Summary
In the present study we examined the effects of intracerebroventricular (i.c.v.) injections of prolactin (PRL) on the presynaptic activity and postsynaptic sensitivity of mesolimbic and nigrostriatal dopaminergic neurons. In addition, the effects of PRL onin vitro release of dopamine (DA) from perifused striatal fragments were examined. Tyrosine hydroxylase (TH) activity and D2 receptor density in the striatum decreased after i.c.v. PRL administration; this was accompanied by an increase in D2 receptor affinity. These effects occurred after i.c.v. administration of PRL to normoprolactinemic rats, although normally they did not appear after administration to animals with pituitary grafting-induced hyperprolactinemia. Thus, in these animals, i.c.v. PRL failed to decrease TH activity and D1 and D2 receptor densities to a significant extent. In the case of D2 receptors, this was probably due to the fact that pituitary grafting-induced hyperprolactinemia itself was able to reduce the density of this receptor. No changes were observed in DA or L-3, 4-dihydroxyphenylacetic acid (DO-PAC) contents after i.c.v. administration of PRL to both normo- and hyperprolactinemic animals. Basal and K+-evoked DA releasein vitro from perifused striatal fragments of normoprolactinemic rats were not affected by the addition of PRL, whereas this hormone enhanced K+-evoked DA release when added to perifused striatal fragments from hyperprolactinemic animals. In the limbic forebrain, i.c.v. administration of PRL to normoprolactinemic animals produced a decrease in DA and DOPAC contents and D1 receptor density. Interestingly, none of these effects appeared when PRL was injected to hyperprolactinemic animals. In summary, our results suggest a possible inhibitory role of PRL on the activity of both the nigrostriatal and mesolimbic dopaminergic neuronal systems. These inhibitory effects were reflected in the decreases elicited in a set of neurochemical parameters, indicating either presynaptic activity or postsynaptic sensitivity, after i.c.v.-administered PRL. This observation supports the hypothesis of a possible neuromodulatory role for an extrapituitary PRL on the activity of these neurons, although the fact that most of these effects did not appear when i.c.v. administration was performed in hyperprolactinemic rats also suggests that they are influenced by peripheral PRL levels.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adler RA (1986) The anterior pituitary-grafted rat: a valid model of chronic hyperprolactinemia. Endocr Rev 7: 302–313
Anton AH, Sayre DF (1962) A study of the factors affecting the aluminum oxide-trihydroxyindole procedure for the analysis of catecholamines. J Pharmacol Exp Ther 138: 360–374
Azad N, Duffner L, Paloyan EB, Reda D, Kirsteins L, Emanuele NV, Lawrence AM (1990) Hypothalamic prolactin stimulates the release of luteinizing hormone-releasing hormone from male rat hypothalamus. Endocrinology 127: 1928–1933
Barbanel G, Ixart G, Arancibia S, Assenmacher I (1986) Probable extrapituitary source of the immunoreactive prolactin measured in the cerebrospinal fluid of unanesthetized rats by push-pull cannulation of the 3rd ventricle. Neuroendocrinology 43: 476–482
Bedard P, Boucher R, DiPaolo T, Labrie F (1984) Interaction between estradiol, prolactin and striatal dopaminergic mechanisms. In: Hassler RG, Christ JF (eds) Advances in neurology, vol 40. Raven Press, New York, pp 489–495
Bridges RS, Numan M, Ronsheim PM, Mann PE, Lupini CE (1990) Central prolactin infusions stimulate maternal behavior in steroid-treated, nulliparous female rats. Proc Natl Acad Sci USA 87: 8003–8007
Cebeira M, Hernández ML, Rodríguez de Fonseca F, de Miguel R, Fernández-Ruiz JJ, Ramos JA (1991) Lack of effect of prolactin on the dopaminergic receptor sensitivity in striatal and limbic areas after experimentally-induced alterations in its peripheral levels. Life Sci 48: 531–541
Chen YF, Ramírez VD (1982) Prolactin stimulates dopamine release from male but not from female rat striatal tissue superfusedin vitro. Endocrinology 111: 1740–1744
Chen JC, Ramírez VD (1985) Prolactin effect onin vivo striatal dopaminergic activity as estimated with push-pull perfusion in male rats. In: MacLeod RM, Thorner MO, Scapagnini U (eds) Prolactin: basic and clinical correlates. Liviana Press, Padova, pp 523–538
Chen JC, Ramírez VD (1988 a) Comparison of the effect of prolactin on dopamine release from the rat dorsal and ventral striatum and from the mediobasal hypothalamus superfusedin vitro. Eur J Pharmacol 149: 1–8
Chen JC, Ramírez VD (1988 b)In vivo dopaminergic activity from nucleus accumbens, substantia nigra and ventral tegmental area in the freely moving rat: basal neurochemical output and prolactin effect. Neuroendocrinology 48: 329–335
DeVito WJ, Connor JM, Hedge GA (1987) Immunoreactive prolactin in the rat hypothalamus:in vitro release and subcellular localization. Neuroendocrinology 46: 155–161
DeVito WJ (1988) Distribution of immunoreactive prolactin in the male and female rat brain: effects of hypophysectomy and intraventricular administration of colchicine. Neuroendocrinology 47: 284–289
Diamond BI, Gordon JH (1981) Hypophysectomy induces striatal dopamine hypersensitivity in male rats: antagonism by prolactin, exacerbation by chronic haloperidol. Annual Meeting of the Society of Neuroscience (USA), p 780 (Abstract)
DiCarlo D, Muccioli G, Lando D, Bellusi G (1985) Further evidence for the presence of specific binding sites for prolactin in the rabbit brain. Preferential distribution in the hypothalamus and substantia nigra. Life Sci 36: 375–382
DiPaolo T, Poyet P, Labrie F (1982) Effect of prolactin and estradiol on rat striatal dopamine receptors. Life Sci 31: 2921–2929
Doherty PC, Lane SJ, Pfeil KA, Morgan WW, Bartke A, Smith MS (1989) Extrahypothalamic dopamine is not involved in the effects of hyperprolactinemia on male copulatory behavior. Physiol Behav 45: 1101–1105
Drago F, Kovacs GL, Continella G, Scapagnini U (1984) Dopamine in the nucleus accumbens: its role in prolactin-enhanced grooming behavior of the rat. Biog Amin 1: 53–59
Drago F, Continella G, Scapagnini U (1985) Behavioral and neurochemical changes in long-term hyperprolactinemia. In: Kemali D, Racagni G (eds) Chronic treatments in neuropsychiatry. Raven Press, New York, pp 47–58
Emanuele NV, Metcalfe L, Lubrano T, Rubinstein H, Kirsteins L, Lawrence AM (1987) Subcellular distribution of hypothalamic prolactin-like immunoreactivity. Brain Res 407: 223–229
Fernández-Ruiz JJ, Ubeda E, Cebeira M, Agrasal C, Tresguerres JAF, Ramos JA, Esquifino AI (1987 a) Modifications of plasma prolactin levels and catecholamine content in an ectopic anterior pituitary gland transplanted under the kidney capsule. Horm Res 25: 105–112
Fernández-Ruiz JJ, Esquifino AI, Steger RW, Amador AG, Bartke A (1987 b) Presence of tyrosine hydroxylase activity in anterior pituitary adenomas and ectopic anterior pituitaries in male rats. Brain Res 421: 65–68
Fernández-Ruiz JJ, Pais JR, Cebeira M, Ramos JA (1988) Decreased dopamine turnover in striatum of female rats bearing ectopic pituitaries or with bilateral ovariectomy. Biog Amin 5: 115–123
Fernández-Ruiz JJ, Alvarez-Sanz C, Ramos JA (1989 a) 2-Hydroxyestradiol is not mediating the effects of estradiol on tuberoinfundibular dopaminergic neurons controlling prolactin release in female rats. J Steroid Biochem 32: 71–75
Fernández-Ruiz JJ, Amor JC, Ramos JA (1989 b) Time-dependent effects of estradiol and progesterone on the number of striatal dopaminergic D2 receptors. Brain Res 476: 388–395
Fernández-Ruiz JJ, Cebeira M, Agrasal C, Tresguerres JAF, Esquifino AI, Ramos JA (1990) Presence and physiological role of biogenic amines in the regulation of prolactin release from ectopic anterior pituitaries. In: Gupta D, Wollmann HA, Ranke MB (eds) Neuroendocrinology: new frontiers. Brain Research Promotion, Tubingen, pp 49–59
Freeman AS, Chiodo LA (1987) Dopamine-cholecystokinin interactions in the central nervous system. In: Chiodo LA, Freeman AS (eds) Neurophysiology of dopamine systems-current status and clinical perspectives. Lakeshore Publishing Co, Grosse Pointe, pp 205–236
Gispen WH, Wiegant VM, Greven HM, de Wied D (1975) The induction of excessive grooming in the rat by intraventricular application of peptides from ACTH: structure-activity. Life Sci 17: 645–652
Glowinski J, Iversen LL (1966) Catecholamine regional metabolism in rat brain. J Neurochem 13: 655–669
González-Mora JL, Guadalupe T, Mas M (1990)In vivo voltametry study of the modulatory action of prolactin on the mesolimbic dopaminergic system. Brain Res Bull 25: 729–733
Hansen BL, Hansen GN, Hagen C (1982) Immunoreactive material resembling ovine prolactin in perikarya and nerve terminals of the rat hypothalamus. Cell Tissue Res 226: 121–131
Harlan RE, Shivers BD, Plaff DW (1983) Midbrain microinfusions of prolactin increase the estrogen-dependent behavior, lordosis. Science 219: 1451–1453
Harlan RE, Shivers BD, Fox SR, Kaplove KA, Schachter BS, Plaff DW (1989) Distribution and partial characterization of immunoreactive-prolactin in the rat brain. Neuroendocrinology 49: 7–22
Hruska RE, Pitman KT, Silbergeld EK, Ludmer LM (1982) Prolactin increases the density of striatal dopamine receptors in normal and hypophysectomized male rats. Life Sci 30: 547–553
Hruska RE (1986) Elevation of striatal dopamine receptors by estrogen: dose and time studies. J Neurochem 47: 1908–1915
Jiménez I, Iglesias T, Fuentes JA (1990) Stereoselectivity and subtype of the opiate receptor involved in stress-induced hypertension. Eur J Pharmacol 182: 155–160
Lambert AE, Henquin JC, Malvaux P (1974) Cationic environment and dynamics of insulin secretion. I. Effects of low concentrations of sodium. Endocrinology 95: 1069–1077
Laping NJ, Ramírez VD (1986) Prolactin induces yawning and the stretch-yawning syndrome in young adult male rats. Horm Behav 20: 49–59
Laping NJ, Ramírez VD (1988) Prolactin-induced yawning behavior requires an intact nigro-striatal dopamine system. Pharmacol Biochem Behav 29: 59–62
Leysen JE, Gommeren W, Laduron PM (1978) Spiperone: a ligand of choice for neuroleptic receptors. I. Kinetics and characteristics ofin vitro binding. Biochem Pharmacol 27: 307–311
Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1958) Protein measurement with the folin phenol reagent. J Biol Chem 193: 265–275
de Miguel R, Tamagawa T, Schmeer W, Nenquin M, Henquin JC (1988) Effects of acute sodium omission on insulin release, ionic fluxes and membrane potential in mouse pancreatic B-cells. Biochem Biophys Acta 969: 198–207
Muccioli G, Ghè C, DiCarlo R (1991) Distribution and characterization of prolactin binding sites in the male and female rat brain: effects of hypophysectomy and ovariectomy. Neuroendocrinology 53: 47–53
Nagatsu T, Oka K, Kato T (1979) Highly sensitive assay for tyrosine hydroxylase activity by high performance liquid chromatography. J Chromat 163: 247–252
Nemeroff CB (1986) The interaction of neurotensin with dopaminergic pathways in the central nervous system: basic neurobiology and implications for the pathogenesis and treatment of schizophrenia. Psychoneuroendocrinology 11: 15–37
Perkins NH, Westfall TC (1978) The effect of prolactin on dopamine release from rat striatum and medial basal hypothalamus. Neuroscience 3: 59–63
Reader T, Briere R, Gottberg E, Diop L, Grondin L (1988) Specific [3H]SCH23390 binding to dopamine D1 receptors in central cortex and neostriatum: evidence for heterogeneities in affinity states and cortical distribution. J Neurochem 50: 451–463
Rodriguez de Fonseca F, Cebeira M, Hernandez ML, Ramos JA, Fernández-Ruiz JJ (1990) Changes in brain dopaminergic indices induced by perinatal exposure to cannabinoids in rats. Dev Brain Res 51: 237–240
Schachter BS, Durgerian S, Harlan RE, Plaff DW, Shivers BD (1984) Prolactin mRNA exists in rat hypothalamus. Endocrinology 114: 1947–1949
Siaud P, Manzoni O, Balmefrezol M, Barbanel G, Assenmacher I, Alonso G (1989) The organization of prolactin-like-immunoreactive neurons in the rat central nervous system. Cell Tissue Res 255: 107–115
Walsh RJ, Slaby FJ, Posner BI (1987) A receptor-mediated mechanism for the transport of prolactin from blood to cerebrospinal fluid. Endocrinology 120: 1846–1850
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hernández, M.L., Fernández-Ruiz, J.J., Navarro, M. et al. Modifications of mesolimbic and nigrostriatal dopaminergic activities after intracerebroventricular administration of prolactin. J. Neural Transmission 96, 63–79 (1994). https://doi.org/10.1007/BF01277929
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01277929