共查询到19条相似文献,搜索用时 93 毫秒
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以花椰菜赛雪的带柄子叶为外植体,以MS为基本培养基,GUS基因为报告基因,分析了遗传转化过程中的影响因子,如预培养时间、农杆菌菌液浓度、侵染时间、共培养时间、乙酰丁香酮浓度、延迟筛选时间等对外植体瞬间表达和稳定表达的影响。结果显示,以花椰菜的带柄子叶为外植体,预培养2d,农杆菌菌液为OD6000.3~0.4,侵染8min,共培养2d,乙酰丁香酮浓度为100μmol/L,延迟筛选7d,卡那霉素筛选压为5mg/L为最优的遗传转化方案,转化率最高可达35.7%。另外,GUS瞬间表达率和转化率并不存在绝对的相关性,但瞬间表达分析仍然可以作为外源基因进入受体细胞的指示。花椰菜农杆菌介导转化方案的优化研究为芸薹属蔬菜高效遗传转化提供了技术保障,有利于芸薹属蔬菜遗传育种与种质创新研究。 相似文献
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通过根癌农杆菌介导的共转化获得具有蜡质基因反义片段的转基因水稻 总被引:6,自引:1,他引:6
在构建剔除潮霉素抗性基因的反义蜡质基因重组质粒p13W8的基础上,用分别携带p13W8质粒和有潮霉素抗性基因的pCAMBIA1300质粒的根癌农杆菌,在不同处理条件下对粳稻3个品种进行共转化.试验结果显示,共感染混合液中pCAMBIA1300菌液比例高,抗性愈伤组织的转化频率也较高;抗性愈伤组织的PCR检测结果表明,潮霉素抗性基因的阳性检测率为98%,反义蜡质基因的阳性检测率为68%.在105株转基因植株中,反义蜡质基因阳性株为30株,占转基因植株的28.6%.乙酰丁香酮处理组的平均转化频率略高于未处理组;在乙酰丁香酮的各种处理中,直接浸泡愈伤组织的转化频率稍高于其它处理方式. 相似文献
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根癌农杆菌介导的金边狗牙根遗传转化条件的优化 总被引:3,自引:0,他引:3
胡繁荣 《植物资源与环境学报》2005,14(2):15-18
为建立根癌农杆菌(Agrobacterium tumefaciens,菌(L.)Pers.]最佳遗传转化体系,以葡萄糖醛酸糖苷酶(GUS)基因的瞬间表达率为指标,从愈伤组织继代时间、根癌农杆菌侵染时间、负压条件及光照时间等方面进行了筛选.结果表明,根癌农杆菌介导的金边狗牙根最佳的转化体系是:以继代培养2周的愈伤组织为起始材料,根癌农杆菌介导感染10 min,经负压处理(抽拉20次)并在全光条件下共培养转化. 相似文献
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无载体主干序列的bar和cecropin B 基因表达框共转化水稻 总被引:10,自引:1,他引:10
基因枪等直接转化法可将去除质粒载体主干序列的外源基因表达框导入植物基因组,消除质粒主干序列对植物基因组的影响,同时由于转基因分子较小,比较容易实现多个基因的共转化,在植物基因工程育种上有重要的应用价值,研究了基因枪介导外源基因表达框(包括启动子、基因开放阅读框和终止子)转化水稻的影响因素和转基因的整合模式,结果表明:(1)基因枪介导外源基因表达框转化水稻的频率约在0.1%~0.5%之间,非选择标准基因与选择标记基因的共转化频率约为50%~60%,增加基因表达框DNA浓度可提高转化率。相同基因构建物对不同品质水稻的转化率不同,基因构建物的侧边序列对基因枪转化的品种差异可能具有重要影响。(2)非选择标记基因cecropin B表达框在水稻基因组内整合模式简单,仅有1~3个拷贝;筛选标记基因bar表达框却比完整质粒转化后的整合模式复杂得多,插入拷贝数在4~14个之间,线形基因表达框的游离DNA末端和CaMV 35S启动中子重组热点介导的转基因重组可能是导致bar基因表达框复杂整合的重要原因。 相似文献
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以"汉中冬韭"韭菜品种为试验材料,用含有pCAMBIA3301质粒的根癌农杆菌菌株EHA105对影响韭菜遗传转化效率的多种因素进行研究。结果表明,诱导40 d的愈伤组织,GUS基因瞬时表达率达到93%,且最适宜于不定芽的分化;当乙酰丁香酮(AS)的浓度为100μmol/L时,愈伤的GUS表达率达到91%,植株再生率为7.9%,AS浓度增加时其值也不会增加;菌液OD600值为0.6侵染10 min时,与其他组合相比,外植体受伤程度小,GUS表达率及再生率最高;侵染后的愈伤共培养3 d后,农杆菌生长较少,GUS表达率为91.1%,而再生率达到7.2%,为最佳的共培养时间。通过试验得到韭菜遗传转化因素的最佳条件,为今后的遗传转化提供一些参考。 相似文献
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影响农杆菌介导狗牙根遗传转化的因素 总被引:2,自引:0,他引:2
农杆菌LBA4404/pCAMBIA1301介导转化狗牙根的体系中,遗传转化的最佳优化条件是:胚性愈伤组织预培养10 d,农杆菌菌液浓度为OD600 0.5~0.8,共培养时间为2d.共培养基中添加100μmol·L-1乙酰丁香酮能有效地提高植物瞬时表达率.侵染处理方法中滤纸滴加法比浸泡法效果更好.黑暗条件下的瞬时表达率比12 h光照/12 h黑暗培养条件下的高.在最佳优化条件下狗牙根的GUS瞬时表达率达到36.36%. 相似文献
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高羊茅和黑麦草农杆菌介导转化体系的研究 总被引:2,自引:0,他引:2
利用C58C1农杆菌菌系(携带的表达载体上含GUS基因和nptII基因)感染4个草坪草品种追寻者、爱神特、腾跃和守门员成熟胚来源的愈伤组织,共培养后部分愈伤组织进行X-Gluc组织化学染色检测,其余愈伤组织在含G418 10-25 mg/L的MS改良培养上先后筛选抗性愈伤组织和分化抗性再生植株,对移栽成活的144棵抗性再生植株分别进行了ELISA检测、PCR检测和组织化学染色检测。愈伤组织阶段X-Gluc染色检测结果表明,4个草坪草品种GUS基因瞬间表达率8.6%~46.9%,爱神特愈伤组织对农杆菌侵染最为敏感,其次是腾跃和守门员,追寻者最不敏感;ELISA检测结果表明,45株呈现阳性,证明nptII基因已转入草坪草并已表达;PCR检测结果与ELISA检测结果一致,表明nptII基因确实已经整合到了草坪草基因组中,且没有发生沉默现象;转基因植株X-Gluc染色检测结果表明,GUS基因在43株中得到了稳定表达,在2株中发生了沉默现象。4个草坪草品种抗性再生植株分化率0~43.5%,转化率0~21.5 %。结果还表明,GUS基因瞬间表达率与稳定转化率在草坪草上很不一致,不能作为衡量基因型转化效果的指标。 相似文献
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水稻sbe1启动子驱动的反义sbe-GUS融合基因在转基因水稻中的表达 总被引:3,自引:0,他引:3
为研究水稻基因启动子对外源基因在转基因水稻中表达的影响,构建了由sbe1启动子引导的反义sbe-GUS融合基因。经农杆菌介导,将不同的融合基因导入水稻中,定量测定转基因水稻植株不同组织中的GUS酶活力。结果表明,sbe1启动子可驱动反义sbe-GUS融合基因在转基因水稻植株的胚乳中高效表达,而在颖壳、胚和茎叶等组织中的表达活性较弱。证实sbe1启动子在驱动外源基因的表达上表现有明显的组织特异性。 相似文献
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光敏核不育水稻(农垦58S)是中国水稻研究中的一个重要发现,在水稻杂交育种上有巨大潜力。研究表明:农垦58S的雄性不育性受光周期调控,光敏色素是育性转变过程中光周期反应的光受体,然而,鉴于高等植物中存在至少两种不同的光敏色素分子,并且它们同时存在于水稻中,人们对调节农垦58S雄性不育过程的光敏色素分子种类及作用方式仍然不清楚。本文采用酶联免疫吸附测定法(ELISA),比较了不同光周期下农垦58S和对照品种农垦58叶片(光周期感受器官)中光敏色素I(phyA)的含量。从农垦58S的二次枝梗原基分化期开始,进行10天的光周期处理。一组为短日照(SD),另一组为长日照(LD)。在第10个暗期结束前,于暗绿光下收获每株水稻的最上部两片新展叶,立即保存在液氮中。样品在研钵中磨成液氮粉,然后加入提取液(含50mmol/LTris-HCI和0.2mol/L巯基乙醇,pH8.5)匀浆。粗提液经0.5%聚乙烯亚胺(PEI)沉淀后,上清液供ELISA分析。以燕麦phyA的多克隆抗体、单克隆抗体分别作ELISA的一抗和检测抗体。采用ELISA可以专一性地检测水稻phyA(Table1)。几次独立的实验说明,光周期处理对phyA含� 相似文献
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利用两个测序水稻品种构建微卫星连锁图谱 总被引:6,自引:0,他引:6
利用已完成基因组测序的两个水稻品种日本晴和931l的数据库成功开发出水稻微卫星新标记,并利用由90个单株组成的日本晴×9311 F2作图群体,构建了一张包含152个SSR标记位点、覆盖基因组总长度2 455.7 cM的连锁图谱,有46个SSR新标记为自主开发,该图谱标记间的平均遗传距离为16.16 cM;并将未能在Temnykh等人(2001)构建的图谱上定位的微卫星标记RM345和RM494定位在第6染色体上.通过与Temnykh等人(2001)和兰涛等人(2003)所构建的图谱从作图群体的类型和大小、标记的类型和数量、标记在染色体上的线性排列顺序等几个方面进行比较,所绘制的图谱其标记在染色体线性排列上与Temnykh等人绘制的图谱具有很高的一致性,达93.81%. 相似文献
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Sandro D. Tatagiba Fabrício A. Rodrigues Marta Cristina C. Filippi Gisele B. Silva Leandro C. Silva 《Journal of Phytopathology》2014,162(9):596-606
This study investigated the effect of silicon (Si) on the resistance of rice plants of the cv. ‘Primavera’ cultivar that were grown in a nutrient solution with 0 (?Si) or 2 mm (+Si) Si to leaf scald, which is caused by Monographella albescens. The leaf Si concentration increased in the +Si plants (4.8 decag/kg) compared to the ?Si plants (0.9 decag/kg), contributing to a reduced expansion of the leaf scald lesions. The extent of the cellular damage that was caused by the oxidative burst in response to the infection by M. albescens was reduced in the +Si plants, as evidenced by the reduced concentration of malondialdehyde. Higher concentrations of total soluble phenolics and lignin‐thioglycolic acid derivatives and greater activities of peroxidases (POX), polyphenoloxidases (PPO), phenylalanine ammonia‐lyases (PAL) and lipoxygenases (LOX) in the leaves of the +Si plants also contributed to the increased rice resistance to leaf scald. In contrast, the activities of chitinases and β‐1,3‐glucanases were higher in the leaves of the ?Si plants probably due to the unlimited M. albescens growth in the leaf tissues, as indicated by the larger lesions. The results of this study highlight the potential of Si in decreasing the expansion of the leaf scald lesions concomitantly with the potentiation of phenolic and lignin production, and the greater activities of POX, PPO, PAL and LOX rather than simply acting only as a physical barrier to avoid M. albescens penetration. 相似文献
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The tissue-specific expression of transgenes is essential in plant breeding programmes to avoid the fitness costs caused by constitutive expression of a target gene. However, knowledge on the molecular mechanisms of tissue-specific gene expression and practicable tissue-specific promoters is limited. In this study, we identified the cis -acting elements of a tissue-specific promoter from rice, PD54O , and tested the application of original and modified PD54O and its cis -elements in the regulation of gene expression. PD54O is a green tissue-specific promoter. Five novel tissue-specific cis -elements (LPSE1, LPSE2, LPSRE1, LPSRE2, PSE1) were characterized from PD54O . LPSE1 activated gene expression in leaf and young panicle. LPSRE2 suppressed gene expression in leaf, root, young panicle and stem, and PSE1 suppressed gene expression in young panicle and stem. LPSRE1 and LPSE2 had dual roles in the regulation of tissue-specific gene expression; both functioned as activators in leaf, but LPSRE1 acted as a repressor in stem and LPSE2 as a repressor in young panicle and root. Transgenic rice plants carrying cry1Ac encoding Bacillus thuringiensis endotoxin, regulated by PD54O , were resistant to leaf-folders, with no Cry1Ac protein found in endosperm or embryo. A reporter gene regulated by a series of truncated PD54O showed various tissue-specific expression patterns. Different fragments of PD54O fused with the constitutive cauliflower mosaic virus 35S promoter suppressed 35S -regulated gene expression in various tissues. PD54O , truncated PD54O and the tissue-specific cis -elements provide useful tools for the regulation of tissue-specific gene expression in rice breeding programmes. 相似文献
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Transferring foreign DNA into plant cells by biolistic and Agrobacterium -mediated methods may result in random integration of different copy numbers of the transgene, and different proportions of intact vs. rearranged copies of the transgene. This may, in turn, affect transgene expression levels. To test the above hypothesis, we first introduced the same plasmid, pAc1PG-CAM, into rice (BX)Oryza sativa L.) calli separately by the biolistic method and by the Agrobacterium -mediated method. To show whether different plasmids may affect the results, we also introduced pTOK233 by the Agrobacterium -mediated method and pJPM44 by the biolistic method. Transgene expression of R0 plants was monitored by histochemical analysis of GUS activity. Transgene copy number was determined by Southern blot analysis after digesting genomic DNA with an enzyme that has a unique cutting site within the input plasmid. The total genomic DNA was also digested by a two-cut enzyme (the cuts are located at two sides of a given transgene expression cassette), followed by Southern blotting analysis, for determining the number of intact transgene expression cassettes. Our data showed that Agrobacterium -mediated transformation resulted in lower transgene copy number (average between 2.1 and 2.3) in transgenic rice plants, compared with those plants obtained by the biolistic method (average between 4.2 and 5.6). The frequency of DNA rearrangement in expression cassettes is lower in transgenic rice plants obtained by the Agrobacterium -mediated method than those obtained by the biolistic method. The average rearrangement frequency is 0.07 to 0.106 for the Agrobacterium -mediated method, and 0.57 to 0.66 for the biolistic method. Our results suggest that it is better to compare the number of intact expression cassettes instead of the total copy number of the transgene in demonstrating their influence on the level of transgene expression. This is the first report on the frequency of expression cassette rearrangement in transgenic plants transformed with the same plasmid by two different transformation methods. 相似文献
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水稻高脯氨酸愈伤组织变异体的选择及其耐盐性 总被引:1,自引:1,他引:1
以水稻(OryzasativaL.)品种双丰1号幼胚愈伤组织为材料,经50COγ-射线诱变处理后,用羟基脯氨酸(Hyp)作为选择压力,通过多次在含Hyp(3.0mmol/L)的选择培养基和无Hyp培养基上交替培养,分离出耐Hyp的愈伤组织变异体。该变异体以高脯氨酸含量为特征,其脯氨酸含量比原型高2.6倍;在NaCl处理时,随着NaCl浓度的提高,变异体愈伤组织脯氨酸含量的增加大大高于原型。这种高脯氨酸变异体的耐盐性较原型强,用相对鲜重估计其耐性比对照提高39%。变异体在盐胁迫下可溶性糖含量比原型多,吸收较多的Na+,并维持较高的K+含量;但K+/Na+比与原型无差异。变异体含水量略有下降。这些性状的变化显示了变异体在盐胁迫下渗透调节的加强。 相似文献
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水稻双元细菌人工染色体载体系统转化体系的建立 总被引:1,自引:0,他引:1
普通双元载体己被广泛碰用于农杆菌介导的植物转化,但这类载体通常只能转移5~20kb的外源DNA片段;而双元细菌人工染色体(BIBAC)载休可以弥补普通双元裁体的不足,通过它已在烟草、番茄等双子叶植物中实现了大片段DNA(150kb)的转移。BIBAC载体在单子叶植物转化中的应用尚未见报道。面于单、双子叶植物间以及大、小片段转化间的转化体系存在明显差异,常规的农杆菌介导的水稻转化体系不能适应BIBAC系统转化的要求。因此,建立适于BIBAC系统的水稻转化体系是十分必要的。通过比较不同的受体材料,不同的预培养、其培养条件,不同的去除农杆菌及选择阳性愈伤的方式等对转化效率的影响,建矿了适合水稻BIBAC系统的转化体系。该体系的技术要点包括:以水稻品种H1493为转化受体:以含毒性辅助质粒pCH32的LBA4404菌株(HP4404)为侵染菌株;预培养的培养拱pH5.6:以N6A代替AAM悬浮农杆菌:侵染菌液浓度为OD600=1.0;共培养温度为24℃;采用过渡(Resting)培养除去农杆菌;采用二步法进行选择等。基于PCR检测、Southern印迹分析的结果表明,BIBAC载体所携带的插入片段及标记基因已整合到转化植株的基因组中。这个体系的建立为在水稻中利用BIBAC系统进行大片段DNA转化奠定基础。 相似文献
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