Naunyn-Schmiedeberg's Archives of Pharmacology

, Volume 292, Issue 2, pp 167–176 | Cite as

Catecholamine receptor agonists

Effects on motor activity and rate of tyrosine hydroxylation in mouse brain
  • Ulf Strömbom
Article
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Summary

Motor activity during the first 5 min in a motility meter was measured in mice given 0.025–3.2 mg/kg of the dopamine and noradrenaline receptor agonists apomorphine and clonidine, respectively. The accumulation of Dopa, as induced by the inhibitor of aromatic amino acid decarboxylase, NSD 1015, was measured in parallel in two dopamine-rich regions, i.e. the limbic system and the corpus striatum, and in two noradrenaline-rich regions, i.e. the neocortex and the lower brain stem. Low doses (0.025–0.2 mg/kg) of apomorphine reduced locomotion in a dose-dependent manner, while the reduction after higher doses was less pronounced, indicating a biphasic dose-response relationship. Clonidine caused a dose-dependent locomotor depression. When low doses of the two drugs were combined, the inhibitory effect observed was at least additive. When clonidine was combined with a high dose of apomorphine (0.8 mg/kg), it caused a significant inhibition of locomotion in a dose of 0.1–0.2 mg/kg, but not after 0.8 mg/kg, indicating a biphasic dose-response relationship.

Either drug given alone reduced Dopa accumulation after inhibition of its decarboxylation, in all regions, but smaller doses of apomorphine had a clearcut effect only in the dopamine-rich regions, whereas the lowest dose of clonidine investigated (0.05 mg/kg) had an inhibitory effect on Dopa formation only in the neocortex. The relationship between the dose of apomorphine and Dopa formation in the neocortex appeared biphasic, the highest dose (3.2 mg/kg) having no significant effect. Further, apomorphine in this dose accelerated the disappearance of noradrenaline after inhibition of synthesis by α-methyltyrosine.

Reversal of reserpine-induced suppression of motor activity was taken to indicate postsynaptic receptor activation. The threshold dose of apomorphine causing reversal was 0.2 mg/kg. The inhibitory effect of e.g. 0.05 mg/kg on locomotion and on Dopa formation suggests a preferential activation of inhibitory autoregulatory dopamine receptors by low doses of this drug. A similar trend was observed for clonidine.

The basal importance of dopamine neurones for the locomotor function studied in the present paper is illustrated by the marked inhibition by low doses of apomorphine. On the other hand, the observations with clonidine suggest a somewhat less striking and perhaps less direct influence of noradrenaline neurones on motor activity.

Mice with a low motor activity, as induced e.g. by reserpine or, in another experiment, mice adapted to the motility meter, displayed an increased motor activity after higher doses of apomorphine (from 0.2 and 2 mg/kg, respectively), whereas all doses depressed the initial high motor activity. Probably, high motor activity requires active dopamine neurones, making this behaviour more susceptible to interference with autoregulatory mechanisms, whereas a low basal activity may be more affected by activation of postsynaptic dopamine receptors.

Key words

Catecholamine receptor agonists Autoreceptors Locomotor inhibition Synthesis inhibition 
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References

  1. Aghajanian, G. K., Bunney, B. S.: Central dopaminergic neurons: Neurophysiological identification and responses to drugs. In: Frontiers in catecholamine research. S. H. Snyder and E. Usdin, eds. New York: Pergamon Press 1973Google Scholar
  2. Aghajanian, G. K., Bunney, B. S.: Pre- and postsynaptic feedback mechanisms in central dopaminergic neurons. In: Frontiers in neurology and neuroscience research. P. Seeman and G. M. Brown, eds., chapter 2. Toronto: The University Press 1974Google Scholar
  3. Andén, N.-E., Corrodi, H., Fuxe, K., Hökfelt, B., Hökfelt, T., Rydin, C., Svensson, T.: Evidence for a central noradrenaline receptor stimulation by clonidine. Life Sci. 9, 513–523 (1970)Google Scholar
  4. Andén, N.-E., Roos, B.-E., Werdinius, B.: Effects of chlorpromazine, haloperidol and reserpine on the levels of phenolic acids in rabbit corpus striatum. Life Sci. 3, 149–158 (1964)Google Scholar
  5. Andén, N.-E., Rubenson, A., Fuxe, K., Hökfelt, T.: Evidence for dopamine receptor stimulation by apomorphine. J. Pharm. Pharmacol. 19, 627–629 (1967)Google Scholar
  6. Andén, N.-E., Strömbom, U.: Adrenergic receptor blocking agents: effects on central noradrenaline and dopamine receptors and on motor activity. Psychopharmacologia (Berl.) 38, 91–103 (1974)Google Scholar
  7. Andén, N.-E., Strömbom, U., Svensson, T. H.: Dopamine and noradrenaline receptor stimulation: reversal of reserpine-induced suppression of motor activity. Psychopharmacologia (Berl.) 29, 289–298 (1973)Google Scholar
  8. Atack, C. V.: The determination of dopamine by a modification of the dihydroxyindole fluorimetric assay. Brit. J. Pharmacol. 48, 699–714 (1973)Google Scholar
  9. Atack, C. V., Magnusson, T.: Individual elution of noradrenaline (together with adrenaline), dopamine, 5-hydroxytryptamine and histamine from a single strong cation exchange column, by means of mineral acid-organic solvent mixtures. J. Pharm. Pharmacol. 22, 625–627 (1970)Google Scholar
  10. Bertler, Å, Carlsson, A., Rosengren, E.: A method for the fluorimetric determination of adrenaline and noradrenaline in tissues. Acta physiol. scand. 44, 273–292 (1958)Google Scholar
  11. Breastrup, C.: Effects of phenoxybenzamine, acaperone and clonidine on the level of 3-methoxy-4-hydroxyphenylglycol (MOPEG) in rat brain. J. Pharm. Pharmacol. 26, 139–141 (1974)Google Scholar
  12. Bunney, B. S., Aghajanian, G. K., Roth, R. H.: Comparison of effects of L-DOPA, amphetamine and apomorphine on firing rate of rat dopaminergic neurons. Nature New Biol. 245, 123–125 (1973)Google Scholar
  13. Carlsson, A.: Drugs which block the storage of 5-hydroxytryptamine and related amines. In: Handbook of experimental pharmacology. O. Eichler, A. Farah, and V. Erspamer, eds., pp. 529–592, vol. 19. Berlin-Heidelberg-New York: Springer 1966Google Scholar
  14. Carlsson, A.: Receptor-mediated control of dopamine metabolism. Paper read at Workshop on “Pre- and Postsynaptic Receptors”, Annual ACNP Meeting, Puerto Rico (1974). In: Pre- and postsynaptic receptors. E. Usdin and W. E. Bunney, Jr., eds. New York: Marcel Dekker 1975Google Scholar
  15. Carlsson, A., Davis, J. N., Kehr, W., Lindqvist, M., Atack, C.: Stimultaneous measurment of tyrosine and tryptophan hydroxylase activities in brain in vivo using an inhibitor of the aromatic amino acid decarboxylase. Naunyn-Schmiedeberg's Arch. Pharmacol. 275, 153–168 (1972)Google Scholar
  16. Carlsson, A., Kehr, W., Lindqvist, M.: Agonist-antagonist interaction on dopamine receptors in brain, as reflected in the rates of tyrosine and tryptophan hydroxylation. Submitted for publication. In: Proceedings of the V. international Parkinson symposium, Wien, September 1975Google Scholar
  17. Carlsson, A., Lindqvist, M.: Effect of chlorpromazine or haloperidol on formation of 3-methoxytyramine and normetanephrine in mouse brain. Acta pharmacol. (Kbh.) 20, 140–144 (1963)Google Scholar
  18. Carlsson, A., Lindqvist, M.: Effect of ethanol on the hydroxylation of tyrosine and tryptophan in rat brain in vivo. J. Pharm. Pharmacol. 25, 437–440 (1973)Google Scholar
  19. Engström, G., Svensson, T. H., Waldeck, B.: Tyrosine and brain catecholamines: increased transmitter synthesis and increased receptor sensitivity. Brain Res. 77, 471–483 (1974)Google Scholar
  20. Ernst, A. M.: Mode of action of apomorphine and dexamphetamine on gnawing compulsion in rats. Psychopharmacologia (Berl.) 10, 316–323 (1967)Google Scholar
  21. Farnebo, L.-O., Hamberger, B.: Drug-induced changes in the release of 3H-monoamines from field stimulated rat brain slices. Acta physiol. scand., Suppl. 371, 35–44 (1971)Google Scholar
  22. Graeff, F. G., Oliveira, L. de: Influence on response topography on the effect of apomorphine and amphetamine on operant behaviour of pigeons. Psychopharmacologia (Berl.) 41, 127–132 (1975)Google Scholar
  23. Hornykiewicz, O.: Dopamine (3-hydroxytyramine) and brain function. Pharmacol. Rev. 18, 925–964 (1966)Google Scholar
  24. Kehr, W., Carlsson, A., Lindqvist, M.: A method for the determination of 3,4-dihydroxyphenylalanine (DOPA) in brain. Naunyn-Schmiedeberg's Arch. Pharmacol. 274, 273–280 (1972a)Google Scholar
  25. Kehr, W., Carlsson, A., Lindqvist, M., Magnusson, T., Atack, C.: Evidence for a receptor-mediated feedback control of striatal tyrosine hydroxylase activity. J. Pharm. Pharmacol. 24, 744–747 (1972b)Google Scholar
  26. Kelleher, R. T., Morse, W. H.: Determinants of the specificity of behavioural effects of drugs. Ergebn. Physiol. 60, 1–56 (1968)Google Scholar
  27. Maj, J., Sowinska, H., Baran, L., Kapturkiewicz, Z.: The effect of clonidine on locomotor activity in mice. Life Sci. 11, 483–401 (1972)Google Scholar
  28. Persson, T., Waldeck, B.: Further studies on the possible interaction between dopamine and noradrenaline containing neurons in the brain. Europ. J. Pharmacol. 11, 315–320 (1970)Google Scholar
  29. Puech, A.-J., Simon, P., Chermat, R., Boissier, J.-R.: Profil neuropsychopharmacologique de l'apomorphine. J. Pharmacol. (Paris) 2, 241–254 (1974)Google Scholar
  30. van Rossum, J. M.: Mode of action of psychomotor stimulant drugs. Int. Rev. Neurobiol. 12, 307–383 (1970)Google Scholar
  31. Svensson, T. H., Bunney, B. S., Aghajanian, G. K.: Inhibition of both noradrenergic and serotonergic neurons in brain by the α-adrenergic agonist clonidine. Brain Res. 92, 291–306 (1975)Google Scholar
  32. Thornburg, J. E., Moore, K. E.: A comparison of effects of apomorphine and ET 495 on locomotor activity and circling behaviour in mice. Neuropharmacology 13, 189–197 (1974)Google Scholar
  33. Walkes, T. P., Udenfriend, S.: A fluorimetric method for the estimation of tyrosine in plasma and tissues. J. Lab. clin. Med. 50, 733–736 (1957)Google Scholar
  34. Winer, B. J.: Statistical principles in experimental design: pxq factorial experiment-unequal cell frequencies, pp. 241–244. New York: McGraw-Hill Inc. 1970Google Scholar

Copyright information

© Springer-Verlag 1976

Authors and Affiliations

  • Ulf Strömbom
    • 1
  1. 1.Department of PharmacologyUniversity of GöteborgGöteborg 33Sweden

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