基因枪在水稻遗传转化中的应用及其转化技术的优化

1983年Zambryski等人用根瘤农杆菌介导法进行烟草基因转移,获得了世界上首例转基因植株.随后,应用DNA直接导入技术如电击法(electroporation)和PEG介导法(PEG—mediated)成功地获得了转基因水稻植株.近年来,随着基因枪技术的建立和发展,水稻遗传转化成功的报道逐年增多.目前基因枪技术在植物遗传转化中的应用超过了根瘤农杆菌介导和其它转化方法的应用.这是因为基因枪转化技术不受植物种类的限制,不需要以原生质体作为转化的受体,可以将外源基因直接导入细胞、组织或器官,因而克服了根瘤农杆菌     

农杆菌介导的Pr基因对非洲菊遗传转化的研究

采用农杆菌介导法将Pr基因转入非洲菊(Gerbera hybrida),建立适合于农杆菌介导的基因遗传转化受体系统,获得再生植株。经PCR和GUS染色检测,Pr基因成功转入非洲菊幼苗。     

苜蓿高含硫氨基酸蛋白转基因植株再生

通过农杆菌介导法将高含硫氨基酸蛋白基因转入苜蓿,成功地诱导转基因植株再生,转化植株生长和发育良好,苜蓿子叶外植体是较理想的转化受体。冷凉湿润的环境条件是苜蓿移栽成活率高所必需的。     

草坪草生物技术研究进展

概述了草坪草植株再生体系和遗传转化体系建立的方法和进展.通过愈伤组织培养、悬浮细胞培养和原生质体培养方法对草坪草的一些种已建立较为完善的植株再生体系.在建立再生体系的基础上,利用原生质体融合、农杆菌介导、基因枪和碳化硅纤维介导等转基因方法在一些草坪草种上建立了遗传转化体系并获得了有一定价值的转基因植株.最后,对草坪草转基因存在的问题和前景作了讨论.     

花生基因工程

建立花生遗传转化和高效植株再生系统是花生基因工再生技术和基因转化体系的完善,已获得抗病、抗虫和提高品质的转基因花生植株,取得了突破性进展.农杆菌介导法和微弹介导法是花生基因工程的主要方法.     

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%.     

农杆菌介导的玉米遗传转化研究进展

农杆菌介导的转基因法是目前玉米遗传转化的主流方法之一。目前,模式玉米种质幼胚的转化体系已程式化,且开发了新筛选基因和获得不含筛选基因转基因玉米的方法,但是大多数育种骨干自交系转化频率低和转化受体基本上是幼胚。从农杆菌、受体及培养条件多方面各种因素对问题进行分析,多数研究认为针对特定基因型和受体材料建立好的受体再生系统,结合高效率农杆菌转化体系,获得多目的基因聚合(无其它外源片段)的转基因玉米将是农杆菌介导玉米转化体系研究的最终目标。本文主要从农杆菌介导(转基因)法应用于玉米遗传转化的历史、现状、问题等方面进行综述,为同领域的研究者提供一定的参考。     

转HS1prol基因番茄植株的获得

目的为了减少根结线虫对番茄的危害,研究并获得转抗线虫基因HS1prol番茄植株.方法在鉴定表达载体之后,采用CaCl2法制作农杆菌EHA105感受态细胞,然后用冻融法将HS1prol基因转入农杆菌中.通过农杆菌介导法将HS1prol基因导入无菌番茄外植体中,获得抗根结线虫转化再生植株.用卡那霉素筛选到再生植株后,提取抗性芽的基因组,利用设计好的引物进行PCR鉴定.结果与结论目的基因已整合到番茄基因组中,获得了转HS1prol基因番茄植株.     

农杆菌介导的高羊茅高效遗传转化和转基因植株再生

用带有质粒pDBA121(含hpt基因和bar基因)的农杆菌EHA 105转化高羊茅(Festucaarundinacea Schreb.)胚性悬浮细胞,建立了可重复的、高效的农杆菌介导的高羊茅遗传转化系统.商业用的除草剂Basta直接用于转化细胞的筛选.基因型、受体材料的类型、培养基成分和筛选剂影响农杆菌介导的转化频率.悬浮细胞的农杆菌转化效率为每克悬浮细胞再生2.85～10.9株转基因植株,大大高于基因枪法的高羊茅转化效率(2～5株).经PCR分析和Southern杂交检测表明,bar基因已整合进入高羊茅基因组,转基因植株Basta喷洒试验表明bar基因已成功地实现高水平的表达.此转化系统的建立为高效地将外源有用基因导入高羊茅并高效稳定地表达奠定了基础.     

转HS1~(pro1)基因番茄植株的获得

目的:为了减少根结线虫对番茄的危害,研究并获得转抗线虫基因HS1pro1番茄植株。方法:在鉴定表达载体之后,采用CaCl2法制作农杆菌EHA105感受态细胞,然后用冻融法将HS1pro1基因转入农杆菌中。通过农杆菌介导法将HS1pro1基因导入无菌番茄外植体中,获得抗根结线虫转化再生植株。用卡那霉素筛选到再生植株后,提取抗性芽的基因组,利用设计好的引物进行PCR鉴定。结果与结论:目的基因已整合到番茄基因组中,获得了转HS1pro1基因番茄植株。     

带内含子卡那霉素抗性基因双元载体构建及烟草转化

农杆菌介导法是植物基因转化的常用方法,然而由于筛选培养基中常用的抗生素头孢霉素和羧苄青霉素具有类植物激素活性,影响外植体的再生和转化频率。将一个植物的内含子插入卡那霉素抗性基因编码区的N端,合成了一个带内含子的卡那霉素抗性基因。构建带该基因的植物双元表达栽体pYP1202并转化烟草,受侵外植体在含卡那霉素50～200mg/L的选择培养基中抗性芽分化频率不受卡那霉素浓度影响,然而具有GUS活性的转化子占分化芽的比例却随着卡那霉素浓度的增加而升高。当培养基中加入500mg/L羧苄青霉素后受侵外植体产生的抗性芽频率比单一的卡那霉素筛选提高近1倍,高达91.4％,然而具GUS活性的转化子占抗性芽的比例仅有26.7％,在200m/L的卡那霉素筛选下,比例升至93.3％。用带内含子卡那霉素抗性基因构建的植物表达载体转化植物可以减少假抗性芽的产生。     

Agrobacterium-mediated transformation of Eucalyptus globulus using explants with shoot apex with introduction of bacterial choline oxidase gene to enhance salt tolerance

Eucalyptus globulus is one of the most economically important plantation hardwoods for paper making. However, its low transformation frequency has prevented genetic engineering of this species with useful genes. We found the hypocotyl section with a shoot apex has the highest regeneration ability among another hypocotyl sections, and have developed an efficient Agrobacterium-mediated transformation method using these materials. We then introduced a salt tolerance gene, namely a bacterial choline oxidase gene (codA) with a GUS reporter gene, into E. globulus. The highest frequency of transgenic shoot regeneration from hypocotyls with shoot apex was 7.4% and the average frequency in four experiments was 4.0%, 12-fold higher than that from hypocotyls without shoot apex. Using about 10,000 explants, over 250 regenerated buds were confirmed as transformants by GUS analysis. Southern blot analysis of 100 elongated shoots confirmed successful generation of stable transformants. Accumulation of glycinebetaine was investigated in 44 selected transgenic lines, which showed 1- to 12-fold higher glycinebetaine levels than non-transgenic controls. Rooting of 16 transgenic lines was successful using a photoautotrophic method under enrichment with 1,000 ppm CO₂. The transgenic whole plantlets were transplanted into potting soil and grown normally in a growth room. They showed salt tolerance to 300 mM NaCl. The points of our system are using explants with shoot apex as materials, inhibiting the elongation of the apex on the selection medium, and regenerating transgenic buds from the side opposite to the apex. This approach may also solve transformation problems in other important plants.     

Comparison of genetic transformation in <Emphasis Type="Italic">Morus alba</Emphasis> L. via different regeneration systems

Three different regeneration systems, viz. direct regeneration of adventitious shoot buds from explant, regeneration through callus cultures and somatic embryos were compared to see their effect on transfer of neomycin phosphotransferase (nptII) and β-glucuronidase (GUS) reporter gene (gus) to Morus alba clone M5, through Agrobacterium tumefaciens mediated transformation. Pre-conditioning and co-cultivation durations had a marked effect on transformation frequency. The highest transformation frequency of 18.6% was obtained using direct induction of adventitious shoot buds. Expression and presence of transgene were assayed histochemically and through polymerase chain reaction. Southern analysis of GUS and PCR positive transformants confirmed stable integration of transgenes with two to four copy numbers. The selected transformants showed normal phenotype under in vitro and field conditions.     

In vitro regeneration and optimization of conditions for Agrobacterium mediated transformation in jute, Corchorus capsularis

Jute is a crop of commercial importance that is widely cultivated for its bast fiber production but susceptible to many diseases that results in major economic loss. New genes can be introduced into this plant through Agrobacterium mediated genetic transformation for its genetic improvement, which is dependent on the availability of suitable in vitro techniques. An efficient regeneration system has been developed for in vitro culture of jute (Corchorus capsularis) from the distal cut ends of cotyledonary petioles. High frequency shoot regeneration was obtained on Murashige and Skoog (MS) nutrient agar medium supplemented with 0.5 mg/l NAA, 0.5 mg/l BAP and 36 g/l sucrose. On transfer to soil, the regenerated plantlets survived and appeared to be morphologically similar to the normal seed-grown plants. They developed pods and set fertile seeds. Histological analysis revealed de novo origin of shoot buds in the in vitro cultured cotyledonary petioles. Parameters affecting transformation were optimized by assaying GUS activity in these regenerable tissues after cocultivation with Agrobacteria. These tissues appear to be susceptible for infection and transformation by Agrobacterium carrying uid (GUS INT) and nptII genes, as well as shoot multiplication. The cells at the cut end of the petioles were found competent to take up the DNA, which was monitored by transient GUS gene expression. EHA105 at 0.3 O.D and LBA4404 at 0.5 O.D were found to be compatible in giving optimal levels of transient GUS expression.     

根癌农杆菌介导的高粱遗传转化体系的研究

采用根癌农杆菌介导法将杀虫晶体蛋白基因cryIA(b)转入高粱胚性愈伤组织中,建立农杆菌转化高粱的遗传转化体系,获得70棵再生植株。经GUS及PCR检测,结果表明,cryIA(b)基因确实转移到高粱恢复系0-30中,报告基因GUS在再生植株中也得到表达。转化植株的抗病性鉴定正在进行中。     

Genetic transformation and regeneration of mature tissues of woody fruit plants bypassing the juvenile stage

Regeneration and transformation systems from mature plant material of woody fruit species have to be achieved as a necessary requirement for the introduction of useful genes into specific cultivars and the rapid evaluation of resulting horticultural traits. We report here, for the first time, a procedure for genetic transformation and regeneration of mature tissues of woody plants that overcomes the long juvenile periods and high heterozygosity that are characteristic of most of these species. An improved regeneration frequency from mature explants was obtained by invigoration of the plant material through grafting of mature buds on juvenile seedlings. Co-cultivation of the explants in feederplates after inoculation with Agrobacterium tumefaciens resulted in enhanced transformation frequencies. Furthermore, in vitro shoot-tip grafting of the regenerated mature shoots on seedling rootstocks provided a rapid and efficient system for plant production. Citrus is the most extensivel y grown fruit crop worldwide and sweet orange (Citrus sinensis L. Osbeck) accounts for approximately 70% of the Citrus total production. Mature transgenic sweet orange plants have been obtained, which flowered and bore fruit in 14 months     

Evaluation of selection strategies alternative to <Emphasis Type="Italic">nptII</Emphasis> in genetic transformation of citrus

The neomycin phosphotransferase (nptII) selection system has proved successful in citrus transformation; however, it may be recommendable to replace it given the pressure exerted against antibiotic-resistance selectable marker genes in transgenic plants. The present work investigates three different selection alternatives, comparing them to nptII selection in two citrus genotypes, Carrizo citrange and Pineapple sweet orange. The first method used the beta-glucuronidase (uidA) reporter marker gene for selection; the second attempted to generate marker-free plants by transforming explants with a multi-auto-transformation (MAT) vector, combining an inducible R/RS-specific recombination system with transgenic-shoot selection through expression of isopentenyl transferase (ipt) and indoleacetamide hydrolase/tryptophan monooxygenase (iaaM/H) marker genes; while the third exploited the phosphomannose isomerase (PMI)/mannose conditional positive selection system. Firstly, GUS screening of all regenerated shoots in kanamycin-free medium gave 4.3% transformation efficiency for both genotypes. Secondly, workable transformation efficiencies were also achieved with the MAT system, 7.2% for citrange and 6.7% for sweet orange. This system affords an additional advantage as it enables selectable marker genes to be used during the in vitro culture phase and later removed from the transgenic plants by inducible recombination and site-specific excision. Thirdly, the highest transformation rates were obtained with the PMI/mannose system, 30% for citrange and 13% for sweet orange, which indicates that this marker is also an excellent candidate for citrus transformation.     

Variability of organ-specific gene expression in transgenic tobacco plants

Variability of expression of introduced marker genes was analysed in a large number of tobacco regenerants from anAgrobacterium-mediated transformation. In spite of standardization of sampling, considerable variation of GUS and NPTII expression was observed between individual transformants at different times of analysis and in different parts of the same plant. Organ-specificity of root versus leaf expression conferred by the par promoter from the haemoglobin gene ofParasponia andersonii in front of thegus gene showed a continuous spectrum. GUS expression in roots was found in 128 out of 140 plants; expression in leaves was found in 46 plants, and was always lower than in the corresponding roots. NPTII expression regulated by the nos promoter also showed a continuous spectrum. Expression levels were generally higher in roots than in leaves. Plants with high GUS expression in leaves showed high NPTII activity as well. A positive correlation between the level of NPTII expression and the numbers of integrated gene copies was noted. Chromosomal position effects and physiological determination are suggested as triggers for the variations. The transformed regenerated tobacco plants were largely comparable to clonal variants.     

An improved method of Agrobacterium tumefaciens-mediated genetic transformation system of melon (Cucumis melo L.)

A reliable Agrobacterium-mediated transformation and shoot regeneration protocol was developed for breeding lines of commercially important melon. Genetic manipulation has been considered a feasible approach for melon improvement; however, melon is considered a crop species difficult to manipulate. Here we proposed meristematic cells from mature embryos as target for gene transfer by Agrobacterium. In vitro meristems proliferation and multiple shoots regeneration were evaluated by sowing melon mature seeds on MS with 1.0 mg/L benzyladenine (BA), and 0.05 mg/L indole acetic acid (IAA) were used for shoot regeneration. The highest number of regenerated shoots was obtained from half mature seeds. A DNA fragment corresponding to selection marker nptII was amplified from genomic DNA extracted from leaves of regenerated plant on hormone free MS medium with 75 mg/L kanamycin, suggesting their transgenic nature. Southern hybridization of transgenic lines revealed random insertion of the transgene in host genome, with insert numbers differing among transformants anthesis, suggesting that ethylene is important for sex determination. Field studies showed that CmACS-7 melons had earlier mature bisexual flowers, increased femaleness as measured by earlier and bisexual buds, and increased number of fruit set on closely spaced nodes on the main stem. Transformation efficiencies of cultivar CM-23 with EHA105 (pBI121-cm) were 4 %, demonstrating that melon meristematic cells are an useful target for genetic manipulation by agroinfection.