利用瞬时表达系统研究马铃薯Y类病毒基因对豌豆Hsp70基因启动子激 …

建立了一个瞬时表达系统以研究豌豆种传花叶病毒（ＰＳｂＭＶ,一种马铃薯Ｙ类病毒）不同基因对豌豆（Ｐｉｓｕｍ ｓａｔｉｖｕｍ Ｌ．）Ｈｓｐ７０基因启动子激少能力的差划。构建了豌豆Ｈｓｐ７０基因启动子指导下的ＧＵＳ基因的表达载体,同时还制备了３５Ｓ启动子指导下的ＰＳｂＭＶ Ｐ１和Ｐ３基因的表达载体。以表达载体ＤＮＡ包被才金焰做子弹,利用基因枪对豌豆离体叶片进行共轰击实验,结果表明,ＰＳＢＭＶ Ｐ１和Ｐ３     

异戊烯基转移酶基因在转基因烟草中的特异性表达

来自农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ ｔｕｍ ｅｆａｃｉｅｎｓ）的细胞分裂素生物合成基因——异戊烯基转移酶基因（ｉｐｔ）与矮牵牛（Ｐｅｔｕｎｉａ ｈｙｂｒｉｄａ Ｖｉｌｍ ．）中的磷酸核酮糖羧化酶小亚基启动子（ＳＳＵ）融合后转入烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ Ｌ．）。在转基因烟草中研究了这种嵌合基因的特异性表达,并且测定了内源细胞分裂素水平的变化。结果表明,矮牵牛的ＳＳＵ 启动子能够特异性地控制ｉｐｔ基因在烟草中的表达     

紫云英细胞转化条件的研究

研究了紫云英（ＡｓｔｒａｇａｌｕｓｓｉｎｉｃｕｓＬ．）细胞遗传转化的条件。根癌农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍｔｕｍ ｅｆａｃｉｅｎｓ）经含乙酰丁香酮的低ｐＨ／ＰＯ３－４ 诱导培养后,用来感染紫云英下胚轴原生质体,随后的细胞ＧＵＳ瞬间表达活性显著提高,间接证明了上述预培养诱导活化了细菌ｖｉｒ基因,促进了Ｔ－ＤＮＡ 向植物细胞转移。在ＰＥＧ介导的ＤＮＡ 转移中,较高的ｐＨ 和Ｃａ２＋ 浓度能够提高细胞ＧＵＳ活性。质粒ＤＮＡ 浓度及启动子类型对外源基因在植物细胞内表达也有一定影响。采用外植体－农杆菌共培养法,获得ＧＵＳ和ＮＰＴ Ⅱ基因稳定表达的紫云英转化植株     

绿色荧光蛋白基因在青蒿转基因芽中的表达

将改良的绿色荧光蛋白（ＧＦＰ）基因,插入到植物表达载体中,构建双ＣａＭＶ３５Ｓ启动子驱动下的植物表达载体ｐＢＩＧＦＰ,在Ｋａｍ浓度为２０ｍｇ／Ｌ的筛选培养基上,用含有ｐＢＩＦＰ质粒的根癌农杆菌ＬＢＡ４４０４感染青蒿叶片,获得５个抗Ｋａｎ阳性丛生芽系。Ｓｏｕｔｈｅｒｎ ｂｌｏｔｔｉｎｇ分析表明,外源ＧＦＰ基因已整合到青蒿转基因芽Ｇ－１系的基因组中。在ＯＬＹＭＰＵＳ－ＢＨ２型荧光显微镜下,观察到转基因     

细胞分裂素基因（T—cyt）启动子驱动下的GUS基因在烟草和马铃薯中的表达

构建了来自根癌农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ ｔｕｍ ｅｆａｃｉｅｎｓ） Ｔ－ＤＮＡ 的细胞分裂素基因（Ｔ－ｃｙｔ）启动子驱动下的ＧＵＳ基因的表达质粒,并用以转化烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ ｃｖ． Ｗ ３８）和马铃薯（Ｓｏｌａｎｕｍ ｔｕｂｅｒｏ－ｓｕｍ Ｌ． ｃｖ． Ｄｅｓｉｒｅｅ）,研究其在转基因植物中表达的定位。结果表明,Ｔ－ｃｙｔ启动子在转基因植株的根、茎、叶、块茎和萌发的种子中均可表达。其中在茎和块茎中的表达是不均一的：在维管束部分表达较强,在侧芽或叶柄的生长点及块茎的芽生长点表达活性较高。此外,在培养基中加入０．１ ｍ ｇ／ＬＢＡＰ,转基因烟草茎中ＧＵＳ基因的表达活性增强,而对ＮＡＡ 没有明显的反应。看来某些外源植物激素对Ｔ－ｃｙｔ启动子的活性有一定的诱导作用     

促红细胞生成素基因表达载体的构建及其在CHO细胞中表达的研究

用从基因文库中所克隆的促红细胞生成素（ＥＰＯ）基因组基因,构建了３种由不同启动子调控的表达载体——ｐＯＰ１３／ＥＰＯ,ｐＲＳＶ／ＥＰＯ,ｐＣＭＶ／ＥＰＯ,在这３个表达载体的构建过程中对基因的转录起始效率、内含子的剪接、５′非翻译区和３′非翻译区对基因表达的影响等因素都加以考虑．用脂质体转染法分别将上述３个载体导入ＣＨＯ细胞,经瞬时表达,用ＥＬＩＳＡ方法检测,表达量分别为１９０ｍＩＵ／ｍｌ、１６０ｍＩＵ／ｍｌ、４４７ｍＩＵ／ｍｌ．用表达载体ｐＯＰ１３／ＥＰＯ转染ＣＨＯ－Ｋ１２细胞,在４００μｇ／ｍｌ的Ｇ４１８浓度下筛选稳定表达细胞克隆,获得了表达量约为１６０ＩＵ／１０６细胞（４８ｈ）的Ｃ１０细胞株．表达产物经Ｗｅｓｔｅｒｎｂｌｏｔ检测发现了ＥＰＯ阳性条带．用ＴＦ－１细胞对ＥＰＯ进行了生物活性检测,初步证实所表达的ＥＰＯ有生物活性．     

利用大肠杆菌克隆在原核生物中有活性的油菜基因启动子

利用本室构建的基因启动子探针型载体ｐＳＵＰＶ４直接在大肠杆菌（Ｅｓｃｈｅｒｉｃｈｉａｃｏｌｉ（Ｍｉｇｕｌａ）ＣａｓｔｅｌａｎｉｅｔＣｈａｌｍｅｒｓ）中分离油菜（ＢｒａｓｉｃａｎａｐｕｓＬ．）基因启动子片段,获得卡那霉素抗性重组子３３个。对重组子ｐＲＰ１０做了进一步鉴定：Ｓｏｕｔｈｅｒｎ杂交表明ＲＰ１０片段来自油菜基因组,并与基因组中的另一些序列具有同源性;ＲＰ１０片段５′端区域的缺失可使卡那霉素抗性水平从１００ｍｇ／Ｌ降至２５ｍｇ／Ｌ,说明缺失的序列可能影响基因转录效率;序列分析发现ＲＰ１０片段内存在几个真核基因启动子的保守序列;用根癌农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍｔｕｍｅｆａｃｉｅｎｓ（ＳｍｉｔｈｅｔＴｏｗｎｓｅｎｄ）Ｃｏｎｎ）转化法将ＲＰ１０ＧＵＳ基因转入油菜,组织化学分析显示ＲＰ１０在愈伤组织中可以启动融合的ＧＵＳ基因表达     

玉米19kD醇溶贮藏蛋白基因启动子种子特异性表达控制区段的分析

为研究玉米（Ｚｅａｍａｙｓ　Ｌ．）１９ｋＤ醇溶贮藏蛋白（ｚｅｉｎ）基因启动子种子特异性表达的控制区段,将全长６９４ｂｐ的启动子进行５’端缺失,共得到６个缺失突变体,长度分别为４８８ｂｐ、３７８ｂｐ、３０２ｂｐ、１５２ｂｐ、１２４ｂｐ和８５ｂｐ。将６个片段分别与报告基因ｇｕｓ连接构建成表达载体ｐＤＧＢ系列,经土壤农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ）介导转化,引入烟草。ＧＵＳ活性检测证明,４８８ｂｐ启动子片段能促使ｇｕｓ基因在种子中特异表达。３７８ｂｐ、３０２ｂｐ、１５２ｂｐ和１２４ｂｐ片段启动子引导的ｇｕｓ基因在烟草根、叶柄、种子中均可表达。     

Epstein-Barr病毒BNLF-1基因的克隆及其在PA317细胞中的表达

本文报道以人Ｅｐｓｔｅｉｎ－Ｂａｒｒ病毒的潜伏膜蛋白基因ＢＮＬＦ－１作为目标基因,插入至逆转录病毒载体ｐＺｉｐＮｅｏＳＶ（ｘ）的克隆位点上,由此获得重组逆转录病毒载体ｐＺｉｐＮｅｏＳＶ（ｘ）－ＬＭＰ及其反义载体ｐＺｉｐＮｅｏＳＶ（ｘ）－ａｎｔｉ－ＬＭＰ,通过质粒ＤＮＡ的电转染和Ｇ４１８培养基筛选,然后对１０个抗性克隆进行基因整合分析,获得６个含ＭＬＶ－ＬＴＲ／ＢＮＬＦ－１融合基因的阳性克隆,采用Ｎｏｒｔｈｅｒｎ杂交及Ｗｅｓｔｅｒｎ印迹证明,在克隆细胞中表达了２．６ｋｂ的ｍＲＮＡ片段及相应的蛋白质分子,这是由ＢＮＬＦ－１基因的ＥＤＬ１启动子表达的产物。     

pINC－lacZ逆转录病毒载体的构建及其在小鼠胚胎干细胞中的表达

小鼠胚胎干细胞系（ＥＳ）是从囊胚的内细胞团中建立起来的多潜能胚胎干细胞系。ＥＳ细胞系目前正广泛用于将基因打靶后的突变和其它遗传变化导入小鼠的种系中。其中,嵌合鼠的获得是非常必要的一步。这就需要用一个可以广泛表达的基因对ＥＳ细胞进行标记。大肠杆菌β－半乳糖苷酶（β－ｇａｌ）基因的表达在细胞水平就能很容易地观察到,而且对哺乳动物细胞没有任何毒害作用,因而是一个被广泛地用于各种细胞基因表达研究中的报导基因。猿类巨细胞病毒早期（ＳｉＣＭＶＩＥ）启动子是一个广泛用于转基因小鼠研究中的强启动子。然而,该启动子在ＥＳ细胞方面应用的报道尚未见到。本研究用ＢａｍＨＩ和ＨｉｎｄⅢ双酶切,从ｐｓｖ－β－ｇａｌａｃｔｏｓｉｄａｓｅ中得到３．７Ｋｂ的ｌａｃＺ基因片断,将其插入到ｐＩＮＣ载体上（Ｆｉｇ．１）,得到ｐＩＮＣ－ｌａｃＺ（Ｆｉｇ．２）。用ＮｏｔⅠ线性化ｐＩＮＣ－ｌａｃＺ后,电击导入ＭＥＳＰＵ－１３细胞中。ＭＥＳＰＵ－１３为本实验室从１２９／Ｔｅｒ品系小鼠的囊胚中建立的一个ＥＳ细胞系。转化细胞在含有２５０μｇ／ｍｌＧ４１８的培养基上培养两周,进行ＭＥＳＰＵ－１３细胞稳定转化子的筛选。在一次转化实验中,从１ｘ１０７个转化的ＭＥＳ     

Alterations of Root and Fiber in Transgenic Cotton Plants with Chimeric Ph/P-ipt Gene Expression

The seed-specific phaseolin promoter (Ph/P) was fused to an ipt gene, then was cloned to a plant expression vector containing a gus gene driven by a 35S promoter. Cotton (Gossypium hirsutum L.) plants were transformed through pollen tube pathway methods. After seed germination, histochemical staining of the roots demonstrated that 32 GUS positive plants were obtained and three of which contained the chimeric Ph/P-ipt transgene as confirmed by PCR analysis. An immunosorbent assay showed that two of the three transgenic cotton lines contained higher levels of zeatin equivalents in seeds than the control. Seedling development of these two transgenic lines differed from the control in a reduction of the shoot growth, showing a stunted phenotype as expected, but a surprisingly developed root system with a 3-4 fold fast-growing lateral roots. In addition, fibers (seed-hairs) of the two transgenic cotton lines were considerably shorter than those of the control. These results indicate that genetic engineering may be used to manipulate the development of cotton plants, particularly cotton fibers.     

转ipt和反义ACO基因番茄的叶片衰老相关特性

以ipt和反义ACO转化的两类转基因番茄纯系为材料,研究在植株不同生长发育阶段,不同叶位中,与叶片衰老相关的生理生化指标.结果表明:两类基因导入番茄后,均可增强内源iPA和IAA表达水平,增加或保持番茄叶片的叶绿素含量、提高光合效率,进而明显地延缓植株的叶片衰老,提高单株果实产量.但它们调控叶片衰老的途径不同,ipt主要通过提高CTK的水平延缓叶片衰老,而反义ACO则主要是通过抑制乙烯生成,间接提高IAA的水平来实现.     

The Commelina Yellow Mottle Virus Promoter Is a Strong Promoter in Vascular Tissue of Transgenic Gossypium hirsutum Plants

Explants of cotton (Gossypium hirsutum L. cv. Jingmian 7) were transformed with Agrobacterium tumefaciens (Smith et Townsend ) Conn LBA4404 harboring an expression cassette composed of CoYMV (Commelina Yellow Mottle Virus) promoter-gus-nos terminator on the plant expression vector pBcopd2. Transgenic plants were regenerated and selected on a medium containing kanamycin. GUS (β-glucuronidase) activity assays and Southern blot analysis confirmed that the chimerical gus gene was integrated into and expressed in the regenerated cotton plants. Plant expression vector pBI121 was also transferred into the same cotton variety and the regenerated transgenic plants were used as a positive control in GUS activity analysis. Evidences from histochemical analysis of GUS activity demonstrated that under the control of a 597 bp CoYMV promoter the gus gene was highly expressed in the vascular tissues of leaves, petioles, stems, roots, hypocotyls, bracteal leaves and most of the flower parts while GUS activity could not be detected in stigma, anther sac and developing cotton fibers of the transgenic cotton plants. GUS specific activity in various organs and tissues from transgenic cotton lines was determined and the results indicated that the CoYMV promoter-gus activities were at the same level or higher than that of CaMV 35S promoter-gus in leaf veins and roots where the vascular tissues occupy a relatively larger part of the organs, but in other organs like leaves, cotyledons and hypocotyls where the vascular tissues occupy a smaller part of the organs the CoYMV promoter-gus activity was only 1/3-1/5 of the CaMV 35S promoter-gus activity. The GUS activity ratio between veins and leaves was averaged 0.5 for 35S-GUS plants and about 2.0 for CoYMV promoter-gus transgenic plants. These results further demonstrated the vascular specific property of the promoter in transgenic cotton plants. An increasing trend of GUS activity in leaf vascular tissues of transgenic cotton plants developing from young to older was observed.     

Excision of selectable marker gene from transgenic tobacco using the GM-gene-deletor system regulated by a heat-inducible promoter

To excise a selectable marker gene from transgenic plants, a new binary expression vector based on the 'genetically modified (GM)-gene-deletor' system was constructed. In this vector, the gene coding for FLP site-specific recombinase under the control of a heat shock-inducible promoter HSP18.2 from Arabidopsis thaliana and isopentenyltransferase gene (ipt), as a selectable marker gene under the control of the cauliflower mosaic virus 35S (CaMV 35S) promoter, were flanked by two loxP/FRT fusion sequences as recombination sites in direct orientation. Histochemical staining for GUS activity showed that, upon induction by heat shock, all exogenous DNA, including the selectable marker gene ipt, beta-glucuronidase (gusA) gene and the FLP recombinase gene, between two loxP/FRT sites was eliminated efficiently from primary transgenic tobacco plants. Molecular analysis further confirmed that excision of the marker gene (ipt) was heritable and stable. Our approach provides a reliable strategy for auto-excising a selectable marker gene from calli, shoots or other tissues of transgenic plants after transformation and producing marker-free transgenic plants.     

A transformation vector for the production of marker-free transgenic plants containing a single copy transgene at high frequency

We represent here the GST-MAT vector system. The R recombinase gene of the site-specific recombination system R/RS from Zygosaccharomyces rouxii was fused to the chemical inducible promoter of the glutathione-S-transferase (GST-II-27) gene from Zea mays. Upon excision, the isopentenyltransferase (ipt) gene that is used as a selectable marker gene is removed. When the cauliflower mosaic virus 35S promoter (CaMV 35S) was used to express R recombinase, 67% of the marker-free transgenic plants had more than three transgene copies. Because the CaMV 35S promoter transiently and efficiently excised the ipt gene before callus and adventitious bud formation, the frequency of emergence of the ipt-shooty explants with a single T-DNA copy might be reduced. In this study we show that the GST-MAT vector efficiently produced transgenic ipt-shooty explants from 37 (88%) out of 42 differentiated adventitious buds and marker-free transgenic plants containing the GUS gene from five (14%) out of 37 ipt-shooty lines. Furthermore, the GST-MAT vector also induced two marker-free transgenic plants without the production of ipt-shooty intermediates. Southern blot analysis showed that six (86%) out of seven marker-free transgenic plants had a single GUS gene. This result suggests that the GST-MAT vector is useful to generate high frequency, marker-free transgenic plants containing a single transgene.     

ipt基因定位表达对转基因烟草育性的影响

杂种优势是生物界的一种普遍现象。作物杂种优势的利用是培育高产、抗逆、优质新品种的重要手段之一。然而 ,常规育种技术获得配套三系的难度很大 ,由此限制了杂种优势利用的发展。近年来应用转基因技术创造雄性不育植株已有不少报道[1- 5] 。有研究表明 ,自然突变的雄性不育株