Dinapsoline: characterization of a D1 dopamine receptor agonist in a rat model of Parkinson's disease.

Dinapsoline is a new potent, full agonist at D1 dopamine receptors with limited selectivity relative to D2 receptors. The efficacy of this compound was assessed in rats with unilateral 6-hydroxydopamine lesions of the medial forebrain bundle, a standard rat model of Parkinson's disease. Dinapsoline produced robust contralateral rotation after either subcutaneous or oral administration. This rotational behavior was attenuated markedly by the D1 receptor antagonist SCH-23390, but not by the D2 receptor antagonist raclopride. During a chronic 14-day treatment period in which rats received dinapsoline either once or twice a day, dinapsoline did not produce tolerance (in fact, some sensitization of the rotational response was observed in one experiment). Because dinapsoline shows less D1:D2 selectivity in vitro than other D1 agonists, the contribution of D2 activity to tolerance was assessed. Chronic daily cotreatment with dinapsoline and raclopride did not enable the development of tolerance to chronic dinapsoline treatment. In contrast, when dinapsoline was administered by osmotic minipump, rapid tolerance was observed. To explore further the contribution of D1 and D2 receptors to tolerance, experiments were performed with the selective D1 agonist A-77636. Daily dosing with A-77636 rapidly produced complete tolerance, as previously observed, whereas coadministration of the D2 agonist quinpirole plus A-77636 failed to either delay or prevent tolerance. Taken together, these results indicate that the development of tolerance to D1 receptor agonists is influenced by the pattern of drug exposure but not by the D1:D2 selectivity of the agonist.

Mammalian-cell-produced neurturin (NTN) is more potent than purified Escherichia coli-produced NTN.

Neurturin (NTN) is a recently identified homologue of glial-cell-line-derived neurotrophic factor. Both factors promote the survival of dopaminergic (DA) neurons. We investigated the biological activity of mammalian-cell-produced NTN versus purified Escherichia coli-produced NTN. Baby hamster kidney cells were engineered to stably secrete mature human NTN. Mammalian-cell-derived NTN enhanced the activity of embryonic DA neurons in vitro, with greater potency (maximum effect achieved in the picogram range) than purified E. coli-produced NTN. Cell-based delivery of NTN (less than 10 ng/day) was also shown to be biologically active in vivo. These results suggest that mammalian-cell-derived NTN, synthesized de novo and delivered in small quantities to the parenchyma at the target site, may be as active as much larger quantities of purified, E. coli-produced NTN, delivered by other means.

Differential in vivo effects of neurturin and glial cell-line-derived neurotrophic factor.

Glial cell-line derived neurotrophic factor (GDNF) and neurturin (NTN) are structurally homologous, and they seem to produce similar effects in vitro. Tissue distributions of their respective receptors, GFR alpha-1 and GFR alpha-2, reveal overlapping but distinct patterns of expression, which implies that the in vivo actions of GDNF and NTN may be different. In the present study, a direct comparison of the in vivo effects of GDNF and NTN was performed using osmotic minipumps delivering either GDNF or NTN over a 30-day period into rat lateral cerebral ventricles. Amphetamine-induced activity levels were increased in both NTN- and GDNF-treated animals, with higher activity levels achieved by GDNF than NTN. The increase in amphetamine-induced activity levels persisted for 2 weeks and returned to control levels at the end of the third week. NTN-treated rats showed higher dopamine levels in the mediodorsal striatum, relative to the ventrolateral striatum. In contrast, no significant change in the regional distribution of dopamine levels was observed in GDNF treated or control animals. On the other hand, an increase in ventrolateral and mediodorsal striatal dopamine utilization was apparent in GDNF-treated animals, while NTN-treated animals showed increased levels of dopamine utilization only in the ventrolateral striatum. With respect to potential adverse effects, GDNF administration resulted in weight loss and the emergence of allodynia. No weight loss or allodynia was detectable with chronic NTN administration. These results suggest that although GDNF and NTN share structural and functional similarities, they may have differential effects in vivo.