Park I S, Hausinger R P
Department of Microbiology, Michigan State University, East Lansing 48824-1101, USA.
Biochemistry. 1996 Apr 23;35(16):5345-52. doi: 10.1021/bi952894j.
Klebsiella aerogenes urease in a Ni-containing enzyme (two Ni per alpha beta gamma unit) that is purified as an apoprotein from cells grown in Ni-free medium. Partial activation of urease and UreD-urease apoproteins is achieved in vitro by incubation in the presence of Ni(II) and CO2, whereas incubation of these proteins with Ni alone leads to the formation of inactive species [Park, I.-S., & Hausinger, R. P. (1995) Science 267, 1156-1158]. Here we determined the kinetics of these inhibitory reactions and demonstrated the presence of two Ni ions per alpha beta gamma unit in the inactive proteins. Although metal-substituted urease has never been purified from Ni-deprived cell, several other metal ions were shown to bind to the urease apoproteins. Divalent Zn, C, Co, and Mn all inhibited Ni- and Co2-promoted urease activation at concentrations below that of Ni, whereas Mg and Ca ions did not inhibit this process. Ni-inhibited species recovered their ability to be partially activated after EDTA treatment. In contrast, samples that were exposed to Co or Cu ions were irreversibly inactivated, and EDTA treatment of Zn- or Mn-inhibited samples led to reduced levels of activation competence. Mn-substituted urease, generated from urease apoprotein samples in a Mn- and Co2-dependent manner, was shown to be active, whereas other metal-substituted forms if urease lacked activity. The Mn-protein possessed only 2% of the activity of Ni-activated apoprotein [ approximately 8.0 vs approximately 400 mumol min-1 (mg protein)-1], but its KM value was only moderately altered from that of the native enzyme (3.86 +/- 0.15 mM vs 0.2 mM). Unlike the Ni-containing enzyme, Mn-urease was inhibited by EDTA. Given the evidence that urease apoprotein binds numerous metal ions, we speculate on possible roles for the UreD, UreF, and UreG accessory proteins in urease activation.
产气克雷伯氏菌脲酶是一种含镍酶(每个αβγ单位含两个镍),它作为脱辅基蛋白从在无镍培养基中生长的细胞中纯化得到。脲酶和脲D - 脲酶脱辅基蛋白在体外通过在Ni(II)和CO₂存在下孵育实现部分活化,而这些蛋白质仅与镍孵育会导致形成无活性物种[Park, I.-S., & Hausinger, R. P. (1995) Science 267, 1156 - 1158]。在此,我们确定了这些抑制反应的动力学,并证明无活性蛋白质中每个αβγ单位存在两个镍离子。尽管从未从缺镍细胞中纯化出金属取代的脲酶,但已表明其他几种金属离子可与脲酶脱辅基蛋白结合。二价锌、镉、钴和锰在浓度低于镍时均抑制镍和钴促进的脲酶活化,而镁和钙离子不抑制此过程。经EDTA处理后,镍抑制的物种恢复了部分活化的能力。相反,暴露于钴或铜离子的样品被不可逆地失活,对锌或锰抑制的样品进行EDTA处理导致活化能力水平降低。以锰和钴依赖的方式从脲酶脱辅基蛋白样品生成的锰取代脲酶显示有活性,而其他金属取代形式的脲酶缺乏活性。锰蛋白的活性仅为镍活化脱辅基蛋白的2%[约8.0对约400 μmol min⁻¹ (mg蛋白)⁻¹],但其KM值与天然酶相比仅适度改变(3.86 ± 0.15 mM对0.2 mM)。与含镍酶不同,锰脲酶被EDTA抑制。鉴于有证据表明脲酶脱辅基蛋白结合多种金属离子,我们推测脲D、脲F和脲G辅助蛋白在脲酶活化中的可能作用。
