雌激素受体2（ESR2）mRNA 5′非翻译区内部核糖体进入位点活性的鉴定与分析

真核生物除了传统的帽依赖型翻译机制外,还存在内部核糖体进入位点（internal ribosome entry site, IRES）介导的翻译机制。雌激素受体2（estrogen receptor 2, ESR2）是雌激素受体家族成员之一,其编码的蛋白质在许多肿瘤中发挥重要的作用。ESR2蛋白的异常表达会导致众多肿瘤的发生,但其蛋白质翻译水平的调控机制至今仍不清楚。研究发现,在药物刺激的条件下,乳腺癌细胞MCF7/WT中ESR2蛋白的表达提高,但是其转录水平基本未见发生改变。猜测ESR2 mRNA 5′非翻译区（5′ untranslated region, 5′ UTR）具有IRES活性。为了验证ESR2 mRNA 5′ UTR是否具有IRES元件,将ESR2 mRNA 5′ UTR插入到双顺反子报告基因载体（pRF）中,构建pRL-ESR2-FL重组质粒载体,将其瞬时转染到HEK293细胞。结果发现,ESR2 mRNA 5′ UTR有假定的IRES活性。并且通过3个排除实验验证了ESR2 IRES活性与其5′ UTR中的内部潜在启动子（P<0.0001）、内部剪切位点以及核糖体通读无关。进一步对其序列进行截短研究发现,ESR2 IRES活性发挥的关键区域是3′端的439～468 nt,且ESR2 IRES最大活性的发挥依赖于5′ UTR序列的完整性。并且发现,ESR2 IRES活性的发挥不但需要特定的一级核酸序列,还要有稳定的二级茎环结构。此研究有望为ESR2蛋白调控的相关疾病提供新的药物治疗靶点。     

转录激活因子1(ATF1)内部核糖体进入位点的鉴定及活性分析

蛋白质翻译起始通常有两种机制,一是依赖帽结构的翻译,另一种是依赖5′非翻译区的内部核糖体进入位点(IRES).在后一种方式中,在某些IRES反式作用因子,如La蛋白、多聚嘧啶串结合蛋白1等的参与下,直接招募核糖体小亚基到mRNA的翻译起始位点,启始翻译.研究发现,参与细胞生长、分化、细胞周期进程、凋亡和压力调控的相关蛋白中通常含有IRES元件.基于功能,我们提出假说：转录激活因子1(ATF1)的5′-UTR可能具有IRES活性.为验证假说,首先构建了含全长ATF1 5′-UTR的双荧光素酶报告质粒|质粒转染结合报告酶活性分析显示,ATF1 5′-UTR在Bel7402、HCT-8和HEK293细胞中表现出不同的IRES活性|而此IRES活性与5′-UTR中的隐藏启动子无关.同时还发现,ATF1 5′-UTR在NIH3T3细胞中却没有IRES活性.与此结果相一致,Western印迹检测ATF1在这几种细胞系中的表达.结果显示,Bel7402、HCT 8和HEK293中ATF1蛋白质表达水平较高,而在NIH3T3中却极低. ATF1 5′-UTR的系列5′-删除突变及报告酶分析证明,ATF1 5′-UTR的完整性对其IRES活性大小发挥重要作用|其中5′端的204 bp序列对其IRES活性贡献较大. RNA-蛋白免疫共沉淀实验揭示,ATF1 5′-UTR可与La和PTBP1蛋白结合|抑制La和PTBP1蛋白质的表达,并可减低HEK293细胞中ATF1蛋白质表达水平.这些结果提示,La和PTBP1蛋白（两种ITAFs）为ATF1 5′-UTR发挥IRES活性所必需.总之,上述结果证明,ATF1 5′-UTR具有IRES活性,其活性发挥依赖与La和PTBP1蛋白的结合.上述发现为进一步研究La和PTBP1表达及亚细胞定位对ATF1 IRES调控机制的影响奠定了基础.     

转录因子GATA3 mRNA 5′非翻译区内部核糖体进入位点的活性

GATA3(GA-TA-binding protein-3)是锌指蛋白GATA家族成员之一,在细胞的增殖和分化中起着重要的作用,GATA3在细胞中的异常表达也是导致众多肿瘤形成的原因。通过对GATA3m RNA 5′非翻译区(untranslated region,UTR)进行分析,发现其UTR长达557 bp并且具有复杂的二级结构。将GATA3 m RNA 5′UTR克隆至双荧光素酶报告载体p RL-FL中,瞬时转染至细胞中然后对细胞进行无血清培养后,发现GATA3 m RNA 5′UTR介导的翻译明显升高。将GATA3 m RNA 5′UTR克隆至Δp RL-FL载体上,瞬时转染细胞后检测萤火虫荧光素酶的表达,发现GATA3 m RNA 5′UTR不具有隐含启动子,进而确定GATA3 m RNA 5′UTR具有内部核糖体进入位点(internal ribosome entry sites,IRES)元件;进一步对GATA3 m RNA 5′UTR进行序列截短分析,发现GATA3 m RNA 5′UTR中345~557 bp区间可能是抑制IRES活性的调控元件,而95~344 bp区间则是IRES元件的主要活性中心调控域,并且在不同的细胞系中GATA3 IRES元件的活性存在显著的差异。该研究结果表明,GATA3m RNA的5′UTR可参与GATA3的表达调控。     

小RNA病毒蛋白翻译调控元件研究进展

真核生物的起始复合物并不是在起始AUG处形成 ,而是在mRNA的 5′末端形成 ,其识别信号就是 5′末端的帽子结构。小RNA病毒科成员RNA 5′末端没有帽子结构 ,而有一个病毒编码的小蛋白质与基因组共价相连。小RNA病毒的蛋白翻译起始于 5′非翻译区中的内部顺式调控元件 ,称为内部核糖体进入位点 (IRES)。口蹄疫病毒 (foot and mouthdiseasevirus,FMDV)是该科病毒的典型代表 ,引起偶蹄动物的急性接触性传染病。完整FMDV含有单链正股RNA、衣壳蛋白及少量装配过程中夹带的非结构蛋白和宿主细胞肌动蛋白 ,其基因组RNA全长约 8 5kb ,可直接作为信使RNA。对IRES的一、二级结构进行了比较 ,对IRES与翻译起始因子的相互作用以及对病毒毒力的影响作了综述。     

热激蛋白Hsp72促进热休克下HuR对p21CIP1的调控作用

RNA结合蛋白HuR可以结合并调控靶标mRNA稳定性与翻译,但影响HuR 结合活性的因素有待探讨。本研究从蛋白质-蛋白质相互作用角度对影响HuR 与RNA结合活性的因素做了探讨。结果发现,热激蛋白Hsp72在细胞浆与HuR相互作用并促进HuR与p21 (KIP1) 3′UTR（3′非翻译区）的结合; 热休克下Hsp72总蛋白质及细胞浆蛋白质水平上调、但HuR总蛋白质及细胞浆蛋白质水平不变|热休克下HuR与p21 3′UTR的相互作用加强、p21蛋白及mRNA水平上调。上述结果提示,Hsp72可通过与HuR相互作用促进后者与p21 mRNA的结合,进而加强热休克下HuR对p21的表达的促进作用。这些结果为进一步解析HuR的生物学作用机制提供了实验依据。     

RNA病毒翻译调控元件—内部核糖体进入位点(IRES)

真核生物大多数蛋白质合成采用了依赖帽子结构的翻译起始方式.但一组缺乏帽子构的RNA病毒的蛋白质合成起始是依赖其5′端非翻译区（untranslated region,UTR）翻译调控的顺式作用元件——内部核糖体进入位点（internal ribosome entry site, IRES）.它 们能够在一些反式作用因子的辅助下,招募核糖体小亚基到病毒mRNA的翻译起始位点.前,依赖IRES元件翻译起始的RNA病毒在哺乳动物,无脊椎动物及植物中均有发现.因此,对RNA病毒IRES元件的深入研究,不仅有助于阐明相关疾病的发生机理,而且为工业应用和疾病治疗提供借鉴意义.本文对RNA病毒IRES元件发现、分类、结构与功能等作了综述.     

MiR-206与ANXA2的3′UTR靶向结合抑制乳腺癌侵袭

膜联蛋白A2（annexin A2,ANXA2）可促进人结直肠癌的侵袭和迁移。然而,ANXA2在乳腺癌中的作用以及调节机制尚缺乏系统的研究。本研究旨在探讨微小RNA-206（microRNA-206,miR-206）如何调节ANXA2基因的表达,进而影响乳腺癌的侵袭。通过基因预测软件TargetScan (TargetScan V5.2)找到与ANXA2的3′UTR区互补结合的miR-206。运用实时定量 PCR（qRT-PCR）检测不同乳腺癌细胞系中miR-206的表达水平,发现低侵袭性乳腺癌MCF-7细胞株miR-206 表达量明显高于高侵袭性乳腺癌细胞株MDA-231、MDA-435和T47D。运用转染技术将 miR-206 质粒及miR-206 抑制剂转入乳腺癌细胞系MDA-231后,qRT-PCR检测转染后各组细胞中miR-206的表达情况,结果显示转染成功。用Western印迹法检测各组细胞中ANXA2的表达情况,结果显示,miR-206负向调控ANXA2蛋白的表达。 qRT-PCR显示,过表达乳腺癌细胞内miR-206 后,ANXA2 mRNA基本没有变化。结果显示,miR-206是在翻译水平上影响ANXA2蛋白的表达。荧光素酶实验显示：miR-206能特异性地与ANXA2 mRNA的3′UTR结合,抑制其荧光素酶活性。Transwell侵袭实验检测各组细胞的侵袭能力。结果显示,过表达miR-206后,乳腺癌细胞体外侵袭能力明显减弱。综上所述,miR-206 通过靶向结合癌基因ANXA2 mRNA的3′UTR区,抑制ANXA2蛋白翻译,从而抑制了乳腺癌细胞的侵袭。因此,miR-206有望成为抑制乳腺癌侵袭与治疗乳腺癌的新靶点和生物学标记物。     

双链RNA激活的蛋白激酶(PKR)的克隆表达及其对丙型肝炎病毒蛋白合成的抑制

α干扰素为治疗丙型肝炎病毒(HCV)感染的主要药物,但部分患者呈干扰素耐受而不能获得持久的病毒阴转,其可能的原因之一是病毒通过其编码的蛋白(NS5A及E2)抑制干扰素诱导的抗病毒效应分子——双链RNA激活的蛋白激酶(PKR)的活性.而关于PKR是否在IFN-α抗HCV的机理中起抑制作用目前仍有争议.为研究PKR对HCV蛋白合成环节是否有抑制作用,通过构建野生型 PKR真核表达载体（pPKRwt）及主要起负性调节作用的缺失突变PKR真核表达载体（pPKRΔ6）,并将pPKRwt /pPKRΔ6 与HCV复制子RNA同时转染Huh7细胞进行共表达, 用Western印迹检测 HCV IRES 下游的NPTⅡ蛋白表达水平,与转染空载体的对照细胞及单用IFN-α处理的细胞相比较.结果显示：表达PKRwt的细胞中NPTⅡ蛋白水平低于转染空载体的对照细胞,但高于经IFN-α单独处理的细胞;表达PKRΔ6的细胞中NPTⅡ蛋白水平与对照细胞无明显差别,但PKRΔ能部分抵消IFN-α的抑制作用,说明在IFN-α抑制HCV IRES指导的蛋白合成中,PKR有一定的抑制作用,但可能还有其它的PKR非依赖机制参与.     

miR-424-5p通过下调BCL-2的表达抑制人肺癌A549细胞增殖

microRNAs(miRNAs)是一类在真核生物中广泛存在的长度约为20～22个核苷酸的单链非编码小RNA,通过与其靶基因mRNA的3′非翻译区（3′UTR）结合发挥转录后抑制作用,参与调节细胞生长增殖、细胞代谢、细胞凋亡以及肿瘤的发生发展等过程。为研究microRNA-424-5p（miR-424-5p）在肺癌细胞中的作用及机理,利用lipo2000转染试剂将miR-424-5p mimics转染入人的非小细胞型肺癌细胞(NSCLC)A549中,流式细胞术检测A549细胞的周期变化及凋亡情况,发现细胞生长阻滞于G1/G0期且凋亡率显著上升。利用克隆形成实验和CCK-8法分别检测,发现miR-424-5p导致A549细胞增殖能力及活力降低。用在线数据库预测出抗凋亡基因BCL-2可能是miR-424-5p的靶基因,随后扩增BCL-2 mRNA 的3′UTR,采用双荧光素酶报告实验及Western印迹检测证明BCL-2确为miR-424-5p的靶基因。构建BCL-2的真核表达载体pCMV-HA-BCL-2,与空载分别转染A549细胞后发现过表达BCL-2可抵消miR-424-5p引起的细胞周期阻滞及细胞凋亡。以上结果提示,miR-424-5p可以通过下调BCL-2的表达来抑制肺癌细胞增殖。     

Translation of eukaryotic translation initiation factor 4GI (eIF4GI) proceeds from multiple mRNAs containing a novel cap-dependent internal ribosome entry site (IRES) that is active during poliovirus infection

Eukaryotic translation initiation factor 4GI (eIF4GI) is an essential scaffolding protein required to recruit the 43 S complex to the 5'-end of mRNA during translation initiation. We have previously demonstrated that eIF4GI protein expression is translationally regulated. This regulation is mediated by cis-acting RNA elements, including an upstream open reading frame and an IRES that directs synthesis of five eIF4GI protein isoforms via alternative AUG initiation codon selection. Here, we further characterize eIF4GI IRES function and show that eIF4GI is expressed from several distinct mRNAs that vary via alternate promoter use and alternate splicing. Several mRNA variants contain the IRES element. We found that IRES activity mapped to multiple regions within the eIF4GI RNA sequence, but not within the 5'-UTR per se. However, the 5'-UTR enhanced IRES activity in vivo and played a role in initiation codon selection. The eIF4GI IRES was active when transfected into cells in an RNA form, and thus, does not require nuclear processing events for its function. However, IRES activity was found to be dependent upon the presence, in cis, of a 5' m7guanosine-cap. Despite this requirement, the eIF4GI IRES was activated by 2A protease cleavage of eIF4GI, in vitro, and retained the ability to promote translation during poliovirus-mediated inhibition of cap-dependent translation. These data indicate that intact eIF4GI protein is not required for the de novo synthesis of eIF4GI, suggesting its expression can continue under stress or infection conditions where eIF4GI is cleaved.     

A peptide derived from RNA recognition motif 2 of human la protein binds to hepatitis C virus internal ribosome entry site, prevents ribosomal assembly, and inhibits internal initiation of translation

Human La protein is known to interact with hepatitis C virus (HCV) internal ribosome entry site (IRES) and stimulate translation. Previously, we demonstrated that mutations within HCV SL IV lead to reduced binding to La-RNA recognition motif 2 (RRM2) and drastically affect HCV IRES-mediated translation. Also, the binding of La protein to SL IV of HCV IRES was shown to impart conformational alterations within the RNA so as to facilitate the formation of functional initiation complex. Here, we report that a synthetic peptide, LaR2C, derived from the C terminus of La-RRM2 competes with the binding of cellular La protein to the HCV IRES and acts as a dominant negative inhibitor of internal initiation of translation of HCV RNA. The peptide binds to the HCV IRES and inhibits the functional initiation complex formation. An Huh7 cell line constitutively expressing a bicistronic RNA in which both cap-dependent and HCV IRES-mediated translation can be easily assayed has been developed. The addition of purified TAT-LaR2C recombinant polypeptide that allows direct delivery of the peptide into the cells showed reduced expression of HCV IRES activity in this cell line. The study reveals valuable insights into the role of La protein in ribosome assembly at the HCV IRES and also provides the basis for targeting ribosome-HCV IRES interaction to design potent antiviral therapy.     

Functional characterization of the X-linked inhibitor of apoptosis (XIAP) internal ribosome entry site element: role of La autoantigen in XIAP translation

X-linked inhibitor of apoptosis protein (XIAP) is a key regulator of programmed cell death triggered by various apoptotic triggers. Translation of XIAP is controlled by a 162-nucleotide (nt) internal ribosome entry site (IRES) element located in the 5' untranslated region of XIAP mRNA. XIAP IRES mediates efficient translation of XIAP under physiological stress and enhances cell protection against serum deprivation and radiation-induced apoptosis. In the present report we describe the assembly of a sequence-specific RNA-protein complex consisting of at least four cytosolic proteins on the XIAP IRES element. We determine that the core binding sequence is approximately 28 nt long and is located 34 nt upstream of the initiation site. Moreover, we identify the La autoantigen as a protein that specifically binds XIAP IRES in vivo and in vitro. The biological relevance of this interaction is further demonstrated by the inhibition of XIAP IRES-mediated translation in the absence of functional La protein. The results suggest an important role for the La protein in the regulation of XIAP expression, possibly by facilitating ribosome recruitment to the XIAP IRES.     

The sequence element of the internal ribosome entry site and a 25-kilodalton cellular protein contribute to efficient internal initiation of translation of hepatitis C virus RNA.

Translation of hepatitis C virus (HCV) RNA is initiated by internal entry of ribosomes into the 5' noncoding region (NCR). This process depends on genomic elements within the 5' NCR called the internal ribosome entry site (IRES) and may involve host factors. The alpha-branch structure (nucleotides 47 to 67) of the HCV IRES is considered a cis-acting element critical for translation initiation because it is indispensable for translation in vitro (S. Fukushi, K. Katayama, C. Kurihara, N. Ishiyama, F. B. Hoshino, T. Ando, and A. Oya, Biochem. Biophys. Res. Commun. 199:425-432, 1994). In order to further characterize the function of the alpha-branch, we determined whether sequence exchange within the alpha-branch had any effect on translation initiation. An in vitro translation study revealed that the stem sequences of this region played an important role in efficient IRES function. In addition to several HeLa cell proteins, which had a binding affinity for the 5' NCR, a novel 25-kDa protein that specifically interacted with the HCV IRES was discovered. The binding affinity of the 25-kDa protein for the 5' NCR was correlated with the efficiency of translation initiation of HCV RNA, indicating a critical role for the 25-kDa protein in HCV translation.     

Deregulation of Internal Ribosome Entry Site-Mediated p53 Translation in Cancer Cells with Defective p53 Response to DNA Damage

Synthesis of the p53 tumor suppressor and its subsequent activation following DNA damage are critical for its protection against tumorigenesis. We previously discovered an internal ribosome entry site (IRES) at the 5′ untranslated region of the p53 mRNA. However, the connection between IRES-mediated p53 translation and p53''s tumor suppressive function is unknown. In this study, we identified two p53 IRES trans-acting factors, translational control protein 80 (TCP80), and RNA helicase A (RHA), which positively regulate p53 IRES activity. Overexpression of TCP80 and RHA also leads to increased expression and synthesis of p53. Furthermore, we discovered two breast cancer cell lines that retain wild-type p53 but exhibit defective p53 induction and synthesis following DNA damage. The levels of TCP80 and RHA are extremely low in both cell lines, and expression of both proteins is required to significantly increase the p53 IRES activity in these cells. Moreover, we found cancer cells transfected with a shRNA against TCP80 not only exhibit decreased expression of TCP80 and RHA but also display defective p53 induction and diminished ability to induce senescence following DNA damage. Therefore, our findings reveal a novel mechanism of p53 inactivation that links deregulation of IRES-mediated p53 translation with tumorigenesis.