Solano-Muñoz F, Bardsley W G, Indge K J
Biochem J. 1981 Jun 1;195(3):589-601. doi: 10.1042/bj1950589.
Numerous chemical compounds are known that alter the rate of conversion of substrates into products in enzyme-catalysed reactions by interacting with the enzyme rather than substrates. Where this takes place in such a way that the effect is reversible on removing the compound, say by dialysis, and where the compound is unchanged chemically by the enzyme system, we refer to such a compound as a modifier. So protons, inorganic salts, activators, inhibitors or even specific allosteric effectors would all be modifiers, and any chemically reasonable kinetic scheme that is proposed to account for such effects is referred to as modifier mechanism. Three versions of a modifier mechanism of enzyme action are studied. The implicit representation is 2:2 in [S] (with alpha(0)=0) and 2:2 in [M] (with alpha(0) not equal0), and this is a short-hand scheme for the minimum chemical formulation, the explicit one, involving discrete ES and EP species, which is 2:2 in [S] (with alpha(0)=0) and 3:3 in [M] (with alpha(0) not equal0). If m extra steps are allowed between interconversion of ES and EP species, the degree of the rate equation remains 2:2 in [S] (with alpha(0)=0), but increases to degree (m+3):(m+3) in modifier (with alpha(0) not equal0). It is proved that this increase in degree is genuine and that highly complex v([M]) (i.e. v-versus-[M]) curves can occur. Computation of the probabilities of the five possible double-reciprocal plots in 1/v versus 1/[S] show that all of these formulations of the modifier mechanism give similar probabilities, and these are characteristic for the mechanism and quite distinct from the intrinsic curve-shape probabilities. It is also established that the probabilities of alternative complex v([M]) plots are similar for the various formulations, and again the probabilities of the allowed complex curves for the mechanism are quite distinct from the instrinsic probabilities of the ten possible v([M]) curves for a 2:2 function (with alpha(0) not equal0). The computer studies reported lead to several conclusions about the probability of modifiers leading to inhibition or activation or causing changes in v([S]) curve shapes, and suggest that differentiation between model mechanisms may be facilitated by knowledge of the intrinsic curve-shape probabilities for the appropriate degree rational function and the characteristic way that this is altered by specific mechanisms. It is shown that, although in some instances new curve-shape complexities are possible when schemes are considered that allow for interconversion of ES and EP species, these are highly improbable and, for theoretical purposes, schemes formulated with node compression provide good approximations to the more complicated explicit schemes. By node compression we refer to the procedure whereby enzyme kinetic schemes are simplified by replacing sequences of steps such as ESright harpoon over left harpoonX(1)right harpoon over left harpoonX(2)right harpoon over left harpoon...right harpoon over left harpoonEP... by a single step... ES/EP... that does not formally recognize the existence of the intermediate species. We show that the modifier mechanism studied is one where this process alters the form of the rate equation.
已知有许多化合物,它们通过与酶而非底物相互作用,改变酶催化反应中底物转化为产物的速率。若这种作用以如下方式发生:去除该化合物(如通过透析)后效果是可逆的,且该化合物在酶系统作用下化学性质不变,我们就称这种化合物为调节剂。所以质子、无机盐、激活剂、抑制剂乃至特定的别构效应剂都属于调节剂,任何为解释此类效应而提出的化学上合理的动力学方案都称为调节剂机制。本文研究了酶作用调节剂机制的三种形式。隐式表示在底物浓度[S]中为2:2(α₀ = 0),在调节剂浓度[M]中为2:2(α₀ ≠ 0),这是最小化学表达式的简记形式,显式形式涉及离散的ES和EP物种,在底物浓度[S]中为2:2(α₀ = 0),在调节剂浓度[M]中为3:3(α₀ ≠ 0)。如果在ES和EP物种的相互转化之间允许额外的m个步骤,速率方程的次数在底物浓度[S]中仍为2:2(α₀ = 0),但在调节剂浓度[M]中增加到(m + 3):(m + 3)(α₀ ≠ 0)。已证明这种次数的增加是真实的,并且可能出现高度复杂的v([M])(即v对[M])曲线。计算1/v对1/[S]中五种可能的双倒数图的概率表明,调节剂机制的所有这些表达式给出的概率相似,这些概率是该机制的特征,与内在曲线形状概率截然不同。还确定了各种表达式的替代复杂v([M])图的概率相似,并且该机制允许的复杂曲线的概率同样与2:2函数(α₀ ≠ 0)的十种可能v([M])曲线的内在概率截然不同。所报道的计算机研究得出了关于调节剂导致抑制或激活或引起v([S])曲线形状变化的概率的几个结论,并表明通过了解适当次数有理函数的内在曲线形状概率以及特定机制改变它的特征方式,可能有助于区分模型机制。结果表明,虽然在某些情况下,考虑允许ES和EP物种相互转化的方案时可能会出现新的曲线形状复杂性,但这些情况极不可能发生,并且出于理论目的,用节点压缩法制定的方案能很好地近似更复杂的显式方案。我们所说的节点压缩是指这样一种过程,即通过将诸如ES⇌X₁⇌X₂⇌...⇌EP这样的步骤序列替换为单个步骤...ES/EP...来简化酶动力学方案,该单个步骤并不正式承认中间物种的存在。我们表明所研究的调节剂机制就是这样一个过程改变速率方程形式的机制。
