通过诱导剂作用于启动子的条件性基因表达

通过遗传工程技术获得的转基因动植物对分析某些生化过程和发育途径极为有用。通过化学诱导剂作用于启动子的条件性基因表达是分子生物学和生物技术应用研究中的强有力的手段。建立于目标基因激活和失活基础之上的几个究子诱导基因表达系统已有报道。将来自于原核生物、昆虫和其它动物的调节因子应用于新的物种有利于促进转基因技术的应用和有关基因的时空表达研究。本文综述了有关的基因表达调节系统,启动子激活的基因表达系统,启动子失活的基因表达系统,以及可诱导的基因过度表达和反义抑制系数。     

化学诱导表达系统及其在植物中的应用

化学诱导启动子可以在特定时间和部位激活或抑制目的基因的表达。目前,已经建立了多种化学诱导表达系统,用于基因功能分析、无标记植物转化、特定位点DNA切除、育性恢复和RNA沉默等方面的研究。化学诱导表达系统为基础分子生物学研究和生物技术应用提供了强有力的工具,将大大加快植物转基因技术的应用。     

p16表达异常与肿瘤关系的研究进展

作为一种抑癌基因,p16能通过阻遏细胞周期而抑制细胞增殖,p16基因失活亦是肿瘤发生发展与侵袭转移的重要因素。导致p16失活的原因主要包括基因缺失或突变,以及基因启动子甲基化所致的表观遗传性表达抑制。但在部分肿瘤组织中,p16表达显著性上调,这可能是致癌因素激活p16基因表达的结果。本文简要综述近年来p16基因表达与肿瘤相关性的研究进展。     

植物逆境相关启动子及功能

启动子是调控基因表达的重要顺式元件, 在植物基因表达调控过程中起着重要作用。目前植物抗逆基因工程中, 人们大多使用组成型表达启动子驱动目的基因的表达。组成型表达启动子虽然能提高转基因植株的抗逆性, 但是其持续过量地表达转化的外源基因会阻碍植物的生长且减少其产量。因此, 只在胁迫条件下才会驱动外源基因表达的诱导型启动子的研究显得尤其重要, 已成为目前研究的热点。文章综述了受非生物逆境和生物逆境胁迫诱导的植物基因启动子的种类和功能, 并展望了植物逆境诱导启动子的研究方向和前景。     

时空表达可控的转基因动物模型调控体系的研究

目的在血管内皮细胞建立时空表达可控的转基因动物模型调控体系。方法培育两个配套的转基因动物品系,利用组织专一性启动子确保转基因表达的空间专一性,利用四环素诱导系统对转基因表达在时间上实施调控。结果将血管内皮细胞特异性表达的VE cadherin基因启动子与人工融合的转录因子tTA基因连接,建立转基因小鼠品系VE cadherin:tTA;将tetoperon的启动子与myrAkt1连接,建立转基因小鼠品系TET:myrAkt1。两系鼠杂交的子代,筛选的阳性纯合子,能可控性地在血管内皮细胞特异性表达目的基因Akt1PKB。结论利用VE cadherin基因启动子和tet off诱导表达系统,可以达到在时间上和空间上都能人为控制目的基因在血管内皮细胞上特异性表达的目的。     

Strict Regulation of Gene Expression Utilizing a Dual-control Gene Expression Vector System

可严格调控性是体现原核表达载体优越性的重要指标。构建了一种双控双调节原核表达载体系统,用双载体控制调节目的基因的表达,即SP6启动子（promoter）＋乳糖（lac）调节基因表达系统和araB启动子（promoter）＋ara C调节基因表达系统,分别由乳糖类似物IPTG和阿拉伯糖（L-arabinose）诱导目的基因的表达。该系统由2个表达载体共同完成目的基因的表达。pE SP-1为主表达载体,即目的基因克隆到此表达载体上,由SP6启动子（promoter）＋乳糖（lac）调节基因调控;pA RA-SP6为辅助表达载体,该载体通过SP6 RNA聚合酶的表达来控制调节主表达载体的启动子（SP6）,由araB启动子（promoter）＋ara C调节基因调控。实验结果显示该双控双调节表达载体系统控制严格,并且表达蛋白的量具有可调控性。     

双控表达载体系统的构建及其在基因表达方面的应用（英文）

可严格调控性是体现原核表达载体优越性的重要指标。构建了一种双控双调节原核表达载体系统,用双载体控制调节目的基因的表达,即SP6启动子(promoter)+乳糖(lac)调节基因表达系统和araB启动子(promoter)+ara C调节基因表达系统,分别由乳糖类似物IPTG和阿拉伯糖(L-arabinose)诱导目的基因的表达。该系统由2个表达载体共同完成目的基因的表达。pE SP-1为主表达载体,即目的基因克隆到此表达载体上,由SP6启动子(promoter)+乳糖(lac)调节基因调控;pA RA-SP6为辅助表达载体,该载体通过SP6 RNA聚合酶的表达来控制调节主表达载体的启动子(SP6),由araB启动子(promoter)+ara C调节基因调控。实验结果显示该双控双调节表达载体系统控制严格,并且表达蛋白的量具有可调控性。     

一种新型的生物素诱导的真核基因表达调控系统的建立

为建立一种适用于生物制药工业和基因治疗领域的基因表达调控系统,构建枯草芽胞杆菌生物素连接酶(BS-BirA)与转录激活结构域的融合蛋白,以其表达载体为调控载体;在弱化的CMV启动子上游连接BS-BirA特异的操纵子序列,获得响应载体,从而得到响应于生物素的真核基因表达调控系统BS-Biotin-On。以增强型绿色荧光蛋白(EGFP)为报告基因对该系统进行考察,结果表明,与现有的类似调控系统相比,该系统具有良好的诱导率;可通过调节培养体系中生物素的浓度,实现对目的基因表达水平快速、较高效的调节。上述结果表明,BS-Biotin-On系统可能为外源基因的调控表达提供新的选择。     

植物转基因的失活与沉默

植物外源基因转化研究揭示有相当比例的植物转基因表现失活与沉默。这一现象涉及转基因重复拷贝之间的异源配对,基因顺序的甲基化,转录后的衰退调控以及插入位点染色质高级结构的改变,并与外源基因的随机整合有关。克服转基因失活的方法包括单拷贝转基因子代筛选,构建细胞核基质支架附着区载体以及采用具有特殊功能的启动子与增强子。转基因失活问题的发生提示人们,外源基因的转化与整合存在一些特有的遗传机制。     

DNMT3a通过提升基因内部甲基化介导紫杉醇诱导的LINE-1异常表达

药物诱导的长散在重复序列LINE-1异常激活可促进细胞基因组不稳定,而基因组不稳定是促进肿瘤发生发展和耐药表型形成的重要因素。因此,探索LINE-1异常激活的分子机制具有重要的理论和临床意义。DNA甲基化是调控基因表达的重要方式,已知DNA甲基转移酶家族成员DNMT3a不仅能通过促进基因启动子甲基化抑制基因表达,还可通过增强基因内部甲基化上调基因表达。本实验室前期研究发现,将乳腺癌细胞暴露于化疗药物可诱导LINE-1异常高表达,但LINE-1启动子甲基化水平并无显著改变。本研究进一步探讨了在化疗药物压力下DNMT3a是否可通过增强LINE-1基因内部甲基化水平促进LINE-1在乳腺癌细胞中的异常高表达。ChIP实验和甲基分析结果显示,用化疗药物紫杉醇(PTX)处理乳腺癌细胞,不仅可以诱导DNMT3a表达,而且可以促进DNMT3a与LINE-1基因内部区域的结合,提升其基因内部甲基化水平,进而上调LINE-1的表达水平。利用表达载体增加细胞内DNMT3a的表达水平,可显著上调LINE-1基因内部的甲基化及基因的表达水平,而下调DNMT3a的表达可有效抑制LINE-1表达。上述研究结果表明,DNMT3a介导的基因非启动子区甲基化在药物诱导的LINE-1异常激活中发挥重要作用,为认识LINE-1在乳腺癌化疗耐药性形成过程中异常激活的机制提供了新思路。     

A preliminary analysis of antineoplastic activity of parvovirus MVMp NS—1 proteins

Human gastric cancer MKN-45 cells were transfected with pULB 3238,a plasmid carrying MVMp MS-1 gene with its original P4 promoter replaced by the glucocorticoid inducible promoter MMTV-LTR.After the integration and expression of NS-1 gene,some of the transfectants died,while others remained alive,but the growth features of survived cells were changed.For further study on the antineoplastic function of parvoviral NS-1 protein in vivo,transgenic mice carrying NS-1 genes were established by conventional method.Among 4 founders,one of them was found to be able to transmit the transgene to around 50% of their offsprings.RT-PCR was performed to indicate the expression of NS-1 gene in transgenic mice and its mRNA appeared in a variety of tissues.The expression of integrated NS-1 gene may correlate with the decreased incidence of tumor induced in vivo by chemical carcinogens.     

重组DNA技术中可诱导的基因表达调控系统

在重组DNA技术中,可诱导的基因表达调控系统可被用来调节目的基因的表达以达到基因功能研究、转基因动物研究、以及基因治疗研究等目的。该系统主要由诱导剂、可诱导的受体或转录因子、顺式作用元件以及载体系统四部分组成。本文以诱导剂为分类依据,叙述目前主要的6类可诱导的基因表达调控系统:类固醇激素受体诱导的基因表达调控系统、四环素诱导的基因表达调控系统、缺氧诱导的基因表达调控系统、高热诱导的基因表达调控系统、电离辐射诱导的基因表达调控系统和lac基因表达调控系统。     

The Expression of GUS Gene Driven by T-cyt Promoter in Transgenic Tobacco andPotato

The location of GUS gene expression under control of T-cyt gene (gene 4 of T- DNA coding isopenteryl transferase) 5′ region in transgenic tobacco (Nicotiana tabacum cv. W38) and potato (Solanum tuberosum L, cv. Desiree) plants was examined with biochemical assays. The results showed differential distribution in various organs and different cell types. The highest levels of GUS activity were found in tobacco stem where axillary bud was initiated and potato buds on tubers. Moreover, the expression of T-cyt promoter/GUS was found to be inducible in transgenic tobacco stem with cytokinin rather than auxin treatment. Additionally, the level of expression was high in the wounded leaf of transgenic potato. It was suggested that T-cyt promoter may be selectively induced by some exogenous plant hormones.     

Double-inducible gene activation system for caspase 3 and 9 in epidermis

Expression of genes with tight and precise temporal and spatial control is desired in a wide variety of applications ranging from cultured cells and transgenic animals to gene therapy. While current inducible systems, such as RU486 and chemical inducers of dimerization (CID), have improved earlier inducible models (Gossen et al., 1995, Science. 268:1766-1769; Wang et al., 1994, Proc Natl Acad Sci USA 91:8180-8184), no single system is perfect at present. One potential drawback of these systems is leakage of transgene expression, causing limitations of each system. We have developed an inducible model containing both RU486 and CID systems, which in addition to inducing caspase activation, has potential applicability specifically to other genes encoding proteins that require a dimerization event for activation. This Double-Inducible Gene Activation System generates two barriers for the target gene expression and protein activation thereby minimizing leakage.     

Dexamethasone-inducible green fluorescent protein gene expression in transgenic plant cells

Genomic research has made a large number of sequences of novel genes or expressed sequence tags available. To investigate functions of these genes, a system for conditional control of gene expression would be a useful tool. Inducible transgene expression that uses green fluorescent protein gene (gfp) as a reporter gene has been investigated in transgenic cell lines of cotton (COT; Gossypium hirsutum L.), Fraser fir [FRA; Abies fraseri (Pursh) Poir], Nordmann fir (NOR; Abies nordmanniana Lk.), and rice (RIC; Oryza sativa L. cv. Radon). Transgenic cell lines were used to test the function of the chemical inducer dexamethasone. Inducible transgene expression was observed with fluorescence and confocal microscopy, and was confirmed by northern blot analyses. Dexamethasone at 5 mg/L induced gfp expression to the nearly highest level 48 h after treatment in COT, FRA, NOR, and RIC. Dexamethasone at 10 mg/L inhibited the growth of transgenic cells in FRA and NOR, but not COT and RIC. These results demonstrated that concentrations of inducer for optimum inducible gene expression system varied among transgenic cell lines. The inducible gene expression system described here was very effective and could be valuable in evaluating the function of novel gene.