The distribution of dopamine D-1 receptors has been determined in the rat brain by a quantitative in vitro light-microscopic autoradiographic method. The binding of [N-methyl-3H]-SCH 23390 to slide-mounted tissue sections takes place with characteristics expected of a substance that recognizes D-1 receptors. The binding is saturable, has high affinity, and exhibits an appropriate pharmacology and stereospecificity in several discrete microscopic brain regions as determined by quantitative autoradiography. The highest density of D-1 receptors occurs in the caudate-putamen, accumbens nucleus, olfactory tubercle, and the substantia nigra pars reticulata. High concentrations of D-1 receptors were associated with the intercalated and medial nuclei of the amygdala, entopeduncular nucleus, and major island of Calleja. Furthermore, moderate to low concentrations were observed in several other structures, such as the frontal cortex, subthalamic nucleus, and several thalamic, hypothalamic, and hippocampal areas. The distribution of D-1 receptors correlates very well with projection areas of dopaminergic pathways. This technique furnishes a powerful assay for the accumulation of detailed pharmacologic and anatomical data about D-1 receptors, and the results suggest possible CNS sites of action of D-1 dopamine receptor selective compounds.
A vaginal gel containing the antiretroviral tenofovir (TFV) recently demonstrated 39% protection against HIV infection in women. We designed and evaluated a novel reservoir TFV intravaginal ring (IVR) to potentially improve product effectiveness by providing a more controlled and sustained vaginal dose to maintain cervicovaginal concentrations. Polyurethane tubing of various hydrophilicities was filled with a high-density TFV/glycerol/water semisolid paste and then end-sealed to create IVRs. In vitro, TFV release increased with polyurethane hydrophilicity, with 35 weight percent water-swelling polyurethane IVRs achieving an approximately 10-mg/day release for 90 days with mechanical stiffness similar to that of the commercially available NuvaRing. This design was evaluated in two 90-day in vivo sheep studies for TFV pharmacokinetics and safety. Overall, TFV vaginal tissue, vaginal fluid, and plasma levels were relatively time independent over the 90-day duration at approximately 10 4 ng/g, 10 6 ng/g, and 10 1 ng/ml, respectively, near or exceeding the highest observed concentrations in a TFV 1% gel control group. TFV vaginal fluid concentrations were approximately 1,000-fold greater than levels shown to provide significant protection in women using the TFV 1% gel. There were no toxicological findings following placebo and TFV IVR treatment for 28 or 90 days, although slight to moderate increases in inflammatory infiltrates in the vaginal epithelia were observed in these animals compared to naïve animals. In summary, the controlled release of TFV from this reservoir IVR provided elevated sheep vaginal concentrations for 90 days to merit its further evaluation as an HIV prophylactic. R ecent progress in antiretroviral HIV prevention research has advanced the field from concept toward medical practice (46). The CAPRISA 004 study demonstrated that a vaginal gel containing the reverse transcriptase inhibitor tenofovir (TFV) was partially effective in preventing HIV transmission in women (1), with significant protection observed in women who maintained preventative TFV concentrations of at least 1,000 ng/ml in vaginal fluid (23). However, the overall effectiveness (39%) was likely reduced by poor user adherence to the inconvenient before-andafter-sex dosing regimen. The correlation of adherence and TFV vaginal fluid concentrations to protection was a key finding (23,24), indicating the need for vaginal drug delivery systems that attain and maintain elevated user adherence and vaginal drug concentrations. More recently, the VOICE trial tested the same TFV 1% gel formulation as CAPRISA 004 but with a once-daily dosage regimen and failed to show any effectiveness in women. Here, as well, low adherence may have contributed to the gel's inability to prevent HIV transmission (54). As a result, we (6, 21) and others (4,35,36,44,49) aim to develop TFV drug delivery systems to provide sustained protective vaginal tissue concentrations and potentially increase user adherence.The micromolar anti-HIV activity of TFV motivated sel...
Conantokin G (Con G) is a 17-amino-acid peptide antagonist of N-methyl-D-aspartate (NMDA) receptors isolated from the venom of the marine cone snail, Conus geographus. The mechanism of action of Con G has not been well defined; both competitive and noncompetitive interactions with the NMDA-binding site have been proposed. In this study the mechanism of action and subunit selectivity of Con G was examined in whole-cell voltage-clamp recordings from cultured neurons and in two electrode voltage-clamp recordings from Xenopus oocytes expressing recombinant NMDA receptors. Con G was a potent and selective antagonist of NMDA-evoked currents in murine cortical neurons (IC(50) = 480 nM). The slow onset of Con G block could be prevented by coapplication with high concentrations of NMDA or of the competitive antagonist (RS)-3-(2-carboxypiperazine-4-yl)-propyl-1-phosphonic acid. Furthermore, in oocytes expressing NR1a/NR2B receptors, Con G produced a rightward shift in the concentration-response curve for NMDA, providing support for a competitive interaction with the NMDA-binding site. Con G produced an apparent noncompetitive shift in the concentration-response curve for spermine potentiation of NMDA responses, but this was due to spermine-induced enhancement of Con G block. Spermine produced a similar enhancement of DL-2-amino-S-phosphopentanoic acid block. Finally, Con G selectively blocked NMDA receptors containing the NR2B subunit. These results demonstrate that Con G is a subunit-specific competitive antagonist of NMDA receptors. The unique subunit selectivity profile of Con G may explain its favorable in vivo profile compared with nonselective NMDA antagonists.
Subunit non-selective N-methyl-D-aspartate (NMDA) receptor antagonists reduce injury-induced pain behavior, but generally produce unacceptable side effects. In this study, we examined the antinociceptive and motor effects of cone snail venom-derived peptides, conantokins G and T (conG and conT), which are selective inhibitors of the NR2B or NR2A and NR2B subtypes of the NMDA receptor, respectively. We tested the effects of conG and conT in models of tissue (formalin test), nerve injury (partial sciatic nerve ligation) and inflammation-induced (intraplantar Complete Freund's Adjuvant; CFA) pain in mice. In the formalin test, intrathecal (i.t.) conG or conT suppressed the ongoing pain behavior (ED(50) and 95% confidence intervals (CI), 11 (7-19) and 19 (11-33), respectively) at doses that were 17-27 times lower than those required to impair motor function (accelerating rotarod treadmill test: ED(50) and 95% CI, 300 (120-730) and 320 (190-540) pmol, respectively). By comparison, SNX-111, an N-type voltage-sensitive calcium channel antagonist that is also derived from cone snail venom, produced significant motor impairment at a dose (3.0 pmol, i.t.) that was only partially efficacious in the formalin test. Furthermore, conG reversed the allodynia produced by nerve injury, with greater potency on thermal (ED50 and 95% CI, 24 (10-55) pmol) than on mechanical allodynia (59 (33-105) pmol). Finally, a single dose of conG (100 pmol, i.t.) also reduced CFA-evoked thermal and mechanical allodynia. Taken together, these results demonstrate that conantokins exhibit potent antinociceptive effects in several models of injury-induced pain. The study supports the notion that drugs directed against subtypes of the NMDA receptor, by virtue of their reduced side-effect profile, hold promise as novel therapeutic agents for the control of pain.
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