鸭梨多酚氧化酶基因反义表达载体的构建及农杆菌介导的遗传转化

根据鸭梨多酚氧化酶基因序列设计引物,PCR扩增该基因3′端450bp的片段,并将该片段反向插入真核表达载体pB I121的CaMV 35S启动子和NOS终止子之间,首次构建了鸭梨PPO基因的反义表达载体;其后,在农杆菌EHA105的介导下,成功实现了PPO反义基因对鸭梨组培苗的遗传转化。经Northern杂交和酶活检测证实,转基因鸭梨植株体内的多酚氧化酶基因转录和翻译水平均得到明显抑制,从而为耐褐化梨新品种的培育奠定了基础。     

鸭梨ACC氧化酶基因cDNA片段的克隆及农杆菌介导的反义遗传转化

研究根据ACC氧化酶基因的保守序列设计一对特异性引物。以鸭梨果实为试材,借助RT,PCR方法扩增得到一条长度为831bp的鸭梨ACC氧化酶基因eDNA片段,该片段编码276个氨基酸残基,与其它梨品种ACC氧化酶基因序列同源性均在94％以上。将此片段反向插入真核表达载体pBI121的CaMV35S启动子和NOS终止子之间,构建了鸭梨ACC氧化酶基因的反义表达载体．并在农杆菌LBA4404的介导下实现对鸭梨组培苗的遗传转化。经PCR鉴定证实共有4株鸭梨组培苗中外源基因得到成功转化,Southern杂交显示在这4株转基因鸭梨中除有1株外源基因呈双拷贝外,其余3株中外源基因均以单拷贝形式存在。     

鸭梨ＡＣＣ 氧化酶基因ｃＤＮＡ 片段的克隆及农杆菌介导的反义遗传转化

研究根据ACC氧化酶基因的保守序列设计一对特异性引物,以鸭梨果实为试材,借助RT PCR方法扩增得到一条长度为831bp的鸭梨ACC氧化酶基因cDNA片段,该片段编码276个氨基酸残基,与其它梨品种ACC氧化酶基因序列同源性均在94%以上。将此片段反向插入真核表达载体pBI121的CaMV 35S启动子和NOS终止子之间,构建了鸭梨ACC氧化酶基因的反义表达载体,并在农杆菌LBA4404的介导下实现对鸭梨组培苗的遗传转化。经PCR鉴定证实共有4株鸭梨组培苗中外源基因得到成功转化,Southern杂交显示在这4株转基因鸭梨中除有1株外源基因呈双拷贝外,其余3株中外源基因均以单拷贝形式存在。     

甜味蛋白thaumatin基因转入烟草的研究

利用基因工程技术 ,将分别克隆在两个不同载体上的甜味蛋白 thaum atin c DNA基因片段连接成一个完整的 c DNA基因 ,并将该基因克隆进 p BI12 1,构建成表达载体 p BI12 1- tha.通过冻融法导入农杆菌 ,农杆菌介导叶盘法转入烟草 ,经过组培 ,得到转基因的植株 .提取转基因烟草总 DNA,经 PCR,PCR- Southern和 Southern杂交证实 ,甜味蛋白基因已整合到烟草基因组中 .RT- PCR结果证明 ,thaumatin基因已在转基因烟草中转录成 m RNA,但SDS- PAGE和甜味尝试都表明 thaumatin基因在转基因烟草中没有表达出甜味蛋白     

玉米Lc基因植物表达载体构建及菊花转化

Lc基因是从玉米中分离得到的与花青素合成相关的调节基因,它在多种植物中的异源表达可以增加花青素的含量.本研究对pBI121载体Gus基因后的终止子进行2次PCR扩增,在原Sac Ⅰ酶切位点后添加了新的Sac Ⅰ酶切位点,利用组织化学染色法检测,结果表明改造后的载体上的Gus基因能正常表达,终止子功能正常,载体改造成功.用改造的pBI121N构建了含有Lc基因的植物表达载体pBl121N-Lc,利用农杆菌介导法转化菊花叶盘,获得了19株生根抗性苗.通过提取抗性苗基因组总DNA,PCR扩增Lc基因和CaMv35S启动子获得了11个阳性株系,PCR结果表明Lc基因已经转入菊花中.同时,在已获得的转基因植株中发现7个株系的根系有变红的现象.     

苎麻CCoAOMT基因cDNA反义转化模式烟草''WS38''

苎麻咖啡酰辅酶A氧甲基转移酶(CCoAOMT)是其木质素合成过程的一种关键酶,运用克隆的该酶基因cDNA及植物表达载体pBI121、pWM101,分别构建了35S启动子控制的苎麻CCoAOMT基因反义cDNA基因质粒(pBI121-antiBnCCoAOMT)和cDNA全长表达质粒(pWM101-BnCCoAOMT),并通过根癌农杆菌介导法将其转化至模式烟草WS38,获得了转基因烟草.对转基因植株进行分子分析和组织学初步研究表明,转反义RNA基因植株叶柄木质素含量较野生烟草或转正义基因烟草叶柄木质素含量降低.说明运用反义RNA技术对CCoAOMT基因的表达进行基因工程调控,一定程度上可以对木质素的合成产生干扰,为获得低木质素或木质素组分改良的苎麻基因工程奠定基础.     

LeCOP1LIKE基因的克隆、反义构建及微型番茄的转化

本文报告利用EST筛选结合RT-PCR的方法从番茄中克隆了LeCOP1LIKE基因的1060bpcDNA片段,并利用其非保守域构建反义RNA表达载体。利用农杆菌介导法．将LeCOP1LIKE基因的反义RNA表达载体转入微型番茄Micro-Tom．获得了10株反义LeCOP1LIKE转基因微型番茄。RT-PCR分析表明其中4个转基因株系中的LeCOP1LIKE表达被显著抑制．并发现抑制LeCOP1LIKE基因的表达导致转基因番茄的株高下降、叶片的叶绿素含量提高、果实中番茄红素含量增加,并且明显抑制转基因种子的发育。这些实验结果证明了LeCOP1LIKE基因为番茄发育过程中光形态建成的抑制因子。     

马铃薯多酚氧化酶基因克隆及反义表达载体构建

从甘农薯1号马铃薯试管苗叶片中提取总DNA,根据Genebank报道的马铃薯多酚氧化酶基因(PPT32)序列,设计合成了带有BamHⅠ、SacⅠ特定酶切位点的2对特异引物,通过PCR获得l840bP和476bP的扩增产物。测序结果表明,l840bp的扩增产物与Oenebank中发表的序列一致,476bp的扩增产物正是欲扩增的马铃薯多酚氧化酶基因的同源片段。将2个扩增产物反向连接到表达载体PC3中,通过双酶切鉴定后,按直接导入法实现反义基因表达载体质粒向农杆菌EHA105的导人;并经PCR鉴定证明,此质粒已整合到农杆菌Ti上。     

番茄叶片GDP-甘露糖焦磷酸化酶基因表达载体的构建与转化

GDP-甘露糖焦磷酸化酶(GMPase,EC 2.7.7.22)是维生素C合成途径的第一步关键酶。通过RT-PCR扩增到1498 bp的GMPase全长序列,GenBank登录号为DQ449030。利用克隆到的基因分别构建得到正义及反义植物表达载体。并将其克隆至PBI121真核表达载体,转化农杆菌LBA4404,利用农杆菌介导法转化烟草植株,经基因组PCR及琼脂糖凝胶电泳检测,结果表明GMPase真核表达载体构建成功,并成功获得转基因植株。     

人干扰素α-2b基因植物表达载体的构建及转化

目的:通过构建人干扰素α-2b(hIFNα-2b)基因的植物表达载体,为后期将其导入胡萝卜愈伤组织中作准备。方法:采用PCR技术从人基因组DNA扩增hIFNα-2b编码基因及全长基因,将其克隆于pMD19-T载体中,双酶切hIFNα-2b基因及植物表达载体pBI121,回收目的片段,T4DNA连接酶连接得到植物表达载体pBI121-hIFN。采用三亲交配法将后者导入根瘤农杆菌。结果:经PCR检测,双酶切及DNA序列测定表明hIFNα-2b编码基因及全长基因已分别插入植物表达载体pBI121中,重组表达载体pBI121-IFN已成功转化根瘤农杆菌LBA 4404。结论:成功构建了植物表达载体pBI121-hIFN并转入根瘤农杆菌。     

谷子PAL基因家族全基因组的鉴定和表达分析

苯丙氨酸解氢酶(phenylalanine ammonia-lyase,PAL)基因家族参与苯丙烷类代谢过程,通过调控植物抗病次生物质的合成在植物抗逆反应中发挥重要作用。为明确谷子PAL基因家族在逆境胁迫下的表达规律,该研究利用生物信息学方法对谷子PAL基因家族进行鉴定和表达分析。结果表明:谷子具有11个PAL基因,在进化树中可分为3个亚家族,SiPAL7独自进化为一支。通过构建蛋白结构域发现PAL基因家族成员均含有保守的PAL结构域。启动子分析显示,PAL基因含有应答激素、逆境胁迫等多种因子的顺式作用元件,说明PAL基因广泛参与不同生物学调控过程。RT-qPCR结果显示,谷子PAL基因家族多为诱导型表达,不同光照条件下PAL基因表达量变化明显,不同基因具有不同响应模式,说明谷子PAL基因家族在参与光调节反应中发挥重要作用。谷子PAL基因高度保守,广泛响应不同非生物胁迫,具有表达特异性。该研究结果为揭示PAL基因家族在调节谷子抗性及胁迫应答过程中的作用提供了参考。     

用单性结实基因2A11-iaaM转化罗汉果的研究

为了实现罗汉果生产中免除人工授粉和果实无籽化,该研究利用pBI121-Gus构建果实特异启动子2A11与生长素合成相关基因iaaM的嵌合基因(2A11-iaaM)过量表达载体,以罗汉果雌株叶盘为材料,采用农杆菌介导法建立罗汉果高效遗传转化体系,转化和创制单性结实罗汉果种质,通过基因特异引物对的PCR扩增,初步检测出转基因阳性植株,将之移栽大田,观察转基因植株的单性结实性的表现。结果表明:构建罗汉果单性结实性相关的pBAI-Gus植物双元表达载体获得成功;建立了农杆菌介导的罗汉果叶盘遗传转化优化体系,即农杆菌菌液OD_(600)值为0.3～0.5,侵染10 min,最优选择培养基为MS+TDZ 0.7 mg·L~(-1)+IBA 0.5 mg·L~(-1)+Kan 5 mg·L~(-1)+Cef 300 mg·L~(-1);经PCR鉴定共获得4株转基因阳性雌株;将阳性植株扩繁后移栽田间,经田间调查发现,24株阳性扩繁植株中有5株正常开花,占总植株数的20.8%,且其子房未经人工授粉发育成幼果,表现单性结实性。在载体构建和农杆菌介导的罗汉果遗传转化体系优化的基础上,将外源单性结实相关嵌合基因整合进罗汉果基因组并得到表达,为后续研究单性结实罗汉果的遗传生理,创制转基因罗汉果单性结实新种质,以及克服其产业化中需要人工授粉和无籽化提供了理论和应用基础。     

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.     

Construction of genetically modified tobacco (<Emphasis Type="Italic">Nicotiana tabacum</Emphasis> cv. Petit Havana) harboring <Emphasis Type="Italic">ompH(A:3)</Emphasis> from <Emphasis Type="Italic">Pasteurella multocida</Emphasis> (A:3)

Fowl cholera, caused by Pasteurella multocida (A:3), is a fearsome disease leading to a nonproductive influence upon poultry industry. It has been known that outer membrane protein H (OmpH) in the bacterium is a strong candidate to bring on the notorious ailment. Genetically modified (GM) tobacco (Nicotiana tabacum cv. Petit Havana) harboring ompH(A:3) was constructed to develop a plant expression system for the protein, OmpH(A:3). Some 987 bp-long (ORF with the stop codon, TAA) of the ompH(A:3) excluding the nucleotide for signal peptide, was amplified by RT-PCR with the gene specific primers and pGEM-T-ompH(A:3) as template DNA. The PCR-amplified DNA was ligated into BamHI/Sacl-cut pBI121 to obtain a recombinant plasmid, pBI121-ompH(A:3). It was then transformed into Agrobacterium tumefaciens (LBA 4404) by liquid nitrogen method to generate a recombinant clone of Agrobacterium LBA4404/pBI121-ompH(A:3). The Agrobacterium LBA4404/pBI121-ompH(A:3) was inoculated into leaf discs of tobacco (2 day old). The gene-transfected leaves were cultured on Murashige-Skoog basal medium containing kanamycin (50 mg/mL) to generate numerous calli, from which some GM tobacco plants were obtained. Transgenicity of the tobacco plant was confirmed by PCR screening along with the DNA sequencing. Also, its expression in the GM-tobacco was examined qualitatively as well as quantitatively by ELISA/Western blot. These results suggest that the genetically modified tobacco plant can be potentially used as a model system to develop plant-based vaccine against the fowl cholera.     

Transformation of radish (Raphanus sativus L.) via sonication and vacuum infiltration of germinated seeds with Agrobacterium harboring a group 3 LEA gene from B. napus

A protocol for producing transgenic radish (Raphanus sativus) was obtained by using both ultrasonic and vacuum infiltration assisted, Agrobacterium-mediated transformation. The Agrobacterium strain LBA4404 contained the binary vector pBI121-LEA (late embyogenesis abundant), which carried a Group 3 LEA gene, from Brassica napus. Among six combinations, Agrobacterium-mediated transformation assisted by a combination of 5-min sonication with 5-min vacuum infiltration resulted in the highest transformation frequency. The existence, integration and expression of transferred LEA gene in transgenic T₁ plants were confirmed by PCR, genomic Southern and Western blot analysis. Transgenic radish demonstrated better growth performance than non-transformed control plants under osmotic and salt stress conditions. Accumulation of Group 3 LEA protein in the vegetative tissue of transgenic radish conferred increased tolerance to water deficit and salt stress.     

马尾松HDR基因克隆及其对旱与盐胁迫的响应

干旱和土地盐渍化是制约林业可持续发展的重要因素,植物在遭受生物或非生物胁迫时,会在叶片释放萜类等挥发性物质。1-羟基-2-甲基-2-(E)-丁烯基-4-焦磷酸还原酶(HDR)是MEP途径的末端活性酶,具有提供前体萜类物质和主要限速作用。为探究马尾松HDR基因是否参与干旱和盐胁迫条件下的胁迫响应,该研究克隆了马尾松HDR基因开放阅读框,并初步分析了其生物信息、组织特异性表达水平和初步功能。结果表明:(1)PmHDR基因编码区长度为1 458 bp,编码485个氨基酸,其编码蛋白包含LytB/IspH基因超家族的核心序列和PLN02821多功能结构域,属于HDR家族。(2)PmHDR密码子使用偏好性较弱,偏好使用A/U结尾的密码子,烟草、拟南芥与酿酒酵母更适合作为其异源表达受体。(3)qRT-PCR结果显示,PmHDR基因在马尾松老叶中表达量最高,其次为幼叶、幼茎和老茎,在根中表达量最低。(4)构建基因表达载体pBI121-PmHDR并转化拟南芥,转基因拟南芥对干旱和盐胁迫表现出更强的抗逆性。以上研究结果表明PmHDR参与了植物干旱和盐胁迫的响应和调节,并为马尾松抗逆育种提供了一定的理论支持。     

西瓜花叶病毒诱导对不同抗性美洲南瓜防卫基因表达的影响

为了明确防卫基因PAL与美洲南瓜抗西瓜花叶病毒(watermelon mosaic virus,WMV)之间的关系,通过室内接种和实时荧光定量PCR技术,测定了WMV侵染对不同抗性美洲南瓜体内防卫基因PAL表达的影响。结果表明:(1)室内测定显示,抗病品种GBRV-8发病率和病情指数(15.6%和14.2)显著低于感病品种‘光板’(91.1%和65.9)。(2)实时荧光定量PCR表明,接种WMV后不同抗感品种不同组织部位PAL基因相对表达量随着接种时间增加,整体呈现出先增加后降低的趋势,而且不同组织部位PAL基因相对表达量总体呈现出叶片较高,叶柄和茎秆次之。(3)接种后5个品种不同组织部位PAL基因相对表达量与对照相比均存在显著差异,且抗病和中抗品种不同组织部位PAL基因相对表达量显著高于感病品种,尤其抗病品种GBRV-8不同组织部位PAL基因相对表达量最高,感病品种光板最低。研究认为,防卫基因PAL表达量与美洲南瓜品种抗病毒病强弱密切相关。     

Tissue-specific expression of the PAL3 promoter requires the interaction of two conserved cis sequences

The bean PAL2 and PAL3 promoters confer expression in overlapping sets of tissue types in transgenic tobacco. The PAL3 promoter contains motifs that resemble two AC cis elements which are required for tissue-specific expression of the PAL2 promoter. The functions of these motifs in the PAL3 promoter were determined by analysis of mutated PAL3 promoter-GUS constructs in transgenic tobacco. This revealed that the AC motifs are necessary for tissue-specific expression of the PAL3 promoter. Therefore, a key role is indicated for AC elements, which are Myb-protein binding sites, in regulating tissue-specific expression of the bean PAL gene family.     

Control of phenylalanine ammonia-lyase gene promoters from pea by UV radiation

The gene fusion system was used to study UV light-control of PS PAL1 and PS PAL2 genes encoding phenylalanine ammonia-lyase of pea. The induction of pea PAL promoters was analysed in transgenic tobacco plants. Binary plasmids (derivatives of pBI101.2 vector) containing 5′ regulatory fragments of PS PAL1 and PS PAL2 linked to reporter genes (GUS,LUC) were constructed. The analyses were performed with the use of single constructs (containing one variant of PS PAL promoter and one reporter gene) and dual constructs (containing both PS PAL1 and PS PAL2 promoters connected with different reporter genes). The use of dual constructs enabled the evaluation of both PS PAL promoters activity in the same plant. The analyses of in vitro grown plants have shown that both PAL promoters are strongly induced in leaves subjected to UV radiation. In some cases, the UV-stimulated expression exceeded the exposed areas. This phenomenon was observed more often in the leaves of plants containing the PS PAL1::GUS than PS PAL2::GUS construct. Removal of boxes 2, 4, 5 from PS PAL1 promoter and deletion of its 5′ end region (-339 to -1394) decreases the level of gene expression but does not eliminate its responsiveness to UV.