Leong Chee Onn, Suggitt Marie, Swaine David J, Bibby Michael C, Stevens Malcolm F G, Bradshaw Tracey D
Centre for Biomolecular Sciences, School of Pharmacy, University of Nottingham, Nottingham, United Kingdom.
Mol Cancer Ther. 2004 Dec;3(12):1565-75.
Phortress is a novel, potent, and selective experimental antitumor agent. Its mechanism of action involves induction of CYP1A1-catalyzed biotransformation of 2-(4-amino-3-methylphenyl)-5-fluorobenzothiazole (5F 203) to generate electrophilic species, which covalently bind to DNA, exacting lethal damage to sensitive tumor cells, in vitro and in vivo. Herein, we investigate the effects of DNA adduct formation on cellular DNA integrity and progression through cell cycle and examine whether a relevant pharmacodynamic end point may be exploited to probe the clinical mechanism of action of Phortress and predict tumor response. Single cell gel electrophoresis (SCGE) was applied to quantify DNA damage and cell cycle analyses conducted upon 5F 203 treatment of benzothiazole-sensitive MCF-7 and inherently resistant MDA-MB-435 breast carcinoma cells. Following treatment of xenograft-bearing mice and mice possessing hollow fiber implants containing MCF-7 or MDA-MB-435 cells with Phortress (20 mg/kg, i.p., 24 hours), tumor cells and xenografts were recovered for analyses by SCGE. Dose- and time-dependent DNA single and double strand breaks occurred exclusively in sensitive cells following treatment with 5F 203 in vitro (10 nmol/L-10 micromol/L; 24-72 hours). In vivo, Phortress-sensitive and Phortress-resistant tumor cells were distinct; moreover, DNA damage in xenografts, following treatment of mice with Phortress, could be determined. Interrogation of the mechanism of action of 5F 203 in silico by self-organizing map-based cluster analyses revealed modulation of phosphatases and kinases associated with cell cycle regulation, corroborating observations of selective cell cycle perturbation by 5F 203 in sensitive cells. By conducting SCGE, tumor sensitivity to Phortress, an agent currently undergoing clinical evaluation, may be determined.
福瑞司是一种新型、高效且具有选择性的实验性抗肿瘤药物。其作用机制包括诱导细胞色素P450 1A1(CYP1A1)催化2-(4-氨基-3-甲基苯基)-5-氟苯并噻唑(5F 203)进行生物转化,生成亲电物质,这些亲电物质与DNA共价结合,在体外和体内对敏感肿瘤细胞造成致命损伤。在此,我们研究DNA加合物形成对细胞DNA完整性和细胞周期进程的影响,并考察是否可以利用相关的药效学终点来探究福瑞司的临床作用机制并预测肿瘤反应。应用单细胞凝胶电泳(SCGE)来量化DNA损伤,并在5F 203处理苯并噻唑敏感的MCF-7和固有耐药的MDA-MB-435乳腺癌细胞后进行细胞周期分析。在用福瑞司(20 mg/kg,腹腔注射,24小时)处理携带异种移植瘤的小鼠以及植入含有MCF-7或MDA-MB-435细胞的中空纤维的小鼠后,回收肿瘤细胞和异种移植瘤,通过SCGE进行分析。体外在用5F 203(10 nmol/L - 10 μmol/L;24 - 72小时)处理后,剂量和时间依赖性的DNA单链和双链断裂仅在敏感细胞中出现。在体内,对福瑞司敏感和耐药的肿瘤细胞有所不同;此外,在用福瑞司处理小鼠后,异种移植瘤中的DNA损伤可以被测定。通过基于自组织映射的聚类分析在计算机上探究5F 203的作用机制,揭示了与细胞周期调控相关的磷酸酶和激酶的调节,证实了5F 203在敏感细胞中对细胞周期的选择性扰动。通过进行SCGE,可以确定肿瘤对目前正在进行临床评估的药物福瑞司的敏感性。
