Huang Nancy N, Hunter Craig P
Molecular Biology Department, Colorado College, Colorado Springs, CO 80903, USA.
Department of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138, USA.
Gene. 2015 Jan 10;554(2):160-73. doi: 10.1016/j.gene.2014.10.042. Epub 2014 Oct 28.
The RNA binding protein MEX-3 is required to restrict translation of pal-1, the Caenorhabditis elegans caudal homolog, to the posterior of the early embryo. MEX-3 is present uniformly throughout the newly fertilized embryo, but becomes depleted in the posterior by the 4-cell stage. This MEX-3 patterning requires the CCCH zinc-finger protein MEX-5, the RNA Recognition Motif protein SPN-4, and the kinase PAR-4. Genetic and biochemical evidence suggests that MEX-5 binds to MEX-3 in the anterior of the embryo, protecting MEX-3 from degradation and allowing it to bind the pal-1 3'UTR and repress translation. MEX-3 that is not bound to MEX-5 becomes inactivated by par-4, then targeted for spn-4 dependent degradation. After the 4-cell stage, residual MEX-3 is degraded in somatic cells, and only persists in the germline precursors. To better understand regulation of mex-3, GFP was fused to MEX-3 or regions of MEX-3 and expressed in developing oocytes. GFP::MEX-3 expressed in this manner can replace endogenous MEX-3, but surprisingly is not asymmetrically localized at the 4-cell stage. These results indicate that GFP::MEX-3 retains asymmetric activity even in the absence of asymmetric protein localization. Neither the mex-3 3'UTR nor protein degradation at the 4-cell stage is strictly required. A region of MEX-3 containing a glutamine-rich region and potential ubiquitination and phosphorylation sites is sufficient for soma-germline asymmetry. Results from mex-5/6 and spn-4(RNAi) suggest two pathways for MEX-3 degradation, an early spn-4 dependent pathway and a later spn-4 independent pathway. These results indicate that mex-3 activity is regulated at multiple levels, leading to rapid and robust regulation in the quickly developing early embryo.
RNA结合蛋白MEX-3是将秀丽隐杆线虫尾部同源物pal-1的翻译限制在早期胚胎后部所必需的。MEX-3在新受精的胚胎中均匀存在,但在4细胞阶段时在后部耗尽。这种MEX-3的模式形成需要CCCH锌指蛋白MEX-5、RNA识别基序蛋白SPN-4和激酶PAR-4。遗传和生化证据表明,MEX-5在胚胎前部与MEX-3结合,保护MEX-3不被降解,并使其能够结合pal-1 3'UTR并抑制翻译。未与MEX-5结合的MEX-3会被par-4失活,然后被靶向进行spn-4依赖性降解。在4细胞阶段之后,残留的MEX-3在体细胞中被降解,仅在生殖系前体中持续存在。为了更好地理解mex-3的调控,绿色荧光蛋白(GFP)与MEX-3或MEX-3的区域融合,并在发育中的卵母细胞中表达。以这种方式表达的GFP::MEX-3可以替代内源性MEX-3,但令人惊讶的是,它在4细胞阶段并没有不对称定位。这些结果表明,即使在没有不对称蛋白质定位的情况下,GFP::MEX-3仍保留不对称活性。4细胞阶段的mex-3 3'UTR和蛋白质降解都不是严格必需的。MEX-3的一个包含富含谷氨酰胺区域以及潜在泛素化和磷酸化位点的区域足以实现体细胞-生殖系不对称。mex-5/6和spn-4(RNA干扰)的结果表明了MEX-3降解的两条途径,一条早期的spn-4依赖性途径和一条后期的spn-4非依赖性途径。这些结果表明,mex-3的活性在多个水平上受到调控,从而在快速发育的早期胚胎中实现快速而稳健的调控。
