Structure based exploration of mitochondrial alpha carbonic anhydrase inhibitors as potential leads for anti-obesity drug development

IF 2.5 4区 医学 Q3 PHARMACOLOGY & PHARMACY DARU Journal of Pharmaceutical Sciences Pub Date : 2024-09-14 DOI:10.1007/s40199-024-00535-w
Ipsa Padhy, Tripti Sharma, Biswajit Banerjee, Sujata Mohapatra, Chita R. Sahoo, Rabindra Nath Padhy
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Abstract

Background

Obesity has emerged as a major health challenge globally in the last two decades. Dysregulated fatty acid metabolism and de novo lipogenesis are prime causes for obesity development which ultimately trigger other co-morbid pathological conditions thereby risking life longevity. Fatty acid metabolism and de novo lipogenesis involve several biochemical steps both in cytosol and mitochondria. Reportedly, the high catalytically active mitochondrial carbonic anhydrases (CAVA/CAVB) regulate the intercellular depot of bicarbonate ions and catalyze the rapid carboxylation of pyruvate and acetyl-co-A to acetyl-co-A and malonate respectively, which are the precursors of fatty acid synthesis and lipogenesis. Several in vitro and in vivo investigations indicate inhibition of mitochondrial carbonic anhydrase isoforms interfere in the functioning of pyruvate, fatty acid and succinate pathways. Targeting of mitochondrial carbonic anhydrase isoforms (CAVA/CAVB) could thereby modulate gluconeogenetic as well as lipogenetic pathways and pave way for designing of novel leads in the development pipeline of anti-obesity medications.

Methods

The present review unveils a diverse chemical space including synthetic sulphonamides, sulphamates, sulfamides and many natural bioactive molecules which selectively inhibit the mitochondrial isoform CAVA/CAVB with an emphasis on major state-of-art drug design strategies.

Results

More than 60% similarity in the structural framework of the carbonic anhydrase isoforms has converged the drug design methods towards the development of isoform selective chemotypes. While the benzene sulphonamide derivatives selectively inhibit CAVA/CAVB in low nanomolar ranges depending on the substitutions on the phenyl ring, the sulpamates and sulpamides potently inhibit CAVB. The virtual screening and drug repurposing methods have also explored many non-sulphonamide chemical scaffolds which can potently inhibit CAVA.

Conclusion

The review could pave way for the development of novel and effective anti-obesity drugs which can modulate the energy metabolism.

Graphical abstract

Abstract Image

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基于结构探索线粒体α碳酸酐酶抑制剂作为抗肥胖药物开发的潜在线索
背景过去二十年来,肥胖已成为全球面临的一项重大健康挑战。脂肪酸代谢失调和新脂肪生成是导致肥胖的主要原因,最终会引发其他并发症,从而危及寿命。脂肪酸代谢和新脂肪生成涉及细胞质和线粒体中的多个生化步骤。据报道,高催化活性线粒体碳酸酐酶(CAVA/CAVB)可调节细胞间碳酸氢根离子库,并催化丙酮酸和乙酰-Co-A 快速羧化,分别转化为乙酰-Co-A 和丙二酸,后者是脂肪酸合成和脂肪生成的前体。一些体外和体内研究表明,抑制线粒体碳酸酐酶同工酶会干扰丙酮酸、脂肪酸和琥珀酸途径的功能。因此,以线粒体碳酸酐酶同工酶(CAVA/CAVB)为靶点可以调节糖元生成和脂肪生成途径,并为设计抗肥胖药物研发中的新线索铺平道路。方法本综述揭示了一个多样化的化学领域,包括合成磺酰胺类、氨基磺酸盐类、氨基磺酸盐类和许多天然生物活性分子,它们可选择性地抑制线粒体同工酶 CAVA/CAVB,重点介绍了最先进的主要药物设计策略。结果碳酸酐酶同工酶结构框架的相似性超过 60%,这使得药物设计方法趋向于开发同工酶选择性化学类型。苯磺酰胺衍生物可根据苯环上的取代物在低纳摩尔范围内选择性抑制 CAVA/CAVB,而磺胺酸盐和磺胺类化合物则可有效抑制 CAVB。虚拟筛选和药物再利用方法也探索出了许多能有效抑制 CAVA 的非磺酰胺化学支架。
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DARU Journal of Pharmaceutical Sciences
DARU Journal of Pharmaceutical Sciences PHARMACOLOGY & PHARMACY-
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期刊介绍: DARU Journal of Pharmaceutical Sciences is a peer-reviewed journal published on behalf of Tehran University of Medical Sciences. The journal encompasses all fields of the pharmaceutical sciences and presents timely research on all areas of drug conception, design, manufacture, classification and assessment. The term DARU is derived from the Persian name meaning drug or medicine. This journal is a unique platform to improve the knowledge of researchers and scientists by publishing novel articles including basic and clinical investigations from members of the global scientific community in the forms of original articles, systematic or narrative reviews, meta-analyses, letters, and short communications.
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