Although dopamine inhibits PRL release from the normal anterior pituitary lactotroph, a conclusive demonstration of the mechanisms involved in this response has been impeded by the presence of other cell types in the anterior pituitary. To circumvent this problem, we have isolated a clonal cell line, designated MMQ, from the 7315a rat pituitary tumor. The MMQ cell is an exemplary model for our use because it only secretes PRL. Our studies show that dopamine inhibits secretagogue-induced PRL release from these cells. In addition, dopamine decreases the intracellular cAMP concentration in MMQ cells that have been exposed to forskolin, cholera toxin, or vasoactive intestinal polypeptide, each a stimulator of cAMP generation. This inhibition is, in turn, reversed by the dopamine antagonist haloperidol and by pertussis toxin, an inactivator of the GTP-binding coupling protein. Dopamine also decreases the uptake and fractional efflux of 45Ca2+ by MMQ cells that have been exposed to the calcium channel activator maitotoxin. It seems, therefore, that dopamine decreases PRL release from MMQ cells at least in part by decreasing intracellular cAMP levels and calcium uptake. In additional experiments, we have found that MMQ cells are responsive to somatostatin, estrogen, progesterone, and acetylcholine, but not to TRH, angiotensin II, neurotensin, or bombesin. Furthermore, these cells possess a functional protein kinase-C system, as evidenced by the increase in PRL release and decrease in stimulated intracellular cAMP levels that occur in response to treatment with phorbol diesters. We suggest that the MMQ cell line will prove a useful model system for study of the biochemical effects of dopamine and other factors that modify PRL release.
Medical therapy of prolactinomas with bromocriptine has been demonstrated to reduce serum PRL levels to normal and also to reduce the size of such tumors. This size reduction may occur very rapidly.It is widely recognized that PRL levels rise again after withdrawal of bromocriptine therapy. We now describe the effects of drug withdrawal and reinstitution on tumor size in two young men harboring large prolactinomas. Bromocriptine had been extremely successful in lowering serum PRL levels by more than 80%, as well as reducing tumor size. After 12 months of therapy bromocriptine was withdrawn. Within 48 h PRL levels had started to rise, reaching 2580 ng/ml at 13 days off therapy and 1040 ng/ml at 4 weeks off therapy in patients 1 and 2, respectively. At 13 days bitemporal hemianopsia recurred in patient 1, and this was associated with radiographic demonstration of expansion in the pituitary mass from a partially empty pituitary fossa to a large 12-mm suprasellar extension. The second patient remained asymptomatic, but his tumor also reexpanded after withdrawal of bromocriptine. Bromocriptine (2.5 mg, three times daily) was reinstituted in both cases and resulted in a rapid fall in serum PRL and reduction of tumor size in both patients; patient 1 had improvement in headaches at 24 h, vision at 3 days, and restoration of visual fields to normal at 6 months.Bromocriptine therapy is successful in reducing tumor size and lowering PRL levels with return of normal gonadal function. Patients with large prolactinomas treated with bromocriptine alone should be withdrawn from therapy very cautiously to avoid reexpansion of their tumor. (J Clin Endocrinol Metab 53: 480,1981)
Tetrabenazine is considered to act in a manner similar to reserpine to reduce the involuntary movements of tardive dyskinesia or Huntington's disease and to improve psychoses. We determined that tetrabenazine also has properties of a dopamine receptor antagonist by testing the ability of tetrabenazine to block the inhibitory effect of dopamine on prolactin secretion from rat anterior pituitary glands in vitro and to displace 3H-spiperone binding to dopamine receptors in the pituitary, corpus striatum, and a rat transplantable prolactin-secreting tumor. Under in vitro conditions, 0.5 to 10 microM tetrabenazine directly blocked dopaminergic inhibition of prolactin secretion. Furthermore, 1 hour after tetrabenazine injection (30 mg/kg intraperitoneally) in vivo, when the serum prolactin had increased from 22 +/- 9 to 450 +/- 52 ng/ml (p less than 0.01), pituitary glands of the treated rats examined in vitro were refractory to dopaminergic inhibition of prolactin release. Tetrabenazine apparently interacts with the dopamine receptor because this drug displaced the dopamine antagonist 3H-spiperone from dopamine receptors of the three different tissues with an apparent inhibitory constant of about 5 microM. We conclude that tetrabenazine has biological and pharmacological properties typical of a dopamine receptor antagonist. These observations should stimulate a reevaluation of the mechanisms for the actions of tetrabenazine previously attributed exclusively to a "reserpine-like" effect.
Thymosin fraction 5 (TF5) is a partially purified extract of bovine thymus containing 40-60 peptides. In addition to its well documented immunopotentiating effects, TF5 reportedly modulates the secretion of some hypothalamic peptides and pituitary hormones. In this study, TF5 (10-100 micrograms/ml) stimulated PRL release from normal, MtTW15, and 7315a cells and GH release from normal and MtTW15 cells, but had no apparent effect on LH release. No changes in intracellular cAMP or cGMP levels could be correlated with these responses. Stimulation of PRL release from perifused normal anterior pituitary cells was rapid, sustained, and concentration related. Although it had no apparent effect on normal prelabeled anterior pituitary cells with respect to 45Ca2+ efflux, the calcium channel blocker D-600 inhibited TF5-mediated hormone release from these cells. Additive increases in TRH-stimulated PRL release and GRF-stimulated GH release by TF5 suggested independent mechanisms of action. Dopamine (500 nM) blocked TF5-stimulated PRL release, but somatostatin (10-100 nM) had no effect on TF5-stimulated PRL or GH release. TF5 failed to affect either basal or TRH-induced polyphosphoinositide hydrolysis. Perifused normal anterior pituitary cells prelabeled with [3H]arachidonate responded to TF5 treatment with a liberation of radioactive arachidonate and/or its metabolites. BW755c, an inhibitor of all known catabolic pathways of arachidonic acid, blocked the ability of TF5 to stimulate PRL and GH release. Reversed phase HPLC separation of TF5 into five fractions resulted in two fractions that exhibited hormone-releasing activity. These data suggest that TF5 stimulates pituitary hormone release through a mechanism different from that ascribed to TRH or GRF. The stimulus-secretion coupling mechanism involves neither polyphosphoinositide hydrolysis nor cAMP generation, but appears to be dependent on the generation of arachidonate metabolites.
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