Molecular Cancer Research Group, Institute of Medical Biology, University of Tromsø, 9037 Tromso, Norway.
Cell Mol Life Sci. 2010 Dec;67(23):4079-94. doi: 10.1007/s00018-010-0429-0. Epub 2010 Jun 25.
The transcription factor Pax6 is crucial for the embryogenesis of multiple organs, including the eyes, parts of the brain and the pancreas. Mutations in one allele of PAX6 lead to eye diseases including Peter's anomaly and aniridia. Here, we use fluorescence recovery after photobleaching to show that Pax6 and also other Pax family proteins display a strikingly low nuclear mobility compared to other transcriptional regulators. For Pax6, the slow mobility is largely due to the presence of two DNA-binding domains, but protein-protein interactions also contribute. Consistently, the subnuclear localization of Pax6 suggests that it interacts preferentially with chromatin-rich territories. Some aniridia-causing missense mutations in Pax6 have impaired DNA-binding affinity. Interestingly, when these mutants were analyzed by FRAP, they displayed a pronounced increased mobility compared to wild-type Pax6. Hence, our results support the conclusion that disease mutations result in proteins with impaired function because of altered DNA- and protein-interaction capabilities.
转录因子 Pax6 对于包括眼睛、大脑部分和胰腺在内的多种器官的胚胎发生至关重要。PAX6 基因的一个等位基因突变会导致包括 Peter 异常和无虹膜症在内的眼部疾病。在这里,我们使用光漂白后荧光恢复(fluorescence recovery after photobleaching)来表明 Pax6 以及其他 Pax 家族蛋白的核流动性与其他转录调节剂相比非常低。对于 Pax6 而言,这种缓慢的流动性主要是由于存在两个 DNA 结合结构域,但蛋白-蛋白相互作用也有贡献。一致地,Pax6 的亚核定位表明它优先与富含染色质的区域相互作用。一些导致无虹膜症的 Pax6 错义突变会损害 DNA 结合亲和力。有趣的是,当通过 FRAP 分析这些突变体时,它们与野生型 Pax6 相比表现出明显增加的流动性。因此,我们的结果支持这样的结论,即疾病突变导致蛋白质功能受损,因为其 DNA 和蛋白相互作用能力发生改变。