第二:加泰罗尼亚的氢氧化反应机制当地活动中心的活动及其影响

H. Hermel, R. Havemann
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引用次数: 4

摘要

1.1. 过氧化氢酶蛋白质组分中的二硫基、巯基和碱基是过氧化氢酶与H2O2反应的活性中心。二硫化物和巯基表现为作用于H2O2的氧化还原体系。基基与基基相互作用。这影响了过氧化物的结合强度,它与假体基的Fe+结合。讨论了蛋白质组分中哪些基团可能负责血红素-蛋白相互作用。过氧化氢酶的实际活性可以通过消除5个中间平衡得到测定的活性- ph关系。这些是:过氧化氢解离,氢过氧化氢酶解离,过氧化氢酶解离,氧化还原电位的pH依赖性和潜在巯基的pH依赖性。由于血红素-蛋白相互作用,过氧化氢酶的实际活性依赖于pH值。利用这些结果可以解释催化反应的基本机理。过氧化氢酶的二硫桥将过氧化物氧化为氧是决定速率的过程,过氧化物与血红素组的铁结合。反应速度取决于过氧化氢酶氧化还原电位的大小和血红素-蛋白相互作用的强度。给出了这些量的大小值
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Über den mechanismus der katalase-wasserstoffperoxid-reaktion II. Die aktivitätszentren der katalase und ihre wirkungs-weise

  • 1.

    1. Besides the prosthetic groups, disulfide, sulfhydryl and basic groups in the protein component of catalase are active centers for the reaction with H2O2. The disulfide and sulfhydryl groups behave as a redox system acting upon H2O2. The basic groups interact with the prosthetic groups. This influences the binding strength of the peroxide, which is combined with the Fe+ of the prosthetic group. It is discussed which groups in the protein component could be responsible for the heme-protein interaction.

  • 2.

    2. The actual activity of catalase may be derived from the measured activity-pH relationship by elimination of the five intermediate equilibria. These are: the dissociation of peroxide, the dissociation of catalase hydroxide, the dissociation of catalase peroxide, the pH dependence of the redox potential and the pH dependence of latent sulfhydryl groups. The actual catalase activity is pH dependent because of heme-protein interaction.

  • 3.

    3. With the help of these results the fundamental mechanism of the catalatic reaction may be explained. The oxidation of peroxide to oxygen by the disulfide bridges of catalase is the rate-determining process, the peroxide being combined with the Fe of the heme group. The reaction velocity depends upon the size of the catalase redox potential and the strength of the heme-protein interaction. Values for the magnitude of these quantities are presented

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