Selective ß2-AR Blockage Suppresses Colorectal Cancer Growth Through Regulation of EGFR-Akt/ERK1/2 Signaling, G1-Phase Arrest, and Apoptosis.

The stress-upregulated catecholamines-activated ß1- and ß2-adrenergic receptors (ß1/2-ARs) have been shown to accelerate the progression of cancers such as colorectal cancer (CRC). We investigated the underlying mechanism of the inhibition of ß1/2-ARs signaling for the treatment of CRC and elucidated the significance of ß2-AR expression in CRC in vitro and in clinical samples. The impacts of ß1/2-AR antagonists in CRC in vitro and CRC-xenograft in vivo were examined. We found that repression of ß2-AR but not ß1-AR signaling selectively suppressed cell viability, induced G1-phase cell cycle arrest, caused both intrinsic and extrinsic pathways-mediated apoptosis of specific CRC cells and inhibited CRC-xenograft growth in vivo. Moreover, the expression of ß2-AR was not consistent with the progression of CRC in vitro or in clinical samples. Our data evidence that the expression profiles, signaling, and blockage of ß2-AR have a unique pattern in CRC comparing to other cancers. ß2-AR antagonism selectively suppresses the growth of CRC accompanying active ß2-AR signaling, which potentially carries wild-type KRAS, in vitro and in vivo via the inhibition of ß2-AR transactivated EFGR-Akt/ERK1/2 signaling pathway. Thus, ß2-AR blockage might be a potential therapeutic strategy for combating the progressions of ß2-AR-dependent CRC.

Beta-adrenergic receptors, from their discovery and characterization through their manipulation to beneficial clinical application.

ß-Adrenergic receptors (ß-AR) are central to the overall regulation of cardiac function. From the first proposed receptor/transmitter concept to the latest clinical ß-blocker trials ß-AR have been shown to play an important role in cardiac disease and heart failure in particular. This study provides a historical perspective, reviews the latest discoveries and beliefs, and discusses the current clinical practices of ß-AR and their modulation with their associated guanine-nucleotide regulatory protein/adenylylcyclasesignal transduction pathways.

ß-Adrenergic receptor subtype signaling in heart: from bench to bedside.

ß-adrenergic receptor (ßAR) stimulation by the sympathetic nervous system or circulating catecholamines is broadly involved in peripheral blood circulation, metabolic regulation, muscle contraction, and central neural activities. In the heart, acute ßAR stimulation serves as the most powerful means to regulate cardiac output in response to a fight-or-flight situation, whereas chronic ßAR stimulation plays an important role in physiological and pathological cardiac remodeling.There are three ßAR subtypes, ß(1)AR, ß(2)AR and ß(3)AR, in cardiac myocytes. Over the past two decades, we systematically investigated the molecular and cellular mechanisms underlying the different even opposite functional roles of ß(1)AR and ß(2)AR subtypes in regulating cardiac structure and function, with keen interest in the development of novel therapies based on our discoveries. We have made three major discoveries, including (1) dual coupling of ß(2)AR to G(s) and G(i) proteins in cardiomyocytes, (2) cardioprotection by ß(2)AR signaling in improving cardiac function and myocyte viability, and (3) PKA-independent, CaMKII-mediated ß(1)AR apoptotic and maladaptive remodeling signaling in the heart. Based on these discoveries and salutary effects of ß(1)AR blockade on patients with heart failure, we envision that activation of ß(2)AR in combination with clinically used ß(1)AR blockade should provide a safer and more effective therapy for the treatment of heart failure.

Noradrenaline acting at central beta-adrenoceptors induces interleukin-10 and suppressor of cytokine signaling-3 expression in rat brain: implications for neurodegeneration.

Evidence indicates that the monoamine neurotransmitter noradrenaline elicits anti-inflammatory actions in the central nervous system (CNS), and consequently may play a neuroprotective role where inflammatory events contribute to CNS pathology. Here we examined the ability of pharmacologically enhancing central noradrenergic tone to induce expression of anti-inflammatory cytokines in rat brain. Administration of the noradrenaline reuptake inhibitor reboxetine (15mg/kg; ip) combined with the alpha(2)-adrenoceptor antagonist idazoxan (1mg/kg; ip) induced interleukin-10 (IL-10) expression in rat cortex and hippocampus. In addition, these drug treatments induced IL-10 signaling as indicated by increased STAT3 phosphorylation and suppressor of cytokine signaling-3 (SOCS-3) mRNA expression. In contrast to the profound increase in IL-10 induced by the reboxetine/idazoxan combination, the other two broad spectrum anti-inflammatory cytokines IL-4 and TGF-beta were not induced by this treatment. The ability of combined treatment with reboxetine and idazoxan to induce IL-10 and SOCS3 expression was mediated by beta-adrenoceptor activation, as their induction was blocked by pre-treatment with the beta-adrenoceptor antagonist propranolol. Moreover, administration of the brain penetrant beta(2)-adrenoceptor agonist clenbuterol induced a time- and dose-dependent increase in central IL-10 and SOCS3 expression, and the ability of clenbuterol to induce IL-10 and SOCS-3 expression was blocked by the centrally acting beta-adrenoceptor antagonist, propranolol, and was mimicked by the highly selective beta(2)-adrenoceptor agonist formoterol. In all, these data indicate that increasing central noradrenergic tone induces IL-10 production and signaling in the CNS, which may protect against neurodegeneration.

Gene therapy in heart failure.

With increasing knowledge of basic molecular mechanisms governing the development of heart failure (HF), the possibility of specifically targeting key pathological players is evolving. Technology allowing for efficient in vivo transduction of myocardial tissue with long-term expression of a transgene enables translation of basic mechanistic knowledge into potential gene therapy approaches. Gene therapy in HF is in its infancy clinically with the predominant amount of experience being from animal models. Nevertheless, this challenging and promising field is gaining momentum as recent preclinical studies in larger animals have been carried out and, importantly, there are 2 newly initiated phase I clinical trials for HF gene therapy. To put it simply, 2 parameters are needed for achieving success with HF gene therapy: (1) clearly identified detrimental/beneficial molecular targets; and (2) the means to manipulate these targets at a molecular level in a sufficient number of cardiac cells. However, several obstacles do exist on our way to efficient and safe gene transfer to human myocardium. Some of these obstacles are discussed in this review; however, it primarily focuses on the molecular target systems that have been subjected to intense investigation over the last decade in an attempt to make gene therapy for human HF a reality.

Evolving mechanisms of action of beta blockers: focus on nebivolol.

Beta (beta) blockers are widely used for treatment of cardiovascular and noncardiovascular diseases. Nevertheless, their mechanism of action is not fully understood and differs significantly among agents in this class. Chronic increases in adrenergic activity in heart failure result in desensitization of cardiac beta-adrenergic receptor signal transduction and adverse effects on myocytes. By reducing heart rate and decreasing myocardial workload, the pathologic remodeling of the heart may be reversed with beta-blocking agents. Among beta-blockers, there are clear differences in pharmacodynamic and pharmacokinetic properties. Newer beta-blockers differ from older agents with respect to beta-adrenoceptor affinity and selectivity and partial agonist activity, which may affect their mechanism of action and be important in clinical use.The first beta-antagonist compounds were nonselective; the next generation of beta-blockers was selective for beta1-receptors. The most recent beta-blockers may be nonselective or selective, and they have the additional ancillary property of vasodilation. Nebivolol is among the newer third-generation beta-blockers. It is unique in the class, since apart from its cardioselectivity, it also produces nitric oxide-mediated vasodilation. As a result, its hemodynamic profile is clearly different from those of traditional beta-blockers. This review will evaluate this class of agents and the basis for their differences in clinical use.

beta-adrenergic relaxation in pulmonary arteries: preservation of the endothelial nitric oxide-dependent beta2 component in pulmonary hypertension.

AIMS: beta-adrenoceptor (beta-AR)-mediated relaxation was characterized in pulmonary arteries from normoxic and hypoxic (as model of pulmonary hypertension) mice. The endothelial NO synthase (eNOS) pathway was especially investigated because of its potential vasculoprotective effects. METHODS: Pulmonary arteries from control or hypoxic (0.5 atm for 21 days) wild-type or eNOS-/- mice were used for pharmacological characterization of beta-AR-mediated relaxation in myograph, and for immunohistochemistry using anti-beta-AR antibodies. RESULTS: In pulmonary arteries from normoxic mice, isoproterenol (beta-AR agonist) and procaterol (selective beta2-AR agonist) elicited relaxation, while cyanopindolol and CL316243 (beta3-AR agonists) were ineffective. The effect of isoproterenol was antagonized by CGP20712A and ICI118551 (beta1- or beta2-AR antagonists, respectively) and also partially inhibited by N omega-nitro-L-arginine methylester (L-NAME, a NOS inhibitor), endothelium denudation, or eNOS gene deletion. Relaxation to procaterol was abolished by L-NAME or endothelium removal. In eNOS-/- mice, procaterol-induced relaxation was decreased but was insensitive to L-NAME, this residual effect involving other endothelium-dependent relaxant factors as compensatory mechanisms. Immunostaining for beta2-AR was observed in the endothelial layer, but not the medial layer of pulmonary arteries. Pulmonary arteries from hypoxic mice exhibited decreased endothelial NO-dependent relaxation to acetylcholine. However, in these arteries, relaxation to procaterol was either unaffected (extralobar segments) or even increased (intralobar segments) and was still abolished by L-NAME or endothelium removal. CONCLUSION: beta1- and beta2-AR, but not beta3-AR, mediate relaxation of mice pulmonary arteries. The beta2-AR component is dependent on eNOS activity and is preserved following chronic hypoxia. These data highlight the role of the beta2-AR as a pharmacological target to induce/restore endothelial NO-dependent protective effects in pulmonary circulation.

Three Generations of ß-blockers: History, Class Differences and Clinical Applicability.

BACKGROUND: Beta-adrenergic receptors are expressed in cardiomyocytes and activated by either noradrenaline released from sympathetic synapses or circulating catecholamines. Their corresponding receptors have three subtypes, namely, ß1, ß2 and ß3, which are members of the G protein-coupled receptors (GPCRs) family. Activation of ß1-adrenergic receptors causes various physiological reactions including cardiac contraction and renin secretion from juxtaglomerular cells of the kidney. Antagonists of ß-adrenergic receptors, known as ß-blockers, have been used effectively for over four decades and have beneficial effects in the treatment of cardiovascular diseases. There are three generations of ß-blockers according to their pharmacological properties. Firstgeneration ß-blockers are non-selective, blocking both ß1- and ß2-receptors; second-generation ß- blockers are more cardioselective in that they are more selective for ß1-receptors; and thirdgeneration ß-blockers are highly selective drugs for ß1-receptors. The latter also display vasodilator actions by blocking α1-adrenoreceptors and activating ß3-adrenergic receptors. In addition, thirdgeneration ß-blockers exhibit angiogenic, antioxidant, anti-proliferative, anti-hypertrophic and antiapoptotic activities among other effects that are still under investigation. CONCLUSION: The objective of this review is to describe the evolution observed during the development of the three distinctive generations, thereby highlighting the advantages of third-generation ß- blockers over the other two drug classes.

Tissue distribution of beta 3-adrenergic receptor mRNA in man.

Expression of mRNA for beta 1-, beta 2-, and beta 3-adrenergic receptors (beta 1-, beta 2-, and beta 3-AR) was investigated in human tissues. beta 1- and beta 2-AR mRNA distribution correlated with that of the cognate receptors established by pharmacological studies. beta 3-AR transcripts were abundant in infant perirenal brown adipose tissue, characterized by the presence of uncoupling protein (UCP) mRNA. In adult whole adipose tissues, beta 3-AR mRNA levels were high in deep deposits such as perirenal and omental, and lower in subcutaneous. In these deposits, UCP mRNA levels paralleled those of beta 3-AR. However, isolated omental and subcutaneous adipose cells, enriched in white adipocytes, expressed beta 3-AR but no UCP transcripts. beta 3-AR mRNA was highly expressed in gallbladder, and to a much lower extent in colon, independently of UCP mRNA. Quadriceps or abdominal muscles, heart, liver, lung, kidney, thyroid, and lymphocytes did not express intrinsic beta 3-AR mRNA. This study demonstrates that substantial amounts of brown adipocytes exist throughout life in adipose deposits, which are generally classified as white. These deposits are the main sites of beta 3-AR expression, which also occurs in gallbladder and colon. beta 3-AR may thus be involved in the control of lipid metabolism, possibly from fat assimilation in the digestive tract, to triglyceride storage and mobilization in adipose tissues.

"Phenotypic" pharmacology: the influence of cellular environment on G protein-coupled receptor antagonist and inverse agonist pharmacology.

A central dogma of G protein-coupled receptor (GPCR) pharmacology has been the concept that unlike agonists, antagonist ligands display equivalent affinities for a given receptor, regardless of the cellular environment in which the affinity is assayed. Indeed, the widespread use of antagonist pharmacology in the classification of receptor expression profiles in vivo has relied upon this 'antagonist assumption'. However, emerging evidence suggests that the same gene-product may exhibit different antagonist pharmacological profiles, depending upon the cellular context in which it is expressed-so-called 'phenotypic' profiles. In this commentary, we review the evidence relating to some specific examples, focusing on adrenergic and muscarinic acetylcholine receptor systems, where GPCR antagonist/inverse agonist pharmacology has been demonstrated to be cell- or tissue-dependent, before going on to examine some of the ways in which the cellular environment might modulate receptor pharmacology. In the majority of cases, the cellular factors responsible for generating phenotypic profiles are unknown, but there is substantial evidence that factors, including post-transcriptional modifications, receptor oligomerization and constitutive receptor activity, can influence GPCR pharmacology and these concepts are discussed in relation to antagonist phenotypic profiles. A better molecular understanding of the impact of cell background on GPCR antagonist pharmacology is likely to provide previously unrealized opportunities to achieve greater specificity in new drug discovery candidates.

Different changes of plasma membrane beta-adrenoceptors in rat heart after chronic administration of propranolol, atenolol and bevantolol.

Recently, tissue segment binding method with a hydrophilic radioligand [(3)H]-CGP12177 was developed to detect plasma membrane beta-adrenoceptors in rat heart (Horinouchi et al., 2006). In the present study, propranolol (40 mg kg(-1) day(-1)), atenolol (40 mg kg(-1) day(-1)) and bevantolol (200 mg kg(-1) day(-1)) were administered to rats for 6 weeks, and the changes of plasma membrane beta-adrenoceptors and their mRNA expression in rat ventricle were examined. Chronic administration of propranolol increased the beta(1)-adrenoceptors but decreased the beta(2)-adrenoceptors without changing total amount of plasma membrane beta-adrenoceptors. Atenolol increased both plasma membrane beta(1)- and beta(2)-adrenoceptors, whereas bevantolol had no effect on the beta-adrenoceptor density and their subtype proportions. In contrast, the density of beta-adrenoceptors detected in conventional homogenate binding study was extremely low (approximately 60% of plasma membrane beta-adrenoceptors detected with the tissue segment binding method) and the effects of chronic administration of beta-adrenoceptor antagonists were not necessarily in accord with those at the plasma membrane beta-adrenoceptors. The mRNA levels of beta(1)- and beta(2)-adrenoceptors were not altered by propranolol treatment, while beta(1)-adrenoceptor mRNA significantly decreased after administration of atenolol or bevantolol without changing the level of beta(2)-adrenoceptor mRNA. The present binding study with intact tissue segments clearly shows that the plasma membrane beta(1)- and beta(2)-adrenoceptors of rat heart, in contrast to the homogenate binding sites and the mRNA levels, are differently affected by chronic treatment with three beta-adrenoceptor antagonists; up- and down-regulations of beta(1)- and beta(2)-adrenoceptors, respectively, by propranolol, and up-regulation of both the subtypes by atenolol, but no significant change in both the subtypes by bevantolol.

Norepinephrine-induced migration of SW 480 colon carcinoma cells is inhibited by beta-blockers.

Beta-adrenoceptors are highly expressed on SW 480 colon carcinoma cells as was assessed by flow cytometry. We investigated the influence of norepinephrine on the migration of these cells using time-lapse videomicroscopy. Norepinephrine-treatment increased the locomotor activity within the population from 25% spontaneously locomoting cells to 65% locomoting cells. The beta1/2-blocker propranolol but not the beta1-blocker atenolol inhibited this increase. The intracellular signaling solely of norepinephrine-induced locomotion involved protein tyrosine kinase activity, whereas both spontaneous and norepinephrine-induced migration were reduced by inhibiting phospholipase Cgamma and protein kinase Calpha activity. In summary, norepinephrine-induced locomotion of SW 480 cells is beta2-adrenoceptor mediated and distinct from spontaneous locomotion concerning the PTK involvement.

The distribution and significance of CNS adrenoceptors examined with in situ hybridization.

Several of the established alpha 1-, alpha 2- and beta-adrenoceptors have now been isolated and cloned. The in situ hybridization method has been used to map the distribution of many of these adrenoceptors within cells of the CNS. These studies add complementary and new information to our knowledge of adrenoceptor localization provided previously by radioligand-mediated autoradiography. Neuronal cell groups containing one or more mRNAs for seven adrenoceptor subtypes throughout the rat CNS have been mapped. In the present review Anthony Nicholas, Tomas Hökfelt and Vincent Pieribone will examine these localizations and discuss the additional information these maps supply, as well as some implications for understanding central noradrenaline and adrenaline systems.

Impaired expression and functional activity of the beta 3- and beta 1-adrenergic receptors in adipose tissue of congenitally obese (C57BL/6J ob/ob) mice.

Adipocytes from genetically obese (ob/ob) mice display an impaired response to beta-adrenergic stimulation, but the molecular defects have not been unequivocally identified. The expression and functional activity of the beta 1-, beta 2-, and beta 3-adrenergic receptor (AR) subtypes in white and brown adipose tissue from genetically lean and obese (ob/ob) mice were compared. Three beta 3AR transcripts of 2.1, 2.6, and 3.5 kilobases were identified in adipose tissue from lean mice by Northern blotting. All three beta 3AR mRNA species were dramatically reduced (by approximately 300-fold) in 12-week-old obese mice compared to those in lean animals. beta 1AR mRNA levels were also reduced (by approximately 4-fold) in obese mice, whereas beta 2AR mRNA levels were not significantly changed. The functional consequences of these changes in beta 3AR and beta 1AR expression were assessed by measuring beta-agonist-stimulated adenylyl cyclase activity in adipocyte plasma membranes with subtype-selective beta-adrenergic agonists and antagonists. Dose-response curves with epinephrine from lean mice were best fit to a two-component model comprised of 23% high affinity (K(act) = 1.42 x 10(-7) M) and 77% low affinity (K(act) = 1.67 x 10(-5) M) components, corresponding to activation of beta 1AR and beta 2AR conjointly, and beta 3AR, respectively. The beta 1AR-selective antagonist CGP20712A reduced the high affinity component to about 10%, whereas the nonselective beta-antagonist propranolol eliminated the high affinity component. The beta 3AR-selective agonist BRL37344 stimulated adenylyl cyclase activity in lean membranes to a slightly lesser extent than epinephrine, but was more potent (73% high affinity component; K(act) = 3.61 x 10(-8) M). In obese mice, stimulation of adenylyl cyclase by all agonists was severely blunted and was best fit to a single class of sites. Studies with CGP20712A or the beta 2AR-selective antagonist ICI118,551 indicated that this residual response was predominantly beta 2AR in character. Expression of beta AR subtypes in both brown and white adipose tissue of weanling obese mice (4-5-weeks of age) was also affected, but to a lesser extent, consistent with the progressive severity of obesity with age. Together the reduction in expression of the beta 3AR and beta 1AR impairs the beta-agonist-stimulated adenylyl cyclase response over a broad concentration range by greatly lowering the maximum stimulation and shifting the adrenergic sensitivity at low concentrations from a mixed beta 1AR/beta 2AR response to predominantly beta 2AR.

[Genotype combination distribution of 5-site SNPs in 3 subtypes of beta adrenoceptor].

DNA was extracted from the peripheral venous blood of 338 subjects using BLOOD DNA MINI KIT. The 5 site SNP in 3 subtypes of Beta-AR were genotyped by PCR-RFLP (polymerase chain reaction-restriction fragment length polymorphism) and allele-specific primer PCR techniques. The genotypes combination distribution of SNP at 5 sites in the 3 subtypes of Beta-AR were determined by clustering analysis technique. The natural combination distribution characteristics for SNP at 5 sites in the 3 subtypes of Beta-AR in 338 subjects were obtained. Sixty-seven combinations types were found. The preceding 5 combinations in the natural combination distribution of the SNP were: (1) The genotype combination of forty subjects was B1-AR S/S49+B1-AR R/R389+B2-AR R/G16+B2-AR Q/E27+B3-AR W/W64, its probability was 11.83%. (2) The genotype combination of thirty-three subjects was B1-AR S/S49+B1-AR R/R389+B2-AR R/G16+B2-AR Q/Q27+B3-AR W/W64, its probability was 9.76%. (3) The genotype combination of nineteen subjects was B1-AR S/S49+B1-AR R/G389+B2-AR R/G16+B2-AR Q/Q27+B3-AR W/W64, its probability was 5.62%. (4) The genotype combination of sixteen subjects was B1-AR S/S49+B1-AR R/G389+B2-AR R/G16+B2-AR Q/E27+B3-AR W/W64, its probability was 4.74%. (5) The genotype combination of thirteen subjects was B1-AR S/G49+B1-AR R/R389+B2-AR R/G16+B2-AR Q/E27+B3-AR W/W64, its probability was 3.85%. The obvious correlations exist among full sample and female or male subgroup, and between female and male subgroups.

Apparent lack of beta 2 adrenergic receptors in porcine myocardium.

The aim of this study was to investigate the relative numbers of myocardial beta 1 and beta 2 receptors in pigs. Membrane particles from left ventricular porcine and mixed ventricular rat myocardium were examined for subtypes of beta adrenergic receptors with a radioligand binding technique using [125I]-cyanopindolol (ICYP) as trace, and the new highly beta 1 selective antagonist Sandoz 204 545 and the beta 2 selective antagonist ICI 118 551 for displacement. Radioligand displacement experiments were also performed using propranolol, isoprenaline and terbutaline. The displacement curves obtained with the subtype selective antagonists and agonist revealed biphasic inhibition of specific ICYP binding in rat preparations, indicating a beta 1/beta 2 ratio of approximately 2/1. In porcine preparations displacement of specific ICYP binding with all agents resulted in monophasic curves, thus sharply contrasting the rat preparations. Affinity constants of displacing drugs derived from these monophasic curves indicated that the specific binding site was a beta 1 receptor. No displacement compatible with beta 2 affinity was found. In the same rat preparations we found that adenylate cyclase activation and inhibition by beta receptor subtype specific agonists and antagonists were mediated by two receptor subtypes, whereas in the pig, adenylate cyclase activation and its inhibition seemed to occur via only one receptor subtype, the beta 1 adrenoceptor.

Characterization of alpha- and beta-adrenergic agonist stimulation of adenylate cyclase activity in human epidermal keratinocytes in vitro.

Adrenergic receptors are responsible for selective recognition and binding of catecholamines and may in turn have an effect on epidermal cell growth and maturation via adenosine-3',5'-monophosphate (cAMP). Using endogenous catecholamines and drugs specific for alpha- and beta-receptor subtypes, we have characterized the adrenergic receptor coupled to adenylate cyclase in cultured human epidermal keratinocytes. The relative potency order of stimulation of adenylate cyclase was: isoproterenol greater than epinephrine much greater than norepinephrine. The predominant adrenergic receptor is of the beta 2-subtype, as also confirmed by use of the selective antagonists propranolol, butoxamine, and atenolol. No evidence of alpha-adrenergic receptor mediation of adenylate cyclase was noted with the alpha 2-specific agonist, clonidine. Phenylephrine, the alpha 1-specific agonist, affected cAMP formation but this response could not be totally inhibited with prazosin, suggesting an unknown mechanism of action. Human keratinocytes retained the same beta-adrenergic receptor potency order properties throughout growth and maturation.

Age-dependent changes in beta-adrenergic receptor subtypes and adenylyl cyclase activation in adipocytes from Fischer 344 rats.

Epididymal adipocytes were isolated from Fischer 344 rats aged 3, 6, 12, and 24 months, to study the mechanisms responsible for age-dependent diminution in cellular adrenergic responsiveness. Messenger RNA (mRNA) levels for the beta 1-, beta 2-, and beta 3-adrenergic receptors (ARs) were compared across age groups and related to adenylyl cyclase activation by selective receptor agonists in adipocyte plasma membranes and activation of lipolysis in intact cells. mRNA levels for the beta 1-AR decreased by 60% between 3-6 months and remained at this reduced level through 12 and 24 months. A modest increase in beta 2-AR mRNA was noted between 3-12 months, but decreased between 12-24 months to levels seen in the 3-month-old group. mRNA for the beta 3-AR did not change between 3-6 months, but decreased by about 40% between 6-12 months, and by a further 50% between 12-24 months. Lipolytic responsiveness also diminished with age, and regardless of whether beta 3-selective or beta 1/beta 2-selective agonists were used, the maximal release of glycerol was most severely blunted in adipocytes from 24-month-old rats. The age-dependent changes in adenylyl cyclase activation by beta-adrenergic agonists mirrored the observed changes in lipolytic responsiveness with respect to diminished efficacy. These results together with the similar forskolin-stimulated adenylyl cyclase activity among the groups suggest age-dependent changes in activation of adenylyl cyclase at a prior step. This suggestion is also supported by the comparable inhibitory capacities of the alpha 2-adrenergic and A1-adenosine signaling systems among the age groups. In view of the similar levels of Gs alpha, the age-dependent decrease in adrenergic responsiveness in rat adipocytes appears to result primarily from specific decreases in the expression of both beta 3-AR and beta 1-ARs.

Beta-adrenergic receptor binding in human and rat hypothalamus.

Quantitative autoradiographic analysis of beta-adrenergic binding sites was conducted in human postmortem hypothalamus using the radioligand 125I-pindolol. The focus was on the hypothalamic nuclei most clearly involved in corticotropin-releasing hormone (CRH) release, the PVN and SON. For comparison, the distribution of hypothalamic beta-adrenergic receptors was evaluated in the rat. A high level of beta-adrenergic receptor binding was found in the human paraventricular nucleus (PVN) and supraoptic nucleus (SON), but not in the rat. The majority of the beta-adrenergic receptors found in the human hypothalamus were of the beta 2-subtype. In contrast, in the rat hypothalamus, the majority of receptors were of the beta 1-subtype. These results show that the anatomical loci exist for direct beta-adrenergic influence on hypothalamic neuroendocrine function in the human and that the topography of beta-adrenergic receptors is markedly different in the rat and human hypothalamus.