Verboon Jeffrey M, Rincon-Arano Hector, Werwie Timothy R, Delrow Jeffrey J, Scalzo David, Nandakumar Vivek, Groudine Mark, Parkhurst Susan M
Basic Sciences Division, Fred Hutchinson Cancer Research Center, Seattle, WA 98109, USA.
Genomics Resource, Fred Hutchinson Cancer Research Center, Seattle, WA 98109, USA.
Curr Biol. 2015 Mar 16;25(6):804-810. doi: 10.1016/j.cub.2015.01.052. Epub 2015 Mar 5.
The cytoplasmic functions of Wiskott-Aldrich syndrome family (WAS) proteins are well established and include roles in cytoskeleton reorganization and membrane-cytoskeletal interactions important for membrane/vesicle trafficking, morphogenesis, immune response, and signal transduction. Misregulation of these proteins is associated with immune deficiency and metastasis [1-4]. Cytoplasmic WAS proteins act as effectors of Rho family GTPases and polymerize branched actin through the Arp2/3 complex [1, 5]. Previously, we identified Drosophila washout (wash) as a new member of the WAS family with essential cytoplasmic roles in early development [6, 7]. Studies in mammalian cells and Dictyostelium suggest that WASH functions primarily in a multiprotein complex that regulates endosome shape and trafficking in an Arp2/3-dependent manner [8-11]. However, roles for classically cytoplasmic proteins in the nucleus are beginning to emerge, in particular, as participants in the regulation of gene expression [12, 13]. Here, we show that Drosophila Wash is present in the nucleus, where it plays a key role in global nuclear organization. wash mutant and knockdown nuclei disrupt subnuclear structures/organelles and exhibit the abnormal wrinkled morphology reminiscent of those observed in diverse laminopathies [14-16]. We find that nuclear Wash interacts with B-type Lamin (Lamin Dm0), and, like Lamin, Wash associates with constitutive heterochromatin. Wash knockdown increases chromatin accessibility of repressive compartments and results in a global redistribution of repressive histone modifications. Thus, our results reveal a novel role for Wash in modulating nucleus morphology and in the organization of both chromatin and non-chromatin nuclear sub-structures.
威斯科特-奥尔德里奇综合征家族(WAS)蛋白的细胞质功能已得到充分证实,包括在细胞骨架重组以及膜-细胞骨架相互作用中发挥作用,这些作用对于膜/囊泡运输、形态发生、免疫反应和信号转导至关重要。这些蛋白的失调与免疫缺陷和转移相关[1-4]。细胞质中的WAS蛋白作为Rho家族GTP酶的效应器,通过Arp2/3复合体聚合分支肌动蛋白[1,5]。此前,我们鉴定出果蝇的washout(wash)是WAS家族的一个新成员,在早期发育中具有重要的细胞质作用[6,7]。在哺乳动物细胞和盘基网柄菌中的研究表明,WASH主要在一个多蛋白复合体中发挥作用,该复合体以Arp2/3依赖的方式调节内体的形状和运输[8-11]。然而,经典的细胞质蛋白在细胞核中的作用正开始显现,特别是作为基因表达调控的参与者[12,13]。在这里,我们表明果蝇的Wash存在于细胞核中,在全局核组织中发挥关键作用。wash突变体和敲低细胞核会破坏亚核结构/细胞器,并呈现出异常的皱缩形态,这让人联想到在多种核纤层病中观察到的形态[14-16]。我们发现核内的Wash与B型核纤层蛋白(核纤层蛋白Dm0)相互作用,并且与核纤层蛋白一样,Wash与组成型异染色质相关联。Wash敲低会增加抑制性区域的染色质可及性,并导致抑制性组蛋白修饰的全局重新分布。因此,我们的结果揭示了Wash在调节细胞核形态以及染色质和非染色质核亚结构组织方面的新作用。