An Organogermanium Compound Enhances the Initial Reaction Rate of Alkaline Isomerization of an Aldose into a Ketose through Enediol Complex Formation

IF 1.2 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Katsuyuki Sato, Takae Nagasawa, T. Kasumi
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引用次数: 0

Abstract

We previously demonstrated that the organogermanium compound 3-(trihydroxygermyl)propanoic acid (THGP) enhances the enzymatic and alkaline isomerization of an aldose to a ketose through cis-diol complex formation by multiple mechanisms. Its higher affinity for the ketose than the aldose protects the ketose complex from alkaline decomposition. Furthermore, it has been reported that the aldose-ketose alkaline isomerization pathway includes 1,2-enediol. Therefore, we speculated that the complex-forming ability of THGP could also be applied to enediol, a transient intermediate of alkaline isomerization. To test this prediction, we analyzed the initial rates of glucose or lactose isomerization in a region where there was no substantial difference in pH with and without THGP addition. The results showed that THGP enhanced the rate of fructose or lactulose formation per unit time by approximately 2-fold compared to the control. This finding indicated that THGP could form a complex with the transition state of aldose-ketose alkaline isomerization.
一种有机锗化合物通过形成烯二醇络合物提高醛糖碱性异构化成酮糖的初始反应速率
我们之前证明了有机锗化合物3-(三羟基香豆醇)丙酸(THGP)通过多种机制通过顺式二醇络合物的形成,增强了醛糖到酮糖的酶和碱异构化。它对酮糖的亲和力比醛糖高,保护酮糖复合物免受碱性分解。此外,据报道,醛糖-酮糖碱性异构化途径包括1,2-烯二醇。因此,我们推测THGP的络合物形成能力也可以应用于烯二醇,这是一种碱性异构化的过渡中间体。为了验证这一预测,我们分析了在pH值与不添加THGP没有实质性差异的区域中葡萄糖或乳糖异构化的初始速率。结果表明,与对照组相比,THGP使单位时间内果糖或乳果糖的形成率提高了约2倍。这一发现表明THGP可以与醛糖-酮糖碱性异构化过渡态形成配合物。
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来源期刊
Journal of applied glycoscience
Journal of applied glycoscience BIOCHEMISTRY & MOLECULAR BIOLOGY-
自引率
9.10%
发文量
13
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