RNA聚合酶Ⅱ转录延伸因子

当RNA聚合酶Ⅱ(RNAPⅡ)离开启动子开始转录延伸时,会遇到包括紧密包装形成染色质的核小体在内的多种障碍,细胞内存在多种因子可协助RNAPⅡ克服这些障碍,保证转录的顺利进行。遗传和生化研究已经分离和鉴定了一些在此过程中起作用的延伸因子(elongation factor),现依据作用方式和效果对目前发现的主要延伸因子的研究进展进行了分类综述。     

Human GTPases Associate with RNA Polymerase II To Mediate Its Nuclear Import

Small GTPases share a biochemical mechanism and act as binary molecular switches. One important function of small GTPases in the cell is nucleocytoplasmic transport of both proteins and RNA. Here, we show the stable association of human GPN1 and GPN3, small GTPases related to Ran, with RNA polymerase II (RNAPII) isolated from either the cytoplasmic or nuclear fraction. GPN1 and GPN3 directly interact with RNAPII subunit 7 (RPB7)/RPB4 and the C-terminal domain (CTD) of RNAPII. Depletion of GPN1 or GPN3 using small interfering RNAs led to decreased RNAPII levels in the nucleus and an accumulation of this enzyme in the cytoplasm of human cells. Furthermore, isolation of a GPN1/GPN3/RNAPII complex from stable cell lines expressing a dominant negative GPN1 harboring mutations in the GTP-binding pocket demonstrated a role for these proteins in nuclear import of RNAPII. Thus, GPN1/GPN3 define a new family of small GTPases that are specialized for the transport of RNA polymerase II into the nucleus.     

神经胶质瘤中前体mRNA可变剪接研究进展

胶质瘤是最常见的脑肿瘤,前体mRNA可变剪接可能在不同类型胶质瘤的发生、恶化以及侵入中发挥作用.参与调控胶质瘤中前体mRNA可变剪接的因素包括顺式元件如内含子剪接抑制序列(ISS)、外显子剪接抑制序列(ESS)等,反式因子包括SRp55、SC35、SF2/ASF、PTB等剪接调节因子.近期的研究进展发现,有多种与胶质瘤相关的基因受到可变剪接的调控,包括肿瘤抑制因子、肿瘤促进因子、酶、受体、离子通道等.因此,研究胶质瘤中的前体mRNA可变剪接将有利于深入了解胶质瘤发生的分子机制、有利于为胶质瘤的早期诊断和治疗提供新的潜在靶点.     

表观遗传因素在RNA剪接过程中的作用

RNA剪接是真核生物基因表达过程中的重要环节,增加了蛋白质的多样性和基因表达的可调节性. 日益增多的研究表明,RNA剪接并不是独立的生物过程.RNA Ⅱ型聚合酶(RNA polymerase-Ⅱ, RNA Pol Ⅱ)、核小体定位和组蛋白修饰等因素都与RNA剪接过程密切相关.阐明RNA Pol Ⅱ、核小体定位和组蛋白修饰等因素在RNA剪接过程中的作用,将为剪接位点的准确识别和剪接调控机制的研究提供新思路.本文综述了RNA Pol Ⅱ、核小体定位和组蛋白修饰等因素对RNA剪接的影响以及它们在RNA剪接过程中的调控作用.     

Pre-mRNA选择性剪接的调控及选择性剪接数据库

Pre-mRNA选择性剪接是真核生物转录组和蛋白质组多样性的主要来源,也是细胞分化、发育等过程中重要的基因表达调控方式。约95%的人类多外显子基因存在RNA选择性剪接|很多人类基因疾病的发生与RNA剪接错误相关。随着共转录现象的发现,RNA选择性剪接调控机制研究也取得了很大进展。本文分别从序列层面和核小体定位、组蛋白修饰、DNA甲基化及非编码RNA等表观遗传层面,系统地阐述了RNA选择性剪接的调控机制。为便于搜索,本文介绍了近10年来RNA选择性剪接相关的数据库。     

Unexpected Role of the Steroid-Deficiency Protein Ecdysoneless in Pre-mRNA Splicing

The steroid hormone ecdysone coordinates insect growth and development, directing the major postembryonic transition of forms, metamorphosis. The steroid-deficient ecdysoneless¹ (ecd¹) strain of Drosophila melanogaster has long served to assess the impact of ecdysone on gene regulation, morphogenesis, or reproduction. However, ecd also exerts cell-autonomous effects independently of the hormone, and mammalian Ecd homologs have been implicated in cell cycle regulation and cancer. Why the Drosophila ecd¹ mutants lack ecdysone has not been resolved. Here, we show that in Drosophila cells, Ecd directly interacts with core components of the U5 snRNP spliceosomal complex, including the conserved Prp8 protein. In accord with a function in pre-mRNA splicing, Ecd and Prp8 are cell-autonomously required for survival of proliferating cells within the larval imaginal discs. In the steroidogenic prothoracic gland, loss of Ecd or Prp8 prevents splicing of a large intron from CYP307A2/spookier (spok) pre-mRNA, thus eliminating this essential ecdysone-biosynthetic enzyme and blocking the entry to metamorphosis. Human Ecd (hEcd) can substitute for its missing fly ortholog. When expressed in the Ecd-deficient prothoracic gland, hEcd re-establishes spok pre-mRNA splicing and protein expression, restoring ecdysone synthesis and normal development. Our work identifies Ecd as a novel pre-mRNA splicing factor whose function has been conserved in its human counterpart. Whether the role of mammalian Ecd in cancer involves pre-mRNA splicing remains to be discovered.     

Cyclin E Associates with Components of the Pre-mRNA Splicing Machinery in Mammalian Cells

Cyclin E-cdk2 is a critical regulator of cell cycle progression from G₁ into S phase in mammalian cells. Despite this important function little is known about the downstream targets of this cyclin-kinase complex. Here we have identified components of the pre-mRNA processing machinery as potential targets of cyclin E-cdk2. Cyclin E-specific antibodies coprecipitated a number of cyclin E-associated proteins from cell lysates, among which are the spliceosome-associated proteins, SAP 114, SAP 145, and SAP 155, as well as the snRNP core proteins B′ and B. The three SAPs are all subunits of the essential splicing factor SF3, a component of U2 snRNP. Cyclin E antibodies also specifically immunoprecipitated U2 snRNA and the spliceosome from splicing extracts. We demonstrate that SAP 155 serves as a substrate for cyclin E-cdk2 in vitro and that its phosphorylation in the cyclin E complex can be inhibited by the cdk-specific inhibitor p21. SAP 155 contains numerous cdk consensus phosphorylation sites in its N terminus and is phosphorylated prior to catalytic step II of the splicing pathway, suggesting a potential role for cdk regulation. These findings provide evidence that pre-mRNA splicing may be linked to the cell cycle machinery in mammalian cells.