Myc-Max干扰剂10058-F4 [Z,E]-5-[4-乙基亚苄基]-2-硫代噻唑烷-4-酮在小鼠体内的疗效、药代动力学、组织分布及代谢
Efficacy, pharmacokinetics, tisssue distribution, and metabolism of the Myc-Max disruptor, 10058-F4 [Z,E]-5-[4-ethylbenzylidine]-2-thioxothiazolidin-4-one, in mice.
作者信息
Guo Jianxia, Parise Robert A, Joseph Erin, Egorin Merrill J, Lazo John S, Prochownik Edward V, Eiseman Julie L
机构信息
Hillman Cancer Center, The University of Pittsburgh Cancer Institute, Pittsburgh, PA 15213, USA.
出版信息
Cancer Chemother Pharmacol. 2009 Mar;63(4):615-25. doi: 10.1007/s00280-008-0774-y. Epub 2008 May 29.
OBJECTIVES
c-Myc is commonly activated in many human tumors and is functionally important in cellular proliferation, differentiation, apoptosis and cell cycle progression. The activity of c-Myc requires noncovalent interaction with its client protein Max. In vitro studies indicate the thioxothiazolidinone, 10058-F4, inhibits c-Myc/Max dimerization. In this study, we report the efficacy, pharmacokinetics and metabolism of this novel protein-protein disruptor in mice.
METHODS
SCID mice bearing DU145 or PC-3 human prostate cancer xenografts were treated with either 20 or 30 mg/kg 10058-F4 on a qdx5 schedule for 2 weeks for efficacy studies. For pharmacokinetics and metabolism studies, mice bearing PC-3 or DU145 xenografts were treated with 20 mg/kg of 10058-F4 i.v. Plasma and tissues were collected 5-1440 min after dosing. The concentration of 10058-F4 in plasma and tissues was determined by HPLC, and metabolites were characterized by LC-MS/MS.
RESULTS
Following a single iv dose, peak plasma 10058-F4 concentrations of approximately 300 muM were seen at 5 min and declined to below the detection limit at 360 min. Plasma concentration versus time data were best approximated by a two-compartment, open, linear model. The highest tissue concentrations of 10058-F4 were found in fat, lung, liver, and kidney. Peak tumor concentrations of 10058-F4 were at least tenfold lower than peak plasma concentrations. Eight metabolites of 10058-F4 were identified in plasma, liver, and kidney. The terminal half-life of 10058-F4 was approximately 1 h, and the volume of distribution was >200 ml/kg. No significant inhibition of tumor growth was seen after i.v. treatment of mice with either 20 or 30 mg/kg 10058-F4.
CONCLUSION
The lack of significant antitumor activity of 10058-F4 in tumor-bearing mice may have resulted from its rapid metabolism and low concentration in tumors.
目的
c-Myc在许多人类肿瘤中通常被激活,在细胞增殖、分化、凋亡和细胞周期进程中具有重要功能。c-Myc的活性需要与其客户蛋白Max进行非共价相互作用。体外研究表明,硫代噻唑烷酮10058-F4可抑制c-Myc/Max二聚化。在本研究中,我们报告了这种新型蛋白质-蛋白质破坏剂在小鼠体内的疗效、药代动力学和代谢情况。
方法
对携带DU145或PC-3人前列腺癌异种移植瘤的SCID小鼠,按qdx5方案给予20或30mg/kg的10058-F4治疗2周,以进行疗效研究。对于药代动力学和代谢研究,对携带PC-3或DU145异种移植瘤的小鼠静脉注射20mg/kg的10058-F4。给药后5-1440分钟收集血浆和组织。通过高效液相色谱法测定血浆和组织中10058-F4的浓度,并用液相色谱-串联质谱法对代谢产物进行表征。
结果
单次静脉给药后,在5分钟时血浆中10058-F4的峰值浓度约为300μM,在360分钟时降至检测限以下。血浆浓度与时间数据最适合用二室开放线性模型来近似。10058-F4在脂肪、肺、肝和肾中的组织浓度最高。10058-F4在肿瘤中的峰值浓度比血浆峰值浓度至少低十倍。在血浆、肝脏和肾脏中鉴定出了10058-F4的八种代谢产物。10058-F4的终末半衰期约为1小时,分布容积>200ml/kg。用20或30mg/kg的10058-F4静脉注射治疗小鼠后,未观察到对肿瘤生长的显著抑制作用。
结论
10058-F4在荷瘤小鼠中缺乏显著的抗肿瘤活性,可能是由于其快速代谢和在肿瘤中的低浓度所致。
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