Academic literature on the topic 'Β-adrenoceptor signaling'

There is now evidence for the involvement of four β-adrenoceptor populations in the regulation of cardiac function by catecholamines. β1- and β2-adrenoceptor stimulation classically produces an increase in contractility. A fourth β-adrenoceptor, as yet uncloned and designated provisionally as a β4-adrenoceptor, also mediates a positive inotropic effect. β3-adrenoceptors, which had been cloned at the end of the eighties, has been extensively studied as a potential target for antiobesity and antidiabetic drugs. Its characterization in the heart has opened new fields of investigations for the understanding of the cardiac adrenergic regulation. This review describes the cardiac electrical and mechanical effects induced by β3-adrenoceptor stimulation in different species (including human), as well as the signaling pathway. It also analyzes the role of these receptors in the abnormal responsiveness of catecholamines in heart failure.Key words: beta-adrenoceptor, heart, contractility, signaling pathway, heart failure.

The importance of chronic stimulation of β-adrenoceptors in the development of cardiac dysfunction is the rationale for the use of β-blockers in the treatment of heart failure. Nebivolol is a third-generation β-blocker, which has further properties including stimulation of endothelial nitric oxide synthase and/or β3-adrenoceptors. The aim of this study was to investigate whether nebivolol has additional effects on β-adrenoceptor-mediated functional responses along with morphologic and molecular determinants of cardiac hypertrophy compared with those of metoprolol, a selective β1-adrenoceptor blocker. Rats infused by isoprenaline (100 μg·kg−1·day−1, 14 days) were randomized into three groups according to the treatment with metoprolol (30 mg·kg−1·day−1), nebivolol (10 mg·kg−1·day−1), or placebo for 13 days starting on day 1 after implantation of minipump. Both metoprolol and nebivolol caused a similar reduction on heart rate. Nebivolol mediated a significant improvement on cardiac mass, coronary flow, mRNA expression levels of sarcoplasmic reticulum Ca2+ ATPase (SERCA2a) and atrial natriuretic peptide and phospholamban (PLN)/SERCA2a and phospho-PLN/PLN ratio compared with metoprolol and placebo. Nebivolol prevented the detrimental effects of isoprenaline infusion on isoprenaline (68% of control at 30 μM), BRL37344 (63% of control at 0.1 μM), and forskolin (64% of control at 1 μM) responses compared with metoprolol (isoprenaline, 34% of control; BRL37344, no response; forskolin, 26% of control) and placebo (isoprenaline, 33% of control; BRL37344, 28% of control; forskolin, 12% of control). Both β-blockers improved the changes in mRNA expressions of β1- and β3-adrenoceptors. Our results suggest that nebivolol partially protects the responsiveness of β-adrenoceptor signaling and the development of cardiac hypertrophy independent of its β1-adrenoceptor blocking effect.

The distribution of transducers of regulated cAMP-response element-binding protein activity (TORC) between the cytoplasm and the nucleus is tightly regulated and represents one of the main mechanisms whereby the cAMP response element activation activities of TORC are controlled. Whereas both cAMP and Ca2+ pathways can cause translocation of TORC, the relative importance of these two pathways in regulating different TORC within the same cell is unclear. In this study, we determined the mechanism that regulated TORC1 translocation and compared it with that of TORC2 in rat pinealocytes. Stimulation of pinealocytes with norepinephrine (NE), although having no effect on Torc1 transcription, caused rapid dephosphorylation of TORC1. Although NE also caused rapid dephosphorylation of TORC2, pharmacological studies revealed that TORC1 dephosphorylation could be induced by both β-adrenoceptor/cAMP and α-adrenoceptor/intracellular Ca2+ pathways contrasting with TORC2 dephosphorylation being induced mainly through the β-adrenoceptor/cAMP pathway. PhosTag gel indicated a different pattern of TORC1 desphosphorylation resulting from the selective activation of α- or β-adrenoceptors. Interestingly, only the α-adrenoceptor/intracellular Ca2+-mediated dephosphorylation could translocate TORC1 to the nucleus, whereas the β-adrenoceptor/cAMP-mediated dephosphorylation of TORC1 was ineffective. In comparison, translocation of TORC2 was induced predominantly by the β-adrenoceptor/cAMP pathway. Studies with different protein phosphatase (PP) inhibitors indicated that the NE-mediated translocation of TORC1 was blocked by cyclosporine A, a PP2B inhibitor, but that of TORC2 was blocked by okadaic acid, a PP2A inhibitor. Together these results highlight different intracellular signaling pathways that are involved in the NE-stimulated dephosphorylation and translocation of TORC1 and TORC2 in rat pinealocytes.

Cross talk between adrenergic and insulin signaling systems may represent a fundamental molecular basis of insulin resistance. We have characterized a newly established β3-adrenoceptor-deficient (β3-KO) brown adipocyte cell line and have used it to selectively investigate the potential role of novel-state and typical β-adrenoceptors (β-AR) on insulin signaling and action. The novel-state β1-AR agonist CGP-12177 strongly induced uncoupling protein-1 in β3-KO brown adipocytes as opposed to the β3-selective agonist CL-316,243. Furthermore, CGP-12177 potently reduced insulin-induced glucose uptake and glycogen synthesis. Neither the selective β1- and β2-antagonists metoprolol and ICI-118,551 nor the nonselective antagonist propranolol blocked these effects. The classical β1-AR agonist dobutamine and the β2-AR agonist clenbuterol also considerably diminished insulin-induced glucose uptake. In contrast to CGP-12177 treatment, these negative effects were completely abrogated by metoprolol and ICI-118,551. Stimulation with CGP-12177 did not impair insulin receptor kinase activity but decreased insulin receptor substrate-1 binding to phosphatidylinositol (PI) 3-kinase and activation of protein kinase B. Thus the present study characterizes a novel cell system to selectively analyze molecular and functional interactions between novel and classical β-adrenoceptor types with insulin action. Furthermore, it indicates insulin receptor-independent, but PI 3-kinase-dependent, potent negative effects of the novel β1-adrenoceptor state on diverse biological end points of insulin action.

Stimulating the β-adrenoceptor (β-AR) signaling pathway can enhance the functional repair of skeletal muscle after injury, but long-term use of β-AR agonists causes β-AR downregulation, which may limit their therapeutic effectiveness. The aim was to examine β-AR signaling during early regeneration in rat fast-twitch [extensor digitorum longus (EDL)] and slow-twitch (soleus) muscles after bupivacaine injury and test the hypothesis that, during regeneration, β-agonist administration does not cause β-AR desensitization. Rats received either the β-AR agonist fenoterol (1.4 mg·kg−1·day−1 ip) or saline for 7 days postinjury. Fenoterol reduced β-AR density in regenerating soleus muscles by 42%. Regenerating EDL muscles showed a threefold increase in β-AR density, and, again, these values were 43% lower with fenoterol treatment. An amplified adenylate cyclase (AC) response to isoproterenol was observed in cell membrane fragments from EDL and soleus muscles 7 days postinjury. Fenoterol attenuated this increase in regenerating EDL muscles but not soleus muscles. β-AR signaling mechanisms were assessed using AC stimulants (NaF, forskolin, and Mn2+). Although β-agonist treatment reduces β-AR density in regenerating muscles, these muscles can produce large cAMP responses relative to healthy (uninjured) muscles. Desensitization of β-AR signaling in regenerating muscles is prevented by altered rates of β-AR synthesis and/or degradation, changes in G protein populations and coupling efficiency, and altered AC activity. These mechanisms have important therapeutic implications for modulating β-AR signaling to enhance muscle repair after injury.

Salt sensitivity of blood pressure is characterized by inappropriate sympathoexcitation and renal Na+ reabsorption during high salt intake. In salt-resistant animal models, exogenous norepinephrine (NE) infusion promotes salt-sensitive hypertension and prevents dietary Na+-evoked suppression of the Na+-Cl− cotransporter (NCC). Studies of the adrenergic signaling pathways that modulate NCC activity during NE infusion have yielded conflicting results implicating α1- and/or β-adrenoceptors and a downstream kinase network that phosphorylates and activates NCC, including with no lysine kinases (WNKs), STE20/SPS1-related proline-alanine-rich kinase (SPAK), and oxidative stress response 1 (OxSR1). In the present study, we used selective adrenoceptor antagonism in NE-infused male Sprague-Dawley rats to investigate the differential roles of α1- and β-adrenoceptors in sympathetically mediated NCC regulation. NE infusion evoked salt-sensitive hypertension and prevented dietary Na+-evoked suppression of NCC mRNA, protein expression, phosphorylation, and in vivo activity. Impaired NCC suppression during high salt intake in NE-infused rats was paralleled by impaired suppression of WNK1 and OxSR1 expression and SPAK/OxSR1 phosphorylation and a failure to increase WNK4 expression. Antagonism of α1-adrenoceptors before high salt intake or after the establishment of salt-sensitive hypertension restored dietary Na+-evoked suppression of NCC, resulted in downregulation of WNK4, SPAK, and OxSR1, and abolished the salt-sensitive component of hypertension. In contrast, β-adrenoceptor antagonism attenuated NE-evoked hypertension independently of dietary Na+ intake and did not restore high salt-evoked suppression of NCC. These findings suggest that a selective, reversible, α1-adenoceptor-gated WNK/SPAK/OxSR1 NE-activated signaling pathway prevents dietary Na+-evoked NCC suppression, promoting the development and maintenance of salt-sensitive hypertension.

The aim of the present study was to reveal the effect of hyperlipidemia on β2- and β3-adrenergic signaling in late pregnant rat uterus. Hyperlipidemia was induced in female Wistar rats by feeding a high-fat high-cholesterol diet for 8 weeks before and after mating upto the 21st day of gestation. The effect of hyperlipidemia on β-adrenergic signaling was studied with the help of tension experiments, real-time PCR and cAMP ELISA in 21-day pregnant rat uterus. In tension experiments, hyperlipidemia neither altered the spontaneous contractility nor the oxytocin-induced contractions. However, it decreased the −logEC50 values of β2-adrenoceptor agonist, salbutamol and β3-adrenoceptor agonist, BRL37344. It also decreased the efficacy of adenylyl cyclase activator, forskolin. Further, there was a significant decrease in salbutamol and BRL37344-stimulated cAMP content in uterine tissues. However, there was no alteration in mRNA expressions of β2-adrenoceptor (Adrb2), β3-adrenoceptor (Adrb3) and Gs protein (Gnas) though there was a significant increase in the mRNA expression of Gi protein (Gnai). In conclusion, reduced cAMP content after beta-adrenergic receptor stimulation, which correlates with an increase in Gnai mRNA, may explain the mechanism of the impairment of uterine β-adrenergic signaling in hyperlipidemic pregnant rats. The clinical implication of the present study may relate to reduced myometrial relaxant response to β-adrenergic agonists in high fat-induced uterine dysfunction.

The modulation of β-adrenoceptor signaling in the hearts of hindlimb unweighting (HU) simulated weightlessness rats has not been reported. In the present study, we adopted the rat tail suspension for 4 wk to simulate weightlessness; then the effects of simulated microgravity on β-adrenoceptor signaling were studied. Mean arterial blood pressure (ABP), left ventricular pressure (LVP), systolic function (+dP/d tmax), and diastolic function (−dP/d tmax) were monitored in the course of the in vivo experiment. Single rat ventricular myocyte was obtained by the enzymatic dissociation method. Hemodynamics, myocyte contraction, and cAMP production in response to β-adrenoceptor stimulation with isoproterenol or adenylyl cyclase stimulation with forskolin were measured, and Gs protein was also determined. Compared with the control group, no significant changes were found in heart weight, body weight and ABP, while LVP and ±dP/d tmax were significantly reduced. The ABP decrease, LVP increase, and ±dP/d tmax in response to isoproterenol administration were significantly attenuated in the HU group. The effects of isoproterenol on electrically induced single-cell contraction and cAMP production in myocytes of ventricles in the HU rats were significantly attenuated. The biologically active isoform, Gsα (45 kDa) in the heart, was unchanged. Both the increased electrically induced contraction and cAMP production in response to forskolin were also significantly attenuated in the simulated weightlessness rats. Above results indicated that impaired function of adenylyl cyclase causes β-adrenoceptor desensitization, which may be partly responsible for the depression of cardiac function.

Increased sympathoexcitation and renal sodium retention during high salt intake are hallmarks of the salt sensitivity of blood pressure. The mechanism(s) by which excessive sympathetic nervous system release of norepinephrine influences renal sodium reabsorption is unclear. However, studies demonstrate that norepinephrine can stimulate the activity of the NCC (sodium chloride cotransporter) and promote the development of SSH (salt-sensitive hypertension). The adrenergic signaling pathways governing NCC activity remain a significant source of controversy with opposing studies suggesting a central role of upstream α 1 - and β-adrenoceptors in the canonical regulatory pathway involving WNKs (with-no-lysine kinases), SPAK (STE20/SPS1-related proline alanine-rich kinase), and OxSR1 (oxidative stress response 1). In our previous study, α 1 -adrenoceptor antagonism in norepinephrine-infused male Sprague-Dawley rats prevented the development of norepinephrine-evoked SSH in part by suppressing NCC activity and expression. In these studies, we used selective adrenoceptor antagonism in male Dahl salt–sensitive rats to test the hypothesis that norepinephrine-mediated activation of the NCC in Dahl SSH occurs via an α 1 -adrenoceptor dependent pathway. A high-salt diet evoked significant increases in NCC activity, expression, and phosphorylation in Dahl salt–sensitive rats that developed SSH. Increases were associated with a dysfunctional WNK1/4 dynamic and a failure to suppress SPAK/OxSR1 activity. α 1 -adrenoceptor antagonism initiated before high-salt intake or following the establishment of SSH attenuated blood pressure in part by suppressing NCC activity, expression, and phosphorylation. Collectively, our findings support the existence of a norepinephrine-activated α 1 -adrenoceptor gated pathway that relies on WNK/SPAK/OxSR1 signaling to regulate NCC activity in SSH.

L’AMP cyclique (AMPc) et le GMP cyclique (GMPc) sont des seconds messagers essentiels pour la régulation de la fonction cardiaque. La concentration de l’AMPc intracellulaire est régulée par les activités d'au moins deux familles d'enzymes: les cyclases et guanylyl cyclases, responsable de la synthèse de l'AMPc et du GMPc, et les phosphodiestérases (PDE) qui interviennent dans l’hydrolyse de l'AMPc et du GMPc.Parmi la superfamille des PDEs, la PDE2 est une enzyme à double substrat qui hydrolyse à la fois l'AMPc et le GMPc et a la propriété unique d'être stimulée par le GMPc. Il a été récemment montré que la PDE2 du myocarde est augmentée dans l'insuffisance cardiaque humaine et expérimentale (IC), tandis que d'autres (par exemple PDE3 et PDE4) sont réduites. Cependant, les conséquences physiopathologiques de l'activité PDE2 renforcée dans le cœur sont inconnues.Dans ce contexte, nous avons généré des souris transgénique (TG) avec une surexpression spécifique cardiaque de l’isoforme PDE2A3 (souris PDE2 TG).Grace à l’utilisation de Western blot et de dosage radioenzymatique nous avons montré que l'AMPc cardiaque et l'activité PDE cGMP et l'activité spécifique de PDE2 sont fortement augmentées dans les PDE2 TG par rapport à des souris de type sauvage (WT).Le raccourcissement cellulaire, les transitoires calciques et le courant calcique de type L (ICa, L) ont été enregistrés dans les myocytes ventriculaires adultes de souris WT et PDE2 TG et l'isoprénaline (ISO) a été utilisée pour examiner et comparer la réponse β-adrénergique (β-AR) de ces paramètres. Nous avons montré que lors de la stimulation β-AR, la contractilité cellulaire, la transitoire Ca2+ et l’amplitude du courant ICa,L sont fortement diminués. En conséquence, la surexpression de la PDE2 dans les cardiomyocytes a réduit les taux d'AMPc et abolit l'effet inotrope après une stimulation β-AR aiguë. L'ECG mesuré par télémétrie chez la souris PDE2 TG a montré une réduction marquée de la fréquence cardiaque au repos ainsi que de la fréquence cardiaque maximale, tandis que le débit cardiaque a est entièrement préservé en raison d'une contractilité plus forte. Fait important, les souris TG PDE2 sont résistantes à des arythmies ventriculaires déclenchées et à des arythmies induites par isoprénaline.En conclusion, ce travail montre que PDE2 joue un rôle essentiel dans la régulation du couplage excitation-contraction cardiaque. La surexpression de PDE2 semble protéger les cardiomyocytes contre une stimulation excessive β-AR et réduit le risque d'arythmie lors de l'activation sympathique.L’activation de la PDE2 peut donc représenter une nouvelle stratégie thérapeutique anti-adrénergique et anti-arythmique subcellulaire dans l’insuffisance cardiaque<br>Cyclic AMP (cAMP) and cyclic GMP (cGMP) are critical second messengers for the regulation of cardiac function. Intracellular cAMP concentration is regulated by the activities of at least two families of enzymes: adenylyl and guanylyl cyclases, responsible for cAMP and cGMP synthesis and cyclic nucleotide phosphodiesterases (PDEs) that mediate cAMP and cGMP hydrolysis.Among the PDE superfamily, PDE2 is a dual substrate enzyme that hydrolyzes both cAMP and cGMP and has the unique property to be stimulated by cGMP. It was recently showed that myocardial PDE2 is increased in human and experimental heart failure (HF), while other PDEs (e.g. PDE3 and PDE4) are reduced. However, the pathophysiological consequences of enhanced PDE2 activity in the heart are unknown.In this context, we generated a transgenic (TG) mouse with a heart specific overexpression of the PDE2A3 isoform (PDE2 TG mouse). Using immunoblotting and radioenzymatic assay we showed that total cardiac cAMP and cGMP PDE activity and specific PDE2 activity was strongly increased in PDE2 TG compared to wild type (WT) mice. Sarcomere shortening, Ca2+ transients and the whole L-type Ca2+ current (ICa,L) were recorded in adult ventricular myocytes from WT and PDE2 TG mice and isoprenaline (ISO) was used to examine and compare the β-adrenergic (β-AR) response of these parameters. We showed that upon β-AR stimulation, cell contractility, Ca2+ transient and ICa,L were severely blunted. Accordingly, PDE2 overexpression in cardiomyocytes reduced the cAMP levels and abolished the inotropic effect following acute β-AR stimulation. ECG telemetry in PDE2 TG mice showed a marked reduction in resting as well as in maximal heart rate, while cardiac output was completely preserved due to greater contractility. Importantly, PDE2 TG mice were resistant to triggered ventricular arrhythmias and to isoprenaline-induced arrhythmias.In conclusion, this work demonstrates that PDE2 plays a critical role in the regulation of cardiac excitation-contraction coupling. PDE2 overexpression appears to protect the cardiomyocytes against excessive β-AR drive and reduces the risk of arrhythmias during sympathetic activation. PDE2 activation may thus represent a new subcellular anti-adrenergic and anti-arrhythmic therapeutic strategy in HF

L'AMP cyclique (AMPc) et le GMP cyclique (GMPc) sont des seconds messagers essentiels pour la régulation de la fonction cardiaque. Leurs niveaux sont régulés par l’adénylate cyclase et la guanylate cyclase, respectivement, et par les phosphodiestérases (PDEs). Cependant, une telle régulation est altérée dans l'insuffisance cardiaque (IC). En effet, la diminution de la signalisation de l’AMPc et l’augmentation de celle du GMPc est caractéristique des cœurs défaillants.Parmi la superfamille des PDEs, la PDE2 a la particularité d'être stimulée par le GMPc, conduisant ainsi à une augmentation remarquable de l'hydrolyse de l'AMPc. Ceci semble induire une interaction entre les voies de signalisation de l’AMPc et du GMPc. Cependant, le rôle de la PDE2 dans le cœur défaillant est très peu connu.Dans ce contexte, nous avons examiné si la PDE2 cardiaque est modifiée dans l’IC chez l’Homme et chez les modèles animaux d’IC, et déterminé le rôle de la PDE2 dans la signalisation β-adrénergique dans les cardiomyocytes. Grâce à l’utilisation de Western blot, de technique radioenzymatique, d’imagerie basée sur le FRET, de la planimétrie, de la microscopie à épifluorescence et des mesures du courant calcique de type L, réalisés sur les tissus myocardiques humains et/ou dans des cardiomyocytes isolés de cœurs des modèles animaux d’IC, respectivement, nous avons montré que l’expression et l’activité de la PDE2 sont augmentées dans les cœurs défaillants. Cette augmentation réduit l’effet d’une stimulation β-adrénergique aiguë, contribuant à la désensibilisation β-adrénergique observée dans l’IC. En accord avec ces résultats, la surexpression de la PDE2 dans des cardiomyocytes sains, réduit l’augmentation des taux d'AMPc et l’amplitude du courant ICa,L et abolit l'effet inotrope positif suite à une stimulation β-adrénergique aiguë, sans affecter la contractilité basale. Plus important, les cardiomyocytes surexprimant la PDE2, montrent une protection contre les réponses hypertrophiques induites par la noradrénaline et contre les arythmies induites par l'isoprotérénol.En conclusion, ce travail met en évidence l'altération de la PDE2 dans l’IC et nous laisse suggérer que l’augmentation de la PDE2 dans l’IC peut constituer un mécanisme de défense important dans des conditions de stress cardiaque, notamment en antagonisant la suractivation de la voie β-adrénergique. Ainsi, l'activation de PDE2 myocardique peut représenter une nouvelle stratégie thérapeutique anti-adrénergique intracellulaire dans l’IC<br>Cyclic AMP (cAMP) and cyclic GMP (cGMP) are critical second messengers for the regulation of cardiac function. Their levels are regulated by adenylyl and guanylyl cyclases, respectively, and by cyclic nucleotides phosphodiesterases (PDEs). However, such regulation is altered in heart failure (HF). Indeed diminished cAMP- and augmented cGMP-signaling is characteristic of failing hearts.Among the PDE superfamily, PDE2 has the unique property to be stimulated by cGMP, thus leading to a remarkable increase in cAMP hydrolysis. This appears to mediate a negative cross-talk between cAMP- and cGMP signaling pathways. However, the role of PDE2 in the failing heart is only poorly understood.In this context, we investigated whether myocardial PDE2 is altered in human and experimental HF and determined PDE2 mediated effects on β-adrenoceptor (β-AR) signaling in cardiomyocytes. Using immunoblotting, radioenzymatic- and FRET-based assays, video-edge-detection, epifluorescent microscopy and L-type Ca2+ current measurements, performed in myocardial tissues and/or isolated cardiomyocytes from human and/or experimental HF, respectively, we showed that PDE2 is markedly upregulated in failing hearts. This reduces the effect of an acute β-adrenergic stimulation, and contributes to the β-adrenergic desensitization which is a characteristic feature in HF. Accordingly, PDE2 overexpression in healthy cardiomyocytes reduced the rise in cAMP levels and ICa,L amplitude and abolished the inotropic effect following acute β-AR stimulation, without affecting basal contractility. Importantly, PDE2-overexpressing cardiomyocytes showed marked protection from norepinephrine-induced hypertrophic responses and from isoproterenol-induced arrhythmias.In conclusion, this work highlights the alteration of PDE2 in HF and lets us assume that PDE2 upregulation in HF may constitute an important defence mechanism during cardiac stress, e.g. by antagonizing excessive β-AR drive. Thus, activating myocardial PDE2 may represent a novel intracellular anti-adrenergic therapeutic strategy in HF