氰化物与亚铁过氧化物酶的结合。
The binding of cyanide to ferroperoxidase.
作者信息
Phelps C, Antonini E, Brunori M
出版信息
Biochem J. 1971 Mar;122(1):79-87. doi: 10.1042/bj1220079.
Abstract
- The equilibrium and kinetics of cyanide binding to ferroperoxidase were investigated. At pH9.1 the equilibrium and kinetic measurements agree closely and disclose a single process with an affinity constant of 1.1x10(3)m(-1) and combination and dissociation velocity constants of 29m(-1).s(-1) and 2.5x10(-2)s(-1) respectively. 2. At pH values below 8 the affinity constant falls until at pH6.0 the ferroperoxidase.cyanide complex is no longer formed. This is shown to be associated with the formation of ferriperoxidase.cyanide complex in the mixture even in the presence of excess of sodium dithionite. 3. Rapid-pH-jump experiments show a fast pseudo-first-order interconversion between ferroperoxidase.cyanide complex at pH9.1 and ferriperoxidase.cyanide complex at pH6.0. 4. The kinetics of binding of cyanide to dithionite-reduced peroxidase at pH6.0 are complicated and radically different from those observed at pH9.1. 5. Above pH8 the change of affinity constant with pH is consistent with the undissociated species, HCN, being bound by the ferroperoxidase. The enthalpy for this process measured both by equilibrium and kinetic methods is about -8kcal/mol. 6. The binding of cyanide to reconstituted peroxidases, proto, meso and deutero, was investigated. 7. The results are discussed in relation to known data on cyanide binding to other haemoproteins.
摘要
- 研究了氰化物与亚铁过氧化物酶结合的平衡和动力学。在pH9.1时,平衡和动力学测量结果非常吻合,揭示了一个单一过程,其亲和常数为1.1×10³m⁻¹,结合和解离速度常数分别为29m⁻¹·s⁻¹和2.5×10⁻²s⁻¹。2. 在pH值低于8时,亲和常数下降,直到在pH6.0时不再形成亚铁过氧化物酶 - 氰化物复合物。结果表明,即使存在过量的连二亚硫酸钠,混合物中也会形成高铁过氧化物酶 - 氰化物复合物。3. 快速pH跃变实验表明,在pH9.1的亚铁过氧化物酶 - 氰化物复合物和pH6.0的高铁过氧化物酶 - 氰化物复合物之间存在快速的准一级相互转化。4. 在pH6.0时,氰化物与连二亚硫酸钠还原的过氧化物酶结合的动力学很复杂,与在pH9.1时观察到的情况有根本不同。5. 在pH8以上,亲和常数随pH的变化与未解离的物种HCN被亚铁过氧化物酶结合一致。通过平衡和动力学方法测量的该过程的焓约为 -8kcal/mol。6. 研究了氰化物与重组过氧化物酶原、中过氧化物酶和氘过氧化物酶的结合。7. 结合氰化物与其他血红蛋白的已知数据对结果进行了讨论。
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