Abnormal myocardial contraction in alpha(1A)- and alpha(1B)-adrenoceptor double-knockout mice

We used double-knockout mice (ABKO) lacking both predominant myocardial alpha(1)-adrenergic receptor (AR) subtypes (alpha(1A) and alpha(1B)) to determine if alpha(1)-ARs are required for normal myocardial contraction. Langendorff-perfused ABKO hearts had higher developed pressure than wild type (WT) hearts (123 +/- 3 mmHg n = 22 vs. 103 +/- 3 mmHg, n = 38, P < 0.001). Acutely inhibiting alpha(1)-ARs in WT hearts with prazosin did not increase pressure, suggesting that the increased pressure of ABKO hearts was mediated by long-term trophic effects on contraction rather than direct regulatory effects of alpha(1)-AR removal. Similar to perfused hearts, ABKO ventricular trabeculae had higher submaximal force at 2 mM extracellular [Ca(2+)] than WT (11.4 +/- 1.7 vs. 6.9 +/- 0.6 mN/mm(2), n = 8, P < 0.05); however, the peaks of fura-2 Ca(2+) transients were not different (0.79 +/- 0.11 vs. 0.75 +/- 0.16 microM, n = 10-12, P > 0.05), suggesting ABKO myocardium had increased myofilament Ca(2+)-sensitivity. This conclusion was supported by measuring the Ca(2+)-force relationship using tetanization. Increased myofilament Ca(2+)-sensitivity was not explained by intracellular pH, which did not differ between ABKO and WT (7.41 +/- 0.01 vs. 7.39 +/- 0.02, n = 4-6, P > 0.05; from BCECF fluorescence). However, ABKO displayed impaired troponin I phosphorylation, which may have played a role. In contrast to increased submaximal force, ABKO trabeculae had lower maximal force than WT at high extracellular [Ca(2+)] (29.6 +/- 1.9 vs. 37.6 +/- 1.4 mN/mm(2), n = 7, P < 0.01). However, peak cytosolic [Ca(2+)] was not different (1.13 +/- 0.15 vs. 1.19 +/- 0.04 microM, n = 6-7, P > 0.05), suggesting ABKO myocardium had impaired myofilament function. Finally, ABKO myocardium had decreased responsiveness to beta-AR stimulation. We conclude: alpha(1)-ARs are required for normal myocardial contraction; alpha(1)-ARs mediate long-term trophic effects on contraction; loss of alpha(1)-AR function causes some of the functional abnormalities that are also found in heart failure.     

Inhibition of insulin secretion via distinct signaling pathways in alpha2-adrenoceptor knockout mice

OBJECTIVE: Adrenaline inhibits insulin secretion through activation of alpha(2)-adrenoceptors (ARs). These receptors are linked to pertussis toxin-sensitive G proteins. Agonist binding leads to inhibition of adenylyl cyclase, inhibition of Ca(2+) channels and activation of K(+) channels. Recently, three distinct subtypes of alpha(2)-AR were described, alpha(2A)-AR, alpha(2B)-AR and alpha(2C)-AR. At present, it is unknown which of these alpha(2)-AR subtype(s) may regulate insulin secretion. We used mice deficient in alpha(2)-ARs to analyze the coupling and role of individual alpha(2)-AR subtypes in insulin-secreting beta cells. METHODS: The inhibitory effect of adrenaline on insulin secretion was measured in freshly isolated and cultured wild type (wt) and alpha(2)-AR knockout (KO) mouse islets in order to examine the receptor subtypes which mediate adrenaline-induced inhibition of insulin secretion. Adenylyl cyclase activity was measured in isolated cultured islets. Membrane potential was measured using the amphotericin B permeabilized patch clamp method in isolated and cultured single islet cells. RESULTS: In wt, alpha(2A)- and alpha(2C)-AR KO mouse islets, adrenaline, 1 microM/L, inhibited secretion by 83, 80 and 100% respectively. In contrast, in alpha(2A/2C)-AR double KO mouse islets, adrenaline had no effect on stimulated secretion indicating that both alpha(2A)-AR and alpha(2C)-AR, but not alpha(2B)-AR, are functionally expressed in mouse islets. Surprisingly, glucose (16.7 mM/L)-induced secretion in the presence of 1 microM/L forskolin was greatly impaired in alpha(2A)-AR KO islets. However, when cAMP levels were increased further by the combination of forskolin (5 microM/L) and 3-isobutyl-1-methylxanthine (100 microM/L), secretion was stimulated 2.7-fold (8.5-fold in wt islets). Adrenaline lowered the concentration of cAMP in wt and alpha(2C)-AR KO mouse islets by 74%. Adrenaline also hyperpolarized wt and alpha(2C)-AR KO beta cells. In contrast, adrenaline did not inhibit adenylyl cyclase in islets of alpha(2A)-AR KO mice, nor did it hyperpolarize alpha(2A)-AR KO beta cells. CONCLUSION: Adrenaline inhibits insulin release through alpha(2A)- and alpha(2C)-ARs via distinct intracellular signaling pathways.     

Activation of alpha1B-adrenoceptors alleviates ischemia/reperfusion injury by limitation of mitochondrial Ca2+ overload in cardiomyocytes

OBJECTIVE: Activation of alpha(1)-adrenergic receptors (alpha(1)-ARs) mimics ischemic preconditioning (IP). However, the subtypes of alpha(1)-ARs involved and the protective mechanisms are not entirely clear. Here we tested the hypothesis that preservation of mitochondrial integrity, in particular, Ca(2+) homeostasis via the epsilon isoform of protein kinase C (PKCepsilon) and mitoK(ATP) channels, may underlie the basis of alpha(1B)-AR-triggered cardioprotection. METHODS: Indo-1 fluorescence in adult rat cardiomyocytes was used as an index of cytosolic ([Ca(2+)](c)) or mitochondrial free Ca(2+) concentration ([Ca(2+)](m)), and cell shortening was measured simultaneously. Cells were subjected to 20 min of simulated ischemia followed by 30 min of reperfusion (I/R). RESULTS: Activation of a(1)-ARs by phenylephrine significantly decreased I/R-induced [Ca(2+)](c) and [Ca(2+)](m) overload, mitochondrial cytochrome c release and ATP reduction, and improved Ca(2+) transients and cell shortening. These protective effects were markedly inhibited by blockade of alpha(1B)-AR (chloroethylclonidine) but not alpha(1A)-AR (5'-methylurapidil) or alpha(1D)-AR (BMY 7378). Moreover, phenylephrine-afforded protection on the [Ca(2+)](m), [Ca(2+)](c), and cell shortening was lost when mitoK(ATP) channels were inhibited with 5-hydroxydecanoate and PKCepsilon with PKCepsilon V(1-2). However, PKCepsilon V(1-2) did not affect the mitoK(ATP) channel opener diazoxide-induced protection on these parameters. CONCLUSIONS: These findings indicate that phenylephrine-induced protection on [Ca(2+)](m) homeostasis is mediated by selective activation of alpha(1B)-AR via mitoK(ATP) channel opening and PKCepsilon activation. Mitochondrial function appears to be a determinant of [Ca(2+)](c) and contractile function during I/R injury.     

The alpha(1B)-adrenergic receptor decreases the inotropic response in the mouse Langendorff heart model

OBJECTIVE: alpha(1)-Adrenergic receptors (ARs) are known mediators of a positive inotropy in the heart, which may play even more important roles in heart disease. Due to a lack of sufficiently selective ligands, the contribution of each of the three alpha(1)-AR subtypes (alpha(1A), alpha(1B) and alpha(1D)) to cardiac function is not clearly defined. In this study, we used a systemically expressing mouse model that overexpresses the alpha(1B)-AR to define the role of this subtype in cardiac function. METHODS: We used the mouse Langendorff heart model to assess changes in contractility under basal and phenylephrine-induced conditions. RESULTS: We find that a 50% increase of the alpha(1B)-AR in the heart does not change basal cardiac parameters compared to age-matched normals (heart rate, +/-dP/dT and coronary flow). However, the inotropic response to phenylephrine is blunted. The same results were obtained in isolated adult myocytes. The difference in inotropy could be blocked by the selective alpha(1A)-AR antagonist, 5-methylurapidil, which correlated with decreases in alpha(1A)-AR density, suggesting that the alpha(1B)-AR had caused a compensatory downregulation of the alpha(1A)-AR. CONCLUSIONS: These results suggest that the alpha(1B)-AR does not have a major role in the positive inotropic response in the mouse myocardium but may negatively modulate the response of the alpha(1A)-AR.     

Altered signal transduction in cardiac ventricle overexpressing A(1)-adenosine receptors

OBJECTIVE: The aim of the present study was to assess the effects of A(1)-adenosine receptor (A1-AR) stimulation in ventricle of A(1)-adenosine receptor overexpressing mice (transgenic mice, TG). METHODS: Effects of the A(1)-adenosine receptor agonist R-PIA ((-)-N(6)-phenylisopropyladenosine) on phosphorylation of phospholamban (PLB), Ca(2+) transients, Ca(2+) currents and cell shortening were studied in isolated ventricular cardiomyocytes. RESULTS: R-PIA alone did not affect contractility in isolated electrically stimulated cardiomyocytes from wild-type mice (WT) or TG. However, after pre-stimulation of beta-adrenoceptors by isoproterenol, R-PIA reduced contractility in cardiomyocytes from WT but increased contractility in TG. Under the same conditions, R-PIA reduced isoproterenol-stimulated currents through L-type Ca(2+) channels, Ca(2+) transients and phosphorylation of PLB in cardiomyocytes from WT. In contrast, R-PIA diminished phospholamban phosphorylation induced by isoproterenol but augmented isoproterenol-elevated currents through L-type Ca(2+) channels, and isoproterenol-heightened Ca(2+) transients in cardiomyocytes from TG. CONCLUSIONS: We suggest that A(1)-adenosine receptor overexpression reverses the interaction of beta-adrenergic and A(1)-adenosine receptor stimulation, at least in part. Hence, the receptor/effector coupling is dependent on receptor density in this model.     

Localization of cardiac L-type Ca(2+) channels to a caveolar macromolecular signaling complex is required for beta(2)-adrenergic regulation

L-type Ca(2+) channels play a critical role in regulating Ca(2+)-dependent signaling in cardiac myocytes, including excitation-contraction coupling; however, the subcellular localization of cardiac L-type Ca(2+) channels and their regulation are incompletely understood. Caveolae are specialized microdomains of the plasmalemma rich in signaling molecules and supported by the structural protein caveolin-3 in muscle. Here we demonstrate that a subpopulation of L-type Ca(2+) channels is localized to caveolae in ventricular myocytes as part of a macromolecular signaling complex necessary for beta(2)-adrenergic receptor (AR) regulation of I(Ca,L). Immunofluorescence studies of isolated ventricular myocytes using confocal microscopy detected extensive colocalization of caveolin-3 and the major pore-forming subunit of the L-type Ca channel (Ca(v)1.2). Immunogold electron microscopy revealed that these proteins colocalize in caveolae. Immunoprecipitation from ventricular myocytes using anti-Ca(v)1.2 or anti-caveolin-3 followed by Western blot analysis showed that caveolin-3, Ca(v)1.2, beta(2)-AR (not beta(1)-AR), G protein alpha(s), adenylyl cyclase, protein kinase A, and protein phosphatase 2a are closely associated. To determine the functional impact of the caveolar-localized beta(2)-AR/Ca(v)1.2 signaling complex, beta(2)-AR stimulation (salbutamol plus atenolol) of I(Ca,L) was examined in pertussis toxin-treated neonatal mouse ventricular myocytes. The stimulation of I(Ca,L) in response to beta(2)-AR activation was eliminated by disruption of caveolae with 10 mM methyl beta-cyclodextrin or by small interfering RNA directed against caveolin-3, whereas beta(1)-AR stimulation (norepinephrine plus prazosin) of I(Ca,L) was not altered. These findings demonstrate that subcellular localization of L-type Ca(2+) channels to caveolar macromolecular signaling complexes is essential for regulation of the channels by specific signaling pathways.     

Altered calcium transient and development of hypertrophy in beta2-adrenoceptor overexpressing mice with and without pressure overload

Transgenic (TG) mice with cardiac specific 200-fold overexpression of beta(2)-adrenoceptors (beta(2)-AR) have a facilitated development of heart failure following thoracic aortic constriction (TAC). We have studied the alterations of intracellular Ca(2+) transients and myocyte size in wild-type (WT) and TG mice after TAC. Cardiomyocytes were isolated from mice 9 weeks after TAC or sham operation, and incubated with Fura 2/AM. The Ca(2+) transients were determined by Spex dual wavelength Spectrometer during electrical stimulation. The cell size was also determined planimetrically. Cells of sham operated TG mice displayed higher systolic Ca(2+) amplitude than respective WT group (DeltaF(340)/F(380) ratio: 1.05+/-0.08 vs. 0.63+/-0.05; P<0.01), a finding in keeping with enhanced ventricular contractility in the TG mice. However, hypertrophied and failing myocytes of TG animals showed a fall in Ca(2+) transients from sham-operated control levels and there was no difference between TG and WT groups following TAC. In sham-operated groups, the cell size of TG mice was significantly bigger than in WT animals (3212+/-139 vs. 2605+/-162 microm(2); P<0.05). The cell size increased to a similar extent in both groups after TAC (4715+/-216 vs. 5027+/-365 microm(2), P=n.s.). In summary, hypertrophy of cardiomyocytes was present in beta(2)-AR TG mice under baseline conditions. A further hypertrophy occurred during pressure overload to an extent similar to that in WT animals. However, the increased intracellular Ca(2+) transient, seen in sham-operated TG mice, was no longer detectable following development of severe hypertrophy and heart failure. These findings provide explanation on the lack of hemodynamic benefit in beta(2)-AR TG mice subjected to pressure overload.     

Both alpha(1A)- and alpha(1B)-adrenergic receptors crosstalk to down regulate beta(1)-ARs in mouse heart: coupling to differential PTX-sensitive pathways

Adrenergic receptors (ARs) play an important role in the regulation of cardiac function. Cardiac inotropy is primarily regulated by beta(1)-ARs. However, alpha(1)-ARs may play an important role in inotropy during heart failure. Previous work has suggested that the alpha(1B)-AR modulates beta(1)-AR function in the heart. The potential role of the alpha(1A)-AR has not been previously studied. We used transgenic mice that express constitutively active mutant (CAM) forms of the alpha(1A)-AR or alpha(1B)-AR regulated by their endogenous promoters. Expression of the CAM alpha(1A)-AR or CAM alpha(1B)-AR had no effect on basal cardiac function (developed pressure, +dP/dT, -dP/dT, heart rate, flow rate). However, both alpha(1)-AR subtypes significantly decreased isoproterenol-stimulated +dP/dT. Pertussis toxin had no effect on +dP/dT in CAM alpha(1A)-AR hearts but restored +dP/dT to non-transgenic values in CAM alpha(1B)-AR hearts. Radioligand binding indicated a selective decrease in the density of beta(1)-ARs in both CAM mice. However, G-proteins, cAMP, or the percentage of high and low affinity states were unchanged in either transgenic compared with control. These data demonstrate that CAM alpha(1A)- and alpha(1B)-ARs both down regulate beta(1)-AR-mediated inotropy in the mouse heart. However, alpha(1)-AR subtypes are coupled to different beta-AR mediated signaling pathways with the alpha(1B)-AR being pertussis toxin sensitive.     

Insights into alpha1 adrenoceptor function in health and disease from transgenic animal studies.

Alpha(1)-adrenoceptors (ARs) mediate some of the main actions of the natural catecholamines, epinephrine and norepinephrine, and have a crucial role in the regulation of arterial blood pressure. Since alpha(1)-AR was subdivided into three subtypes (alpha(1A)-AR, alpha(1B)-AR and alpha(1D)-AR), the search has been on to discover subtype-specific physiological roles and to develop subtype-selective agonists and antagonists. Recently, several strains of genetically engineered mice have become available. Studies with these mice have provided several clues to help elucidate subtype-specific physiological functions; for instance, alpha(1A)-AR and alpha(1D)-AR subtypes play an important role in the regulation of blood pressure, suggesting that subtype-selective antagonists might be desirable antihypertensive agents. The ability to study subtype-specific functions in different mouse strains by altering the same alpha(1)-AR in different ways strengthens the conclusions drawn from pharmacological studies. Although these genetic approaches have limitations, they have significantly increased our understanding of the functions of alpha(1)-AR subtypes.     

Recent advances in cardiac beta(2)-adrenergic signal transduction

Recent studies have added complexities to the conceptual framework of cardiac beta-adrenergic receptor (beta-AR) signal transduction. Whereas the classical linear G(s)-adenylyl cyclase-cAMP-protein kinase A (PKA) signaling cascade has been corroborated for beta(1)-AR stimulation, the beta(2)-AR signaling pathway bifurcates at the very first postreceptor step, the G protein level. In addition to G(s), beta(2)-AR couples to pertussis toxin-sensitive G(i) proteins, G(i2) and G(i3). The coupling of beta(2)-AR to G(i) proteins mediates, to a large extent, the differential actions of the beta-AR subtypes on cardiac Ca(2+) handling, contractility, cAMP accumulation, and PKA-mediated protein phosphorylation. The extent of G(i) coupling in ventricular myocytes appears to be the basis of the substantial species-to-species diversity in beta(2)-AR-mediated cardiac responses. There is an apparent dissociation of beta(2)-AR-induced augmentations of the intracellular Ca(2+) (Ca(i)) transient and contractility from cAMP production and PKA-dependent cytoplasmic protein phosphorylation. This can be largely explained by G(i)-dependent functional compartmentalization of the beta(2)-AR-directed cAMP/PKA signaling to the sarcolemmal microdomain. This compartmentalization allows the common second messenger, cAMP, to perform selective functions during beta-AR subtype stimulation. Emerging evidence also points to distinctly different roles of these beta-AR subtypes in modulating noncontractile cellular processes. These recent findings not only reveal the diversity and specificity of beta-AR and G protein interactions but also provide new insights for understanding the differential regulation and functionality of beta-AR subtypes in healthy and diseased hearts.     

Interaction of alpha1-adrenoceptor subtypes with different G proteins induces opposite effects on cardiac L-type Ca2+ channel

We examined the effect of alpha(1)-adrenoceptor subtype-specific stimulation on L-type Ca2+ current (I(Ca)) and elucidated the subtype-specific intracellular mechanisms for the regulation of L-type Ca2+ channels in isolated rat ventricular myocytes. We confirmed the protein expression of alpha(1A)- and alpha(1B)-adrenoceptor subtypes at the transverse tubules (T-tubules) and found that simultaneous stimulation of these 2 receptor subtypes by nonsubtype selective agonist, phenylephrine, showed 2 opposite effects on I(Ca) (transient decrease followed by sustained increase). However, selective alpha(1A)-adrenoceptor stimulation (> or =0.1 micromol/L A61603) only potentiated I(Ca), and selective alpha(1B)-adrenoceptor stimulation (10 mumol/L phenylephrine with 2 micromol/L WB4101) only decreased I(Ca). The positive effect by alpha(1A)-adrenoceptor stimulation was blocked by the inhibition of phospholipase C (PLC), protein kinase C (PKC), or Ca2+/calmodulin-dependent protein kinase II (CaMKII). The negative effect by alpha(1B)-adrenoceptor stimulation disappeared after the treatment of pertussis toxin or by the prepulse depolarization, but was not attributable to the inhibition of cAMP-dependent pathway. The translocation of PKCdelta and epsilon to the T-tubules was observed only after alpha(1A)-adrenoceptor stimulation, but not after alpha(1B)-adrenoceptor stimulation. Immunoprecipitation analysis revealed that alpha(1A)-adrenoceptor was associated with G(q/11), but alpha(1B)-adrenoceptor interacted with one of the pertussis toxin-sensitive G proteins, G(o). These findings demonstrated that the interactions of alpha(1)-adrenoceptor subtypes with different G proteins elicit the formation of separate signaling cascades, which produce the opposite effects on I(Ca). The coupling of alpha(1A)-adrenoceptor with G(q/11)-PLC-PKC-CaMKII pathway potentiates I(Ca). In contrast, alpha(1B)-adrenoceptor interacts with G(o), of which the betagamma-complex might directly inhibit the channel activity at T-tubules.     

Role of alpha(2)-adrenergic receptor subtypes in the acute hypertensive response to hypertonic saline infusion in anephric mice

Experimental evidence suggests that the acute hypertensive response induced in anephric animals by infusion of a hypertonic saline solution is mediated by disinhibition of the presynaptic sympathoinhibitory alpha(2)-adrenergic receptors (alpha(2)-AR) of the central nervous system. The purpose of the present experiments was to dissect the role of the 3 distinct alpha(2)-AR subtypes (alpha(2A)-, alpha(2B), - and alpha(2C)-AR) in this response. Groups of genetically engineered mice deficient in each one of these alpha(2)-AR subtype genes were submitted to bilateral nephrectomy followed by a 0.4-mL infusion of 4% saline over a 2-hour period, with constant direct blood pressure (BP) monitoring. The alpha(2A)-AR-deficient and alpha(2C)-AR-deficient mice responded with significant BP elevations (by 11.8+/-2.5 and 16.7+/-1.7 mm Hg, respectively), and so did their wild-type counterparts (17.8+/-2.5 and 11.8+/-2.0 mm Hg, respectively) and the wild-type alpha(2B) +/+ (13.1+/-2.4 mm Hg). However, the alpha(2B)-AR-deficient mice were unable to raise their BP and had a slightly lowered BP (by -3.0+/-4. 0 mm Hg) at the end of the infusion period. All 6 groups exhibited elevated plasma norepinephrine levels ranging between 0.8 and 1.8 ng/mL at the end of the infusion. In all cases, the alpha(2)-AR-deficient groups tended to have higher norepinephrine levels than their wild-type counterparts. Surprisingly, this difference was significant only in the alpha(2B)-AR-deficient mice, which, despite the elevated norepinephrine, were unable to raise their BP. The data suggest that a full complement of the alpha(2B)-AR is needed to mediate the hypertensive response to acute saline load, even though its absence does not prevent the release of norepinephrine under these conditions.     

Calcium handling and role of endothelin-1 in monocrotaline right ventricular hypertrophy of the rat

We investigated the role of endothelin-1 (ET-1) in right ventricular function and intracellular Ca(2+)(Ca(2+)(i)) handling of isolated perfused rat hearts with right ventricular hypertrophy induced by monocrotaline (50 mg/kg). Nine weeks after monocrotaline (n=9) or saline (control n=9) treatment, hearts were perfused isovolumically at 37 degrees C and right ventricular function (fluid-filled balloon), right ventricular intracellular Ca(2+) transients (aequorin bioluminescence method) and the effects of ET-1 were determined. Monocrotaline-treated rats developed considerable right ventricular hypertrophy (right ventricular weight:body weight ratio: 1.07+/-0.13 v. 0.60+/-0.03 in controls P<0.05) and these hearts generated higher right ventricular systolic and diastolic pressure, but similar systolic and diastolic wall stress, indicating a compensated functional state. Hypertrophied hearts demonstrated a prolonged duration of isovolumic contraction (time to 90% decline from peak: 105+/-1 v 89+/-4 ms at 3 m M extracellular Ca(2+) P<0.05), but neither the time to peak pressure (71+/-3 ms) nor time to peak light (25+/-3 ms) were different from controls. The increased duration of contraction correlated with a similar prolongation of the Ca(2+)transient (time to 90% decline from peak: 72+/-4 v 50+/-3 ms P<0.05), indicating a reduced rate of Ca(2+)sequestration in hypertrophic right ventricles. Peak systolic intracellular Ca(2+)was similar in control and hypertrophied hearts (1.04+/-0.02 and 0.99+/-0.02 microM, P>0.05, n=6). ET-1 (1-300 p M) affected neither the time course of right ventricular contraction nor that of the Ca(2+)transient or peak systolic Ca(2+)concentrations. These data are the first measurements of right ventricular Ca(2+)transients in beating normal and hypertrophic hearts. We conclude that ET-1 plays no role in compensated hypertrophy because it affected neither right ventricular function nor intracellular Ca(2+)handling in this model.     

Alpha1-adrenergic stress induces downregulation of Na+/Ca2+ exchanger in myocardial preparations from rabbits at physiological preload

Alpha1-adrenergic stimulation and mechanical load are considered crucial for the expression of sarcolemmal Na+/Ca2+ exchanger (NCX1). However, the interaction between these processes is unknown. We investigated electrically stimulated (1 Hz, 1.75 mmol/L Ca2+) rabbit ventricular trabeculae at physiological preload under stimulation by the selective alpha1-agonist phenylephrine (PE, 10 micromol/L). Using quantitative real-time PCR, downregulation of mRNA to 76.5% (p<0.05) was found, while B-type natriuretic peptide (BNP) was increased to 569.5% (p<0.05) compared to control. These changes were abolished in the presence of both the alpha1-blocker prazosin (13 micromol/L) and the PKC inhibitor GF109203X (1 micromol/L). Furthermore, no changes in NCX mRNA levels under the influence of PE were found in unstretched trabeculae or in unstretched isolated rabbit myocytes (24 h), while BNP was increased in both preparations. In addition, since the alpha1-adrenergic effect could be Ca2+-dependent we tested increased extracellular Ca2+ (3.0 mmol/L) in stretched trabeculae and found downregulation of NCX1 to 75.2% (p<0.05). alpha1-stimulation decreases NCX1 mRNA in rabbit myocardium via PKC. This is critically load-dependent and may be mediated by changes in [Ca2+]. In hypertrophy and heart failure, distinct phenotypes with respect to NCX1 expression may result from the interaction between mechanical load and alpha1-adrenergic stimulation.     

Physiological and pathophysiological modulation of calcium signaling in myocardial cells.

The relationship between changes in intracellular Ca2+ transients and isometric contractions has been assessed in intact cardiac muscle preparations, superficial cells of which have been microinjected with the Ca(2+)-sensitive bioluminescent protein aequorin. Regulation of myocardial contractility by physiological and pathophysiological intervention is achieved by either (1) modulation of intracellular Ca2+ mobilization, or (2) modulation of Ca2+ sensitivity of myofibrils, or both. Regulation of contractility by changes in heart rate a well established frequency-force relationship that plays an important role in the cardiac pumping function in situ is mainly achieved by mechanism (1), other mechanisms becoming involved depending on the range of frequency of stimulation. The length-dependent regulation of contractility (length-tension relationship in vitro or Frank-Starling's law, or ventricular function curve in situ) is achieved essentially by mechanism (2). Catecholamines promote mechanism (1) through activation of beta- and/or alpha-adrenoceptors, alpha-adrenoceptor stimulation being much less effective than beta-stimulation in this respect. beta-Adrenoceptor stimulation decreases, while alpha-stimulation may increase the Ca(2+)-sensitivity of contractile proteins. Subsequent to exposure of muscle preparations to Ca2+ free solution, a prominent and reversible dissociation of force of contraction from Ca2+ transients was produced when the [Ca2+]0 was gradually returned to the level of the normal Krebs-Henseleit solution [( Ca2+]0 = 2.5 mM). The aequorin-injected multicellular intact myocardial cell preparation provides an excellent experimental paradigm through which to address the physiological, pharmacological and pathophysiological modulation of E-C coupling in mammalian cardiac muscle. The subcellular mechanism involved, especially in the pathophysiological modulation of Ca2+ signaling process in myocardial cells, awaits further study.     

Reduced contractile response to alpha1-adrenergic stimulation in atria from mice with chronic cardiac calmodulin kinase II inhibition

The sustained positive inotropic effect of alpha-adrenoceptor agonists in the heart is associated with a small increase in intracellular Ca(2+) transients together with a larger sensitization of myofilaments to Ca(2+). The multifunctional Ca(2+) and calmodulin-dependent protein kinase II (CaMKII) could contribute to this effect, either by affecting the Ca(2+) release (ryanodine receptor) or by an uptake mechanism (via phospholamban [PLB] and SR Ca(2+) ATPase). Here we examined the role of CaMKII in the positive inotropic effect of the alpha-adrenoceptor agonist phenylephrine in left atria isolated from a genetic mouse model of cardiac CaMKII inhibition (AC3-I). Compared to atria from wild-type (WT) or AC3-C (scrambled peptide), AC3-I atria showed the following abnormalities. PLB phosphorylation at Thr17, a known CaMKII target, was significantly lower ( approximately 20%). Post-rest (30 s, 1 Hz, 37 degrees C) potentiation of force was absent (AC3-C, 190% of pre-rest amplitude). Basal force was approximately 20% lower at 1.8 mM Ca(2+), but normal at high Ca(2+) concentration (>4.5 mM). The maximal positive inotropic effect of phenylephrine, which was more pronounced at low frequencies in WT and AC3-C atria, lost its frequency dependence (1 Hz to 8 Hz). Thus, the effect of phenylephrine was reduced by approximately 50% at 1 Hz, but was normal at 8 Hz. All three groups showed a negative force-frequency relation, and did not differ in the frequency-dependent acceleration of relaxation. Our data indicate a role of CaMKII in post-rest potentiation and the positive inotropic effect of alpha-adrenergic stimulation at low frequencies.     

Crucial role of type 1, but not type 3, inositol 1,4,5-trisphosphate (IP(3)) receptors in IP(3)-induced Ca(2+) release, capacitative Ca(2+) entry, and proliferation of A7r5 vascular smooth muscle cells

Stimulation of G protein- or tyrosine kinase-coupled receptors regulates cell proliferation through intracellular Ca(2+) ([Ca(2+)](i)) signaling. In A7r5 cells, we confirmed that inositol 1,4,5-trisphosphate (IP(3)) mediates vasopressin (VP)-evoked Ca(2+) release from intracellular stores and showed that types 1 (IP(3)R(1)) and 3 (IP(3)R(3)) IP(3) receptors were expressed. Using antisera selective for IP(3)R(1) or IP(3)R(3) and another that interacted equally well with both subtypes, together with membranes from SF:9 cells expressing only single IP(3)R subtypes to calibrate immunoblotting, we established that A7r5 cells express 81% IP(3)R(1) and 19% IP(3)R(3). To elucidate the contributions of IP(3)R(1) and IP(3)R(3) to Ca(2+) signaling and proliferation, stable clones expressing promoter-inducible antisense cDNA fragments (-90 to +9) corresponding to the two IP(3)R subtypes were selected. Mild inhibition of IP(3)R(1) (71+/-8% of control level) slightly attenuated the IP(3)-evoked Ca(2+) release (IICR) induced by VP but significantly decreased the subsequent capacitative Ca(2+) entry (CCE) and proliferation. Moderate inhibition (34+/-6%) strongly decreased both IICR and CCE and further blocked proliferation. Complete inhibition almost abolished IICR and CCE and arrested proliferation entirely. Complete inhibition of IP(3)R(3) expression slightly attenuated IICR without affecting CCE or proliferation. In cells microinjected with a low dose of heparin, VP-induced CCE was more susceptible than IICR to mild inhibition of both IP(3)R(1) and IP(3)R(3). A high dose of heparin had a similar effect to complete inhibition of IP(3)R(1) expression: it blocked VP-evoked IICR entirely and CCE by 90%. We conclude that IP(3)R(1), but not IP(3)R(3), is crucial for IICR, CCE, and proliferation of vascular smooth muscle cells.     

Relative abundance of alpha2 Na(+) pump isoform influences Na(+)-Ca(2+) exchanger currents and Ca(2+) transients in mouse ventricular myocytes

In the mouse, genetic reduction in the Na(+), K(+)-ATPase alpha1 or alpha2 isoforms results in different functional phenotypes: heterozygous alpha2 isolated hearts are hypercontractile, whereas heterozygous alpha1 hearts are hypocontractile. We examined Na(+)/Ca(2+) exchange (NCX) currents in voltage clamped myocytes (pipette [Na(+)]=15 mM) induced by abrupt removal of extracellular Na(+). In wild-type (WT) myocytes, peak exchanger currents were 0.59+/-0.04 pA/pF (mean+/-S.E.M., n=10). In alpha1(+/-) myocytes (alpha2 isoform increased by 54%), NCX current was reduced to 0.33+/-0.05 (n=9, P<0.001) indicating a lower subsarcolemmal [Na(+)]. In alpha2(+/-) myocytes (alpha2 isoform reduced by 54%), the NCX current was increased to 0.89+/-0.11 (n=8, P=0.03). The peak sarcolemmal Na(+) pump currents activated by abrupt increase in [K(+)](o) to 4 mM in voltage clamped myocytes in which the Na(+) pump had been completely inhibited for 5 min by exposure to 0 [K(+)](o) were similar in alpha1(+/-) (0.86+/-0.12, n=10) and alpha2(+/-) myocytes (0.94+/-0.08 pA/pF, n=16), and were slightly but insignificantly reduced relative to WT (1.03+/-0.05, n=24). The fluo-3 [Ca(2+)](i) transient (F/F(o)) in WT myocytes paced at 0.5 Hz was 2.18+/-0.09, n=34, was increased in alpha2(+/-) myocytes (F/F(o)=2.56+/-0.14, n=24, P=0.02), and was decreased in alpha1(+/-) myocytes (F/F(o)=1.93+/-0.08, n=28, P<0.05). Thus the alpha2 isoform rather than the alpha1 appears to influence Na(+)/Ca(2+) exchanger currents [Ca(2+)](i) transients, and contractility. This finding is consistent with the proposal that alpha2 isoform of the Na pump preferentially alters [Na(+)] in a subsarcolemmal micro-domain adjacent to Na(+)/Ca(2+) exchanger molecules and SR Ca(2+) release sites.     

Influence of mitochondrial inhibition on global and local [Ca(2+)](I) in rat tail artery

Inhibition of oxidative metabolism is often found to decrease contractility of systemic vascular smooth muscle, but not to reduce global [Ca(2+)](i). In the present study, we probe the hypothesis that it is associated with an altered pattern of intracellular Ca(2+) oscillations (waves) influencing force development. In the rat tail artery, mitochondrial inhibitors (rotenone, antimycin A, and cyanide) reduced alpha(1)-adrenoceptor-stimulated force by 50% to 80%, but did not reduce global [Ca(2+)](i). Less relaxation (about 30%) was observed after inhibition of myosin phosphatase activity with calyculin A, suggesting that part of the metabolic sensitivity involves the regulation of myosin 20-kDa light chain phosphorylation, although no decrease in phosphorylation was found in freeze-clamped tissue. Confocal imaging revealed that the mitochondrial inhibitors increased the frequency but reduced the amplitude of asynchronous cellular Ca(2+) waves elicited by alpha(1) stimulation. The altered wave pattern, in association with increased basal [Ca(2+)](i), accounted for the unchanged global [Ca(2+)](i). Inhibition of glycolytic ATP production by arsenate caused similar effects on Ca(2+) waves and global [Ca(2+)](i), developing gradually in parallel with decreased contractility. Inhibition of wave activity by the InsP(3) receptor antagonist 2-APB correlated closely with relaxation. Furthermore, abolition of waves with thapsigargin in the presence of verapamil reduced force by about 50%, despite unaltered global [Ca(2+)](i), suggesting that contraction may at least partly depend on Ca(2+) wave activity. This study therefore indicates that mitochondrial inhibition influences Ca(2+) wave activity, possibly due to a close spatial relationship of mitochondria and the sarcoplasmic reticulum and that this contributes to metabolic vascular relaxation.     

Coupling function of endogenous alpha(1)- and beta-adrenergic receptors in mouse cardiomyocytes

Genetically altered mouse models constitute unique systems to delineate the role of adrenergic receptor (AR) signaling mechanisms as modulators of cardiomyocyte function. The interpretation of results from these models depends on knowledge of the signaling properties of endogenous ARs in mouse cardiomyocytes. In the present study, we identify for the first time several defects in AR signaling in cardiomyocytes cultured from mouse ventricles. beta(1)-ARs induce robust increases in cAMP accumulation and the amplitude of the calcium and cell motion transients in mouse cardiomyocytes. Selective beta(2)-AR stimulation increases the amplitude of calcium and motion transients, with only a trivial rise in cAMP accumulation in comparison. beta(2)-AR responses are not influenced by pertussis toxin in cultured mouse cardiomyocytes. alpha(1)-ARs fail to activate phospholipase C, the extracellular signal-regulated protein kinase, p38-MAPK, or stimulate hypertrophy in mouse cardiomyocytes. Control experiments establish that this is not due to a lesion in distal elements in the signaling machinery, because these responses are induced by protease-activated receptor-1 agonists and phospholipase C is activated by Pasteurella multocida toxin (a G(q) alpha-subunit agonist). Surprisingly, norepinephrine activates p38-MAPK via beta-ARs in mouse cardiomyocytes, but beta-AR activation of p38-MAPK alone is not sufficient to induce cardiomyocyte hypertrophy. Collectively, these results identify a generalized defect in alpha(1)-AR signaling and a defect in beta(2)-AR linkage to cAMP (although not to an inotropic response) in cultured mouse cardiomyocytes. These naturally occurring vagaries in AR signaling in mouse cardiomyocytes provide informative insights into the requirements for hypertrophic signaling and impact on the value of mouse cardiomyocytes as a reconstitution system to investigate AR signaling in the heart.