesterase can be selectively inhibited by different pharmacological agents. The possibility exists that such selective inhibitors may produce discrete changes in cyclic AMP or cyclic GMP levels, and that these changes may be produced in specific tissues and/or cells.

Subclasses of cyclic AMP-specific phosphodiesterase in left ventricular muscle and their involvement in regulating myocardial contractility.

Ventricular muscle contains a low Km, cyclic AMP-specific form of phosphodiesterase (PDE III), which is believed to represent the site of action for several of new cardiotonic agents including Imazodan (CI-914), amrinone, cilostamide, and enoximone. However, species differences in the inotropic response to these agents have raised questions about the relationship between PDE III inhibition and cardiotonic activity. The present study demonstrates that these differences can be accounted for by the presence of two subclasses of PDE in in ventricular muscle and variations in the intracellular localization of these two enyzmes. For these experiments, PDE III was initially isolated from canine, guinea pig, and rat left ventricular muscle. The results demonstrate that canine left ventricular muscle contains two functional subclasses of PDE III: an imazodan-sensitive form, which is membrane bound, and an imazodan-insensitive form, which is soluble. Although only weakly inhibited by imazodan, this latter enzyme is potently inhibited by the selective PDE III inhibitors, Ro 20–1724 and rolipram. Guinea pig ventricular muscle also contains the imazodan-sensitive subclass of PDE III. Unlike canine left ventricle, however, this enzyme is soluble in the guinea pig. No membrane-bound subclass of PDE III was observed in the guinea pig. Rat left ventricle possesses only the soluble form of PDE III, which apparently represents a mixture of the imazodan-sensitive and imazodan-insensitive subclasses of PDE III. Measurements of in vivo contractility in these three species showed that imazodan exerts a potent positive inotropic effect only in the dog, in which the imazodan-sensitive subclass of PDE III is membrane bound. In addition, a strong correlation was observed between in vitro inhibition of the membrane-bound, imazodan-sensitive PDE III from canine ventricular muscle and the in vivo positive inotropic response to imazodan, amrinone, and related cardiotonic agents in the dog. Inhibitors of the imazodan-insensitive subclass of PDE III did not exert any pronounced inotropic effect in the dog. These results demonstrate that functional subclasses of PDE III exist in ventricular muscle and suggest that species differences in the positive inotropic response to imazodan and related cardiotonics can be attributed to the proper intracellular localization of the imazodan-sensitive subclass of PDE III.

Differential inhibition of human neutrophil functions: Role of cyclic amp-specific, cyclic gmp-insensitive phosphodiesterase

Multiple molecular forms of cyclic nucleotide phosphodiesterase have been characterized in various tissues and cells according to their substrate specificity, intracellular location, and calmodulin dependence. The purpose of this study was to evaluate the possible involvement of different molecular forms of phosphodiesterase in regulating the respiratory burst and lysosomal enzyme release responses of human neutrophils. Treatment with the selective cyclic AMP-specific, cyclic GMP-insensitive phosphodiesterase inhibitors Ro 20-1724 or rolipram, or the nonselective phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX), resulted in inhibition of respiratory burst stimulated by the chemoattractants formyl-L-methionyl-L-leucyl-L-phenylalanine (FMLP) (IC50 values: 0.71-17 microM) and complement fragment C5a (IC50 values: 61-93 microM), but did not inhibit phagocytosis-stimulated respiratory burst (less than 10% inhibition at 100 microM). Selective inhibitors of calmodulin-dependent phosphodiesterase (ICI 74,917), calmodulin-insensitive, cyclic GMP-specific phosphodiesterase (M & B 22,948), cyclic GMP-stimulated phosphodiesterase (AR-L 57), or cyclic AMP-specific, cyclic GMP-inhibited phosphodiesterase (amrinone and cilostamide) exhibited little or no inhibitory effect on FMLP- or phagocytosis-stimulated respiratory burst (0-42% inhibition at 100 microM). Regulation of neutrophil activation by phosphodiesterase was also response specific, as Ro 20-1724, rolipram and IBMX were less potent inhibitors of FMLP-induced lysosomal enzyme release (0-14% inhibition at 100 microM). Analysis of human neutrophil preparations confirmed the existence of a cyclic AMP-specific, cyclic GMP-insensitive phosphodiesterase, which was associated with the particulate fraction of the cell. These results demonstrate a role for the cyclic AMP-specific, cyclic GMP-insensitive phosphodiesterase in the regulation of human neutrophil functions, which appears to be both stimulus specific and response specific.

Relaxant Effect of Human Brain Natriuretic Peptide on Human Artery and Vein Tissue

Brain natriuretic peptide (BNP) is a cardiac-derived peptide hormone with cardiovascular and renal actions that is structurally and functionally related to atrial natriuretic peptide (ANP). Previous studies using rat vascular tissue have demonstrated a direct vasorelaxant effect of BNP. However, species-specific potency issues have precluded an accurate measurement of the effect of human BNP. This report demonstrates the vasorelaxant effects of human BNP on human vascular tissue prepared from internal mammary artery and saphenous vein samples. The vasorelaxant effect of human BNP is compared to the other members of the natriuretic peptide family, human ANP and C-type natriuretic peptide (CNP). With regard to potency and magnitude of effect, human BNP and human ANP were similar in relaxing arterial tissue preconstricted with endothelin-1 (BNP ED50 = 1.9 nmol/L and ANP ED50 = 1.8 nmol/L) or phenylephrine (BNP ED50 = 10 nmol/L and ANP ED50 = 19 nmol/L), while CNP was significantly less effective. All three natriuretic peptides exhibited weak venodilating action. These data demonstrate that human BNP is a potent inhibitor of the vasoconstrictive actions of endothelin-1 and the alpha-adrenergic agonist phenylephrine on isolated human artery tissue preparations.

Subclasses of cyclic AMP phosphodiesterase in cardiac muscle

Canine and guinea-pig left ventricular muscle contains multiple molecular forms of phosphodiesterase (PDE) which vary according to substrate specificity, stimulation by calmodulin and response to various selective and nonselective phosphodiesterase inhibitors. Both species possess a cyclic AMP-specific form of phosphodiesterase (PDE III). In the dog, both soluble and particulate forms of PDE III are present. The particulate form of PDE III is potently inhibited by cyclic GMP and the selective PDE III inhibitors imazodan (CI-914) and cilostamide, but is only weakly inhibited by the selective PDE III inhibitors Ro 20-1724 and rolipram. In contrast, the soluble form of PDE III in canine left ventricle is only weakly inhibited by cyclic GMP, imazodan and cilostamide, but is potently inhibited by Ro 20-1724 and rolipram. Guinea-pig left ventricle contains only one subclass of PDE III, which is potently inhibited by cyclic GMP, imazodan and cilostamide, but not by Ro 20-1724 or rolipram. However, whereas the imazodan-sensitive subclass of PDE III is a particulate enzyme in the canine left ventricle, in the guinea-pig this subclass of PDE III is a soluble enzyme. Both soluble and particulate PDE IIIs are (i) insensitive to calmodulin; (ii) possess comparable Km and Vmax values for hydrolysis of cyclic AMP; (iii) are equally inhibited by the nonselective PDE inhibitor theophylline, and (iv) are eluted from DEAE-cellulose anion-exchange resin by comparable concentrations of sodium acetate. The demonstration of distinct subclasses of the cyclic AMP-specific phosphodiesterase (PDE III) in canine left ventricular muscle associated with different domains of the cell suggests compartmentation of cyclic AMP. In addition, the observation that the imazodan-sensitive form of PDE III is a particulate enzyme in canine left ventricle and a soluble enzyme in guinea-pig left ventricle may explain the species differences which exist regarding the positive inotropic response to imazodan in these two species.

Effects of quinapril, a new angiotensin converting enzyme inhibitor, on left ventricular failure and survival in the cardiomyopathic hamster. Hemodynamic, morphological, and biochemical correlates.

The effect of chronic therapy with quinapril on the temporal progression of left ventricular failure and survival was assessed in the CHF 146 cardiomyopathic (CM) hamster, which is an idiopathic model of congestive heart failure. Age-matched Golden Syrian (GS) hamsters served as normal controls. Quinapril was administered in the drinking water at average daily doses of 10.2, 112.4, and 222.4 mg/kg/day. In untreated CM hamsters, in vitro left ventricular performance progressively deteriorated with increasing age beginning at roughly 180 days. This decline in left ventricular performance was accompanied by a decrease in coronary flow and an increase in left ventricular volume. Administration of quinapril from 180 to 300 days of age prevented the decline of in vitro left ventricular contractile performance and coronary flow and also reduced the age-dependent increases in left ventricular volume. The cardioprotective effects of quinapril were observed at doses of 112.4 and 222.4 mg/kg/day but not at 10.2 mg/kg/day. Lung angiotensin converting enzyme activity was significantly inhibited by quinapril in GS and CM hamsters at 240 and 300 days of age at all dose levels. In contrast, significant inhibition of ventricular angiotensin converting enzyme activity was observed consistently at doses of 112.4 and 222.4 mg/kg/day quinapril but not at 10.2 mg/kg/day. In the survival protocol, CM and GS hamsters were treated with vehicle or quinapril (100 mg/kg/day) from 180 to 522 days of age. During the initial 210 days of treatment (from 180 to 390 days of age) 78.3% of the vehicle-treated CM hamsters died compared with 27.7% of quinapril-treated CM hamsters. Quinapril increased the median survival time of CM hamsters by 32.9% (112 days). It is concluded that chronic quinapril therapy exerts a significant cardioprotective effect and also increases survival.

Subclasses of cyclic GMP-specific phosphodiesterase and their role in regulating the effects of atrial natriuretic factor.

Two subclasses of cyclic guanosine monophosphate (GMP)-specific phosphodiesterases were identified in vascular tissue from several beds. The activity of one subclass (phosphodiesterase IB) was stimulated severalfold by calmodulin and selectively inhibited by the phosphodiesterase inhibitor TCV-3B. The activity of the other subclass (phosphodiesterase IC) was not stimulated by calmodulin and was selectively inhibited by the phosphodiesterase inhibitor M&B 22,948. To assess the involvement of both subclasses in regulating cyclic GMP-dependent responses, the ability of TCV-3B and M&B 22,948 to potentiate the in vitro and in vivo responses to the endogenous guanylate cyclase stimulator atrial natriuretic factor (ANF) was evaluated. Both TCV-3B and M&B 22,948 relaxed isolated rabbit aortic and pulmonary artery rings and also potentiated the relaxant effect of ANF. In addition, both inhibitors produced small increases in urine flow and sodium excretion in anesthetized rats and potentiated the diuretic and natriuretic responses to exogenous ANF. M&B 22,948 (30 micrograms/kg/min) produced a threefold increase in the natriuretic response to simultaneously administered ANF, and TCV-3B (10 micrograms/kg/min) produced a twofold increase in the response to ANF. The results of the present experiments suggest that both the calmodulin-sensitive and calmodulin-insensitive subclasses of cyclic GMP-specific phosphodiesterase play a role in regulating the in vitro and in vivo response to ANF.

Studies aimed at elucidating the mechanism of action of CI-914, a new cardiotonic agent

CI-914 is a novel positive inotropic agent whose cardiotonic activity is not due to inhibition of Na+, K+-ATPase or to stimulation of cardiac beta-receptors. CI-914 also has no direct effect on sarcoplasmic reticulum, mitochondria or adenylate cyclase activity. CI-914 does, however, exert a potent inhibitory effect on cardiac phosphodiesterase activity. In evaluating the effect of this agent on the different molecular forms of phosphodiesterase present in cardiac muscle, CI-914 was found to selectively inhibit PDE III, which is a low Km, cAMP-specific form of the enzyme (IC50 = 6.1 microM). This inhibitory effect was found to be competitive with respect to the substrate. Papaverine and theophylline on the other hand were found to inhibit all three forms of phosphodiesterase present in cardiac muscle. The role of phosphodiesterase inhibition in mediating the positive inotropic response to CI-914 is supported by the finding that this agent: (i) significantly elevates cyclic AMP levels in ventricular tissue; (ii) shifts the normal concentration-response to the beta-receptor stimulant isoproterenol to the left: and (iii) restores contractility to K+-depolarized papillary muscles.

Two phases of contractile response in rat isolated vas deferens and their regulation by adenosine and α-receptors

Contractions to transmural electrical stimulation and exogenous norepinephrine were recorded in isolated longitudinal segments of rat vas deferens. Electrical stimulation for 30 s produced a biphasic contraction in the vas deferens consisting of a rapid, transient response (Phase I), followed by a slowly developing, sustained contraction (Phase II). N6-Cyclohexyladenosine (CHA), a selective adenosine1 (A1)-receptor agonist, attenuated in a concentration-dependent manner the Phase I contractile response, while having little effect on the Phase II response. In contrast, 2-(phenylamino)adenosine (CV-1808), a selective adenosine2 (A2)-receptor agonist had little effect on either contractile phase. CHA did not inhibit the contraction to exogenous norepinephrine, suggesting that A1-receptors were located at a presynaptic site. The relatively selective alpha 2-receptor agonist clonidine produced the same pattern of contractile inhibition as CHA. The inhibitory effect of CHA on the Phase I contractile response in the vas deferens could be antagonized by the selective A1-receptor antagonist 8-cyclopentyltheophylline, while the selective alpha 2-receptor antagonist idazoxan preferentially antagonized the inhibitory effect of clonidine on the Phase I response. Both the Phase I and Phase II contractile responses were reduced by the selective alpha 1-adrenoceptor antagonist prazosin and the ATP analog alpha, beta-methylene adenosine triphosphate (alpha, beta-methylene ATP), suggesting that norepinephrine and ATP are coreleased as neurotransmitters for both responses. The results of the present study demonstrate that in the rat vas deferens the presynaptic inhibitory effects of adenosine is mediated by the A1-receptor subtype, and that both A1- and alpha 2-receptor agonists exert a selective inhibitory effect on the Phase I contractile response to electrical stimulation.

Development of a High Renin Model of Hypertension in the Cynomolgus Monkey

Hypertension was produced in cynomolgus monkeys by reducing blood flow to the left kidney by 60% via renal artery stenosis (2-kidney, 1-clip). Significant increases in mean arterial blood pressure (MABP) were observed within two to three weeks. Maximum increase (from 95 +/- 6 mmHg to 130 +/- 7 mmHg) occurred at about four to six weeks following renal artery stenosis and was sustained for more than 24 weeks. Plasma renin activity (PRA) was elevated concomitantly with the increase in MABP. PRA was raised to 42 +/- 3 ng angiotensin I/ml/hr six weeks after renal artery stenosis from a control PRA of 3 +/- 0.7 ng angiotensin I/ml/hr. At six months post renal artery stenosis, PRA was 33.4 +/- 4.2 ng angiotensin I/ml/hr. The angiotensin II (AII) receptor antagonist saralasin, the angiotensin I converting enzyme inhibitor captopril, and the renin inhibitor CGP 38,560 produced sustained reductions in MABP. The antihypertensive response to the renin inhibitor CGP 38,560 was associated with a reduction in PRA of greater than 99%, and a greater than 90% reduction in immunoreactive AII. These studies demonstrate that high-renin hypertension can be induced in the cynomolgus monkey. This pathological model provides a useful method for investigating the antihypertensive effects of agents which antagonize the renin-angiotensin system in a nonhuman primate.