Axotomy induces axonogenesis in hippocampal neurons through STAT3

After axotomy of embryonic hippocampal neurons in vitro, some of the axotomized axons lose their identity, and new axons arise and grow. This axotomy-induced axonogenesis requires importin, suggesting that some injury-induced signals are transported via axons to elicit axonogenesis after axotomy. In this study, we show that STAT3 is activated in response to axotomy. Because STAT3 was co-immunoprecipitated with importin β in the axotomized neurons, we suggest that STAT3 is retrogradely transported as molecular cargo of importin α/β heterodimers. Indeed, inhibition of importin α binding with STAT3 resulted in the attenuation of axonogenesis. Silencing STAT3 blocked the axonogenesis, demonstrating that STAT3 is necessary for axotomy-induced axonogenesis. Furthermore, the overexpression of STAT3 enhanced axotomy-induced axonogenesis. Taken together, these results demonstrate that activation and retrograde transport of STAT3 in injured axons have key roles in the axotomy-induced axonogenesis of hippocampal neurons.     

核蛋白MARVELD1与核质转运受体蛋白Importin β1相互作用的鉴定

核蛋白MARVELD1（MARVEL domain containing 1）是一个在多种肿瘤中表达下调的肿瘤相关基因. 为寻找其相互作用分子,构建pGEX-4T-2/MARVELD1重组体并在大肠杆菌中成功表达GST-MARVELD1融合蛋白. 采用GST pull-down 结合LC-MS/MS（液相色谱-串联质谱）的方法对MARVELD1蛋白的相互作用分子进行筛选,发现了16个与MARVELD1相互结合的蛋白. 进一步的免疫共沉淀实验证实, MARVELD1与核质转运受体蛋白importin β1能够相互作用,说明MARVELD1可能参与了importin β1的部分生物学作用, 或是它通过与importin β1结合而进入细胞核. 研究结果为进一步分析MARVELD1和importin β1的生物学功能奠定了基础.     

The nuclear localization of SET mediated by impalpha3/impbeta attenuates its cytosolic toxicity in neurons

SET is a multi-functional protein in proliferating cells. Some of the proposed functions of SET suggest an important nuclear role. However, the nuclear import pathway of SET is also unknown and the function of SET in neurons is unclear. Presently, using cortical neurons, we report that the nuclear import of SET is mediated by an impalpha/impbeta-dependent pathway. Nuclear localization signal, (168)KRSSQTQNKASRKR(181), in SET interacts with impalpha3, which recruits impbeta to form a ternary complex, resulting in efficient transportation of SET into nucleus. By in vitro nuclear import assay based on digitonin-permeabilized neurons, we further demonstrated that the nuclear import of SET relies on Ran GTPase. We provide evidence that this nuclear localization of SET is important in neuronal survival. Under basal conditions, SET is predominately nuclear. However, upon death induced by genotoxic stress, endogenous SET decreases in the nucleus and increases in the cytoplasm. Consistent with a toxic role of SET in the cytoplasm, targeted expression of SET to the cytoplasm exacerbates death compared to wild type SET expression which is protective following DNA damage. Taken together, our results indicate that SET is imported into the nucleus through its association with impalpha3/impbeta, and that localization of SET is important in regulation of neuronal death.     

Ran及其结合与调控蛋白在核膜装配过程中的调控作用

核膜在细胞周期中呈现高度的动态性：在细胞分裂的前中期,核膜崩解并分散到细胞质中;在细胞分裂的后期,核膜开始在染色体的表面重新装配,最终形成完整的核膜结构。近期的研究发现,Ran GTP酶、物质转运蛋白importinβ、内层核膜蛋白LBR（lamin B receptor）以及核孔复合体蛋白nucleoporins在核膜重建的过程中起关键性调控作用,并受到细胞周期调控因子p34cdc2激酶的调节。LBR是一个八次跨膜的膜蛋白,主要定位于内层核膜。在细胞分裂的早期,随着核膜崩解,LBR与核膜崩解而生成的小膜泡一起分散到细胞质中;在细胞分裂的后期,通过LBR与importinβ相互结合,含有LBR的膜泡被importinβ携带至染色质的表面参与核膜重建。目前已知p34cdc2激酶对LBR与importinβ介导的核膜重建起重要调控作用。Nucleoporins是核孔复合体主要组分。随核膜崩解,核孔复合体解聚成nucleoporins,分散到细胞质中,或结合到其他亚细胞成分上。细胞分裂后期,核孔复合体伴随核膜装配而组装。     

Dissecting the roles of Cse1 and Nup2 in classical NLS‐cargo release in vivo

The importin α/β transport machinery mediates the nuclear import of cargo proteins that bear a classical nuclear localization sequence (cNLS). These cargo proteins are linked to the major nuclear protein import factor, importin‐β, by the importin‐α adapter, after which cargo/carrier complexes enter the nucleus through nuclear pores. In the nucleus, cargo is released by the action of RanGTP and the nuclear pore protein Nup2, after which the importins are recycled to the cytoplasm for further transport cycles. The nuclear export of importin‐α is mediated by Cse1/CAS. Here, we exploit structures of functionally important complexes to identify residues that are critical for these interactions and provide insight into how cycles of protein import and recycling of importin‐α occur in vivo using a Saccharomyces cerevisiae model. We examine how these molecular interactions impact protein localization, cargo import, function and complex formation. We show that reversing the charge of key residues in importin‐α (Arg44) or Cse1 (Asp220) results in loss of function of the respective proteins and impairs complex formation both in vitro and in vivo. To extend these results, we show that basic residues in the Nup2 N‐terminus are required for both Nup2 interaction with importin‐α and Nup2 function. These results provide a more comprehensive mechanistic model of how Cse1, RanGTP and Nup2 function in concert to mediate cNLS‐cargo release in the nucleus.     

植物中的核质转运相关蛋白

细胞内各个生命过程的有序进行需要生物大分子在细胞核与细胞质之间有选择、有控制地转运.而细胞核膜的存在为大分子的自由穿梭设置了屏障,因此生物大分子在细胞核与细胞质之间的转运要依赖于一些受体蛋白.输入蛋白β(importinβ)是首先从人类细胞中发现的生物大分子向细胞核输入的受体,其后相继鉴定出多个与输入蛋白β具有同源性的细胞核转运受体,命名为类输入蛋白β.这些转运受体介导的转运过程在生物有机体之间高度保守,在动物及酵母中调控核质穿梭以及各个信号过程的组分与分子机制研究较为清楚,但在植物中相对匮乏.本文在介绍细胞核转运受体共有结构特点和转运机制基础上,重点综述了植物细胞核转运受体的最新研究进展以及这些受体在植物信号转导中的重要调节作用.