Identification of antimitotic sulfonamides inhibiting chromosome congression.

IF 5.3 2区医学 Q1 PHARMACOLOGY & PHARMACY Biochemical pharmacology Pub Date : 2024-12-17 DOI:10.1016/j.bcp.2024.116718

Jun-Ichi Sawada, Kenji Matsuno, Naohisa Ogo, Akira Asai

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Abstract

The discovery of new small-molecule inhibitors is essential to enhancing our understanding of biological events at the molecular level and driving advancements in drug discovery. Mitotic inhibitors have played a crucial role in development of anticancer drugs. Beyond traditional microtubule inhibitors, various inhibitors targeting specific mitotic factors have been developed. This study aimed to develop novel mitotic inhibitors targeting chromosome alignment. We established a cell-based screening method using Cell Division Cycle Associated 5 (CDCA5) and kinesin-5 as markers, designed to efficiently detect mitotic phenotypes characterized by aberrant bipolar spindles with some misaligned chromosomes. Through this screening, we identified CAIS-1, an aryl sulfonamide with unique antimitotic properties. CAIS-1 exhibits dual functionality by inhibiting chromosome congression at low concentrations and spindle microtubule formation at high concentrations, causing a concentration-dependent mitotic arrest, followed by apoptotic cell death. Mechanistic studies revealed that CAIS-1 directly acts on tubulin at high concentrations, thereby inhibiting tubulin polymerization in vitro. In contrast, at low concentrations, CAIS-1 functions through a mechanism distinct from GSK923295, a conventional chromosome congression inhibitor targeting Centromere-associated protein-E (CENP-E), highlighting its unique mode of action. Moreover, CAIS-2, a structural analog of CAIS-1, selectively inhibits chromosome congression without significantly affecting spindle microtubules. This observation suggests that CAIS-1 and CAIS-2 function as antimitotic sulfonamides with distinct targets beyond tubulin, thus offering additional biological potential of sulfonamide compounds. Together, CAIS-1 and CAIS-2 represent promising tools for providing new molecular insights into kinetochore function during mitosis and for exploring new approaches in anticancer drug development.

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抑制染色体聚集的抗有丝分裂磺胺类化合物的鉴定。

新的小分子抑制剂的发现对于增强我们对分子水平生物事件的理解和推动药物发现的进步至关重要。有丝分裂抑制剂在抗癌药物的开发中起着至关重要的作用。除了传统的微管抑制剂外，针对特定有丝分裂因子的各种抑制剂已经开发出来。本研究旨在开发针对染色体排列的新型有丝分裂抑制剂。我们建立了一种基于细胞的筛选方法，使用细胞分裂周期相关5 （CDCA5）和激酶-5作为标记，旨在有效检测以异常双极纺锤体和一些染色体错位为特征的有丝分裂表型。通过这种筛选，我们鉴定出CAIS-1，一种具有独特抗有丝分裂特性的芳基磺胺。CAIS-1表现出双重功能，在低浓度下抑制染色体聚集，在高浓度下抑制纺锤体微管形成，导致浓度依赖性有丝分裂停止，随后是细胞凋亡死亡。机制研究表明，CAIS-1在高浓度下直接作用于微管蛋白，从而在体外抑制微管蛋白聚合。相比之下，在低浓度下，CAIS-1通过与GSK923295不同的机制发挥作用，GSK923295是一种针对着丝粒相关蛋白e （CENP-E）的传统染色体连接抑制剂，突出了其独特的作用模式。此外，CAIS-2是CAIS-1的结构类似物，可以选择性地抑制染色体聚集，而不会显著影响纺锤体微管。这一观察结果表明，CAIS-1和CAIS-2作为抗有丝分裂的磺胺类化合物具有除微管蛋白外的不同靶点，从而为磺胺类化合物提供了额外的生物学潜力。总之，CAIS-1和CAIS-2代表了有丝分裂过程中着丝点功能的新分子见解和探索抗癌药物开发的新方法的有前途的工具。

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来源期刊

Biochemical pharmacology 医学-药学

CiteScore

10.30

自引率

1.70%

发文量

420

审稿时长

17 days

期刊介绍： Biochemical Pharmacology publishes original research findings, Commentaries and review articles related to the elucidation of cellular and tissue function(s) at the biochemical and molecular levels, the modification of cellular phenotype(s) by genetic, transcriptional/translational or drug/compound-induced modifications, as well as the pharmacodynamics and pharmacokinetics of xenobiotics and drugs, the latter including both small molecules and biologics. The journal''s target audience includes scientists engaged in the identification and study of the mechanisms of action of xenobiotics, biologics and drugs and in the drug discovery and development process. All areas of cellular biology and cellular, tissue/organ and whole animal pharmacology fall within the scope of the journal. Drug classes covered include anti-infectives, anti-inflammatory agents, chemotherapeutics, cardiovascular, endocrinological, immunological, metabolic, neurological and psychiatric drugs, as well as research on drug metabolism and kinetics. While medicinal chemistry is a topic of complimentary interest, manuscripts in this area must contain sufficient biological data to characterize pharmacologically the compounds reported. Submissions describing work focused predominately on chemical synthesis and molecular modeling will not be considered for review. While particular emphasis is placed on reporting the results of molecular and biochemical studies, research involving the use of tissue and animal models of human pathophysiology and toxicology is of interest to the extent that it helps define drug mechanisms of action, safety and efficacy.