Pharmaceutical Chemistry Department, Faculty of Pharmacy, Menoufia University, Menoufia, Egypt.
Pharmaceutical Organic Chemistry Department, Faculty of Pharmacy, Cairo University, Cairo, Egypt.
Drug Dev Res. 2022 Aug;83(5):1075-1096. doi: 10.1002/ddr.21934. Epub 2022 Mar 14.
New cytotoxic agents based on benzothienopyrimidine scaffold were designed, synthesized, and evaluated against the MCF-7 breast cancer line in comparison to erlotinib and letrozole as reference drugs. Eight compounds demonstrated up to 20-fold higher anticancer activity than erlotinib, and five of these compounds were up to 11-fold more potent than letrozole in MTT assay. The most promising compounds were evaluated for their inhibitory activity against EGFR and ARO enzymes. Compound 12, which demonstrated potent dual EGFR and ARO inhibitory activity with IC of 0.045 and 0.146 µM, respectively, was further evaluated for caspase-9 activation, cell cycle analysis, and apoptosis. The results revealed that the tested compound 12 remarkably induced caspase-9 activation (IC = 16.29 ng/ml) caused cell cycle arrest at the pre-G /G phase and significantly increased the concentration of cells at both early and late stage of apoptosis. In addition, it showed a higher safety profile on normal MCF-10A cells, and higher antiproliferative activity on cancer cells (IC = 8.15 µM) in comparison to normal cells (IC = 41.20 µM). It also revealed a fivefold higher selectivity index than erlotinib towards MCF-7 cancer cells. Docking studies were performed to rationalize the dual inhibitory activity of compound 12.
基于苯并噻吩嘧啶骨架的新型细胞毒性药物被设计、合成,并与厄洛替尼和来曲唑作为参考药物进行了 MCF-7 乳腺癌细胞系的活性比较。8 种化合物的抗癌活性比厄洛替尼高 20 倍,其中 5 种化合物在 MTT 测定中比来曲唑的活性高 11 倍。最有前途的化合物被评估了对 EGFR 和 ARO 酶的抑制活性。化合物 12 对 EGFR 和 ARO 具有双重抑制活性,IC 分别为 0.045 和 0.146 μM,进一步评估了其 caspase-9 激活、细胞周期分析和细胞凋亡的能力。结果表明,测试化合物 12 显著诱导 caspase-9 激活(IC 为 16.29ng/ml),导致细胞周期停滞在 G0/G1 期,并显著增加了早晚期凋亡细胞的浓度。此外,与正常 MCF-10A 细胞相比,它在正常细胞(IC 为 41.20 μM)上显示出更高的安全性和对癌细胞(IC 为 8.15 μM)的更高的增殖抑制活性。与厄洛替尼相比,它对 MCF-7 癌细胞的选择性指数也高了 5 倍。进行了对接研究,以合理化化合物 12 的双重抑制活性。
