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. 1976 Dec;58(6):1307–1316. doi: 10.1172/JCI108586

The lymphocyte beta-adrenoceptor in normal subjects and patients with bronchial asthma: the effect of different forms of treatment on receptor function.

M E Conolly, J K Greenacre
PMCID: PMC333302  PMID: 186488

Abstract

beta-Adrenoceptor function has been compared in lymphocytes of normal subjects, asthmatic patients taking large doses of beta-adrenergic bronchodilators, and comparable asthmatics treated exclusively with nonadrenergic medication. The effect of prolonged administration of beta-adrenoceptor agonists on receptor function in normal subjects has also been examined. beta-receptor response in each situation was quantitated by changes in levels of cyclic AMP, measured by a protein-binding assay. Dose response curves to isoproterenol (10 nM-0.1 mM) have been constructed for each group. Maximal increase in cyclic AMP in lymphocytes from normal subjects (393.2+/-44.0%) and in asthmatics on nonadrenergic preparations (408.3+/-46.7%) was significantly greater (P less than 0.001) than in asthmatics taking large doses of beta-sympathomimetics (67.5+/-24.2%). Depression of the cyclic AMP response appeared to correlate with the degree of exposure to beta-adrenergic agonists but not with the prevailing severity of the patient's asthma. Withdrawal of beta-adrenergic drugs was followed by a reversion of the cyclic AMP response to normal values, which suggests that the depression was drug-induced rather than an inherent feature of the disease. This interpretation was confirmed by the finding that prolonged exposure of normal subjects to high doses of a beta-adrenergic agonist caused a marked and significant (p less than 0.001) reduction in the cyclic AMP response, very similar to that seen in asthmatics on large doses of adrenergic bronchodilators. A possible link between drug-induced changes in the cyclic AMP response and the rise in the United Kingdom asthma death rate in the 1960's is discussed.

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Selected References

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