肼类似物对γ-氨基丁酸转氨酶的慢结合抑制作用。

Lightcap E S, Silverman R B

Department of Chemistry, Northwestern University, Evanston, Illinois 60208-3113, USA.

J Med Chem. 1996 Feb 2;39(3):686-94. doi: 10.1021/jm950437v.

(3-Hydroxybenzyl)hydrazine and methylhydrazine have been found to be potent slow-binding inhibitors of the pyridoxal 5-phosphate (PLP)-dependent enzyme gamma-aminobutyric acid aminotransferase (GABA-AT). Both compounds follow mechanism A (Morrison, J.F.; Walsh, C. T. Adv. Enzymol. 1988, 61, 201-301) which does not involve formation of a rapidly reversible enzyme-inhibitor complex before the formation of the final tight complex. The rate constant for formation of the enzyme-inhibitor complex determined from the slow-binding kinetics was 2.08 x 10(3) and 1.98 x 10(4) M-1 min-1 for methylhydrazine and (3-hydroxybenzyl)hydrazine, respectively. The rate constant for dissociation of the enzyme--inhibitor complex determined for the slow-binding kinetics was 4.6 x 10(-3) and 5 x 10(-3) min-1, respectively. The inhibition constants calculated from the slow-binding inhibition kinetics are 2.2 microM for methylhydrazine and 0.3 microM for (3-hydroxybenzyl)hydrazine. Reactivation of the inhibited enzyme was not first order, perhaps due to a side reaction of the hydrazine, but was consistent with the results obtained from the slow-binding kinetics. Inhibition constants were calculated from the level of enzyme activity at equilibrium inhibition. These constants are 2.8 and 0.46 microM for methylhydrazine and (3-hydroxybenzyl)hydrazine, respectively, in good agreement with those calculated from the slow-binding inhibition kinetics. 3-Hydrazinopropionate also behaved as a slow-binding inhibitor. However, the dependence of its kinetics on the concentration of inhibitor could not be described by the slow-binding or slow, tight-binding inhibition models. These kinetics could not be described by the tight-binding character of the inhibition because the addition of the competitive inhibitor propionic acid at 100 times its Ki did not affect the shape of the curve for inhibitor concentration dependence. The slow-binding inhibition appeared to require 2-4 molecules of 3-hydrazinopropionate/enzyme. The reactivation of enzyme inhibited by 3-hydrazinopropionate was first order with a rate constant of 6.9 x 10(-3) min-1. Its equilibrium inhibition constant was calculated to be < 20 nM. However, the inhibition constant calculated was dependent on the concentration of inhibitor because of the unusual character discussed above and may be much lower. Only 1 PLP/enzyme dimer reacted with methylhydrazine or (3-hydroxybenzyl)hydrazine, as indicated by Scatchard plots, or with 3-hydrazinopropionate, as shown by a spectrophotometric titration. Slow-binding inhibition does not appear to be the result of a significant enzyme conformational change because there is no change in the tryptophan fluorescence of GABA-AT upon binding either methylhydrazine or 3-hydrazinopropionate. Implications for the design of hydrazine inhibitors of GABA-AT are discussed.

已发现（3 - 羟基苄基）肼和甲基肼是磷酸吡哆醛（PLP）依赖性酶γ-氨基丁酸转氨酶（GABA - AT）的强效慢结合抑制剂。这两种化合物均遵循机制A（莫里森，J.F.；沃尔什，C.T.《酶学进展》1988年，61卷，201 - 301页），该机制在最终紧密复合物形成之前不涉及快速可逆酶 - 抑制剂复合物的形成。根据慢结合动力学测定的酶 - 抑制剂复合物形成速率常数，甲基肼和（3 - 羟基苄基）肼分别为2.08×10³和1.98×10⁴ M⁻¹ min⁻¹。根据慢结合动力学测定的酶 - 抑制剂复合物解离速率常数分别为4.6×10⁻³和5×10⁻³ min⁻¹。由慢结合抑制动力学计算得出的抑制常数，甲基肼为2.2 μM，（3 - 羟基苄基）肼为0.3 μM。被抑制酶的重新激活并非一级反应，可能是由于肼的副反应，但与慢结合动力学得到的结果一致。抑制常数是根据平衡抑制时的酶活性水平计算得出的。甲基肼和（3 - 羟基苄基）肼的这些常数分别为2.8和0.46 μM，与从慢结合抑制动力学计算得出的结果吻合良好。3 - 肼基丙酸酯也表现为慢结合抑制剂。然而，其动力学对抑制剂浓度的依赖性无法用慢结合或慢、紧密结合抑制模型来描述。这些动力学无法用抑制的紧密结合特性来描述，因为加入其解离常数（Ki）100倍的竞争性抑制剂丙酸并不影响抑制剂浓度依赖性曲线的形状。慢结合抑制似乎需要2 - 4个3 - 肼基丙酸酯分子/酶。被3 - 肼基丙酸酯抑制的酶的重新激活是一级反应，速率常数为6.9×10⁻³ min⁻¹。其平衡抑制常数经计算小于20 nM。然而，由于上述异常特性，计算得出的抑制常数取决于抑制剂浓度，可能会低得多。如Scatchard图所示，只有1个PLP/酶二聚体与甲基肼或（3 - 羟基苄基）肼反应，或如分光光度滴定所示，与3 - 肼基丙酸酯反应。慢结合抑制似乎不是显著的酶构象变化的结果，因为在结合甲基肼或3 - 肼基丙酸酯时，GABA - AT的色氨酸荧光没有变化。文中讨论了GABA - AT肼类抑制剂设计的相关影响。