Daiber A, Herold S, Schöneich C, Namgaladze D, Peterson J A, Ullrich V
Department of Biology, Universität Konstanz, Germany.
Eur J Biochem. 2000 Dec;267(23):6729-39. doi: 10.1046/j.1432-1033.2000.01768.x.
Peroxynitrite (PN) is likely to be generated in vivo from nitric oxide and superoxide. We have previously shown that prostacyclin synthase, a heme-thiolate enzyme essential for regulation of vascular tone, is nitrated and inactivated by submicromolar concentrations of PN [Zou, M.-H. & Ullrich, V. (1996) FEBS Lett. 382, 101-104] and we have studied the effect of heme proteins on the PN-mediated nitration of phenolic compounds in model systems [Mehl, M., Daiber, A. & Ullrich, V. (1999) Nitric Oxide: Biol. Chem. 2, 259-269]. In the present work we show that bolus additions of PN or PN-generating systems, such as SIN-1, can induce the nitration of P450BM-3 (wild-type and F87Y variant), for which we suggest an autocatalytic mechanism. HPLC and MS-analysis revealed that the wild-type protein is selectively nitrated at Y334, which was found at the entrance of a water channel connected to the active site iron center. In the F87Y variant, Y87, which is directly located at the active site, was nitrated in addition to Y334. According to Western blots stained with a nitrotyrosine antibody, this nitration started at 0.5 microM of PN and was half-maximal between 100 and 150 microM of PN. Furthermore, PN caused inactivation of the P450BM-3 monooxygenase as well as the reductase activity with an IC50 value of 2-3 microM. As two thiol residues/protein molecule were oxidized by PN and the inactivation was prevented by GSH or dithiothreitol, but not by uric acid (a powerful inhibitor of the nitration), our data strongly indicate that the inactivation is due to thiol oxidation at the reductase domain rather then to nitration of Y residues. Stopped-flow data presented here support our previous hypothesis that ferryl-species are involved as intermediates during the reactions of P450 enzymes with PN.
过氧亚硝酸盐(PN)很可能在体内由一氧化氮和超氧化物生成。我们之前已经表明,前列环素合酶是一种调节血管张力所必需的血红素硫醇盐酶,在亚微摩尔浓度的PN作用下会发生硝化并失活[邹,M.-H. & 乌尔里希,V.(1996年)《欧洲生物化学学会联合会快报》382卷,第101 - 104页],并且我们已经研究了血红素蛋白对模型系统中PN介导的酚类化合物硝化作用的影响[梅尔,M.,戴伯,A. & 乌尔里希,V.(1999年)《一氧化氮:生物学与化学》2卷,第259 - 269页]。在本研究中,我们表明一次性添加PN或PN生成系统(如SIN - 1)可诱导P450BM - 3(野生型和F87Y变体)的硝化作用,对此我们提出了一种自催化机制。高效液相色谱(HPLC)和质谱(MS)分析表明,野生型蛋白在Y334处被选择性硝化,Y334位于连接活性位点铁中心的水通道入口处。在F87Y变体中,除了Y334外,直接位于活性位点的Y87也被硝化。根据用硝基酪氨酸抗体染色的蛋白质印迹法,这种硝化作用在0.5微摩尔的PN时开始,在100至150微摩尔的PN之间达到最大反应速率的一半。此外,PN导致P450BM - 3单加氧酶以及还原酶活性失活,半数抑制浓度(IC50)值为2 - 3微摩尔。由于每个蛋白分子的两个硫醇残基被PN氧化,并且谷胱甘肽(GSH)或二硫苏糖醇可阻止失活,但尿酸(一种强力的硝化抑制剂)不能阻止,我们的数据强烈表明失活是由于还原酶结构域的硫醇氧化,而不是Y残基的硝化。此处呈现的停流数据支持我们之前的假设,即高铁物种作为中间体参与P450酶与PN的反应。
