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Notizen: Summary Dopamine receptors subtypes were studied in homogenates from rat brain areas, mainly the corpus striatum, using the two highly selective ligands 3H-apomorphine and 3H-domperidone. The clearly biphasic inhibition of the specific binding of these two ligands by some agents allowed us to define four distinct classes of binding site. 3H-apomorphine labels two classes of site displaying a large difference in affinity for domperidone, i.e. class I sites well recognized (IC50=5 nM) and class II sites poorly recognized (IC50=10 μM). 3H-domperidone also labels two distinet classes of site displaying a large difference in affinity for apomorphine and dopamine, i.e. class III sites well recognized by these agents (IC50=5 and 35 nM, respectively) and class IV sites poorly recognized (IC50=790 nM and 14 μM, respectively). The two classes I and III represent a single pharmacological class of dopaminergic receptors (labelled by either 3H-apomorphine or 3H-domperidone) as indicated by 1) their almost identical pharmacological specificities (high correlation between K d or K i values for a variety of dopaminergic agonists and antagonists); 2) their similar capacity in striatum as well as in other brain regions; 3) the identical decrease in capacity following kainate lesions; 4) their similar sensitivity to GTP and thermal denaturation. Because the pharmacological specificity of these sites excludes the possibility that they represent the recognition sites of the dopamine-sensitive adenylate cyclase, i.e. D-1 receptors, we propose to term them D-2 receptors. Class II and IV sites also differ from D-1 receptors as shown by drug specificity and the effect of kainate. We propose to term class II sites D-3 receptors and class IV sites D-4 receptors. D-2 receptors are characterised by a high affinity for both dopamine receptor agonists and antagonists (K i and K d values in the nM range). They are localised post-synaptically to dopaminergic terminals in the striatum as indicated by 1) their decreased number (−60%) following kainate lesions of intrinsic neurones, and 2) their increased number (+40%) after 6-OHDA-induced degeneration of dopaminergic neurones. The capacity of D-2 receptors is decreased by 80% in the presence of 25 μM GTP. The binding of ligands to D-2 receptors preicubated at 45°C decreases with a half-life of 10 min. D-2 receptors may mediate behavioral actions of apomorphine in low dosage which are easily antagonised by neuroleptics. D-3 receptors appear to be, at least in part, autoreceptors: their number decreases in striatum after 6-OHDA lesions (−30%) and is not modified following kainate lesions. They are characterised by a high affinity (K i in the nM range) for dopaminergic agonists (except for bromocriptine) contrasting with a rather low affinity for antagonists. The pharmacologically homogeneous class of D-3 receptor appears heterogeneous regarding both localisation and regulation by GTP. D-4 receptors are partly localised on intrastriatal neurones (−17% after kainate lesions, +17% following 6-OHDA lesions). However, the small change after kainate-induced lesions suggests that a significant fraction of D-4 receptors is localised on terminals from extrinsic neurones. D-4 receptors are characterised by a high affinity for dopamine receptor antagonists (K i in the nM range) contrasting with a relatively low affinity for agonists. The number of D-4 receptors increases after either GTP or heat denaturation, a change which probably corresponds to the decrease in D-2 receptors. D-4 receptors may mediate typical behavioral actions of apomorphine in moderate dosage.

Notizen: A type of tandem mass spectrometric scan is described in which m1 +, m2 + and m3, defined in terms of the process m1 + → m2 + + m3, are all varied while maintaining some prescribed relationship between them. The scan can be viewed as a variant upon the neutral loss scan in which the constant mass difference between parent and daughter ion masses is replaced by some other functional relationship. Specific examples of this scan are provided in two simple applications: (i) symmetrical proton-bound dimers are recognized using the functional scan m2 = (m1 + 1)/2; and (ii) symmetrical Diels-Alder adducts comprised of diene and dienophile of equal masses are recognized in mixtures using the scan function m2 = (1/2)m1.