Basile A S, Paul I A, Mirchevich A, Kuijpers G, De Costa B
Laboratory of Neuroscience, National Institutes of Diabetes, Digestive, and Kidney Diseases, National Institutes of Health, Bethesda, Maryland 20892.
Mol Pharmacol. 1992 Nov;42(5):882-9.
The ability of cations to modulate the binding of the sigma 1 receptor-selective ligand (+)-[3H]pentazocine to guinea pig cerebellum was investigated. Di- and trivalent cations biphasically inhibited (+)-[3H]pentazocine binding, revealing multiple affinity states. The rank order of potency of these cations (based on the high affinity component of inhibition) was Zn2+ > Co2+ >> La3+ = Ni2+ = Cd2+ = Mn2+ = Gd2+ > Ba2+ = Sr2+ >> Mg2+ > Ca2+. The inhibition of 1,3-[3H]di(2-tolyl)guanidine binding to the sigma 2 receptor by these cations differed qualitatively and quantitatively from their effects on (+)-[3H]pentazocine binding. Although monovalent cations decreased the Kd for (+)-[3H]pentazocine binding, divalent cations split (+)-[3H]pentazocine binding into low and high affinity components. The Bmax of the high affinity component decreased with increasing divalent cation concentrations. Both mono- and divalent cations significantly reduced the rate of association of (+)-[3H]pentazocine with the sigma 1 receptor without altering the dissociation rate. (+)-[3H]Pentazocine binding was not altered by guanine nucleotides or by treatment with cholera or pertussis toxins. However, nonselective cation channel blockers (cinnarizine, hydroxyzine, prenylamine, amiodarone, and proadifen) potently inhibited (+)-[3H]pentazocine binding. These results indicate that physiologically relevant concentrations of divalent cations allosterically modulate (+)-[3H]pentazocine binding to the sigma 1 receptor, to reveal multiple affinity states. These sites do not represent sigma 1 to sigma 2 subtype interconversion or ternary complex formation with guanine nucleotide-binding proteins. However, the rank order of cation potency and the inhibition of binding by cation channel blockers is consistent with a potential role for sigma receptors as constituents of cation channels.
研究了阳离子调节σ1受体选择性配体(+)-[3H]喷他佐辛与豚鼠小脑结合的能力。二价和三价阳离子对(+)-[3H]喷他佐辛的结合呈双相抑制,揭示了多种亲和状态。这些阳离子的效力顺序(基于抑制的高亲和力成分)为Zn2+>Co2+>>La3+=Ni2+=Cd2+=Mn2+=Gd2+>Ba2+=Sr2+>>Mg2+>Ca2+。这些阳离子对1,3-[3H]二(2-甲苯基)胍与σ2受体结合的抑制在质量和数量上与其对(+)-[3H]喷他佐辛结合的影响不同。虽然单价阳离子降低了(+)-[3H]喷他佐辛结合的解离常数,但二价阳离子将(+)-[3H]喷他佐辛的结合分为低亲和力和高亲和力成分。高亲和力成分的最大结合量随二价阳离子浓度的增加而降低。单价和二价阳离子均显著降低(+)-[3H]喷他佐辛与σ1受体的结合速率,而不改变解离速率。鸟嘌呤核苷酸或霍乱毒素或百日咳毒素处理均不改变(+)-[3H]喷他佐辛的结合。然而,非选择性阳离子通道阻滞剂(桂利嗪、羟嗪、普尼拉明、胺碘酮和丙胺卡因)能有效抑制(+)-[3H]喷他佐辛的结合。这些结果表明,生理相关浓度的二价阳离子通过变构调节(+)-[3H]喷他佐辛与σ1受体的结合,以揭示多种亲和状态。这些位点并不代表σ1到σ2亚型的相互转化或与鸟嘌呤核苷酸结合蛋白形成三元复合物。然而,阳离子效力顺序和阳离子通道阻滞剂对结合的抑制作用与σ受体作为阳离子通道组成成分的潜在作用一致。
