Polypyrimidine Tract-Binding Protein Enhances Zika Virus Translation by Binding to the 5'UTR of Internal Ribosomal Entry Site

Objectives To identify the 5'untranslated region of Zika virus(ZIKV 5'UTR)RNA-binding proteins and to investigate the impact of the binding protein on the activity of internal ribosomal entry site(IRES)located in ZIKV 5'UTR and virus production.Methods Interacting proteins in U251 cells were captured using tRSA-tagged ZIKV 5'UTR RNA and tRSA-ZIKV 5'UTR RNA-binding proteins were visualized by SDS-PAGE silver staining,Subsequently,liquid chromatographytandem mass spectrometry(LC-MS/MS),bioinformatics analysis,and Western blot were used to identify the candidate proteins binding to ZIKV 5'UTR.Dicistronic expression assay and plaque forming assay were performed to analyze the effect of the binding protein on ZIKV IRES activity and ZIKV production,respecitvely.Results tRSA RNA pull-down assay,LC-MS/MS,and Western blot analysis showed that polypyrimidine tractbinding protein(PTB)bound to the ZIKV 5'UTR.Furthermore,dual luciferase reporter assay revealed that overexpression of PTB significantly enhanced the IRES activity of ZIKV(t=10.220,P<0.001),while PTB knockdown had the opposite effect(t=4.897,P<0.01).Additionally,virus plaque forming assay demonstrated that up-regulation of PTB expression significantly enhanced viral titer(t=6.400,P<0.01),whereas reducing PTB expression level weakened virus infectivity(t=5.055,P<0.01).Conclusion PTB positively interacts with the ZIKV 5'UTR and enhances IRES activity and virus production.

Human Enterovirus 71 DNA Vaccine Constructs Containing 5’UTR with Complete Internal Ribosome Entry Site Sequence Stimulated Improved Anti-Human Enterovirus 71 Neutralizing Immune Responses

Recent improvement in the technologies for efficient delivery of DNA vaccines has renewed interest in the DNA-based vaccines. Several DNA-based vaccines against human enterovirus 71 (EV71), the causative agent for hand, foot and mouth disease (HFMD) have been developed. Here we examined the potential of improving the vaccines by inserting the EV71 5’ untranslated region (5’ UTR) containing the full length internal ribosome entry site (IRES) sequence to the EV71 VP1-based DNA vaccine constructs. Four vaccine constructs designated as 5’ UTR-VP1/EGFP, VP1/EGFP, 5’ UTR-VP1/pVAX and VP1/pVAX, were designed using the pEGFP-N1 and pVAX-1 expression vectors, respectively. Transfection of Vero cells with the vaccine constructs with the 5’-UTR (5’-UTR-VP1/EGFP and 5’ UTR-VP1/pVAX) resulted in higher percentages of cells expressing the recombinant protein in comparison to cells transfected with vectors without the 5’-UTR (67% and 57%, respectively). Higher IgG responses (29%) were obtained from mice immunized with the DNA vaccine construct with the full length 5’ UTR. The same group of mice when challenged with life EV71 produced significantly higher neutralizing antibody (NAb) titers (>5-fold). These results suggest that insertion of the EV71 5’ UTR sequence consisting of the full length IRES to the EV71 DNA vaccine constructs improved the efficacy of the constructs with enhanced elicitation of the neutralizing antibody responses.

Internal ribosome entry site-based vectors for combined gene therapy

Gene therapy appears as a promising strategy to treatincurable diseases. In particular, combined gene therapy has shown improved therapeutic efficiency. Internal ribosome entry sites(IRESs), RNA elements naturally present in the 5' untranslated regions of a few m RNAs, constitute a powerful tool to co-express several genes of interest. IRESs are translational enhancers allowing the translational machinery to start protein synthesis by internal initiation. This feature allowed the design of multi-cistronic vectors expressing several genes from a single m RNA. IRESs exhibit tissue specificity, and drive translation in stress conditions when the global cell translation is blocked, which renders them useful for gene transfer in hypoxic conditions occurring in ischemic diseases and cancer. IRES-based viral and non viral vectors have been used successfully in preclinical and clinical assays of combined gene therapy and resulted in therapeutic benefits for various pathologies including cancers, cardiovascular diseases and degenerative diseases.

Artificial intelligence and machine learning could support drug development for hepatitis A virus internal ribosomal entry sites

Hepatitis A virus(HAV)infection is still an important health issue worldwide.Although several effective HAV vaccines are available,it is difficult to perform universal vaccination in certain countries.Therefore,it may be better to develop antivirals against HAV for the prevention of severe hepatitis A.We found that several drugs potentially inhibit HAV internal ribosomal entry site-dependent translation and HAV replication.Artificial intelligence and machine learning could also support screening of anti-HAV drugs,using drug repositioning and drug rescue approaches.

IRES核心区12-bp非连续插入突变对猪塞内卡病毒复制和细胞嗜性的影响

【背景】塞内卡病毒(senecavirus A,SVA)是新近暴发的一种引起猪特发性水疱病及仔猪死亡的小核糖核酸病毒。该病毒基因组5′非编码区(untranslated region,UTR)中的内部核糖体进入位点(IRES)元件在病毒复制过程中发挥重要作用。2017年我国出现IRES核心区Domain II 12个碱基非连续插入的自然突变SVA毒株,在病毒复制和致病性方面存在明显改变。【目的】探讨IRES Domain II区域发生的突变对SVA的复制及细胞嗜性的影响,为进一步了解SVA致病机制奠定基础。【方法】以实验室前期构建的含HeN-1/2018株全基因组感染性克隆pHeN-1/2018为基础,通过定点突变的方式,逐步将其IRES Domain II核心区域308—317 nt的9个碱基(ACTCAAGCG)替换为GD04/2017株基因组308—328 nt的21个碱基(CACGCCTGCCGATAGACGATT),构建重组载体pHeN-1/2018-i12并进行了病毒拯救。随后,利用病毒基因组克隆测序、间接免疫荧光试验和Western blot试验对所拯救病毒进行鉴定,同时验证了IRES核心区12个碱基插入突变对SVA病毒体外复制能力和细胞嗜性的影响。【结果】将构建完成的重组载体pHeN-1/2018-i12转染细胞,盲传至P2代,获得致使感染细胞病变明显、病变时间稳定的IRES突变病毒rHeN-1/2018-i12。病毒连续传代后测序结果表明rHeN-1/2018-i12遗传稳定,P5代病毒基因组序列未发生碱基突变,P10代病毒IRES区域没有出现突变现象。用低代次的突变病毒rHeN-1/2018-i12体外感染本体动物猪源细胞系PK-15和IBRS-2,及仓鼠源细胞系BHK-21,进行细胞感染试验,结果表明rHeN-1/2018-i12与亲本毒株rHeN-1/2018在PK-15、IBRS-2和BHK-21中均能导致明显的细胞病变,表现出相似的生长曲线趋势,表明IRES核心区Domain II 12个碱基突变不能够改变对上述细胞的嗜性;但SVA突变病毒和亲本株在不同细胞中的病变时间及病毒滴度上存在较大的差异,rHeN-1/2018-i12株在细胞中生长能力较其亲本株rHeN-1/2018差,诱使细胞病变的时间较晚,在感染24 hpi,两者病毒滴度相差可达10倍。【结论】本研究基于SVA反向遗传操作系统构建并拯救SVA IRES突变毒株,确定了IRES突变对SVA生物学特性的影响,有助于我们更好地了解SVA致病机制,拓宽我们对病毒IV型IRES功能的认识。

IRES介导的非帽依赖翻译调控研究进展

内部核糖体进入位点(Internal ribosome entry site,IRES)是一种存在于RNA内部的特殊功能元件,其可在不依赖5’端帽子结构的情况下直接招募核糖体启动蛋白翻译,已被发现与多种细胞过程密切相关。近来,越来越多的证据表明IRES在环形RNA翻译调控中扮演着极其重要的角色,由此IRES引起人们的极大关注。本文针对目前真核细胞中IRES介导的翻译调控机制进行了综述,并对IRES元件相关生物信息学工具进行了总结。

乙型肝炎病毒大表面蛋白诱导内质网应激调控p27 IRES翻译活性的机制研究

目的探讨在乙型肝炎病毒大表面蛋白(LHB)诱导的内质网应激条件下,抑癌基因p275′UTR内部核糖体进入位点(IRES)的活性变化及其调控机制。方法构建双荧光素酶报告质粒,用双荧光素酶报告基因实验检测p275′UTR中IRES的活性;利用qRT-PCR和Western blotting检测LHB诱导的未折叠蛋白反应相关分子水平;RNA下拉、质谱技术和RNA免疫沉淀筛选并确认潜在的与p275′UTR结合的相关蛋白;siRNA转染建立PCBP2和ANXA2敲低细胞模型,用双荧光素酶报告基因检测在敲低PCBP2和ANXA2后p27 IRES翻译活性的变化。结果成功构建了检测p27 IRES活性的双荧光素酶报告质粒。LHB可以诱导内质网应激,同时显著提高p27的IRES翻译活性(P<0.01)。LHB过表达激活了PERK通路并提高了eIF2α的磷酸化水平,特异性PERK通路抑制剂GSK2606414使RERK和eIF2α的磷酸化水平降低,从而引起p275′UTR的IRES翻译活性显著降低(P<0.01,P<0.05)。同时,磷酸酶抑制剂Sal003能显著增加eIF2α磷酸化水平,使p27 IRES活性进一步增强(P<0.01,P<0.05)。最后,我们发现PCBP2和ANXA2作为潜在的反式作用因子可增强p27 IRES活性。结论LHB诱导的内质网应激通过eIF2α磷酸化增强p27 IRES翻译活性。反式作用因子PCBP2和ANXA2正向调控其IRES翻译活性。

IRESfinder:Identifying RNA internal ribosome entry site in eukaryotic cell using framed k-mer features

In eukaryotic cells, initiation of protein translation is to recruit the ribosome to a specific mRNA, which is generally dependent on the 5＇ cap structure. However, protein translation can also be initiated in a cap-independent manner by using a cis-regulatory element termed the internal ribosome entry site （IRES）. The first experimentally validated IRES was reported in the poliovirus （Pelletier and Sonenberg, 1988）. Then eukaryotic cellular mRNAs were also validated to contain IRES elements.

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.但一组缺乏帽子结构的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.目前,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.

HCVIRES介导萤火虫荧光素酶翻译的双顺反子载体的构建与在小鼠体内的表达

将HCVIRES插入双报告基因海肾荧光素酶 (Rluc)基因和萤火虫荧光素酶 (Fluc)基因之间 ,建立了“依赖帽子的扫描机制”翻译表达Rluc ,HCVIRES调控Fluc翻译的双顺反子表达载体pCI Rluc HCVIRES Fluc ,通过酶切反应及转染HepG2细胞鉴定双荧光素酶瞬间表达活性等试验 ,证实获得了表达双荧光素酶的双顺反子载体 .并应用水压转染法将双顺反子表达质粒导入小鼠体内 ,在小鼠肝脏检测到高水平表达的Rluc和Fluc .该研究成功构建一种HCVIRES介导萤火虫荧光素酶基因表达的双顺反子载体 ,并在HepG2细胞及小鼠体内进行了瞬时表达 。

一种新的双元表达质粒pCMV-Myc-IRES-EGFP的构建及其表达

为了研究基因的特征、理化特性及其功能机制,通常需要构建多个真核表达载体,涉及到多次的引物设计、酶切、连接和鉴定等繁琐的亚克隆过程。构建携带易于多种实验研究的多用或通用载体是基因工程载体的发展方向。为此,利用pIRES载体为骨架质粒,在A和B多克隆位点上分别插入c-Myc标签蛋白序列和增强型绿色荧光蛋白(EGFP)序列,从而构建了一个包含c-Myc标签蛋白序列并携带有核糖体结合位点(IRES)介导的增强型绿色荧光蛋白的真核表达载体pCMV-Myc-IRES-EGFP。通过荧光检测和免疫印迹实验证实该载体能在哺乳细胞中表达。该载体可用于监测细胞的转染效率、分选稳定表达的阳性细胞群体、体外转录和翻译、检测或纯化目的蛋白以及捕获相关作用蛋白等多种实验研究,为基因功能研究提供了便利。

携带IRES的BMP_2绿色荧光蛋白表达载体的构建和表达

目的 :构建携带有BMP2 基因的pIRES2 绿色荧光蛋白表达载体 ,为BMP2 在体内外表达及蛋白定位提供标记。方法 :酶切 pCDAN3.1-BMP2 质粒 ,获得BMP2 cDNA片段并亚克隆至 pUC18载体上 ,随后用SalⅠ单酶切pUC18-BMP2 ,再次获得BMP2 cDNA ,同时用SalⅠ将载体 pIRES2 -EGFP线性化后去磷酸化修饰。连接二者构建重组质粒。酶切筛选阳性克隆并鉴定插入的方向。重组质粒转染细胞 ,用激光共聚焦显微镜、RT -PCR及流式细胞仪检测基因在细胞内的定位、表达及转染效率 ;结果 :重组载体经酶切和测序证明构建正确 ,并在细胞中表达。结论 :成功构建了 pIRES2 -BMP2 -EGFP表达载体 ,为研究BMP2

pIRES-p16ink4a-hRb1载体的构建及其对骨肉瘤细胞周期的调控

目的应用内部核糖体插入位点(IRES)序列构建单启动子双顺反子穿梭载体pIRES-p16ink4a-hRb1并鉴定,观察其导入骨肉瘤细胞后对细胞周期的调控。方法利用基因工程技术,将p16ink4a与hRb1全长cDNA编码区依次亚克隆至pIRES载体中,质粒构建通过PCR、双酶切与测序鉴定;脂质体转染至p16ink4a表达缺失、hRb1表达阳性的骨肉瘤细胞株MG63,G418筛选获得抗性克隆,通过RT-PCR和Western blot法分析外源基因表达;流式细胞术分析细胞周期特异性和细胞凋亡率,四甲基偶氮唑蓝(MTT)比色法与细胞生长曲线观察细胞增殖情况。结果成功构建出pIRES-p16ink4a-hRb1载体,外源基因在靶细胞mRNA和蛋白水平分别有独立表达。与对照组比较,双基因导入组细胞生长抑制率显著上升,细胞周期显著阻滞在G1期,且细胞凋亡率极显著升高。结论pIRES-p16ink4a-hRb1双顺反子穿梭载体的构建与真核细胞导入、目的基因表达成功,为进一步研究p16ink4a与hRb1相互关系在细胞周期调控中的作用奠定了基础。

pIRES2-NGF-NT-3真核表达载体的构建与鉴定

构建双基因共表达载体pIRES2-NGF-NT-3并检测其在HEK293细胞中的表达。人神经生长因子(nerve growth factor,NGF)和神经营养素3(neurotrophin-3,NT-3)是采用直接PCR的方法从人外周血单个核细胞的基因组DNA中获取,将人神经生长因子的cDNA片段插入到pIRES2-EGFP多克隆位点构建成为pIRES2-NGF-EGFP。神经营养素3 cDNA片段通过替换绿色荧光蛋白基因(EGFP)的方式插入到pIRES2-NGFEGFP中构建成为pIRES2-NGF-NT-3双基因共表达载体,将pIRES2-NGF-NT-3用脂质体转染HEK293细胞并采用RT-PCR与Western-blot的方法检测其表达。人神经生长因子和神经营养素3被克隆,通过测序和酶切鉴定的得知与基因库报道序列一致。pIRES2-NGF-NT-3转染HEK293细胞后双基因在mRNA和蛋白水平均得到了表达。人神经生长因子和神经营养素3双基因真核表达载体成功构建,它提供了一个新的表达系统,为进一步研究双基因的功能奠定了基础。

pcDNA3与pIRES1.neo筛选克隆效率的比较

将绿色荧光蛋白(GFP)报告基因分别插入pIRES1.neo与pcDNA3二真核表达载体,构建pGFP-IRES1.neo和pcDNA3-GFP,转染小鼠B16细胞和人HepG2细胞,经G418筛选出抗性克隆,在倒置荧光显微镜下观察,鉴定共表达克隆数;结果在两个细胞系中,pcDNA3-GFP共表达率分别为0%和4%,而pIRES1.neo-GFP共表达率为75%和100%,差异非常显著;因此在筛选稳定表达目的基因细胞克隆的实验中,pIRES1.neo是一个较理想的载体。

重组表达载体pIRES-CD、pIRES-TK的构建及其在ACC-2细胞中的表达

目的:运用分子生物学技术扩增CD、TK基因,进行其DNA序列分析,并构建真核表达质粒pIRES-CD及pIRES-TK,将其共同转染ACC-2细胞,为进一步研究双自杀基因对ACC-2细胞杀伤作用奠定基础。方法:根据CD和TK基因DNA的序列分别设计、合成引物,构建克隆载体pMD18-T-CD和pMD18-T-TK,并进行DNA序列分析;构建以内部核糖体进入位点(IRES)相连的CD和TK基因的真核表达质粒pIRES-CD及pIRES-TK,用电穿孔法以真核表达质粒共同转染ACC-2细胞,用RT-PCR检测CD和TK的表达。结果:克隆DNA片段和GeneBank上报道的CD、TK序列基本一致,且经酶切鉴定,CD、TK基因成功插入真核表达质粒IRES,RT-PCR检测表明,以真核表达质粒pIRES-CD及pIRES-TK共同转染的ACC-2细胞能表达CD和TK。结论:成功扩增了CD、TK的DNA片段,并进行了序列分析;成功构建CD和TK基因的重组真核表达质粒pIRES-CD及pIRES-TK,将其转染ACC-2细胞后能分泌性表达CD和TK,为肿瘤基因治疗的研究提供一定途径。

HCVIRES调控外分泌性碱性磷酸酶基因在肝细胞中的表达

目的 :构建HCVIRES调控外分泌性碱性磷酸酶 (SEAP)基因表达的细胞模型。方法 :用PCR技术扩增HCV 5′NCR片段 ,定向克隆至表达质粒 pSEAP2 Control的SEAP基因上游 ,构建HCV 5′NCR调控SEAP表达的重组质粒 pdNCRSEAP。用脂质体基因转染技术 ,将pdNCRSEAP转染至肝细胞株QSG770 1。用化学发光法检测SEAP的表达 ,并观察不同浓度反义寡聚核苷酸 (ASODN)对SEAP表达的影响。结果 :重组质粒 pdNCRSEAP表达的发光强度为pSEAP2 Control的 76 %,5 μmol和 10 μmolASODN对pdNCRSEAP发光强度的抑制率分别为2 9.2 %和 44 .6 %,而对 pSEAP2 Control的SEAP表达无显著抑制作用 (P >0 .0 5 )结论 :重组质粒 pdNCRSEAP的SEAP表达受HCV 5′NCR调控 ,为以HCV 5′NCR为靶位点的药物评价建立了检测方便的细胞模型。

CTLA4Ig-IRES-OX40Ig重组腺病毒的构建及其生物学特性

利用基因重组技术,拼接目的基因CTLA4Ig-IRES-OX40Ig,并亚克隆入腺病毒载体pTrack-CMV中,构建pT/CTLA4Ig-IRES-OX40Ig载体,与pAdeasy-1共同转染BJ5183以进行同源重组,所获得的重组子用LipofectAMINE2000转染293A细胞包装病毒,获得了可同时分别表达CTLA4Ig和OX40Ig的重组腺病毒AdCTLA4Ig-IRES-OX40Ig,并进行扩增和滴度测定,用Western印迹鉴定293A细胞培养上清中目的基因的表达,用混合淋巴细胞反应研究其免疫抑制活性.利用上述方法成功构建了穿梭质粒pT/CTLA4Ig-IRES-OX40Ig;并且获得了重组腺病毒AdCTLA4Ig-IRES-OX40Ig,在感染的293A细胞的培养上清中可以同时检测到CTLA4Ig和OX40Ig分子;AdCTLA4Ig-IRES-OX40Ig、AdCTLA4Ig和AdOX40Ig感染的Lewis大鼠脾细胞(刺激细胞)对Balb/c小鼠的脾细胞(反应细胞)的增殖均具有抑制作用,但AdCTLA4Ig-IRES-OX40Ig感染组的抑制效率明显强于AdCTLA4Ig和AdOX40Ig感染组,体外实验证实该两种分子可协同作用,强烈抑制混合淋巴细胞反应.

质粒表达载体pIRES-CD的构建及其在ACC-2细胞中的表达

目的:克隆大肠杆菌胞嘧啶脱氨酶(CD)基因,构建质粒表达载体pIRES-CD,并利用该载体转染ACC-2细胞,建立稳定表达大肠杆菌CD基因的ACC-2细胞克隆。方法:通过PCR从大肠杆菌DH5αDNA中扩增出CD基因全长序列,将扩增产物定向插入到克隆载体pMD18-T中,进行序列测定。测序正确后,将其亚克隆到质粒表达载体pIRES中,构建以内部核糖体进入位点(IRES)相连的CD基因的质粒表达载体pIRES-CD,采用电穿孔法,以质粒表达载体转染ACC-2细胞,用400μg/mL的G418筛选10d,获得稳定表达CD基因的ACC-2细胞系,提取该细胞的总RNA,用RT-PCR检测CD基因的表达。结果:PCR扩增出1280bp大小的片段,测序结果与GeneBank报道的CD序列基本一致;阳性重组质粒pIRES-CD经XbaI和NotI双酶切后,获得6.1kb和1280bp的片段;RT-PCR从转染细胞的总RNA中扩增出228bp的预期片段。结论:成功扩增了CD基因的DNA片段;成功构建了质粒表达载体pIRES-CD;建立了稳定表达CD基因的ACC-2细胞系,为CD/5-FC自杀基因系统在腺样囊性癌基因治疗中的应用奠定了基础。

一个包含HCVIRES的高效真核双顺反子表达载体的构建

In this paper, a new eukaryotic bi-cistronic expression vector containing Hepatitis C Virus(HCV) internal ribosome entry site (IRES) expressing two foreign genes from one mRNA was constructed. The sequence starting from the 5’ untranslated region of 18nt to 32nt in HCV core coding region was cloned and then the encephalomyocarditis virus (ECMV) IRES sequence in the commercial vector pIRES was substituted to construct a new vector pCVIR. Green fluorescent protein (GFP) and Hepatitis B virus surface antigen (HBsAg) coding genes were inserted up-stream and down-stream of IRES sequence. The fluorescence intensity of GFP and HBsAg were determined by flow cytometry and ELISA respectively., thus, the expression efficiency of the two vectors, pCVIR and pIRES could be compared. The experimental results showed that the vector pCVIR could translate the GFP and HBsAg genes down-stream of its HCV IRES sequence more efficiently without impairing the expression of genes up-stream of IRES sequence than the vector pIRES.It is concluded that a new eukaryotic bi-cistronic expression vector containing HCV IRES was constructed successfully by the method described above.