Evidence for two specific affinity states of 3H-antagonist binding to cardiac beta-adrenergic receptors and influence of Gpp(NH)p.

P H Lang, B Lemmer
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Abstract

Binding of the lipophilic antagonist ligand 3H-DHA and the hydrophilic antagonist ligand 3H-CGP 12177 to beta-adrenergic receptors of rat heart ventricular membranes was studied. Quantitative analysis of the binding data indicated the existence of two specific affinity states of the beta-adrenergic receptor population aside from a third non-specific binding site for 3H-DHA. In order to exclude that the biphasic saturation isotherm may be due to retained endogenous agonist, crude membranes as well as modified membranes were used. In the latter a 99% reduction of noradrenaline concentration was obtained by washing and preincubation or by catecholamine depletion. Two affinity states of antagonist binding could be demonstrated independently from the kind of membrane suspension. A biphasic dissociation of 3H-DHA by unlabelled (-)-alprenolol was also found in kinetic studies. In crude or washed membranes of untreated rats the guanine nucleotide Gpp(NH)p affected saturation and antagonist competition curves. However, this was not observed in catecholamine-depleted membranes of reserpine-treated rats. Stereoselectivity of the high and the low affinity state was demonstrated in competition experiments with (-) - and (+) -alprenolol in catecholamine-depleted membranes. The data are best explained by assuming a ternary complex model (1) in which antagonists, instead of passively occupying binding sites, play an active role in receptor mechanisms. Based on this model, it is assumed that beta-adrenergic antagonists bind with high affinity to the free form of the receptor and with low affinity to the precoupled form. Furthermore, an interaction of Gpp(NH)p with the regulatory component is proposed.

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3h -拮抗剂与心脏β -肾上腺素能受体结合的两种特定亲和力状态及其对Gpp(NH)p的影响的证据。
研究了亲脂拮抗剂配体3H-DHA和亲水拮抗剂配体3H-CGP 12177与大鼠心室膜β -肾上腺素能受体的结合。结合数据的定量分析表明,除了3H-DHA的第三个非特异性结合位点外,β -肾上腺素能受体群体存在两种特异性亲和力状态。为了排除两相饱和等温线可能是由于内源性激动剂残留造成的,我们采用了粗膜和改性膜。在后者中,通过洗涤和预孵育或儿茶酚胺消耗,去甲肾上腺素浓度降低99%。拮抗剂结合的两种亲和状态可以独立于膜悬浮液的种类而被证明。在动力学研究中也发现了3H-DHA被未标记的(-)-阿普萘洛尔双相解离。在未经处理的大鼠粗膜或水洗膜中,鸟嘌呤核苷酸Gpp(NH)p影响饱和和拮抗剂竞争曲线。然而,在利血平处理的大鼠的儿茶酚胺耗尽膜中没有观察到这一点。(-) -和(+)-阿普萘洛尔在儿茶酚胺耗竭膜中具有高和低亲和态的立体选择性。这些数据最好通过假设三元复合物模型(1)来解释,在该模型中,拮抗剂不是被动地占据结合位点,而是在受体机制中发挥积极作用。基于这个模型,我们假设β -肾上腺素能拮抗剂与自由形式的受体结合具有高亲和力,而与预偶联形式结合的亲和力较低。此外,还提出了Gpp(NH)p与调控组分的相互作用。
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