拟南芥新型脂转移蛋白AtDHyPRP1的亚细胞定位及其对灰霉菌的抗性

通过遗传转化技术研究了拟南芥脂转移蛋白AtDHyPRP1在细胞中的定位及其对真菌病原体的抗性。采用PCR方法从拟南芥Ws生态型克隆了AtDHyPRP1基因,构建产生pRI101-AN-AtDHyPRP1植物双元表达载体和pCAMBIA1302-AtDHyPRP1-GFP融合表达载体,经农杆菌介导的叶盘和浸花法得到烟草和拟南芥转基因植株。AtDHyPRP1基因能够明显增加烟草对灰霉菌的抗性,转AtDHyPRP1烟草叶片的被侵染部位有大量H2O2积累,激光共聚焦显微观察发现AtDHyPRP1蛋白定位于细胞表面。说明AtDHyPRP1蛋白在合成后被分泌到细胞外执行特殊的功能,与植物抗病防御机制有关。     

利用转基因烟草确定AtELHYPRP2蛋白对赤霉菌的抗性及其亚细胞定位特征

采用遗传转化技术获得了整合有拟南芥AtELHYPRP2(EARLI1-LIKE HYBRID PROLINE-RICH PROTEIN 2,AT4G12500)基因的转基因烟草株系,研究了该基因编码蛋白对真菌病原体赤霉菌的抗性及其亚细胞定位特征。以拟南芥Col-0生态型基因组DNA为模板,通过聚合酶链反应扩增AtELHYPRP2基因编码序列,经限制性酶切后连接至pCAMBIA1302载体,构建产生pCAMBIA1302-AtELHYPRP2-GFP融合表达载体。进一步采用农杆菌LBA4404转化烟草叶片外植体,筛选得到转基因烟草植株。RT-PCR、Western blotting印迹分析结果显示,AtELHYPRP2基因在转化体中可以有效表达。激光共聚焦显微观察发现AtELHYPRP2-GFP融合蛋白产生的绿色荧光与碘化丙啶染色后产生的红色荧光能够重合,说明AtELHYPRP2蛋白定位于细胞表面。真菌侵染实验结果显示,组成性表达AtELHYPRP2基因能够增强烟草对赤霉菌的抗性,被侵染部位有明显的H2O2积累。转基因烟草植株中PR1基因的本底表达水平比野生型高,PR1和PR5基因的系统表达水平比野生型高,说明AtELHYPRP2基因可能在SAR反应中具有一定的作用。     

拟南芥AZI1基因对酿酒酵母细胞生长和蒜薹灰霉菌侵染的抑制作用

本工作采用酿酒酵母细胞表达载体pESC和植物细胞表达载体pPZP211分析了拟南芥AZI1基因对真菌的抗性功能。半乳糖诱导产生的AZI1蛋白可以使酵母细胞的生长能力明显降低。DAB和台酚蓝染色结果显示用蒜薹灰霉菌孢子处理Col-0野生型植株叶片后被侵染部位只能产生少量H2O2,病原体可以扩散,而AZI1基因过表达植株叶片在侵染部位有大量H2O2产生,着色较深,表明转化体能够以局部细胞的死亡来阻止病原体侵染周围的细胞。在Col-0野生型植株中,AZI1基因的表达受外源水杨酸诱导,24h后达到峰值。以上结果说明AZI1基因在拟南芥对生物胁迫因素的应答过程中具有重要作用。     

利用病毒载体在烟草中瞬时表达融合HBsAg基因

利用马铃薯PVX病毒载体构建了外源人工融合乙肝表面抗原HBsAg基因的表达载体,在烟草中利用农杆菌介导进行瞬时表达,以快速鉴定外源基因瞬时表达的状况以及重组蛋白的免疫活性。利用PCR技术从含有人工融合HBsAg基因的表达载体中分别扩增出LP PreS1 PreS2 S、PreS1 PreS2 S、PreS2 S序列,将其分别与PVX病毒载体pgR106连接,构建成PVX-LP、PVX-S1和PVX-S2等3个转化载体,并将此载体导入农杆菌菌株GV3101中用于侵染烟草植株叶片。感染植株经RT-PCR、RNA Dot blotting和HBsAg蛋白的ELISA检测显示,3个人工融合的HBsAg基因均可在植物体内得到转录,翻译成具有活性的蛋白。结果表明,外源融合HB-sAg基因经过植物病毒载体瞬时表达系统可以在植物系统中正常转录和翻译。     

两种瞬时表达体系研究拟南芥Profilin-1的亚细胞定位

使用两种瞬时表达方法研究Profilin-1(PRF1)的亚细胞定位,并比较了2种瞬时表达体系在亚细胞定位研究中的优缺点。利用拟南芥幼叶作为材料,提取叶片的RNA,采用特异性引物RT-PCR的方法克隆PRF1基因,连接到p CAMBIA1300-GFP的改造载体上,成功的构建p CAMBIA1300-GFP-PRF1的表达载体。然后分别利用PEG转化拟南芥原生质体、农杆菌浸染烟草叶片两种技术进行了瞬时表达,并在激光共聚焦显微镜下观察绿色荧光蛋白(GFP)融合蛋白的表达。研究结果表明,将PRF1基因导入拟南芥的原生质体和烟草表皮细胞后,融合蛋白绿色荧光均能被观察到,PRF1基因与GFP融合蛋白的产物在烟草表皮细胞中主要定位在细胞质和外周细胞器中,在拟南芥的原生质体中的细胞核和细胞质中都有定位。两种不同的瞬时表达体系中PRF1蛋白的定位出现了不同,这可能与同源或异源表达的植物的特性相关。     

导入Ghabpl基因对烟草叶细胞发育的影响

将棉花生长素结合蛋白基因cDNA与CaMV35S启动子和NOS终止子融合,构建了一个新的表达载体pGABPl—121,采用农杆菌介导法转化烟草,经过分化、筛选和再生,得到了具有卡那霉素抗性的植株。抗性植株经PCR及Southern杂交检测,证明外源目的基因已经整合到烟草基因组中。扫描电镜观察发现转基因烟草与对照相比叶细胞增大,结果表明,棉花生长素结合蛋白基因的表达影响了烟草叶细胞的发育。     

拟南芥抵抗丁香假单胞杆菌过程中AZI1基因功能研究

AZI1属于脂转移蛋白家族,它在拟南芥抵抗病原菌侵染过程中可能起着传递信号物质的作用。该实验以过表达和T-DNA插入突变体及野生型拟南芥植株为材料,通过RNA印迹、蛋白质免疫印迹和原位免疫组织化学方法,研究了拟南芥壬二酸诱导基因AZI1对丁香假单胞杆菌的抗性功能。结果表明:(1)AZI1基因可以被丁香假单胞杆菌、H2O2和乙烯利诱导,它可能参与水杨酸和乙烯介导的抗菌途径。(2)蛋白质免疫印迹实验结果显示,丁香假单胞杆菌侵染叶片的叶柄渗出液中存在AZI1蛋白及其同源物EARLI1,并能够与其他蛋白质形成复合体,说明AZI1有可能通过维管组织移动到个体的其他部位,与信号分子的转移有关。(3)AZI1及其同源物EARLI1主要在花序茎的木质化部位表达,过表达AZI1基因能够促进木质素的合成,提高拟南芥对丁香假单胞杆菌的抗性。     

GFP基因在新疆小拟南芥和拟南芥中的表达分析

以质粒pMCB30为模板,扩增GFP基因,连接到载体pCMBIA2300-35S-OCS上,构建过量表达载体p35S:GFP,将其转入农杆菌GV3101.通过农杆菌介导法将p35S:GFP载体分别转入新疆特色植物小拟南芥和拟南芥中.T0代经含有卡那霉素的1/2MS培养基筛选,获得了T1代转基因小拟南芥2株,T1代转基因拟南芥9株.通过激光共聚焦显微镜观察,在转基因小拟南芥和拟南芥的根尖细胞中均可检测到GFP绿色荧光蛋白;对转基因植株进行PCR扩增,均可检测到GFP基因,表明GFP基因已成功转入小拟南芥和拟南芥中.该研究建立了小拟南芥的遗传转化体系,为进一步利用GFP基因和进一步研究小拟南芥的功能基因奠定基础.     

导入Ghabp1基因对烟草叶细胞发育的影响

将棉花生长素结合蛋白基因cDNA与CaMV35S启动子和NOS终止子融合,构建了一个新的表达载体pGABP1-121,采用农杆菌介导法转化烟草,经过分化、筛选和再生,得到了具有卡那霉素抗性的植株。抗性植株经PCR及Southern杂交检测,证明外源目的基因已经整合到烟草基因组中。扫描电镜观察发现转基因烟草与对照相比叶细胞增大,结果表明,棉花生长素结合蛋白基因的表达影响了烟草叶细胞的发育。     

拟南芥CYCD2;1基因植物表达载体的构建及在烟草中的遗传转化分析

细胞分裂是生物的基本特征之一,在植物生长发育的过程中,发挥着极其重要的作用,细胞周期蛋白CYCD2;1基因作为一个调控因子,对调节细胞周期具有重要作用。本文以拟南芥细胞周期蛋白(At CYCD2;1基因)作为研究对象,利用PCR技术从拟南芥花序c DNA扩增出At CYCD2;1基因,构建植物表达载体(pROKIIAt CYCD2;1)并利用农杆菌介导的叶盘法转化野生型烟草。转基因植株的PCR检测结果表明,At CYCD2;1基因已经整合到了烟草基因组中。在T2代植株中,通过实时定量荧光PCR检测显示,At CYCD2;1在mRNA水平也均有表达。过量表达CYCD2;1的转基因烟草在花器官中存在明显表型,与野生型相比主要表现为转基因植株花冠宽度变大,花瓣和萼片长度变长,果实变大,上述结果表明At CYCD2;1基因影响花的发育。     

Arresten在烟草中的表达及其生物学活性分析

采用5'端引入His-tag的引物从携带有Arresten基因的质粒pCA中扩增血管生成抑制因子Arresten编码基因,构建其植物表达载体pCAMBIAarr并通过冻融法转化根癌农杆菌LBA4404,获得携带目的基因的重组农杆菌.采用叶盘法以重组农杆菌转化烟草,在50 μg/mL潮霉素B为选择压力下获得再生烟草植株,经过Southern杂交、RT-PCR和Western blotting检测,获得稳定整合有Arresten编码基因的烟草转基因植株.牛血管内皮细胞BCE增殖抑制实验表明,采用镍离子螯合次氨基三乙酸亲和层析法从转基因烟草叶片中分离纯化的重组Arresten蛋白具有明显的抑制牛血管内皮细胞增殖的生物活性.     

T-DNA vector backbone sequences are frequently integrated into the genome of transgenic plants obtained by Agrobacterium-mediated transformation

Transgenic Arabidopsis and tobacco plants (125) derived from seven Agrobacterium-mediated transformation experiments were screened by polymerase chain reaction and DNA gel blot analysis for the presence of vector `backbone' sequences. The percentage of plants with vector DNA not belonging to the T-DNA varied between 20% and 50%. Neither the plant species, the explant type used for transformation, the replicon type nor the selection seem to have a major influence on the frequency of vector transfer. Only the border repeat sequence context could have an effect because T-DNA vector junctions were found in more than 50% of the plants of three different transformation series in which T-DNAs with octopine borders without inner border regions were used. Strikingly, many transgenic plants contain vector backbone sequences linked to the left T-DNA border as well as vector junctions with the right T-DNA border. DNA gel blots indicate that in most of these plants the complete vector sequence is integrated. We assume that integration into the plant genome of complete vector backbone sequences could be the result of a conjugative transfer initiated at the right border and subsequent continued copying at the left and right borders, called read-through. This model would imply that the left border is not frequently recognized as an initiation site for DNA transfer and that the right border is not efficiently recognized as a termination site for DNA transfer.     

大豆fad基因反义表达载体构建及转化烟草研究

使用PCR方法从大豆基因组DNA中扩增出大豆油酸脱饱和酶基因fad2-1,连接到pMD18-T载体中,转化大肠杆菌JM109菌株.测序后,用DNAstar软件进行同源性比对.然后将正确的序列反向克隆到表达载体pBt,并转化农杆菌菌株LBA4404,经双酶切鉴定和PCR扩增检测,获得具有该基因反向序列的农杆菌工程菌,转化...     

Transgenic tomato (Lycopersicon esculentum L.) transformed with a binary vector in Agrobacterium rhizogenes: Non-chimeric origin of callus clone and low copy numbers of integrated vector T-DNA

Summary We transformed tomato (Lycopersicon esculentum L.) by using Agrobacterium rhizogenes containing two independent plasmids: the wild-type Ri-plasmid, and the vector plasmid, pARC8. The T-DNA of the vector plasmid contained a marker gene (Nos/Kan) encoding neomycin phosphotransferase which conferred resistance to kanamycin in transformed plant cells. Transgenic plants (R ₀) with normal phenotype were regenerated from transformed organogenic calli by the punctured cotyledon transformation method. Southern blot analysis of the DNA from these transgenic plants showed that one or two copies of the vector plasmid T-DNA, but none of the Ri-plamid T-DNA, were integrated into the plant genome. Different transgenic plants derived from the same callus clone showed an identical DNA banding pattern, indicating the non-chimeric origin of these plants. We also transformed tomato by using A. tumefaciens strain LBA4404 containing a disarmed Ti-plasmid (pAL4404), and a vector plasmid (pARC8). Transgenic plants derived via A. tumefaciens transformation, like those via A. rhizogenes, contained one to two copies of the integrated vector T-DNA. The kanamycin resistance trait in the progeny (R ₁) of most transgenic plants segregated at a ratio of 3:1, suggesting that the vector T-DNAs were integrated at a single site on a tomato chromosome. In some cases, the expression of the marker gene (Nos/Kan) seemed to be suppressed or lost in the progeny.     

Chimeric vector construction for higher-plant transformation

A chimeric vector pKR612B1 was developed containing the neomycin phosphotransferase (APH) gene from the Tn5 transposon under the control of the gene VI promoter of cauliflower mosaic virus (CaMV), and was used to transform higher plant protoplasts. Plasmid pDOB612, the parental vector of pKR612B1, has two unique restriction sites, SmaI and BamHI, positioned just downstream of the CaMV gene VI promoter sequence. These unique cloning sites can be used for any kind of gene insertion into this vector. Using the polyethylene glycol transformation procedure, a large number of turnip and tobacco protoplasts were transformed and proved to be resistant to kanamycin (Km). From tobacco protoplasts whole Km-resistant plants were regenerated and shown to contain the integrated foreign gene. APH activity was detected in both transformed calli and in regenerated plants. DNA from transformed clones was analysed by Southern blot hybridization, showing the presence of the Tn5-derived gene.     

抗草甘膦抗虫植物表达载体的构建及其转基因烟草的分析

构建了含草甘膦抗性突变基因（aroAM12）和人工合成重组Bt抗虫基因（Bts1m）的植物表达载体pCM12_s1m。aroAM12基因的表达由CaMV35S启动子控制,Bts1m基因的表达由2E_CaMV35S启动子和Ω因子控制。通过农杆菌介导,将aroAM12和Bts1m基因转化到烟草中,转基因烟草通过在含草甘膦的MS培养基上筛选而获得。Southern blot分析表明所有经过草甘膦筛选出的转化植株都整合有aroAM12基因,约70%的转化植株同时整合有aroAM12和Bts1m基因。Northern blot、Immunodot blot分析进一步证明整合的两个基因在转录、翻译水平上均进行了表达,不同植株之间表达存在着差异。草甘膦抗性和虫试实验证明,获得的转基因烟草对草甘膦和烟青虫具有很强的抗性。     

人干扰素α-2b基因在烟草中的表达研究

应用PCR的技术从质粒pAIFN中扩增人干扰素α-2b(Human interferon α-2b,HuIFN α-2b)编码基因,将其连接到pBI121双元载体构建植物真核表达载体pBIFN;用冻融法将该载体转染根癌农杆菌LBA4404;并用叶盘浸染法转化烟草叶片,经转化的烟草叶片的组织培养,诱导愈伤获得再生植株。通过应用PCR,RT-PCR,Wes-tern blot和WISH/VSV方法检测获得的烟草再生植株,结果表明HuIFN α-2b基因已成功整合进烟草核基因组并表达出具有活性的HuIFN α-2b蛋白。本文对HuIFN α-2b基因在烟草核系统中的表达进行了研究,为进一步在烟草叶绿体系统中该基因的表达研究奠定了基础。