Zhong Hanbing, Xin Shengchang, Zhao Yanqiu, Lu Jing, Li Song, Gong Jianxian, Yang Zhen, Lin Shuo
Laboratory of Chemical Genomics, School of Chemical Biology and Biotechnology, Shenzhen Graduate School of Peking University, Shenzhen University Town, Shenzhen, China.
Mol Biosyst. 2010 Aug;6(8):1463-8. doi: 10.1039/b919743e. Epub 2010 May 19.
During the preclinical drug discovery process it remains a challenge to enable early elimination of candidate molecules that may have non-specific, off-target activities. Here, we use whole zebrafish embryo assays coupled with genetic analysis to address this issue. PLK1 (Polo-like kinase 1) is one of the key regulators that control mitotic entry, spindle assembly, chromosome segregation, and cytokinesis in the cell cycle. Since plk1 expression is abnormally up-regulated in several tumors, it is regarded as a good target for cancer therapy. A number of small-molecule inhibitors targeting PLK1 have been developed as reagents and anticancer drug candidates. It will be interesting to determine if these inhibitors indeed specifically target PLK1 in vivo. Bioinformatics analysis revealed that the zebrafish and human genomes share high homology across all PLK family members. In particular, PLK1 has a nearly identical 3-D structure between zebrafish and human. We selected three published PLK1 inhibitors, LFM-A13, ON01910, and thiazole-carboxamide 10A in our assay. When added at 2-cell stage, all of these inhibitors prevented embryos from dividing and caused cells to fuse into one large cell. When added at the later stage during zygotic mRNA transcription program initiation, embryos survived for 3 days but showed different phenotypes for each compound. Embryos treated with LFM-A13 appeared relatively normal. Embryos treated with ON01910 failed to properly develop trunk and tail regions while the head structure was unaffected. Embryos treated with thiazole-carboxamide 10A had a shorter body axis and deformed head structure. To determine which inhibitor is more selectively targeting PLK1, we inhibited PLK1 activity using anti-sense morpholino. Comparative analysis indicated that thiazole-carboxamide 10A could faithfully phenocopy zebrafish embryos genetically deficient of plk1. These findings demonstrate that these three PLK1 inhibitors, although well established by in vitro studies, have different off-target activities in vivo, and that thiazole-carboxamide 10A appears most specific to PLK1. Our studies suggest that zebrafish should be generally useful as an efficient in vivo model to evaluate specificity of small molecules designed to regulate any conserved target proteins through comparative analysis of genetic phenotypes.
在临床前药物发现过程中,早期排除可能具有非特异性脱靶活性的候选分子仍然是一项挑战。在此,我们使用全斑马鱼胚胎试验结合遗传分析来解决这个问题。PLK1(波罗样激酶1)是细胞周期中控制有丝分裂进入、纺锤体组装、染色体分离和胞质分裂的关键调节因子之一。由于plk1在多种肿瘤中表达异常上调,它被视为癌症治疗的一个良好靶点。许多靶向PLK1的小分子抑制剂已被开发为试剂和抗癌药物候选物。确定这些抑制剂在体内是否确实特异性靶向PLK1将是很有趣的。生物信息学分析表明,斑马鱼和人类基因组在所有PLK家族成员中具有高度同源性。特别是,PLK1在斑马鱼和人类之间具有几乎相同的三维结构。我们在试验中选择了三种已发表的PLK1抑制剂,LFM-A13、ON01910和噻唑甲酰胺10A。在2细胞期添加时,所有这些抑制剂都阻止胚胎分裂并导致细胞融合成一个大细胞。在合子mRNA转录程序启动的后期添加时,胚胎存活3天,但每种化合物表现出不同的表型。用LFM-A13处理的胚胎看起来相对正常。用ON01910处理的胚胎未能正常发育躯干和尾部区域,而头部结构未受影响。用噻唑甲酰胺10A处理的胚胎身体轴较短且头部结构变形。为了确定哪种抑制剂更具选择性地靶向PLK1,我们使用反义吗啉代抑制PLK1活性。比较分析表明,噻唑甲酰胺10A可以忠实地模拟plk1基因缺陷的斑马鱼胚胎。这些发现表明,这三种PLK1抑制剂虽然在体外研究中已得到充分证实,但在体内具有不同的脱靶活性,并且噻唑甲酰胺10A似乎对PLK1最具特异性。我们的研究表明,通过对遗传表型的比较分析,斑马鱼通常可作为一种有效的体内模型来评估旨在调节任何保守靶蛋白的小分子的特异性。
