Stereotaxic mapping of the monoamine pathways in the rat brain

Dopamine-sensitive adenylate cyclase in mammalian brain: a possible site of action of antipsychotic drugs

Adenylate cyclase (EC 4.6.1.1), selectively stimulated by low concentrations of dopamine, has been found in the olfactory tubercle, the nucleus accumbens, and the caudate nucleus of several mammalian species. Several different classes of drugs effective in the treatment of schizophrenia (antipsychotic drugs) were potent inhibitors of the stimulation by dopamine of the enzyme from these various regions. The drugs studied included representatives of the phenothiazine, butyrophenone, and dibenzodiazepine classes. The inhibition by these antipsychotic drugs was competitive with respect to dopamine. The most potent of the antipsychotic agents tested was fluphenazine, which had a calculated inhibition constant (K(i)) of about 5 x 10(-9) M. For each of several drugs tested, the K(i) for the enzyme from the olfactory tubercle was similar to that for the enzyme from the caudate nucleus. Several compounds closely related structurally to the psychoactive phenothiazines, but which have little or no antipsychotic or extrapyramidal actions clinically, had low relative potencies as inhibitors of dopamine-stimulated adenylate cyclase activity. The results, considered together with other data, raise the possibility that the therapeutic effects, as well as the extrapyramidal side effects, of these antipsychotic agents may be attributable, at least in part, to their ability to block the activation by dopamine of specific dopamine-sensitive adenylate cyclases in the human brain.

L-dopa and arousal

In 10 patients with Parkinsonism, treatment with L-dopa was associated with a rise in the skin conductance level and its fluctuations, an increased electromyographic activity in the frontalis muscle, and with faster reaction times. The change of skin conductance in response to a loud noise also increased and its habituation to the repetition of the stimulus was delayed. One patient developed a schizophreniform psychosis and showed high arousal and absent habituation. It is possible that dopamine is the transmitter associated with the arousal reaction and that it plays a part in the pathogenesis of schizophrenia.

Concomitant changes in formaldehyde-induced fluorescence of dopamine interneurones and in slow inhibitory post-synaptic potentials of the rabbit superior cervical ganglion, induced by stimulation of the preganglionic nerve or by a muscarinic agent

1. Dopamine was identified by formaldehyde histochemistry and cytospectrofluorometry in the rabbit's superior cervical ganglion. Dopamine was localized to the intraganglionic ;small intensely fluorescent' cells, and also to the characteristically beaded fibres forming a network in close contact with virtually all ganglion cell bodies. The extensive beaded fibres are therefore presumed to be processes of the small intensely fluorescent cells.2. Changes in the dopamine content of these interneurones were studied by recording alterations in their relative fluorescence intensity in conjunction with changes in the slow inhibitory post-synaptic potential (s.-i.p.s.p.) response of the ganglion to orthodromic nerve input.3. Dopamine content was lower after several hours in vitro even without special stimulation; this was in accord with a regularly observed spontaneous reduction of the s.-i.p.s.p. response.4. After a period of conditioning stimulation of the preganglionic nerve, in the presence of an anticholinesterase agent (eserine) and an inhibitor of catecholamine synthesis (alpha-methyl-p-tyrosine), the s.-i.p.s.p. was selectively and markedly reduced. The dopamine fluorescence in the small intensely fluorescent cell interneurones was also significantly reduced, to a mean value of about 55 or 60% of the fluorescence in the dopamine interneurones of the paired but unstimulated control ganglion. A significant reduction in dopamine fluorescence was always accompanied by a marked loss of s.-i.p.s.p. response; the reverse was not always true.5. Treatment with the muscarinic agent bethanechol for 30 min, with no alpha-methyl-p-tyrosine or eserine present, similarly resulted in reductions in the s.-i.p.s.p. response of the ganglia and in the formaldehyde-induced fluorescence of the dopamine interneurones.6. A functional uptake of extrinsic dopamine by the dopamine interneurones was also demonstrated: temporary exposure to dopamine restored a large fraction of both the s.-i.p.s.p. response and the dopamine fluorescence of the small intensely fluorescent cells, in ganglia already subjected either to the conditioning stimulation of the preganglionic nerve or to the action of bethanechol.7. It is concluded that (a) preganglionic impulses, by a cholinergic muscarinic synaptic action, can induce a release of dopamine from dopamine interneurones (small intensely fluorescent cells) in the superior cervical ganglion, (b) the ability of the ganglion to respond with a s.-i.p.s.p. to orthodromic input may be viewed as being dependent on the supply of functionally releasable dopamine in these interneurones, (c) the functionally releasable transmitter in vitro appears to comprise roughly 50% of the total dopamine content of the interneurones, and (d) the results fulfil some of the requirements of the hypothesis that a dopamine interneurone is activated muscarinically by preganglionic nerve impulses and mediates the production of s.-i.p.s.p. in sympathetic ganglion cells.