一种强启动子的分离与功能

以棉花曲叶病毒（ＣＬＣｕＶ）侵染的番茄叶片组织总ＤＮＡ为模板,通过ＰＣＲ反应扩增ＣＬＣｕＶ双向启动子片段并插入克隆载体。序列分析和同源性比较表明,克隆的启动子长４３６ｂｐ,与目前发现的４类ＣＬＣｕＶ分离物的启动子序列的同源性最高为９９．３２％。将启动子片段分别以不同方向与ｇｕｓ报告基因和ｎｏｓ终止子融合,构建了瞬时表达载体。通过基因枪法将质粒载体导入烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ Ｌ．）     

水稻蜡质基因5＇上游区缺失对基因表达的影响

为研究水稻蜡质基因（ｗａｘｙ）５＇上游调控区中存在的顺式作用元件,我们将水稻ｗａｘｙ基因翻译起始声、（ＡＴＧ）５＇上游３．４ｋｂ（－２１１８～＋１２９１ｂＰ）片段经外切核酸酶ＥｘｏⅢ部分酶解,得到一系列５＇端缺失的片段。将这些缺失片段分别与ｇｕｓ基因编码区连接,构建成融合质粒,经ＰＥＧ介导引入水稻原生质体,２６℃培养４８ｈ后,定量测定ＧＵＳ酶活力,并以同时导入的由３５Ｓ启动子指导的荧光素酶（ＬＵＣ）基因表达的酶活力作为内对照。结果表明,ＧＵＳ酶活性随５’上游调控区长度的减少而逐渐减弱。由─８６１ｂｐ缺失至─６４０ｂＰ时,ｇｕｓ基因表达水平有较明显的降低,推测在该区域中可能存在一个顺式作用元件区。     

人类连接蛋白基因Cx26的新调控区序列

人类连接蛋白２６基因（ｃｏｎｎｅｘｉｎ２６,Ｃｘ２６）已被看作乳腺癌上皮细胞中的抑瘤基因候选者。为了阐明此基因的调控机理,本文对其转译起始点上游的一个ＤＮａｓｅ１超敏区片段１．６ｋｂ进行了序列分析和ＣＡＴ报告基因分析。结果表明此１．６ｋｂ片段具有强效启动子功能,其中含有两个ＧＴ盒（分别位于－６１５８ｂｐ和－６２１３ｂｐ）,一个非ＴＡＴＡ的ＴＴＡＡＡＡ盒位于－６２３７ｂｐ,这是在人类Ｃｘ２６基因中新发现的第二个启动区。     

人淋巴细胞CD2基因5’侧翼序列的克隆和鉴定

本文报告以ＣＤ２ｃＤＮＡ５’端的片段作探针,从人Ｔ淋巴细胞基因组文库筛选阳性重组克隆,经限制性内切酶降解和Ｓｏｕｔｈｅｒｎ杂交分析,证明其中一个阳性克隆的插入片段中含ＣＤ２基因５’侧翼顺序。经插入片段的亚克隆、限制性内切酶图谱及ＤＮＡ序列分析,鉴定出一含转录起始点及其上游序列的４．０ｋｂ片段。将此片段中含转录起始点和两个ＤＮ（ａｓｅ）Ⅰ高敏感位点的２．５ｋｂ片段定向克隆到以虫萤光素酶为报告基因的表达载体ｐＭＧ３中,并用限制性内切酶对此２．５ｋｂ片段作不同程度缺失,构成一系列突变子。这些重组的表达质粒转染人ＪｕｒｋａｔＴ细胞后,以瞬时表达实验分析各突变子驱动虫萤光素酶基因的表达,结果发现在ＣＤ２基因５’上游具有很弱的启动子活性,初步测定该启动子位于－１．２ｋｂ～－９８ｂｐ域。ＣＤ２基因具有弱启动子、强增强子的特点与Ｔ细胞表面其它抗原分子基因是相似的。     

拟南芥生长素受体基因TIR1启动子的初步分析

以野生型拟南芥（Arabidopsis Columbia）基因组DNA为模板,通过PCR扩增得到拟南芥生长素受体基因T1R1启动子的5个不同长度的系列缺失片段,将这些片断分别克隆到PGM—T载体上。序列分析表明,该启动子系列缺失片段的大小分别为2008bp、1524bp、939bp、532bp和321bp。与已报道的序列完全相同。将不同长度的启动子克隆片断分别与GUS基因融合,构建成表达载体后,在烟草叶片中作遗传转化。分析结果显示：不同长度的启动子片段已整合到烟草基因组中并有GUS酶活性存在,且不同长度启动子片段的表达活性有较明显差异。     

水稻cDNA c73片段在大肠杆菌中的表达及其产物的纯化

曾以水稻蜡质基因５’调控区内一段３１ｂｐ片段为探针,用酵母单杂交法从水稻ｃＤＮＡ文库中筛选出若干个其编码的蛋白可能与此３１ｂｐ片段结合的ｃＤＮＡ克隆,现将其中的ｐＣ７３克隆中的插入片段ｃ７３连接到含Ｈｉｓ６的表达载体ｐＥＴ２８－ｃ（＋）上,在大肠杆菌ＢＬ２１（ＤＥ３）中进行诱导表达,并用Ｎｉ－ＮＴＡ树脂纯化得到预期的融合表达产物。在合适的诱导表达条件下,融合表达产物主要以可溶形式存在于大肠杆菌细胞     

CS3纤毛抗原表达调控机理的研究

ＣＳ３是某些肠毒素大肠杆菌菌体表面上的多聚物,它能使病原菌粘附于宿主的小肠上皮细胞上,是致病的重要因素．为了探索ＣＳ３菌毛抗原基因的表达调控机制,根据ＣＳ３亚基结构基因的核苷酸序列分析表明,在其翻译起始位点的上游存在着ｒｂｓ位点及原核启动子的－１０区和－３５区ＤＮＡ序列．采用基因重组技术将ＣＳ３结构基因上游１２０ｂｐ的ＤＮＡ片段亚克隆进缺乏启动子而只含报告基因ｌａｃＺ的质粒ｐＣＢ２６７中．凝胶滞留和启动报告基因表达的实验证明了ＣＳ３亚基结构基因具有自身的启动子（Ｐｓ）．将该启动子上游区域不同长度的核苷酸片段克隆进ｐＣＢ２６７中,报告基因表达结果表明ＣＳ３结构基因的表达受其上游区域的抑制．核苷酸序列分析发现,在Ｐｓ－３５区上游５５０ｂｐ和８４０ｂｐ处各存在一个富Ａ－Ｔ簇．结合原核启动子的一般作用规律推知,ＣＳ３的表达可能受ＤＮＡ结合蛋白型的正向调节因子的作用．用ＣＦＡ／１菌毛抗原基因的正向调节基因ｃｆａＤ对ＣＳ３基因进行的互补表达试验表明ｃｆａＤ基因不仅可消除上游区对Ｐｓ的抑制,而且可大幅度地提高Ｐｓ的启动能力．在分析表达调控的基础上获得ＣＳ３重组高效表达．同时提出了其表达调控模型．     

种子特异表达ipt转基因棉花根和纤维的改变

将种子特异表达的菜豆蛋白启动子（Ｐｈ／Ｐ）与ｉｐｔ基因融合,构建了植物表达载体。该载体含有由３５Ｓ启动子驱动的ｇｕｓ报告基因。应用该载体通过花粉管通道法转化棉花（Ｇｏｓｓｙｐｉｕｍ ｈｉｒｓｕｔｕｍ Ｌ．）,种子萌发后剪取幼根进行ＧＵＳ染色,获得ＧＵＳ阳性植株２３棵。ＰＣＲ检测证明有３棵ＧＵＳ阳性植株中含有Ｐｈ／Ｐ－ｉｐｔ基因,并进一步用地高辛标记的ＤＮＡ探针作杂交验证了上述结果。分析表明２棵转基     

粘虫核型多角体病毒凋亡抑制基因的定位,序列和启动子结构

以ＡｃＮＰＶ凋亡抑制基因ｐ３５为探针,与ＬｓＮＰＶＤＮＡ的限制性片段和ＬｓＮＰＶＤＮＡＥｃｏＲＶ片段杂交,发现ＥｃｏＲＶ５．５ｋｂ片段有强烈的杂交信号。将此片段亚克隆后,测定了１２４４ｂｐ序列,发现一个完整的ＯＲＦ,推导的３０２个氨基酸与ＡｃＮＰＶｐ３５蛋白有７０．４％的氨基酸同源性,证明所测ＯＲＦ为ＬｓＮＰＶ的ｐ３５基因。结构分析发现其５′端有早期基因启动子元件ＧＣ、ＡＣＧＴ和ＴＡＴＡｂｏｘ。有２２ｂｐ的顺向重复序列,包括由两个重叠的ＴＡＴＡｂｏｘ和上下游两个ＡＣＧＴｍｏｔｉｆ组成的两套启动子元件,这些结构特征与ＡｃＮＰＶ的凋亡抑制基因十分相似。     

cIts857基因的克隆,修饰及温敏诱导表达载体

从噬菌体λＤＮＡ克隆出９９０ｂｐ的ｃＩｔｓ８５７基因,经缺失,点突变等修饰改造和ＤＮＡ序列测定,获得了带有自身启动子区的修饰型ｃＩｔｓ８５７基因（７７０ｂｐ）。进而利用它大肠杆菌表达载体ｐＢＬＭＶＬ２和一套含３种不同阅读框架Ｉｉｎｋｅｒ区的表达载体ｐＢＬＭＦＶ４、５Ｂ、６。上述表达载体,用于表达人工合成的牛生长激素、人干扰素－γ△Ｃ－１３和酵母ｐｈｏ８５等外源基因,都观察到这些基因产物的温敏表达。     

Analysis of the Maize 19 kD Zein Gene Promoter Fragment Driving Seed specific Expression

A deletion works of a maize 19 kD zein gene promoter in the 5'end was performed and six promoter fragments of different length were obtained. A series of expression vectors was constructed and then transferred into tobacco ( Nicotiarta tabacum L. ) plants. GUS activity assays indicated that the expression of 488 bp promoter was tissue-specific, for which GUS was active only in transgenic tobacco seeds. The other four fragments containing 378 bp,302 bp,152 bp and 124 bp also have the activity of promoter. They could drive gus gene expressed not only in seeds but also in roots and petioles.     

玉米醇溶贮藏蛋白基因启动子PCR扩增及其驱动GUS基因在转基因烟草种子中的表达

以玉米(Zea mays L.)黄化苗为材料,利用PCR技术扩增了玉米19kDa醇溶贮藏蛋白基因(zein)起始密码子上游启动子片段,序列分析结果表明,克隆的-1～-694片段具有19kDa zein启动子特点,与同一家族中其它基因的对应区段同源性达90％以上。将此启动子插入pPKGT的GUS基因及NOS终止子上游构成表达载体。经农杆菌转化烟草(Nicotiana tabaccum Var.samsum),得到了转化植株。转化的烟草的PCR扩增及Southern杂交证明目的片段已整合到烟草基因组中。转基因植株的GUS活性检测表明,在叶、根中无GUS活性,GUS活性只存在于种子中。转基因植株烟草种子经冷冻切片,GUS底物Xgluc活体组织染色证明GUS活性只存在一层介于种子胚乳与种皮之间的细胞中。     

竹节花黄斑驳病毒启动子的缺失分析及功能

竹节花黄斑驳病毒(CoYMV)是侵染单子叶植物竹节花的一 种双链环状DNA病毒,它的启动子可介导外源基因在烟草韧皮部特异表达。为了研究其组织 特异性表达的最佳启动子区域,对CoYMV启动子进行了5′端五种不同长度的缺失分析,用不同长度的启动子片段与GUS基因及NOS3′端转录中止序列构建了全长启动子及5 个缺失启动子序列的六个嵌合GUS基因植物表达载体。利用农杆菌将上述嵌合基因转化烟草 外植体后,每种表达载体都获得了一批转基因烟草植株。转化再生烟草植株的PCR分析、GUS 酶活测定及GUS组织染色的结果表明六种类型的嵌合基因已整合到烟草染色体中,并有五种 表达出GUS活性。缺失到870bp的启动子比全长启动子(1040bp)的活性约高78%,870bp比585bp启动子介导的GUS活性略高但差别不明显,缺失到447和232时GUS活性有明显下 降,但仍具有韧皮部特异表达的特性。当缺失到TATA box附近的44bp时启动子丧失组织特 异性,GUS活性也降低到测不出来的水平。以上结果表明CoYMV启动子从转录起始位点上游 870bp～230bp及232bp下游区分别与启动子的活性和韧皮部组织特异性密切相关,870bp上游可能存在一个负调控序列,所以该启动子的活性和组织特异性的最佳调控区应在87 0bp或585bp的下游区。CoYMV启动子与35S启动子驱动GUS基因在烟草中表达的活性相比, 前者为后者的70%左右,考虑到前者仅在韧皮部细胞表达而后者为组成型表达,所以CoYMV启 动子在韧皮部的活性可能与35S启动子相当或更高。CoYMV启动子在其它转基因植物中驱动外 源基因表达的特点正在研究中。     

Cotton α-Globulin Promoter: Isolation and Functional Characterization in Transgenic Cotton,Arabidopsis, and Tobacco

Globulins are the most abundant seed storage proteins in cotton and, therefore, their regulatory sequences could potentially provide a good source of seed-specific promoters. We isolated the putative promoter region of cotton -globulin B gene by gene walking using the primers designed from a cotton staged embryo cDNA clone. PCR amplified fragment of 1108 bp upstream sequences was fused to gusA gene in the binary vector pBI101.3 to create the test construct. This was used to study the expression pattern of the putative promoter region in transgenic cotton, Arabidopsis, and tobacco. Histochemical GUS analysis revealed that the promoter began to express during the torpedo stage of seed development in tobacco and Arabidopsis, and during cotyledon expansion stage in cotton. The activity quickly increased until embryo maturation in all three species. Fluorometric GUS analysis showed that the promoter expression started at 12 and 15 dpa in tobacco and cotton, respectively, and increased through seed maturation. The strength of the promoter expression, as reflected by average GUS activity in the seeds from primary transgenic plants, was vastly different amongst the three species tested. In Arabidopsis, the activity was 16.7% and in tobacco it was less than 1% of the levels detected in cotton seeds. In germinating seedlings of tobacco and Arabidopsis, GUS activity diminished until it was completely absent 10 days post imbibition. In addition, absence of detectable level of GUS expression in stem, leaf, root, pollen, and floral bud of transgenic cotton confirmed that the promoter is highly seed-specific. Analysis of GUS activity at individual seed level in cotton showed a gene dose effect reflecting their homozygous or hemizygous status. Our results show that this promoter is highly tissue-specific and it can be used to control transgene expression in dicot seeds.     

Cloning of a new LEA1 gene promoter from soybean and functional analysis in transgenic tobacco

LEA1 gene from Glycine max can be expressed in late-embryo stage of plants, and respond to salinity and dehydration stress. To elucidate the mechanism for stress tolerance and high expression in seeds, we isolated and characterized the promoter of LEA1 gene (EQ, 1997 bp) starting the 5′LEA1 coding region. A deletion mutant of EQ promoter (ED) and the full length promoter (EQ) were fused to GUS reporter gene and transformed into the tobacco leaf discs. The results indicated that expression of the reporter gene (GUS) could be regulated by EQ promoter, and was stronger than the mutant under the stress conditions. Also, the expression level of GUS gene driven by EQ promoter in transgenic tobacco seeds was significantly higher than that by the mutant promoter, which meant that it had a better tissue-specificity. Therefore, the active domain for the promoter was located between ?1997 and ?1000 bp. Additionally, the activity of EQ promoter was 2.1-, 3.3- and 0.4- times stronger than the activity of promoter CaMV35S under salt (24 h), drought (10 h) or ABA (24 h), respectively. Meanwhile, the GUS activity of EQ promoter in seeds was 1.8-fold stronger compared to the promoter CaMV35S. In summary, the new promoter (EQ) is bi-functional, stress-inducible and seed-specific. These findings provide a further understanding for the regulation of LEA1gene expression, and suggest a new way for improving seed quality under saline and alkaline land.