5-aminosalicylate–4-thiazolinone hybrid derivatives: A potent modulator of DNA damage response and G2/M cell cycle arrest via ATM/ATR pathway and Cyclin-CDK complex

W. Ramadan, M. Ayad, R. Hamoudi, A. Laham, V. Menon, L. Lozon, H. Abdu-Allah, A. El-Shorbagi, H. Tarazi, R. El-Awady
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Abstract

The last several years have witnessed a tremendous advance in the knowledge of DNA repair and cell cycle mechanisms for the purpose of increasing the treatment efficacy of radiotherapy and DNA damaging agents. Thereby, targeting DNA damage and repair pathways and cell cycle checkpoints become an attractive rationale to optimize treatment strategies through identifying new targets. However, the improved knowledge has increased the complexity of DNA damage response (DDR) and checkpoint pathways which extremely proved challenges in the development of cell cycle and DNA repair targeting drugs. To this end, a novel approach of synthesizing new compounds has been recently introduced which involved accommodating two chemical entities that target several molecules into a single structure. Here we combined 5-aminosalicylic acid and 4-thiazolinone, which both reported to affect DDR and cell cycle progression, in a single structural framework to generate two derivatives named HH32 and HH33. The transcriptomic, in silico, and in vitro analysis has been used to uncover the anti-cancer potential of these two compounds. Both compounds exhibited a high cytotoxic effect against a panel of eight cancer cell lines from different tissue origins and showed a low toxicity profile on normal cells compared to Doxorubicin. The in-silico molecular docking predicts a strong binding of the HH32 and HH33 to cell cycle regulators like CDC2-cyclin B, CDK2-cyclin A complexes, and retinoblastoma. Interestingly, the transcriptomic analysis revealed that DNA double-strand repair and cell cycle are the most affected pathways by HH33 compound. These findings were validated using in vitro models and demonstrated the induction of DNA double-strand breaks and the stimulation of ATM/ATR signaling pathway by HH32 and HH33. In addition to the potent effect of HH compounds on cell cycle progression mediated through upregulation of cyclin-dependent kinase inhibitors and downregulation of G2/M phase cell cycle markers which ultimately arrest the cells at G2/M phase and promote apoptosis. In conclusion, the pleiotropic biological effect of HH32 and HH33 compounds on cancer cells suggests the requirement for assessing their anti-cancer activities in preclinical models which may lead to a new area in the development of potentially therapeutic drugs.
5-氨基水杨酸- 4-噻唑啉酮杂化衍生物:通过ATM/ATR途径和Cyclin-CDK复合物有效调节DNA损伤反应和G2/M细胞周期阻滞
在过去的几年里,为了提高放射治疗和DNA损伤剂的治疗效果,DNA修复和细胞周期机制的知识取得了巨大的进步。因此,靶向DNA损伤和修复途径以及细胞周期检查点成为通过识别新靶点来优化治疗策略的一个有吸引力的理论依据。然而,知识的进步增加了DNA损伤反应(DDR)和检查点途径的复杂性,这给细胞周期和DNA修复靶向药物的开发带来了极大的挑战。为此,最近引入了一种合成新化合物的新方法,该方法涉及容纳两种化学实体,这些化学实体针对几个分子形成一个单一结构。在这里,我们将5-氨基水杨酸和4-噻唑啉酮结合在一个单一的结构框架中,生成了两个名为HH32和HH33的衍生物,这两个衍生物都影响DDR和细胞周期进程。转录组学、硅和体外分析已被用来揭示这两种化合物的抗癌潜力。与阿霉素相比,这两种化合物对来自不同组织来源的八种癌细胞系显示出高细胞毒性作用,对正常细胞显示出低毒性。硅分子对接预测HH32和HH33与细胞周期调节因子如CDC2-cyclin B、CDK2-cyclin a复合物和视网膜母细胞瘤的强结合。有趣的是,转录组学分析显示,DNA双链修复和细胞周期是受HH33化合物影响最大的途径。这些发现在体外模型中得到了验证,并证实了HH32和HH33诱导DNA双链断裂和刺激ATM/ATR信号通路。除了HH化合物通过上调周期蛋白依赖性激酶抑制剂和下调G2/M期细胞周期标记物介导的细胞周期进程的强大作用外,G2/M期细胞周期标记物最终使细胞停滞在G2/M期并促进凋亡。综上所述,HH32和HH33化合物对肿瘤细胞的多效生物学作用提示了在临床前模型中评估其抗癌活性的必要性,这可能为潜在治疗药物的开发开辟一个新的领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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