影响根癌农杆菌介导水稻转化的因素分析

根癌农杆菌与来自水稻成熟种子盾片的愈伤组织共培养,将GUS基因导入水稻愈伤组织,并获得了转基因植株。通过比较影响根癌农杆菌转化频率的各种因素,表明激素配比为2,4-D1mg/L、TDZ0.5mg/L、NAA1mg/L时,可以大大促进籼稻愈伤组织的分化能力;酚类化合物的加入使农杆菌的转化频率提高8.9%-23.5%;共培养时农杆菌的稀释方式及适当调整潮霉素（hygB）的使用浓度影响到农杆菌的转化频率。     

根癌农杆菌介导的水稻转化及转基因R1代植株表型特征

用根癌农杆菌介导的方法对２个粳稻品种和４个籼稻品种进行了转化。粳稻成熟胚和籼稻幼胚来源的愈伤组织用携带质粒ｐＧＩＨ的农杆菌ＥＨＡ１０１感染,对所有品种均获得较高的愈伤转化频率（２０．８３％～６２．３２％）。粳稻“申香粳４号”植株转化频率为１７．３９％,“秋丰”为９．２１％。４个品种籼稻中仅“超丰早１号”获得１株转化植株。Ｓｏｕｔｈｅｒｎ杂交分析、ＧＵＳ染色、Ｔ－ＤＮＡ整合边界序列分析等结果表明外源     

根癌农杆菌介导的水稻转化及转基因R1代植株表型特征

用根癌农杆菌介导的方法对２ 个粳稻品种和４ 个籼稻品种进行了转化。粳稻成熟胚和籼稻幼胚来源的愈伤组织用携带质粒ｐＧＩＨ 的农杆菌ＥＨＡ１０１ 感染,对所有品种均获得较高的愈伤转化频率（２０．８３ ％ ～６２ ．３２ ％ ） 。粳稻“申香粳４ 号”植株转化频率为１７ ．３９ ％ ,“秋丰”为９ ．２１％ 。４ 个品种籼稻中仅“超丰早１ 号”获得１ 株转化植株。Ｓｏｕｔｈｅｒｎ 杂交分析、ＧＵＳ 染色、ＴＤＮＡ 整合边界序列分析等结果表明外源基因整合入植物基因组中。对Ｒ１ 代分析结果表明外源基因能遗传给后代,大多数株系的分离比符合３∶１ ,也有少数株系分离比异常。对转基因Ｒ１ 代水稻植株表型特征分析结果显示转化植株株高下降,每株分蘖数减少,每株籽粒数明显减少,部分植株播种至开花所需时间延迟。     

一种改进的水稻成熟胚愈伤组织高效基因转化系统

以成熟胚愈伤组织为材料的农杆菌介导水稻转化法虽已建立,但转化频率仍有待提高.本文以粳稻(Oryza sativa)品种(中花10号和中花11号)的成熟胚诱导的愈伤组织为受体材料,对组织培养体系及影响遗传转化的因素进行优化,建立了一套改进的农杆菌介导的水稻高效遗传转化系统.农杆菌菌株为EHA105,质粒载体是pUN1301/OsRAA1,其中含有标记基因GUS和筛选基因HPT.愈伤组织诱导培养基为NBD2(NB 2 mg·L-12,4-D),继代培养基为NBD0.5,预分化与分化培养基为RE1(MS 1 mg·L-16-BA 0.25 mg·L-1NAA 0.5 mg·L-1KT 0.2 mg·L-1ZT)和RE2(MS 1 mg·L-16-BA 0.5 mg·L-1NAA 0.5 mg·L-1KT 0.2 mg·L-1ZT).另外,还分析了影响T-DNA转移的多种因素,如外植体种类、愈伤组织预培养基和愈伤组织继代次数等.采用优化的转化程序,水稻愈伤组织转化率和植株转化率可达70%以上.     

一种改进的水稻成熟胚愈伤组织高效基因转化系统

以成熟胚愈伤组织为材料的农杆菌介导水稻转化法虽已建立, 但转化频率仍有待提高。本文以粳稻(Oryz a sativa)品种(中花10号和中花11号)的成熟胚诱导的愈伤组织为受体材料, 对组织培养体系及影响遗传转化的因素进行优化, 建立了一套改进的农杆菌介导的水稻高效遗传转化系统。农杆菌菌株为EHA105, 质粒载体是pUN1301/ OsRAA1, 其中含有标记基因GUS 和筛选基因HPT。愈伤组织诱导培养基为NBD2 (NB+2 mg·L-12,4-D), 继代培养基为NBD0.5, 预分化与分化培养基为RE1 (MS+1 mg·L-16-BA + 0.25 mg·L-1 NAA + 0.5 mg·L-1 KT + 0.2 mg·L-1 ZT)和RE2 (MS+ 1 mg·L-1 6-BA + 0.5 mg·L-1 NAA+ 0.5 mg·L-1 KT + 0.2 mg·L-1 ZT)。另外, 还分析了影响T-DNA转移的多种因素, 如外植体种类、愈伤组织预培养基和愈伤组织继代次数等。采用优化的转化程序, 水稻愈伤组织转化率和植株转化率可达70%以上。     

根癌农杆菌介导的水稻转基因技术体系的优化

对根癌农杆菌介导水稻遗传转化的各重要因素逐一分析,比较不同基因型、培养基成份、光照、继代次数、菌液浓度、侵染时间、干燥情况等因素对遗传转化的影响。通过培养条件的优化,建立了一个高效的水稻转化技术体系。研究结果表明,相比较于暗培养,光照培养进行愈伤诱导可以使诱导天数缩短4~5d;诱导培养基中加入适量的激素可以使籼稻愈伤诱导提高25%~30%;分化培养基中加入适量的氨基酸和甘露醇可以使植株再生频率提高15%~20%。     

根癌农杆菌介导转化水稻成熟胚及转Metr基因植株的获得

以粳稻品种广陵香糯为材料,用携带有双元载体pBB的根癌农杆菌EHA105为载体,研究了根癌农杆菌介导转化粳稻成熟胚愈伤组织的几个影响因素,建立了合适的粳稻成熟胚愈伤组织转化系统。一种基于MS为基本培养基的商品培养基(HRM)较适合于作为粳稻成熟胚愈伤组织诱导培养基,合适的愈伤组织诱导培养天数为7~8 d,合适的筛选培养基为CC培养基。在此基础上,将Metr基因导入粳稻品种广陵香糯中,获得了一批转基因水稻植株,PCR分析表明外源基因已经整合进了水稻的基因组中。部分转基因植株后代遗传分析表明外源基因的分离符合3∶1的理论比例。     

水稻悬浮细胞再生及根癌农杆菌介导转化的影响因素

已经成功报道的农杆菌介导的水稻遗传转化多以活力较高的胚性愈伤为材料,很少以水稻悬浮细胞作为受体．另外,利用农杆菌转化多数都是通过浸泡的方式进行侵染．本实验利用滴加浸染法进行农杆菌介导转化水稻悬浮细胞,探讨影响 DNA 转化效率的因素．研究显示,在转化前,将水稻悬浮细胞在愈伤诱导培养基上培养1～2周,诱导产生直径为2～3 mm的微小愈伤组织对转化非常重要.微小愈伤组织大小不应小于 2 mm;对悬浮细胞短时间培养不但会缩短植株再生时间,而且会提高转化效率．此外,侵染农杆菌的浓度、侵染时间和不同侵染方法也影响 T-DNA 插入基因组的效率．用 1 ml Ａ600值为 0.5 浓度的农杆菌悬液滴加在水稻悬浮细胞诱导的愈伤,培养3 d或直到可见农杆菌菌落,此方法可以得到较高转化效率．将再生的潮霉素抗性的转化植株在含有 50 mg/L 潮霉素的分化和生根培养基中筛选得到,并对转化植株 gus 基因的表达进行 PCR 检测.结果显示,用 Ａ600值为 0.5 浓度的农杆菌浸泡侵染 20 min和滴加浸染法,分别得到PCR阳性植株率为 70% 和92%.     

发根农杆菌LBA9402 Bin19转化红豆草及再生转基因植株

用含pBin19和pRi1855的发根农杆菌菌株对红豆草下胚轴切段进行遗传转化,种苗年龄和下胚轴切段的预培养时间明显影响转化频率.纸电泳分析表明70%的发状根培养系能够合成农杆碱.发现发状根诱导愈伤组织比发状根具有更强的再生力;发状根切段在含0-9.05μmol/L2,4-D和0-2.22μmol/L6-BA的MS培养基上诱导产生愈伤组织,然后在不含植物激素和卡那霉素的MS培养基上进行再生试验.愈伤组织诱导培养基中的植物激素组成和浓度显著影响愈伤组织后期的再生植株能力.再生频率和每块愈伤组织的芽点发生数随愈伤组织诱导培养基中2,4-D浓度的增加(4.52-9.05μmol/L)而下降,随6-BA浓度增加(0-2.22μmol/L)而上升.在附加4.52μmol/L2,4-D和2.22μmol/L6-BA的MS培养基上,愈伤组织的诱导频率只有14.2%,但愈伤组织在MS0培养基上的再生频率高达58.1%,每块愈伤组织的芽点发生数平均为37.2.对来自8个发状根系的32株再生植株进行Southern分子杂交分析,25株整合有不同拷贝的nptⅡ基因.     

几种影响籼稻成熟胚愈伤组织诱导及再生的因素

建立了适合5个籼稻品种成熟胚籼稻遗传转化的高效植株再生体系.N6基本培养基有利于籼稻愈伤组织的诱导和继代培养;N6大量元素和MS微量元素有利于愈伤组织的分化.降低分化培养基中蔗糖含量,加入适量山梨醇、Cu2 、Ag 和玉米素(2T)均可明显提高水稻愈伤组织的再生植株频率,5个品种分化频率均达到75%以上.     

Agrobacterium-mediated transformation of rice using immature embryos or calli induced from mature seed

Here, we provide comprehensive, highly efficient protocols for Agrobacterium tumefaciens-mediated transformation of a wide range of rice genotypes. Methods that use either immature embryos (japonica and indica rice) or calli (japonica cultivars and the indica cultivar, Kasalath) as a starting material for inoculation with Agrobacterium are described. Immature embryos are pretreated with heat and centrifugal force, which significantly enhances the efficiency of gene transfer, and then infected with Agrobacterium. Callus is induced from mature seeds and infected. Transformed cells proliferated from these tissues are selected on the basis of hygromycin resistance, and transgenic plants are eventually regenerated. A single immature japonica or Kasalath embryo will produce between 10 and 18 independent transgenic plants; for other non-Kasalath indica varieties, the number of transgenic plants expected will be between 5 and 13. For japonica and Kasalath, transformants should be obtained from between 50 and 90% of calli. From inoculation with Agrobacterium to transplanting to soil will take 55 d for japonica and Kasalath, and 74 d for indica other than Kasalath using the immature embryo method, and 50 d for japonica and Kasalath using the callus method.     

Highly efficient production and characterization of T-DNA plants for rice ( Oryza sativa L.) functional genomics

We investigated the potential of an improved Agrobacterium tumefaciens-mediated transformation procedure of japonica rice ( Oryza sativa L.) for generating large numbers of T-DNA plants that are required for functional analysis of this model genome. Using a T-DNA construct bearing the hygromycin resistance ( hpt), green fluorescent protein ( gfp) and beta-glucuronidase ( gusA) genes, each individually driven by a CaMV 35S promoter, we established a highly efficient seed-embryo callus transformation procedure that results both in a high frequency (75-95%) of co-cultured calli yielding resistant cell lines and the generation of multiple (10 to more than 20) resistant cell lines per co-cultured callus. Efficiencies ranged from four to ten independent transformants per co-cultivated callus in various japonica cultivars. We further analysed the T-DNA integration patterns within a population of more than 200 transgenic plants. In the three cultivars studied, 30-40% of the T(0) plants were found to have integrated a single T-DNA copy. Analyses of segregation for hygromycin resistance in T(1) progenies showed that 30-50% of the lines harbouring multiple T-DNA insertions exhibited hpt gene silencing, whereas only 10% of lines harbouring a single T-DNA insertion was prone to silencing. Most of the lines silenced for hpt also exhibited apparent silencing of the gus and gfp genes borne by the T-DNA. The genomic regions flanking the left border of T-DNA insertion points were recovered in 477 plants and sequenced. Adapter-ligation Polymerase chain reaction analysis proved to be an efficient and reliable method to identify these sequences. By homology search, 77 T-DNA insertion sites were localized on BAC/PAC rice Nipponbare sequences. The influence of the organization of T-DNA integration on subsequent identification of T-DNA insertion sites and gene expression detection systems is discussed.     

Reasons for lower transformation efficiency in indica rice using Agrobacterium tumefaciens-mediated transformation: lessons from transformation assays and genome-wide expression profiling

Agrobacterium tumefaciens-mediated genetic transformation has been routinely used in rice for more than a decade. However, the transformation efficiency of the indica rice variety is still unsatisfactory and much lower than that of japonica cultivars. Further improvement on the transformation efficiency lies in the genetic manipulation of the plant itself, which requires a better understanding of the underlying process accounting for the susceptibility of plant cells to Agrobacterium infection as well as the identification of plant genes involved in the transformation process. In this study, transient and stable transformation assays using different japonica and indica cultivars showed that the lower transformation efficiency in indica rice was mainly due to the low efficiency in T-DNA integration into the plant genome. Analyses of the global gene expression patterns across the transformation process in different varieties revealed major differences in the expression of genes responding to Agrobacterium within the first 6 h after infection and more differentially expressed genes were observed in the indica cultivar Zhenshan 97 (ZS), with a number of genes repressed early during infection. Microarray analysis revealed an important effect of plant defense response on Agrobacterium-mediated transformation. It has been shown that some genes which may be necessary for the transformation process were down-regulated in the indica cultivar ZS. This dataset provided a versatile resource for plant genomic research to understand the regulatory network of transformation process, and showed great promise for improving indica rice transformation using genetic manipulation of the rice genome.     

水稻双元细菌人工染色体载体系统转化体系的建立

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。     

High Efficiency of Genetic Transformation of Rice Using Agrobacterium Mediated Procedure

Four japonica varieties and two indica varieties were used for the genetic transformation of rice （Oryza sativa L.） by using Agrobacterium tumefaciens (Smith et Townsend) Conn EHA101 harboring binary vector containing GUS gene and selectable marker gene of NPTⅡ and HPT. Calli derived from mature and immature embryos of rice were infected and cocultured with Agrobacterium at logarithmic phase. The highest transformation frequency was 55.1% (indica) and 85.2% (japonica) respectively according to the estimation of hygromycin resistant calli produced. The ratio of transgenic plants regenerated from the calli of indica and japonica varieties was 37.8% and 69.0% respectively. The putative transformed plants were confirmed by GUS assay, PCR analysis and Southern blotting. The segregation of foreign genes in T1 progeny corresponded to the Mendelian ratio. This transformation procedure of rice will provide an efficient model for the transformation of monocots.     

Fast recovery of transgenic submergence tolerant rice cultivars of North-East India by early co-cultivation of <Emphasis Type="Italic">Agrobacterium</Emphasis> with pre-cultured callus

Agro-climatic conditions of North-East India are very complex and rice cultivars present in the region have been adapted to grow under harsh environmental conditions. Germplasm present in the region is considered to possess several important and unique traits that are of importance in rice improvement programs. Genetic engineering is a powerful tool to introduce new traits into crop plants. However, not much information is available on the methods to introduce foreign genes into North-East rice cultivars. Therefore, the main objective of this study is to develop transformation procedures for fast recovery of transgenic plants from North-East rice cultivars. To achieve this objective, a systematic study was carried out to identify media components and culture conditions for efficient embryogenic callus induction from the mature seeds and differentiation of callus into plantlets from two North-East deep water rice cultivars, Taothabi and Khongan. Also, role of preculture of callus on Agrobacterium-mediated transformation was studied. Co-cultivation of Agrobacterium with 1–5 days precultured callus was found to result in high frequency of transformation. Detailed characterization of transgenic lines confirmed stable integration of transgenes and expression of reporter gfp gene. The whole process starting from callus induction to regenerating of transgenic rice plants that can be established in the soil was achieved in about 35–45 days. The procedures developed were found to be applicable to a popular variety IR 64. Therefore, methods developed in this study should be useful not only to introduce new traits quickly but also to validate the function(s) of several candidate gene(s) identified under the functional genomics of rice.     

Efficient and genotype-independent Agrobacterium--mediated tomato transformation

An efficient method to transform five cultivars of tomato (Lycopersicon esculentum), Micro-Tom, Red Cherry, Rubion, Piedmont, and E6203 is reported. A comparison was made of leaf, cotyledon, and hypocotyl explants on 7 different regeneration media without Agrobacterium tumefaciens cocultivation and on 11 different media with cocultivation. Although all cultivars and explants formed callus and regenerated on the initial 7 media, cocultivation with A. tumefaciens significantly reduced the callus induction and regeneration. From these experiments, a transformation methodology using either hypocotyls or cotyledons cultured for one day on BA 1 mgL-1, NAA 0.1 mgL-1 and 3 days cocultivation with the Agrobacterium on this same medium followed by a transfer to a medium with zeatin 2 mgL-1 and IAA 0.1 mgL-1 for 4-6 weeks resulted in a greater than 20% transformation frequency for all five cultivars tested. In this transformation method, no feeder layers of tobacco, petunia or tomato suspension cultures were used, and the subculture media was minimal. Stable integration and transmission of the transgene in T1 generation plants were confirmed by Southern blot analysis. This procedure represents a simple, efficient and general means of transforming tomato.     

农杆菌介导将白叶枯病抗性基因Xa21导入水稻获得转基因植株

利用农杆菌介导的高效遗传转化系统,将白叶枯病抗性基因Xa21转入黄淮稻区主栽品种豫粳6号的胚性愈伤组织,获得转基因植株,GUS染色和PCR分析证明Xa21基因已整合到水稻基因组中,其自交T1代植株经GUS染色和白叶枯病接种鉴定呈现3：1分离,研究为培育抗白叶枯病水稻品种奠定了基础。