锌指转录因子 Zn3-Sp1 与 Cd2+的反应。
Zinc finger transcription factor Zn3-Sp1 reactions with Cd2+.
机构信息
Department of Chemistry and Biochemistry, University of Wisconsin-Milwaukee, Milwaukee, Wisconsin 53201, USA.
出版信息
Chem Res Toxicol. 2010 Feb 15;23(2):405-12. doi: 10.1021/tx900370u.
Cadmium is a major environmental pollutant that causes kidney failure including the inability to resorb nutrients such as glucose. In a mouse kidney cell culture model, Cd(2+) inhibits Na(+)-dependent glucose uptake mediated by SGLT transporters. This defect has been traced to the down-regulation of SGLT mRNA synthesis mediated by the zinc-finger transcription factor, Zn(3)-Sp1. Incubation of Cd(2+) with Zn(2+)-Sp1 inhibited its capacity to bind to GC1, its binding site in the SGLT1 promoter. The extent of reaction was reduced as increasing concentrations of Zn(2+) are simultaneously present in the reaction mixture. The results are consistent with a Cd(2+)-Zn(2+) exchange reaction that inactivates the DNA binding function of the protein. The equilibrium constant for this reaction was calculated as 14 +/- 3 and 7 +/- 4 for the reactions measured by the binding to GC1 and an analogous SGLT2 promoter site. Sequential addition of Cd(2+) and Zn(2+) to Zn(3)-Sp1 failed to inhibit the reduction in DNA binding seen with Cd(2+) alone, indicating that substitution of Zn(2+) by Cd(2+) was followed by a second reaction that failed to respond to Zn(2+). Buffers for the DNA binding reaction (electrophoretic mobility shift assay) contain EDTA and Cd-EDTA is active in the same concentration range as Cd(2+). During the standard 15 min incubation, Cd(2+) down-regulates Zn(3)-Sp1 but is inactive against the adduct, Zn(3)-Sp1.GC1. Kinetic studies demonstrated that with 5 muM Cd(2+), Zn(3)-Sp1 was about 75% inactivated in 15 min, whereas, Zn(3)-Sp1.GC1 was slowly dissociated with 50% still remaining after 60 min. In contrast, Zn(3)-Sp1 bound to a cognate consensus site resisted any reaction over 60 min. An adduct of Zn(3)-Sp1.(polydI-dC) was just as reactive with Cd(2+) as Zn(3)-Sp1. Reexamination of the NMR structure of Zn- and Cd-finger peptides related to Sp1 fingers has revealed subtle changes in conformation of the metalbinding site and DNA-binding helix that occur when Cd(2+) is substituted by Zn(2+).
镉是一种主要的环境污染物,可导致肾衰竭,包括无法吸收葡萄糖等营养物质。在小鼠肾细胞培养模型中,Cd(2+)抑制 SGLT 转运蛋白介导的 Na(+)-依赖性葡萄糖摄取。这种缺陷可追溯到锌指转录因子 Zn(3)-Sp1 介导的 SGLT mRNA 合成下调。用 Cd(2+)孵育 Zn(2+)-Sp1 会抑制其与 GC1 的结合能力,GC1 是 SGLT1 启动子中的结合位点。随着反应混合物中同时存在的 Zn(2+)浓度增加,反应程度降低。结果与 Cd(2+)-Zn(2+)交换反应一致,该反应使蛋白的 DNA 结合功能失活。通过结合 GC1 和类似的 SGLT2 启动子位点测量,该反应的平衡常数分别计算为 14 ± 3 和 7 ± 4。向 Zn(3)-Sp1 中顺序添加 Cd(2+)和 Zn(2+)未能抑制单独用 Cd(2+)观察到的 DNA 结合减少,表明 Zn(2+)被 Cd(2+)取代后,发生了未能对 Zn(2+)作出反应的第二次反应。DNA 结合反应(电泳迁移率变动分析)的缓冲液含有 EDTA,而 Cd-EDTA 在与 Cd(2+)相同的浓度范围内有效。在标准的 15 分钟孵育期间,Cd(2+)下调 Zn(3)-Sp1,但对加合物 Zn(3)-Sp1.GC1 无活性。动力学研究表明,在 5 μM Cd(2+)存在下,Zn(3)-Sp1 在 15 分钟内约有 75%失活,而 Zn(3)-Sp1.GC1 则缓慢解离,60 分钟后仍有 50%残留。相比之下,与同源共识位点结合的 Zn(3)-Sp1 抵抗任何超过 60 分钟的反应。Zn(3)-Sp1.(polydI-dC)的加合物与 Cd(2+)的反应与 Zn(3)-Sp1 一样活跃。重新检查与 Sp1 指相关的 Zn 和 Cd 指肽的 NMR 结构表明,当 Zn(2+)被 Cd(2+)取代时,金属结合位点和 DNA 结合螺旋的构象发生细微变化。
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