Metolazone and Azosemide, Clinically Utilized Diuretics, Exhibit Inhibitory Activity for Glyoxalase I.

IF 3.2 4区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biotechnology and applied biochemistry Pub Date : 2025-04-08 DOI:10.1002/bab.2760

Masahiro Watanabe, Takao Toyomura, Hidenori Wake, Takashi Nishinaka, Omer Faruk Hatipoglu, Hideo Takahashi, Masahiro Nishibori, Shuji Mori

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引用次数: 0

Abstract

Methylglyoxal (MGO), a byproduct produced in the process of glycolysis, has cytotoxicity and forms advanced glycation endproducts (AGEs), which cause cell failure in several tissues. Because MGO is mainly removed by the action of glyoxalase I (GLO1), the activity of this enzyme contributes to the accumulation of MGO. We recently found that quinetazone, a diuretic pharmaceutical agent, has the potential to inhibit GLO1 activity. Therefore, we explored whether diuretics that have a similar structure to quinetazone inhibit GLO1. The inhibitory characteristics of diuretics with recombinant GLO1 were spectrophotometrically determined. Cell proliferation and accumulation of MGO-derived AGEs were evaluated by MTT assay and Western blotting. Among the thiazide, thiazide-like, and loop diuretics, metolazone and azosemide were found to inhibit GLO1 activity by 97% at 100 µM. Furthermore, we examined whether the substructures of these diuretics have inhibitory activity, quinazolinone or phenyltetrazole were determined to be the minimal structures of metolazone or azosemide required for inhibition of GLO1, respectively. In proximal renal tubule-like HK-2 and vascular endothelial cell-like EA.hy926 cells, these diuretics were shown to inhibit cell proliferation and induce accumulation of MGO-derived AGEs. In contrast, the substructures of these diuretics that did not affect GLO1 activity did not cause these changes. Metolazone and azosemide have inhibitory effects against GLO1. Considering that these diuretics are clinically employed as pharmaceutical agents, high or prolonged dosages may contribute to pathogenesis through GLO1 inhibition, followed by MGO and/or AGE accumulation.

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临床上使用的利尿剂美唑酮和阿唑塞米对乙二醛酶I有抑制作用。

甲基乙二醛（MGO）是糖酵解过程中产生的副产物，具有细胞毒性，并形成晚期糖基化终产物（AGEs），导致多种组织的细胞衰竭。由于MGO主要通过乙二醛酶I （GLO1）的作用去除，因此该酶的活性有助于MGO的积累。我们最近发现，利尿剂喹奈酮具有抑制GLO1活性的潜力。因此，我们探讨了与喹奈酮结构相似的利尿剂是否能抑制GLO1。用分光光度法测定重组GLO1对利尿剂的抑制作用。MTT法和Western blotting法观察mgo源性AGEs的细胞增殖和积累情况。在噻嗪类利尿剂、类噻嗪类利尿剂和环状利尿剂中，发现在100µM时，咪唑酮和阿唑塞米对GLO1活性的抑制率为97%。此外，我们检查了这些利尿剂的亚结构是否具有抑制活性，喹唑啉酮或苯四唑分别被确定为咪唑酮或阿唑塞胺抑制GLO1所需的最小结构。在近端肾小管样HK-2和血管内皮细胞样EA.hy926细胞中，这些利尿剂可抑制细胞增殖并诱导氧化镁来源的AGEs积累。相反，这些不影响GLO1活性的利尿剂的亚结构不会引起这些变化。美唑酮和阿唑塞米对GLO1有抑制作用。考虑到这些利尿剂在临床上作为药物使用，高剂量或长时间服用可能通过抑制GLO1，导致MGO和/或AGE积累而导致发病。

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来源期刊

Biotechnology and applied biochemistry 工程技术-生化与分子生物学

CiteScore

6.00

自引率

7.10%

发文量

117

审稿时长

3 months

期刊介绍： Published since 1979, Biotechnology and Applied Biochemistry is dedicated to the rapid publication of high quality, significant research at the interface between life sciences and their technological exploitation. The Editors will consider papers for publication based on their novelty and impact as well as their contribution to the advancement of medical biotechnology and industrial biotechnology, covering cutting-edge research in synthetic biology, systems biology, metabolic engineering, bioengineering, biomaterials, biosensing, and nano-biotechnology.