Belcheva M M, Barg J, McHale R J, Dawn S, Ho M T, Ignatova E, Coscia C J
E. A. Doisy Department of Biochemistry and Molecular Biology, St. Louis University School of Medicine, Missouri 63104.
Mol Pharmacol. 1993 Jul;44(1):173-9.
The induction of opioid receptor adaptation by mixed agonist-antagonists such as buprenorphine has not been investigated. To this end, neonatal rats were given injections of buprenorphine (0.1-2.5 mg/kg/day) and mu binding (Kd and Bmax) to brain membranes was measured with [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin. At doses of buprenorphine of > or = 0.5 mg/kg, mu sites were reduced 47-75%, without changes in affinity. Chronic administration of the structurally related partial agonist diprenorphine (2.5-75 mg/kg) failed to alter mu binding. Apparent loss of sites due to receptor blockade by residual buprenorphine was ruled out by several lines of evidence. Bmax values for delta ([3H][D-Ser2,L-Leu5]enkephalyl-Thr) and kappa ([3H]U69593) binding were elevated 1.9-4.2-fold by buprenorphine treatment. In adult rats buprenorphine (0.5-2.5 mg/kg) reduced mu-opioid binding to forebrain membranes dose dependently, by 25-77%. [3H][D-Ser2,L-Leu5] Enkephalyl-Thr-labeled delta subtype receptors and kappa sites in adult forebrain membranes were up-regulated 2-3-fold. The delta subtype receptors that bind [3H][D-Pen2,D-Pen5]enkephalin in neonatal or adult brain membranes were unaffected by 0.5-2.5 mg/kg buprenorphine treatment. Down-regulation (70-74%) of mu sites and up-regulation (1.9-6.7 fold) of delta and kappa receptors were also observed in synaptic plasma membrane-enriched and microsomal fractions from buprenorphine-treated adult rat brain. Because agonist-induced opioid receptor down-regulation is difficult to elicit in adult mammalian brain, these data indicate that buprenorphine is a useful tool to study brain opioid receptor adaptation in vivo.
丁丙诺啡等混合激动剂 - 拮抗剂对阿片受体适应性的诱导尚未得到研究。为此,给新生大鼠注射丁丙诺啡(0.1 - 2.5毫克/千克/天),并用[3H][D - Ala2,MePhe4,Gly - ol5]脑啡肽测量其对脑膜的μ结合(Kd和Bmax)。当丁丙诺啡剂量≥0.5毫克/千克时,μ位点减少47 - 75%,亲和力无变化。长期给予结构相关的部分激动剂二丙诺啡(2.5 - 75毫克/千克)未能改变μ结合。多条证据排除了因残留丁丙诺啡导致受体阻断而造成位点明显丢失的可能性。丁丙诺啡处理使δ([3H][D - Ser2,L - Leu5]脑啡肽 - 苏氨酸)和κ([3H]U69593)结合的Bmax值升高1.9 - 4.2倍。在成年大鼠中,丁丙诺啡(0.5 - 2.5毫克/千克)剂量依赖性地使前脑脑膜的μ阿片结合减少25 - 77%。成年前脑脑膜中[3H][D - Ser2,L - Leu5]脑啡肽 - 苏氨酸标记的δ亚型受体和κ位点上调2 - 3倍。在新生或成年脑膜中与[3H][D - Pen2,D - Pen5]脑啡肽结合的δ亚型受体不受0.5 - 2.5毫克/千克丁丙诺啡处理的影响。在丁丙诺啡处理的成年大鼠脑的富含突触质膜和微粒体的组分中也观察到μ位点下调(70 - 74%)以及δ和κ受体上调(1.9 - 6.7倍)。由于在成年哺乳动物脑中难以引发激动剂诱导的阿片受体下调,这些数据表明丁丙诺啡是体内研究脑阿片受体适应性的有用工具。