Abstract
Intra-accumbens d-amphetamine enhances responding for reward-related stimuli (conditioned reinforcers, CRs), whereas intra-caudate d-amphetamine has only weak and variable effects (Taylor and Robbins 1984). The present experiment further examined the involvement of the nucleus accumbens and the role of dopamine (DA) in this effect. Thirsty rats were trained to associate a flash of a light and movement of a dipper (CR) with water. After implantation of permanent guide cannulae aimed at the nucleus accumbens, they were assigned to one of four groups, receiving either bilateral 6-OHDA (4 mg/ml free base in 2 μ1 0.1% ascorbic acid/0.9% saline) or sham (vehicle) infusions into the nucleus accumbens or the caudate nucleus. In the test phase, two novel levers were available. Responding on one lever (CR lever) produced the light and dipper stimuli without water presentation, whereas responding on the other (NCR lever) had no effect. All four groups received four counterbalanced intra-accumbens infusions of d-amphetamine (3, 10, 20 μg/2 μl) or vehicle. On the 5th test day, subjects were pretreated subcutaneously with apomorphine (0.1 mg/kg). Intra-accumbens d-amphetamine in both sham-lesioned groups produced a dose-dependent increase in responding on the CR lever, but no significant change on the NCR lever. No selective increases in responding on either lever were found in animals with 6-OHDA-induced depletion of DA (>80%) in the nucleus accumbens following intra-accumbens d-amphetamine; however, in subjects with DA depletion of the posterior caudate nucleus (>80%), increases in responding on the CR lever were observed to be similar in magnitude to those of both the sham-lesioned groups. Following systemic administration of apomorphine, only rats in the nucleus-accumbens-lesioned group continued to respond, preferring the CR lever, thus suggesting the involvement of DA receptors in these effects. These results indicate that enhanced responding for CR following administration of psychomotor stimulant drugs is critically dependent on dopaminergic activation of the nucleus accumbens, rather than the caudate nucleus.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Andén N, Rubenson A, Fuxe K, Hökfelt T (1967) Evidence for dopamine receptor stimulation by apomorphine. J Pharm Pharmacol 19:627–629
Beninger, RJ, Hanson DR, Phillips AG (1980) The effects of pipradrol on the acquisition of responding with conditioned reinforcement: A role for sensory preconditioning. Psychopharmacology 69: 235–242
Brownstein M, Saavedra JM, Palkovitis M (1974) Norepinephrine and dopamine in the limbic system of the rat. Brain Res 79:431–436
Carr G, White N (1983) Conditioned place preference from intra-accumbens but not intra-caudate amphetamine injections. Life Sci 33:2551–2557
Cools AS (1985) Mesolimbic dopamine and its control of locomotor activity in rats: differences in pharmacology and light/dark periodicity between the olfactory tubercle and nucleus accumbens. Psychopharmacology (in press)
Fink JS, Smith GP (1980) Relationships between selective denervation of dopamine terminal fields in the anterior forebrain and behavioural responses to amphetamine and apomorphine. Brain Res 201:107–127
Fonnum F, Waalas I (1979) Localization of neurotransmitters in the neostriatum. In: Divac I, Oberg RGE (eds) The Neostriatum. Pergamon, Oxford
Fonnum F, Waalas I (1981) Localization of neurotransmitters in the nucleus accumbens. In: Chronister RB, De France JF (eds) The neurobiology of the nucleus accumbens. Haer Institute for Electrophysiological Research, pp 259–272
Hill RT (1967) A behavioral analysis of the psychomotor stimulant effects of a drug: The interaction of pipradrol with conditioned reinforcement. Ph.D. dissertation, Columbia University, New York, USA
Hoebel BG, Monaco AP, Hernandez L, Aulisi EF, Stanley BG, Lenard L (1983) Self-injection of amphetamine directly into the brain. Psychopharmacology 81:158–163
Hörtnagel H, Schlögl H, Sperk G, Hornykiewicz O (1983) The topographical distribution of the monoaminergic innervation in the basal ganglia of the human brain. Prog Brain Res 58:269–274
Kelly PH, Roberts DCS (1983) Effects of amphetamine and apomorphine on locomotor activity after 6-OHDA and electrolytic lesions of the nucleus accumbens septi. Pharmacol Biochem Behav 19:137–143
Kelly PH, Seviour PW, Iversen SD (1975) Amphetamine and apomorphine responses in the rat following 6-OHDA lesions of the nucleus accumbens septi and corpus striatum. Brain Res 94:507–522
Koob GF, Riley SJ, Smith SC, Robbins TW (1978) Effects of 6-hydroxydopamine lesions of the nucleus accumbens septi and olfactory tubercle on feeding, locomotor activity and amphetamine anorexia in the rat. J Comp Physiol Psychol 92:917–927
Kuczenski R (1983) Biochemical actions of amphetamine and other stimulants. In: Creese I (ed) Stimulants: neurochemical, behavioural and clinical perspectives. Raven, New York, pp. 31–61
Lenard L, Hernandez L, Hoebel BG (1980) Self-injection of amphetamine directly into the nucleus accumbens. Proceedings of the International Union of Physiological Science 14:2217
Lyness WH, Friedle NM, Moore KE (1979) Destruction of dopaminergic nerve terminals in nucleus accumbens: effects on d-amphetamine self-stimulation. Pharmacol Biochem Behav 11:553–556
Mackintosh NJ (1974) The psychology of animal learning. Academic Press, London
Mefford IN (1981) Application of high performance liquid chromatography with electrochemical detection to neurochemical analysis: Measurement of catecholamines, serotonin and metabolites in rat brain. J Neurosci Meth 3(3):202–224
Montanaro N, Vaccheri A, Dall'Olio R, Gandolfi O (1983) Time course of rat motility response to apomorphine: A simple model for studying preferential blockade of brain dopamine receptors mediating sedation. Psychopharmacology 81:214–219
Nauta WJH, Domesick VB (1984) Afferent and efferent relationships of the basal ganglia. In: Evered D, O'Connor M (eds) Functions of the basal ganglia. Ciba Foundation Symposium 107. Pitman, London, pp. 3–23
Pettit HO, Ettenberg A, Bloom FE, Koob GF (1984) Destruction of dopamine in the nucleus accumbens attenuates cocaine but not heroin self-administration in rat. Psychopharmacology 84:167–173
Pellegrino LJ, Cushman AJ (1967) A stereotaxic atlas of the rat brain. Century Crofts, New York
Robbins TW (1978) The acquisition of responding with conditioned reinforcement: Effects of pipradrol, methylphenidate, d-amphetamine and nomifensine. Psychopharmacology 58:78–87
Robbins TW, Everitt BJ (1982) Functional studies of the central catecholamines. Int Rev Neurobiol 23:303–365
Robbins TW, Watson BA, Gaskin M, Ennis C (1983a) Contrasting interactions of pipradrol, d-amphetamine, cocaine, cocaine analogues, apomorphine and other drugs with conditioned reinforcement. Psychopharmacology 80:113–119
Robbins TW, Roberts DCS, Koob GF (1983b) Effects of d-amphetamine and apomorphine upon operant behaviour and schedule-induced licking in rats with 6-hydroxydopamine-induced lesions of the nucleus accumbens. J Pharmacol Exp Ther 222:662–673
Roberts DCS, Corcoran ME, Fibiger HC (1977) On the role of the ascending catecholaminergic systems in intravenous self-administration of cocaine. Pharmacol Biochem Behav 6:615–620
Roberts DCS, Koob GF, Klonoff P, Fibiger HC (1980) Extinction and recovery of cocaine self-administration following 6-OHDA lesions of the nucleus accumbens. Physiol Biochem Behav 12:781–787
Sabol KE, Neill DB, Wages SA, Church WH, Justice JB (1985) Dopamine depletion in a striatal subregion disrupts performance of a skilled motor task in the rat. Brain Res 335:33–43
Spyraki C, Fibiger HC, Phillips AG (1982) Dopaminergic substrates of amphetamine-induced place-preference conditioning. Brain Res 253:185–193
Swerdlow NR, Koob GF (1984) Restrained rats learn amphetamine-conditioned locomotion, but not place preference. Psychopharmacology 84:163–166
Taylor JR (1985) Neural mechanisms of the potentiation of conditioned reinforcement by psychomotor stimulant drugs. Unpublished Ph.D. dissertation, University of Cambridge, England
Taylor JR, Robbins TW (1984) Enhanced behavioural control by conditioned reinforcers following microinjections of d-amphetamine into the nucleus accumbens. Psychopharmacology 84:405–412
Ungerstedt U (1971) Post-synaptic supersensitivity after 6-hydroxydopamine-induced degeneration of the nigrostriatal dopamine system. Acta Physiol Scand Suppl 367:69–93
Winer BJ (1971) Statistical principles in experimental design. Tokyo, McGraw-Hill, Kogakusha
Winn P, Robbins TW (1985) Comparative effects of infusions of 6-hydroxydopamine into nucleus accumbens and anterolateral hypothalamus on the response to dopamine agonists, body weight, locomotor activity and measures of exploration in the rat. Neuropharmacology 24(1):25–31
Wise RA (1981) Brain dopamine and reward. In: Cooper SJ (ed) Theory and psychopharmacology Vol. 1. Academic Press, London pp. 102–122
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Taylor, J.R., Robbins, T.W. 6-Hydroxydopamine lesions of the nucleus accumbens, but not of the caudate nucleus, attenuate enhanced responding with reward-related stimuli produced by intra-accumbens d-amphetamine. Psychopharmacology 90, 390–397 (1986). https://doi.org/10.1007/BF00179197
Received:
Revised:
Issue Date:
DOI: https://doi.org/10.1007/BF00179197