Mechanism of enhanced cyclic AMP stimulation by isoproterenol in aged human fibroblasts

Human diploid lung fibroblasts (IMR-90) were used to investigate the reported increase in beta-adrenergic-stimulated cyclic adenosine 3',5'-monophosphate (cAMP) levels in fibroblasts aged in culture. Under basal conditions cellular cAMP was 34.2 +/- 5.6 and 38.4 +/- 9.1 pmol/mg protein in early (PDL 22-24) and late (PDL 47-52) passage fibroblasts, respectively. Net release of cAMP from fibroblasts was 67.8 +/- 8.6 and 18.5 +/- 7.0 pmol/30 min/mg protein in early and late passage cultures, respectively. In confluent, early passage fibroblasts, cellular cAMP and net release of cAMP increased by 2.7-fold and 3.8-fold, respectively, after a 30 min incubation in 2 microM isoproterenol. In confluent late passage fibroblasts, isoproterenol incubation increased cellular cAMP and net release of cAMP by 7.8-fold and 26.1-fold, respectively. Adenosine failed to inhibit isoproterenol-induced stimulation of cAMP in early or late passage fibroblasts. There was no passage-related difference in basal, isoproterenol, or forskolin-stimulated adenylyl cyclase activity in crude fibroblast membrane preparations. The activity of cAMP-phosphodiesterase in sonicates of early and late passage IMR-90 was 9.61 +/- 1.15 and 5.81 +/- 1.11 pmol/min/mg protein respectively. Measurements of cAMP in subconfluent early passage fibroblasts indicated that mechanisms related to the reduced cell density in confluent late passage IMR-90 may, in part, account for the enhanced isoproterenol-induced cAMP levels observed in these cultures. The results suggest that the remainder of the enhanced cAMP response to isoproterenol of in vitro aged fibroblasts may be due to a lower cAMP phosphodiesterase activity in these cells.

Adenosine reduces the Ca2+ transients of isoproterenol-stimulated rat ventricular myocytes

Adenosine in the heart attenuates the contractile and metabolic effects of beta-adrenergic stimulation. The effect of adenosine on changes in intracellular Ca2+ concentration [( Ca2+]i) elicited with electrical stimulation was studied in rat ventricular myocytes in the absence and presence of isoproterenol (ISO). Fura-2 was utilized as a Ca2+ indicator. Autofluorescence was determined, and in vivo calibration was conducted, for each myocyte. Phenylisopropyladenosine (PIA; 10(-7) M; 5 min), an adenosine A1 receptor agonist, had no effect on the Ca2+ transient magnitude (TM) or the rate of Ca2+ transient decline determined at 150 nM Ca2+(i) (RD150). ISO (10(-8) M; 1 min) in the continued presence of PIA resulted in a 16% increase in the TM, but no change in the RD150. Inhibiting the PIA with 8-cyclopentyl-1,3-dipropylxanthine (DPCPX; 10(-7) M; 3 min) in the continued presence of ISO plus PIA resulted in a further 51% increase in the TM and a 57% increase in the RD150. In PIA-treated myocytes, ISO-induced spontaneous high-frequency Ca2+ transients occasionally were observed after the inhibition of PIA by DPCPX. The results of this study suggest that adenosine attenuates myocardial contractile responses to beta-adrenergic stimulation, in part, by reducing the beta-adrenergic-induced changes in the Ca2+ transients occurring in the contracting ventricular myocyte.

Adenosine and acetylcholine reduce isoproterenol-induced protein phosphorylation of rat myocytes

Adenosinergic and muscarinic agents have been shown to attenuate the catecholamine-induced augmentation of both protein phosphorylation and contractile state in perfused hearts. The attenuation by phenylisopropyl-adenosine (PIA) and carbamylcholine chloride (CARB) of the isoproterenol (ISO)-induced incorporation of 32P into protein substrates was examined in isolated rat ventricular myocytes. 32P-labelled myocytes exposed to ISO (0.1 microM, 30 s) demonstrated up to an eight-fold increase of 32P incorporation into three protein substrates (155, 31, 6 kD). When myocytes were pre-incubated with either PIA or CARB for 60 s, the ISO-induced 32P incorporation in the 31 kD and the 155 kD substrates was attenuated 37% and 25%, respectively by 1 microM PIA and only 23% and 11%, by 10 microM PIA. A concentration of 1 microM CARB produced a 24% and 17% reduction in these same substrates while 10 microM CARB produced a 44% and 50% reduction. The effects of ISO were antagonized by 10 microM propanolol. The inhibitory effects of PIA were antagonized by the theophylline, sulfophenyltheophylline and dipropylcyclopentylxanthine, whereas atropine antagonized the inhibitory effects of CARB. The 32P incorporation elicited by 1 microM forskolin was reduced more by CARB than PIA. Additionally, while PIA and CARB reduced the ISO-induced increase in cAMP-dependent protein kinase (PKA) activity by 48% and 41% respectively, only CARB attenuated the ISO-elicited increase in cAMP levels, attenuating this response by 58%. The results indicate that PIA was less effective in attenuating ISO-induced 32P incorporation at higher concentrations than at lower concentrations. Moreover, this compound was less potent than CARB at attenuating the effects of ISO. It is conceivable that this difference could be related to activation of stimulatory adenosine receptors (A2) and/or a greater density of muscarinic receptors including multiple inhibitory muscarinic pathways.

Adenosine attenuation of catecholamine-enhanced contractility of rat heart in vivo

The antiadrenergic action of adenosine was examined in open- and closed-chest preparations of anesthetized rats. The positive inotropic effects of a jugular vein infusion of either isoproterenol or epinephrine were attenuated by phenylisopropyladenosine, an adenosine A1-receptor agonist. 1,3-Dipropyl,8-cyclopentylxanthine, a specific A1-receptor antagonist, inhibited the action of phenylisopropyladenosine. The results indicate that adenosine receptor-mediated mechanisms are functional in the blood-perfused rodent heart and support the possibility of a physiological role for adenosine in modulating cardiac contractility.

Adenosine modulates beta-adrenergic signal transduction in guinea-pig heart ventricular membranes

The mechanism of the antiadrenergic action of adenosine in the heart was investigated by examining the effects of phenylisopropyladenosine (PIA), an adenosine A1 receptor agonist, on beta-adrenergic receptor and non-receptor elicited increases in adenylyl cyclase activity of guinea-pig ventricular membranes. These membranes contained adenosine A1 receptors (approximately 80 fmol/mg) and at least one ADP-ribosylated G protein with a molecular weight of approximately 40 kDa. PIA attenuated isoproterenol-enhanced adenylyl cyclase activity and [3H]GDP release in this membrane preparation. However, PIA had no significant effect on GPP(NP)P or forskolin activated adenylyl cyclase. Additionally, PIA did not change the sensitivity of the cyclase to either magnesium or GTP in these membranes. The inhibition of isoproterenol-enhanced activity appeared to be dependent on the activation state of the enzyme such that the degree of PIA inhibition decreased with increasing isoproterenol concentration. These data suggest that adenosine inhibition of catecholamine-stimulated adenylyl cyclase activity occurs predominantly by modulating beta-adrenergic receptor signal transduction and that subunits of Gi may be involved in this action.

Increased myocardial adenosine production and reduction of beta-adrenergic contractile response in aged hearts

The contractile response of the aged adult heart to beta-adrenergic stimulation is known to be reduced compared with the young adult heart. Since endogenous adenosine exerts an antiadrenergic action in the heart, this study was undertaken to determine if the basal endogenous level of myocardial adenosine increases with age and whether this increase mediates the reduced responsiveness of aged heart to beta-adrenergic stimulation. Young (3-5 months) and aged (12-22 months) Sprague-Dawley adult rat hearts of CD and SD stock were perfused at constant pressure and paced at 270 contractions/min. The two age groups had a similar level of +dP/dtmax (index of contractility) under control conditions. Adenosine release into the coronary effluent was 30 +/- 3 nmol/min/g dry wt from young and 54 +/- 9 nmol/min/g dry wt from aged hearts. Inosine release was also greater from the aged hearts. Isoproterenol (10(-8) M) stimulation increased contractile state by 113% in young hearts and only 69% in aged hearts. Isoproterenol further increased the adenosine and inosine release from both age groups. Theophylline (5 x 10(-5) M), an adenosine antagonist, prevented the difference in the contractile response to isoproterenol stimulation between the young and aged hearts. Elevation of external calcium from 2 to 4 mM increased contractility equally in both age groups without influencing adenosine release. Myocardial oxygen consumption, coronary effluent PO2, oxygen supply-demand ratio, and lactate release were similar for both age groups, indicating that under the conditions studied the elevated release of adenosine by the aged hearts was not due to hypoxia. Aged (10-14 months) adult guinea pig hearts also displayed a reduced responsiveness to the isoproterenol stimulation and released more adenosine compared with young (3-4 months) adult guinea pig hearts. These findings suggest that enhanced adenosine levels that are present in the aged myocardium are responsible, in part, for the reduced contractile responsiveness of the older adult heart to beta-adrenergic stimulation.

Influence of beta-adrenergic stimulation and contraction frequency on rat heart interstitial adenosine

Adenosine (ADO) has an antiadrenergic action in the heart that causes an attenuation of contractile and metabolic responses elicited by beta-adrenergic stimulation. The effect of an increase in oxygen consumption elicited by either beta-adrenergic stimulation or an increase in contraction frequency on interstitial fluid and coronary effluent ADO levels was investigated in isolated perfused isovolumically contracting rat hearts. ADO in left ventricular surface transudates and coronary effluents was rendered fluorescent with chloroacetaldehyde, and the formed ethenoadenosine derivative was quantitated with high-performance liquid chromatography fluorescence detection. Heart preparation integrity was verified by determining the activities of lactate dehydrogenase and ADO deaminase in the transudates. Isoproterenol (10(-8) M) elicited a 45% increase in oxygen consumption and a 54% increase in developed left ventricular pressure in hearts paced at 240 beats/min. With isoproterenol the control transudate ADO concentration (304 pmol/ml) increased 493%, and the control effluent ADO concentration (48 pmol/ml) increased 259%. Increasing the contraction frequency from 180 to 300 beats/min in the presence of 10(-6) M propranolol increased oxygen consumption by 45% and decreased left ventricular pressure by 29%. With the increase in contraction frequency, the transudate ADO concentration did not increase significantly. However, the ADO concentration in the effluent was an average of 269% greater in hearts contracting at the higher frequency. Increasing the contraction frequency of hearts treated with both 10(-6) M propranolol and 10(-5) M atropine also had no significant effect on the level of transudate ADO. The effluent level of ADO increased only 78%. Levels of ADO in transudates were not significantly affected by mesothelial cell metabolism. These results suggest that the beta-adrenergic stimulation the interstitial level of ADO in the heart increases to levels that are sufficient to manifest its antiadrenergic effects. Furthermore, there is not always a correlation between the levels of ADO found in the interstitial and effluent fluid compartments.

Aging increases adenosine and inosine release by human fibroblast cultures

The effect of in vitro age and donor age on net release of adenosine and inosine was studied in cultures of normal human fibroblasts. Confluent cultures of low-(population doubling level [PDL] 23-25) and high- (PDL 43-45) passage human lung fibroblasts derived from a 16-week-old fetal donor (IMR-90) were incubated for 30 min in physiological saline and the release of adenosine and inosine into the saline was determined by HPLC. Release of adenosine and inosine into the saline bathing low-passage human skin fibroblasts derived from a 16-week-old fetal donor (GM6111) was also determined and compared with two strains of low-passage skin fibroblasts from aged (66-67 years) donors (GM3529 and GM3524). The release of adenosine and inosine by low-passage cultures of fetal lung fibroblasts was 911 and 225 pmol/30 min per mg protein, respectively. In high-passage cultures of lung fibroblasts, release of adenosine and inosine was significantly greater at 1403 and 351 pmol/30 min per mg protein, respectively. The release of adenosine and inosine by low-passage cultures of fetal skin fibroblasts was 250 and 179 pmol/30 min per mg protein, respectively. In low-passage skin fibroblasts from aged donors, release of adenosine and inosine was significantly greater at 583 and 652 pmol/30 min per mg protein, respectively. These results indicate that the net release of adenosine and inosine by cultured human fibroblasts into their extracellular environment is enhanced by in vitro aging of lung fibroblasts and is greater in skin fibroblast from aged donors.

Adenosine receptor coupling to adenylate cyclase of rat ventricular myocyte membranes

The effects of adenosine analogues on beta-adrenergic receptor and receptor-independent elicited increases in adenylate cyclase activity were investigated using membranes obtained from primary cultures of adult rat ventricular myocytes. Phenylisopropyladenosine, an A1-receptor agonist, at concentrations of 0.1, 1.0, and 10 microM, maximally inhibited isoproterenol-stimulated adenylate cyclase activity by 35, 55, and 41%, respectively. The inhibition by phenylisopropyladenosine was antagonized by 10 microM theophylline. One micromolar phenylisopropyladenosine was much less effective at attenuating forskolin-stimulated activity, such that the maximum inhibition was 26%. Phenylisopropyladenosine had no effect on adenylate cyclase stimulation by 5'-guanylylimidodiphosphate. Phenylaminoadenosine, an A2 agonist, at 10 microM or greater stimulated adenylate cyclase activity. This effect was not significantly inhibited by theophylline or 0.1 microM 1,3-dipropyl-8-cyclopentylxanthine (DPCPX), which antagonized phenylisopropyladenosine inhibition of isoproterenol-stimulated adenylate cyclase activity. Additionally, N-ethylcarboxamidoadenosine, a nonselective adenosine-receptor agonist, had no effect on adenylate cyclase activity in the absence of DPCPX but stimulated adenylate cyclase activity in the presence of DPCPX. These results indicate that both A1 and A2 receptors exist on the ventricular myocyte sarcolemma. More importantly, the findings suggest that adenosine inhibition of catecholamine-stimulated adenylate cyclase activity is primarily due to an alteration in beta-adrenergic receptor-mediated transduction and perhaps in part by a direct inhibition of the catalytic component.

Measurement by fluorescence of interstitial adenosine levels in normoxic, hypoxic, and ischemic perfused rat hearts

An improved assay was used to investigate the effects of hypoxia or ischemia on interstitial fluid and coronary venous effluent levels of adenosine in isolated perfused nonworking rat hearts. The adenosine in 5- to 10-microliter samples of left ventricular epicardial surface transudates and coronary effluents was reacted with chloroacetaldehyde, and the fluorescent derivative (1,N6-ethenoadenosine) was quantitated using high pressure liquid chromatography and fluorescence detection. Hearts responding to hypoxia could be separated into two groups. In one group of hearts, the control (normoxic) transudate and effluent adenosine concentrations were 94 +/- 24 and 41 +/- 6 pmol/ml, respectively. These values increased by 118 and 96%, respectively, with 5 minutes of hypoxia (30% O2), and returned to control levels 5 minutes after resumption of normoxia. In a second group of hearts, the normoxic control levels of adenosine in the transudates (42 +/- 7 pmol/ml) and coronary effluents (62 +/- 17 pmol/ml) were increased with hypoxia by 174 and 1,178%, respectively. However, the transudate levels continued to rise for 5 minutes after resumption of normoxic perfusion while effluent levels fell. In another series of hearts, global ischemia for 30 seconds elicited an elevation of transudate adenosine levels by 362 to 641% above control (58 +/- 15 pmol/ml) as determined 30 seconds after resumption of perfusion flow.(ABSTRACT TRUNCATED AT 250 WORDS)

Endogenous adenosine inhibits catecholamine contractile responses in normoxic hearts

The importance of endogenous myocardial adenosine in attenuating catecholamine-elicited contractile responses was investigated in perfused oxygenated rat hearts. Perfusion of the isolated hearts with adenosine deaminase potentiated the isoproterenol-induced increases of three contractile variables (left ventricular pressure development and rates of both left ventricular pressure development and relaxation). The peak (maximal, within 30 s) and maintained (after 1 min) increases of the contractile variables caused by 10(-8) M isoproterenol were enhanced by 15-22 and 31-43%, respectively. Adenosine deaminase appeared in epicardial surface transudates of similarly perfused hearts, indicating that the enzyme had entered the myocardial interstitial space. Isoproterenol alone elevated the release of adenosine into coronary effluents of isoproterenol-stimulated hearts, and adenosine deaminase prevented the release of the nucleoside. The higher the level of adenosine in the effluent, the greater the reduction of the peak contractile variables. Phenylisopropyladenosine at 10(-8) M prevented the adenosine deaminase potentiation of 10(-9) M isoproterenol-induced contractile responses. The adenosine analogue at 10(-6) M blocked completely the isoproterenol-produced increases in the contractile variables. These results suggest that endogenous adenosine prevents full mechanical responsiveness to beta-adrenoceptor stimulation in the oxygenated myocardium. In addition, the findings support the notion that adenosine serves as an important negative feedback modulator in the oxygenated heart.

Biochemical changes accompanying enhanced cardiac contractility by ionophore A23187

We have reported that the divalent cation ionophore A23187, like the beta-adrenergic agonist isoproterenol, increased the force of contraction and rate of relaxation and shortened the duration of contraction of papillary muscles isolated from guinea pigs. A23187 produced a fall in resting tension and decreased the contracture tension of K +/- depolarized muscles, as did isoproterenol. In the present studies, isoproterenol produced a concentration-dependent, rapid, and sustained increase in the cyclic AMP (cAMP) content of papillary muscle. In contrast, A23187 had no detectable effect on cAMP levels, even in the presence of the phosphodiesterase inhibitor, papaverine. Neither drug, at concentrations maximal for contractile effects, altered cyclic GMP (cGMP). Isoproterenol increased the cAMP-dependent protein kinase activity ratio, whereas A23187 did not change the activity of this enzyme. However, both A23187 and isoproterenol produced a concentration-dependent increase in phosphorylase activity. Concentrations of A23187 or isoproterenol that enhanced contractility maximally increased the alkali-labile phosphate (by ca. 35%) but were without effect on the acid-labile, alkali-stable phosphate in the total acid precipitable protein. Contractile effects of isoproterenol, which reflect activated Ca2+ uptake, and the increase in phosphorylase activity produced by this agent are believed to be due to an increase in cAMP with subsequent activation of cAMP-dependent protein kinases and phosphorylation of proteins. A23187 may produce similar contractile effects without an increase in cAMP or cAMP-dependent protein kinase activity by activating other protein kinases and/or inhibiting phosphoprotein phosphatases, most likely by its effects on intracellular calcium.

Effects of divalent cation ionophore A23187 on cardiac contractile parameters

The divalent cation ionophore A23187, when added to guinea pig papillary muscle, produced contractile effects that were similar to those produced by isoproterenol or histamine, but the ionophore's effects did not appear to result from the release of endogenous transmitters or prostaglandin production. Optimally effective concentrations of A23187 (6 microM) and isoproterenol (1 microM) more than doubled the peak contractile force and the rates of force development and relaxation and caused a 25% decrease in the duration of the contraction. Both A23187 and isoproterenol decreased the resting tension by approximately 0.15 g and significantly diminished the magnitude of a potassium-induced contracture. The positive inotropic effect of A23187 was prevented by incubating the tissue in calcium-depleted medium and antagonized by D 600, a blocker of sarcolemmal calcium influx, and acetylcholine. The contractile effects of A23187 appear to be related, in part, to its ability to increase the movement of calcium across the sarcolemma electroneutrally, since no change of the action potential occurred. In addition, possible intracellular actions of this ionophore may produce contractile effects that resemble those produced by isoproterenol and that reflect an increased sequestration of calcium within the myocardial cell.

Nicotine increases heart adenosine release, oxygen consumption, and contractility

The effect of nicotine on adenosine release, oxygen consumption, and contractility was investigated in perfused rat hearts. Continuous infusion of nicotine into the perfusing physiological saline (PS) elicited a propranolol (10(-6) M) sensitive transient elevation of developed left ventricular pressure (LVP) and maximum rates of left ventricular pressure development and relaxation (+/- dP/dtmax) within 20 s, which subsequently declined to maintained elevated plateau levels by 1 min. The continuous infusions of nicotine to achieve PS concentrations of 5 X 10(-4), 1 X 10(-4), or 5 X 10(-5) M, respectively resulted in significant increases in the mean plateau levels of LVP (33.4, 10.1, or 6.3%), +dP/dtmax (26.3, 10.8, or 6.9%) and-dP/dtmax (35.0, 11.9, or 9.0%) at 1 min. The inclusion of propranolol (10(-6) M) with or without atropine (10(-6) M) did not alter these maintained plateau responses to nicotine. During the plateau phase of the contractile response oxygen consumption of the hearts was significantly elevated by 36, 19, or 11%, and mean levels for adenosine in the coronary effluent rose by 261, 76, or 74% in response to 5 X 10(-4), 1 X 10(-4), or 5 X 10(-5) M nicotine, respectively. Nicotine did not influence [14C]adenosine uptake by the hearts. These results suggest that nicotine is capable of 1) augmenting cardiac contractility and oxygen consumption independent of beta-adrenergic or muscarinic influence, and 2) elevating the appearance of adenosine in the coronary circulation presumably by enhancing myocardial production of the nucleoside.

Adenosine inhibition of catecholamine-stimulated cardiac membrane adenylate cyclase

Adenosine inhibition of hormone-sensitive adenylate cyclase activity was investigated using isolated myocardial membranes prepared from rat hearts. When cyclase activity was determined in membranes, using [alpha-32P]ATP as substrate, 10(-5) M adenosine inhibited isoproterenol-stimulated adenylate cyclase activity by 25% but did not inhibit basal activity or fluoride (5 mM) activation of the enzyme. The adenosine reduction of isoproterenol-sensitive cyclase activity was dependent on GTP but was not prevented by 10(-3) M theophylline. Adenosine neither appeared to compete with ATP for the substrate converting site of the enzyme nor reduced 5'-guanylyl imidodiphosphate activation of the enzyme. Inasmuch as lower concentrations of adenosine had no influence on enzyme activity, endogenous adenosine may be present in the adenylate cyclase assay. To obviate the effects of endogenous adenosine, the adenylate cyclase assay was then modified to a 2'-deoxy system with [alpha-32P]dATP used as the substrate in the presence of adenosine deaminase. With this assay system, the 15% inhibition of isoproterenol-stimulated adenylate cyclase activity produced by the adenosine receptor agonists, 10(-8) M 2-chloroadenosine or phenylisopropyladenosine, was prevented by 10(-4) M 8-phenyltheophylline or isobutylmethylxanthine (IBMX), respectively. While under these assay conditions, 10(-7) M 2',5'-dideoxyadenosine, a P-site analogue, did not influence the hormone-sensitive cyclase activity. The 35% reduction of the hormone-sensitive enzyme produced by this analogue at 10(-5) M was not prevented by IBMX. These results suggest that nanomolar concentrations of adenosine analogues interact with a methylxanthine-sensitive adenosine receptor that mediates the attention of membrane hormone-sensitive adenylate cyclase activity.

Role of extracellular and intracellular adenosine in the attenuation of catecholamine evoked responses in guinea pig heart

Isolated guinea pig hearts were used to determine whether an extracellular (interstitial) or intracellular pool of myocardial adenosine is most important in attenuating the catecholamine-induced enhancement of cardiac contractile state and glycogenolysis. Isoproterenol (2 X 10(-8) M) stimulation of hypoxic (30% O2) perfused hearts produced a marked elevation in tissue and effluent perfusate adenosine levels that were greater than the increases observed with the isoproterenol stimulation of oxygenated hearts (95% O2). In the isoproterenol stimulated hypoxic hearts nitrobenzylthioinosine (NBMPR), a potent inhibitor of adenosine cellular transport, further increased tissue adenosine content and markedly decreased the perfusate level of the nucleoside. Assuming that perfusate levels of adenosine correlate directly with extracellular levels, NBMPR was used as a tool to increase the intracellular and decrease the extracellular content of the nucleoside. When compared to responses in oxygenated hearts, hypoxia reduced the isoproterenol-produced increase in myocardial cyclic AMP content, cyclic AMP-dependent protein kinase activity and contractility but enhanced the increase in glycogen phosphorylase alpha formation. NBMPR completely prevented the reduction of the isoproterenol-induced cyclic AMP and cyclic AMP-dependent protein kinase responses but only partially prevented the attenuation of the contractile response. The increase in phosphorylase alpha formation in the hypoxic isoproterenol stimulated hearts was not influenced by NBMPR. The results suggest that an increase in extracellular adenosine is more influential than an elevation of intracellular adenosine in attenuating beta-adrenoceptor-elicited increases in myocardial cyclic AMP content, cyclic AMP-dependent protein kinase activity and contractile state.

Adenosine and calcium alter adrenergic-induced intact heart protein phosphorylation

Adenosine reduces cardiac mechanical and metabolic manifestations of catecholamine stimulation possibly by attenuating catecholamine-enhanced adenylate cyclase activity and sarcolemmal Ca2+ flux. The effects of adenosine and Ca2+ on catecholamine-induced myocardial protein phosphorylation were investigated using isolated rat hearts perfused with a 32P-enriched medium. Isoproterenol (10(-7) M, 1 min) elicited a 107-379% increase in 32P incorporation into proteins having molecular weights of 155, 92, 30, 28, 22, and 20 kdaltons. The left ventricular pressures and maximum rates of ventricular pressure development and ventricular relaxation were significantly elevated. These effects of isoproterenol were inhibited by propranolol (10(-5) M). Adenosine (10(-5) M, 2 min) decreased the isoproterenol-elicited increases in 32P incorporation by 50-86% and decreased the contractile responses but had no effect in the absence of isoproterenol. Raising the perfusion Ca2+ concentration from 1 to 4 mM did not alter the 32P incorporations but increased contractile parameters. The increase in Ca2+ augmented the isoproterenol 32P responses but not the contractile responses to isoproterenol. These results are consistent with the proposal that catecholamines augment cardiac metabolism and contractility by enhancing myocardial protein phosphorylation. Adenosine and Ca2+ modulate these responses.

Interaction between adenosine and inotropic interventions in guinea pig atria

Isolated guinea pig atria stimulated to contract isometrically were used to determine whether adenosine at a concentration that does not cause a direct depressant effect on peak contractile force, rate of force development, and rate of relaxation was capable of influencing the elevation in these contractile parameters caused by an increase in preload, paired electrical stimulation, an increase in contraction frequency, and catecholamine stimulation in K+-depolarized and nondepolarized atrial muscle. Adenosine had no effect on the contractile parameters that were enhanced by an increase in preload or paired electrical stimulation. The nucleoside reduced the increases in the contractile parameters produced by isoproterenol stimulation, an increase in contraction frequency, and isoproterenol-induced contractions in depolarized atria. All adenosine reductions were inhibited by theophylline, an antagonist of adenosine actions. The adenosine reduction of the elevated contractile parameters caused by increasing contraction frequency was not prevented by atropine (a muscarinic antagonist) or propranolol (a beta-adrenergic blocking agent). These results suggest that adenosine at a concentration that does not produce direct negative inotropic responses is capable of attenuating the elevation in contractility elicited by catecholamine stimulation, an increase in contraction frequency, and catecholamine-induced contractions in depolarized atria. However, the reduction by adenosine of the contractile responses elicited by an increase in contraction frequency appears to be independent of catecholamines.

Adenosine reduces catecholamine contractile responses in oxygenated and hypoxic atria

The properties of adenosine attenuation of catecholamine-elicited increases in peak contractile force, rate of force development, and rate of relaxation were studied in isolated rat atria. Adenosine, at a concentration that did not cause a direct depressant effect by itself, was capable of reducing by approximately 15% the increase in the contractile parameters elicited by isoproterenol. This reduction was not overcome by elevating the catecholamine concentration. The adenosine reduction was prevented by theophylline or the presence of adenosine deaminase. The reduction appears to be independent of the acetylcholine-mediated reduction of catecholamine responses. Adenosine reduced the positive inotropic responses elicited by norepinephrine and epinephrine but not phenylephrine. Adenosine deaminase in oxygenated atria potentiated the catecholamine-elicited contractile responses and reduced the progressive fall of the elevated contractile responses observed with continual catecholamine stimulation. In hypoxic atria adenosine deaminase potentiated the positive inotropic responses observed with catecholamine stimulation. The results suggest that an adenosine-specific mechanism is capable of attenuating the elevation in contractility elicited by beta-adrenergic stimulation. In addition, endogenous adenosine may be responsible, in part, for the reduction of catecholamine-mediated contractile responses in oxygenated and hypoxic myocardial tissue.

Mechanism of adenosine inhibition of catecholamine-induced responses in heart

The properties of adenosine inhibition of catecholamine-induced responses were investigated, using an isolated rat heart preparation. Perfusion of hearts with 0.1 microM isoproterenol increased myocardial cAMP content 2.8-fold, activation of cAMP-dependent protein kinase 4.4-fold, phosphorylase a formation 3.4-fold, left ventricular pressure 1.8-fold, rate of ventricular pressure development 2.1-fold, and rate of ventricular relaxation 2.2-fold within 1 minute. When perfused with the isoproterenol, 10 microM adenosine reduced the catecholamine-produced increase in cAMP, cAMP-dependent protein kinase, and phosphorylase by 30-40%, and the elevation in left ventricular pressure and rate of ventricular pressure development by 40-70% within 40 seconds. More than 2 minutes were required for the nucleoside to significantly reduce the isoproterenol-elicited increase in the rate of ventricular relaxation. Perfusion of adenosine alone at concentrations from 0.1 to 10 microM were without effect on the above parameters. Theophylline at 50 microM had no effect alone on the above parameters but blocked the inhibitory actions of adenosine on the isoproterenol-induced responses. In the presence of 15 mM Mg++ adenosine reduced by approximately 56% the 2-fold increase in myocardial membrane adenylate cyclase activity produced by 1 microM isoproterenol without affecting basal or fluoride-stimulated activity. Adenosine also reduced the isoproterenol-induced increase in enzyme activity assayed at 1-2 mM Mg++, a level that more closely approximates the intracellular activity of the ion. The results suggest that physiological concentrations of adenosine attenuate the catecholamine-induced increase in cAMP content, cAMP-dependent protein kinase activation, phosphorylase a formation, and contractile parameters in the working heart, via reducing the beta-adrenergic activation of adenylate cyclase.

Inhibition by adenosine of catecholamine-induced increase in rat atrial contractility

Because adenosine has been shown to attenuate the catecholamine-induced increase in myocardial cAMP formation and glycogen phosphorylase activity (Circ. Res. 43: 785-792, 1978), the present study was undertaken to determine whether the nucleoside inhibits the catecholamine-elicited increase in cardiac contractile state. Isolated rat atria were bathed in oxygenated physiologic saline and stimulated to contract isometrically at 2/s. Isoproterenol (0.1 microM) increased peak contractile force (PCF) by 96% and the rate of force development (+dF/dt) by 107%. Adenosine (10 microM) alone had no effect on these contractile parameters. Isoproterenol in the presence of adenosine increased PCF and +dF/dt only 15 and 14%, respectively. Elevation of bathing medium Ca2+ or administration of dibutyryl cAMP (DBcAMP) increased PCF and +dF/dt, but these responses were not decreased by adenosine. Inosine, adenine, adenosine 5'-monophosphate, and guanosine inhibited the isoproterenol-induced responses 5-22%. The results indicate that adenosine markedly inhibits, whereas some related purines only mildly attenuate, the catecholamine-elicited, but not the Ca2+- or DBcAMP-elicited, increases in contractility. Thus, adenosine may antagonize catecholamine-elicited glycogenolysis and enhanced contractile state in the heart by exerting an effect at the level of, or proximal to, cAMP formation.

Properties of epinephrine-induced activation of cardiac adenosine 3',5'-monophosphate-dependent protein kinase

The effects of epinephrine on cyclic AMP content and protein kinase activity were examined in an in situ rat heart preparation. Bolus injection of epinephrine into the superior vena cava caused an increase in the activity ratio (-cyclic AMP/"cyclic AMP) of 12 000 X g supernatant protein kinase. The increase was significant within 5 s and maximal in 10 s. Epinephrine produced a dose-dependent increase in both protein kinase activity ratio and cyclic AMP content. The increases in both parameters exhibited a high degree of correlation. The increase in protein kinase activity ratio observed with low doses of epinephrine (less than or equal to 1 microgram/kg) resulted from an increase in independent protein kinase activity (-cyclic AMP) without a change in total protein kinase activity (+cyclic AMP). However, the increase in the activity ratio observed with higher doses of epinephrine (greater than 1 microgram/kg) was due mainly to a decrease in total protein kinase activity rather than a further increase in independent protein kinase activity. The loss of supernatant total protein kinase activity could be accounted for by an increase in activity associated with particulate fractions obtained from the homogenates. A similar redistribution of protein kinase could be demonstrated by the addition of cyclic AMP to homogenates prepared from hearts not stimulated with epinephrine. These results demonstrate that epinephrine over a wide dose range produces a parallel increase in the content of cyclic AMP and the activation of soluble protein kinase. The findings also suggest that protein kinase translocation to particulate material may depend on the degree of epinephrine-induced enzyme activation.