大鼠脑膜中特异性的[(3)H]-鸟苷结合位点。
Specific [(3)H]-guanosine binding sites in rat brain membranes.
作者信息
Traversa Ugo, Bombi Giulia, Di Iorio Patrizia, Ciccarelli Renata, Werstiuk Eva S, Rathbone Michel P
机构信息
Department of Biomedical Sciences--Basic Research and Integrative Neuroscience Centre, University of Trieste, via Licio Giorgieri 7, 34127 Trieste, Italy.
出版信息
Br J Pharmacol. 2002 Feb;135(4):969-76. doi: 10.1038/sj.bjp.0704542.
Abstract
- Extracellular guanosine has diverse effects on many cellular components of the central nervous system, some of which may be related to its uptake into cells and others to its ability to release adenine-based purines from cells. Yet other effects of extracellular guanosine are compatible with an action on G-protein linked cell membrane receptors. 2. Specific binding sites for [(3)H]-guanosine were detected on membrane preparations from rat brain. The kinetics of [(3)H]-guanosine binding to membranes was described by rate constants of association and dissociation of 2.6122 x 10(7) M(-1) min(-1) and 1.69 min(-1), respectively. A single high affinity binding site for [(3)H]-guanosine with a K(D) of 95.4 +/- 11.9 nM and B(max) of 0.57 +/- 0.03 pmol mg(-1) protein was shown. This site was specific for guanosine, and the order of potency in displacing 50 nM [(3)H]-guanosine was: guanosine=6-thio-guanosine > inosine > 6-thio-guanine > guanine. Other naturally occurring purines, such as adenosine, hypoxanthine, xanthine caffeine, theophylline, GDP, GMP and ATP were unable to significantly displace the radiolabelled guanosine. Thus, this binding site is distinct from the well-characterized receptors for adenosine and purines. 5. The addition of GTP produced a small concentration-dependent decrease in guanosine binding, suggesting this guanosine binding site was linked to a G-protein. 6. Our results therefore are consistent with the existence of a novel cell membrane receptor site, specific for guanosine.
摘要
- 细胞外鸟苷对中枢神经系统的许多细胞成分具有多种作用,其中一些作用可能与其被细胞摄取有关,而其他作用则与其从细胞中释放腺嘌呤类嘌呤的能力有关。细胞外鸟苷的其他作用与对G蛋白偶联细胞膜受体的作用相一致。2. 在大鼠脑的膜制剂上检测到了[(3)H]-鸟苷的特异性结合位点。[(3)H]-鸟苷与膜结合的动力学分别用缔合速率常数2.6122×10(7) M(-1) min(-1)和解离速率常数1.69 min(-1)来描述。显示了一个对[(3)H]-鸟苷具有高亲和力的单一结合位点,其解离常数K(D)为95.4±11.9 nM,最大结合容量B(max)为0.57±0.03 pmol mg(-1)蛋白质。该位点对鸟苷具有特异性,取代50 nM [(3)H]-鸟苷的效力顺序为:鸟苷=6-硫代鸟苷>肌苷>6-硫代鸟嘌呤>鸟嘌呤。其他天然存在的嘌呤,如腺苷、次黄嘌呤、黄嘌呤、咖啡因、茶碱、GDP、GMP和ATP均不能显著取代放射性标记的鸟苷。因此,该结合位点与已充分表征的腺苷和嘌呤受体不同。5. 添加GTP导致鸟苷结合呈小的浓度依赖性下降,表明该鸟苷结合位点与G蛋白相连。6. 因此,我们的结果与存在一种对鸟苷具有特异性的新型细胞膜受体位点相一致。
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