Horvath Monica M, Wang Xuting, Resnick Michael A, Bell Douglas A
Laboratory of Molecular Genetics, National Institute of Environmental Health Sciences, Research Triangle Park, North Carolina, United States of America.
PLoS Genet. 2007 Jul;3(7):e127. doi: 10.1371/journal.pgen.0030127. Epub 2007 Jun 15.
The p53 tumor suppressor is a sequence-specific pleiotropic transcription factor that coordinates cellular responses to DNA damage and stress, initiating cell-cycle arrest or triggering apoptosis. Although the human p53 binding site sequence (or response element [RE]) is well characterized, some genes have consensus-poor REs that are nevertheless both necessary and sufficient for transactivation by p53. Identification of new functional gene regulatory elements under these conditions is problematic, and evolutionary conservation is often employed. We evaluated the comparative genomics approach for assessing evolutionary conservation of putative binding sites by examining conservation of 83 experimentally validated human p53 REs against mouse, rat, rabbit, and dog genomes and detected pronounced conservation differences among p53 REs and p53-regulated pathways. Bona fide NRF2 (nuclear factor [erythroid-derived 2]-like 2 nuclear factor) and NFkappaB (nuclear factor of kappa light chain gene enhancer in B cells) binding sites, which direct oxidative stress and innate immunity responses, were used as controls, and both exhibited high interspecific conservation. Surprisingly, the average p53 RE was not significantly more conserved than background genomic sequence, and p53 REs in apoptosis genes as a group showed very little conservation. The common bioinformatics practice of filtering RE predictions by 80% rodent sequence identity would not only give a false positive rate of approximately 19%, but miss up to 57% of true p53 REs. Examination of interspecific DNA base substitutions as a function of position in the p53 consensus sequence reveals an unexpected excess of diversity in apoptosis-regulating REs versus cell-cycle controlling REs (rodent comparisons: p < 1.0 e-12). While some p53 REs show relatively high levels of conservation, REs in many genes such as BAX, FAS, PCNA, CASP6, SIVA1, and P53AIP1 show little if any homology to rodent sequences. This difference suggests that among mammalian species, evolutionary conservation differs among p53 REs, with some having ancient ancestry and others of more recent origin. Overall our results reveal divergent evolutionary pressure among the binding targets of p53 and emphasize that comparative genomics methods must be used judiciously and tailored to the evolutionary history of the targeted functional regulatory regions.
p53肿瘤抑制因子是一种序列特异性的多效转录因子,可协调细胞对DNA损伤和应激的反应,启动细胞周期停滞或触发细胞凋亡。尽管人类p53结合位点序列(或反应元件[RE])已得到充分表征,但一些基因具有一致性较差的RE,然而这些RE对于p53的反式激活既必要又充分。在这些条件下鉴定新的功能性基因调控元件存在问题,因此常采用进化保守性分析。我们通过检查83个经实验验证的人类p53 RE与小鼠、大鼠、兔子和狗基因组的保守性,评估了用于评估假定结合位点进化保守性的比较基因组学方法,并检测到p53 RE和p53调控途径之间存在明显的保守性差异。作为对照,使用了指导氧化应激和先天免疫反应的真正的NRF2(核因子[红细胞衍生2]样2核因子)和NFκB(B细胞中κ轻链基因增强子的核因子)结合位点,两者均表现出高度的种间保守性。令人惊讶的是,p53 RE的平均保守性并不比背景基因组序列显著更高,并且凋亡基因中的p53 RE作为一个整体显示出很少的保守性。通过80%的啮齿动物序列同一性过滤RE预测的常见生物信息学方法不仅会产生约19%的假阳性率,而且会遗漏高达57%的真实p53 RE。检查种间DNA碱基替换作为p53共有序列中位置的函数,发现凋亡调节RE与细胞周期控制RE相比存在意外的多样性过剩(啮齿动物比较:p < 1.0 e-12)。虽然一些p53 RE显示出相对较高的保守水平,但许多基因(如BAX、FAS、PCNA、CASP6、SIVA1和P53AIP1)中的RE与啮齿动物序列几乎没有同源性。这种差异表明,在哺乳动物物种中,p53 RE的进化保守性不同,有些具有古老的起源,而另一些则起源较新。总体而言,我们的结果揭示了p53结合靶点之间不同的进化压力,并强调必须谨慎使用比较基因组学方法,并根据靶向功能调控区域的进化历史进行调整。
