利用GUS基因瞬时表达探索佛手叶盘基因枪转化参数

佛手是芳香科枸橼类植物,有很好的药用和观赏价值,但其品种较为单一,对其进行遗传改良和品种选育显得十分必要.为了将基因枪转化方法应用于佛手的遗传改良和品种选育,本实验以GUS基因为报告基因,利用基因枪方法将其转入金华佛手外植体内,通过检测GUS基因在佛手叶盘中的瞬时表达情况,分析了外植体的幼嫩程度、射程、氦气压力、真空度、轰击次数等参数对GUS瞬时表达的影响,并研究了最佳检测时间.结果表明,以幼叶为受体,在射程为6 cm、氦气压力为7.584×106Pa,真空度为88.046 kPa条件下,2 d后可检测出GUS基因的最佳表达活性.轰击次数多少对GUS基因瞬时表达影响不明显.     

番茄果实特异性启动子的克隆与遗传转化研究

为了实现外源基因在番茄果实中的高效和特异表达,克隆了番茄果实特异基因多聚半乳糖醛酸酶基因( Polygalacturonase,PG)的启动子.以中蔬四号番茄为材料,建立并优化了以子叶为外植体的番茄高效再生和遗传转化体系;以GUS为报告基因,构建PG:GUS植物表达载体,转化番茄.结果表明,在1.0 mg/L ZT的MS分化培养中,番茄子叶的发芽率最高,芽的诱导率高达91％,且发生畸态芽和褐化的外植体最少;通过抗生素浓度对农杆菌的抑制效果试验发现,当头孢霉素的浓度为200 mg/L时,抑制农杆菌的效果最好;成功克隆了番茄PG启动子,将PG启动子驱动的GUS基因转入番茄,对转基因后代果实的GUS染色表明,PG启动子驱动的外源基因在果实中特异表达.     

利用激光微束将外源基因导入高等植物细胞的研究

本实验室已建立了激光微束向植物细胞导入外源基因的试验程序。用已建立的程序对多种经济作物和林木进行外源基因导入的研究,均得到了GUS基因瞬时表达的结果,正在继续研究GUS基因的整合表达。 广泛地选用了不同科属的植物及不同外植体进行外源基因导入的研究,所用材料如下:在被子植物中选用单子叶无性繁殖的兰科花卉兰花(Dendrobium)小圆球茎为外植体;以双子叶植物中的草本植物锦葵科的棉花(G.hirsulum L.)再生胚状体为外植体;十字花科油菜,选用     

农杆菌介导的转化芦荟的研究

芦荟（Aloe）是美容和医疗保健工业的重要植物资源,然而基因工程途径改良芦荟鲜有报道。本实验研究了次氯酸钠、升汞不同浓度和时间对芦荟外植体的灭菌效果,比较了芦荟不同部位（叶片、叶鞘和茎段）的再生能力,利用GUS基因瞬间表达技术（X-Gluc染色）探讨了不同农杆菌对不同芦荟外植体的侵染效果,确定了G418筛选剂在芦荟转化后的最适筛选浓度,摸索了适宜于农杆菌—芦荟共培养用培养基组成和共培养条件,通过转化、筛选和移栽共获得了67棵抗性再生植株,进一步对抗性再生植株进行了PCR、Southern blotting和ELISA检测。结果表明,芦荟外植体灭菌方法为20.0%次氯酸钠溶液浸泡25min,效果优于利用0.1%升汞灭菌处理,茎部切段的再生能力高于叶片切段和叶鞘切段,适宜的共培养条件为芦荟外植体浸泡在含有农杆菌的液体共培养基中半小时后,在无菌滤纸上、24℃、10h光照共培养3天;EHA105农杆菌菌系对芦荟茎部细胞的侵染能力明显强于C58C1,EHA105侵染后GUS基因瞬时表达率达到了80.0%左右,而C58C1侵染后GUS基因瞬时表达率只有30.0%左右。G418用于筛选抗性再生芽和抗性植株的适宜浓度为10.0～25.0mg/L。PCR和Southern blotting检测证实外源基因已成功整合到芦荟基因组中,转化效率为0.9%,单拷贝整合占80.0%,2～3拷贝整合占20.0%,ELISA检测证明外源基因已在转基因芦荟中稳定表达。综上所述,初步建立了农杆菌介导转化芦荟的技术体系,为利用基因工程途径改良芦荟奠定了基础。     

油葵种子特异启动子Ha ds10 G1的克隆及功能鉴定

从油葵中克隆得到LEA蛋白基因家族Ha ds10 G1基因的启动子序列,并对其进行功能分析。利用PCR技术从油葵品种"矮大头"基因组DNA中分离Ha ds10 G1基因上游的调控序列,将其与GUS基因融合,构建种子特异性表达载体p BI121-PHa ds10,通过根癌农杆菌介导法转化烟草(Nicotiana tabacum)NC89,对再生植株进行PCR、RT-PCR和GUS组织化学分析,以检测GUS基因在转基因烟草中的表达情况。结果表明,油葵Ha ds10 G1基因启动子长度为1 417 bp,与已报道的向日葵Ha ds10G1基因启动子序列同源性为89.42%。作用元件分析发现该区域除了具有启动子核心调控序列外,还含有多个与组织特异性、激素、逆境等表达相关的顺式作用元件,如RY重复元件、ABRE元件、TC-rich元件等。转基因植株的PCR结果显示,成功地获得了转基因阳性植株;GUS活性检测表明,该启动子序列仅能够驱动GUS基因在烟草种子表达,而在根、茎、叶等组织中均未检测到GUS基因表达。因此,油葵LEA蛋白基因家族Ha ds10 G1基因上游1 417 bp片段具有种子特异性启动子功能。研究结果为油葵等油料作物的油脂遗传改良提供组织特异性启动子。     

农杆菌介导韭菜遗传转化相关因素的研究

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。     

小油桐外植体的KN1基因遗传转化及其超量表达的转基因植株

本研究采用农杆菌介导法将KN1基因遗传转化小油桐,并获得了转基因植株。在研究中分析了农杆菌菌液菌液的浓度、侵染时间和外植体的大小对遗传转化效率的影响以及KN1基因超量表达对转基因植株再生的影响。研究结果表明:以苗龄15d左右的小油桐无菌苗子叶为外植体,农杆菌菌液浓度OD600为0.6～0.8时,侵染8min,外植体大小为(0.8×0.8)～(1.0×1.0)mm时,遗传转化效果最好;对抗性芽及再生植株进行GUS及PCR检测结果表明,KN1基因已经整合到小油桐植物基因组中。KN1基因的超量表达可提高小油桐再生芽分化,影响转化芽及植株的外观形态及叶片的表型,包括芽及植株矮小,茎杆粗壮;叶片缩小,边缘分裂,对称性丧失,无子叶柄等。     

花生体胚诱导再生体系及基因枪转化条件的初步探讨

以花生上胚轴为外植体,研究不同Picloram(毒莠定)浓度处理和不同基因型对体细胞胚胎发生及植株再生的影响,并利用基因枪将含GUS基因的pCAMBIA2301质粒载体轰击体胚,对基因枪转化条件进行了初步探索.结果表明:外植体在添加5 mg/ L Picloram+1 mg/L Glutamine(谷氨酰胺)的MB培养基上诱导的体胚发生率、产胚数及植株再生率最高.不同基因型以‘中花8号'体胚再生率最高(体胚诱导率为55.36%,植株再生率为56.79%).在氦气压力为1 100 psi,轰击距离为9 cm时,体细胞胚GUS瞬时表达率可达到22.95%.     

拟南芥ats1A基因启动子的克隆和功能分析

通过PCR扩增,从拟南芥中克隆出ats1A基因启动子(包括叶绿体转运肽),将此启动子与GUS基因相连构建植物瞬时表达载体,用基因枪法将之导入烟草进行瞬时表达。GUS基因检测分析表明,ats1A基因启动子能特异的启动GUS基因在烟草叶片中高效表达。     

拟南芥AtNHX6基因启动子的克隆及表达分析

为了探明拟南芥内膜反向转运体AtNHX6基因的组织表达模式,从基因组中克隆了AtNHX6基因开放阅读框(ORF)上游侧翼调控区1 922bp序列,并成功构建AtNHX6基因启动子与GUS融合表达载体pCAM-BIA1381-proNHX6-GUS,通过农杆菌花序浸染法转化野生型拟南芥获得T3代纯合转基因拟南芥株系,经PCR检测扩增得到2 187bp目的条带。利用组织染色法鉴定转基因拟南芥的GUS表达模式发现,在子叶、下胚轴和花中GUS活性显著。在这些广泛表达的部位中,微管系统中的表达最为显著,真叶中只有局部检测到GUS表达;在根中GUS在根毛和侧根生长部位表达;在未成熟果荚中只有在果荚顶端和基部存在GUS活性,成熟果荚中只在果柄检测到GUS表达;在花中,雄蕊的花丝和花粉粒及雌蕊的柱头中检测到GUS表达。GUS染色分析结果表明,AtNHX6基因启动子与GUS的融合表达载体成功构建并正常启动GUS基因表达,且AtNHX6基因主要在拟南芥的子叶、下胚轴、根、花、果荚中的微管系统、根毛和侧根生长部位以及花丝、花粉、柱头中表达。     

枳壳外植体离体再生及农杆菌介导的遗传转化

以枳壳实生苗的上胚轴及茎段为材料,在附加有ＢＡ和ＭＴ培养基上进行培养,上胚轴出芽率普遍高于茎段,ＢＡ为１ｍｇ／Ｌ时,出芽率最高,ＢＡ浓度升高,出芽率随之下降。外植体在培养基上的接种方式,对出芽有一定影响,上胚轴切段 形态学下端垂直插入,出芽率高。     

Low light and low ammonium are key factors for guayule leaf tissue shoot organogenesis and transformation

A new method has been developed for guayule tissue culture and transformation. Guayule leaf explants have a poor survival rate when placed on normal MS medium and under normal culture room light conditions. Low light and low ammonium treatment greatly improved shoot organogenesis and transformation from leaf tissues. Using this method, a 35S promoter driven BAR gene and an ubiquitin-3 promoter driven GUS gene (with intron) have been successfully introduced into guayule. These transgenic guayule plants were resistant to the herbicide ammonium-glufosinate and were positive to GUS staining. Molecular analysis showed the expected band and signal in all GUS positive transformants. The transformation efficiency with glufosinate selection ranged from 3 to 6%. Transformation with a pBIN19-based plasmid containing a NPTII gene and then selection with kanamycin also works well using this method. The ratio of kanamycin-resistant calli to total starting explants reached 50% in some experiments.     

Agrobacterium mediated transformation of Vigna sesquipedalis Koern (asparagus bean)

Agrobacterium mediated transformation of Vigna sesquipedalis was achieved using cotyledonary node explants prepared from 5 days old seedlings germinated on B5 basal medium, and transformed using Agrobacterium tumefaciens strain EHA101, carrying the phosphinothricin-N-acetyltransferase gene and neomycin-3-phosphotransferase-II gene as selectable markers and GUS gene as a screenable marker. Gene transfer was achieved by inoculation of cotyledonary node explants with a bacterial suspension and a further cocultivation with Agrobacterium suspension for 3 days on B5 basal medium. Only 10% of the explants were transformed with EHA101 and exhibited transient expression of GUS genes, while 2% of shoots exhibited stable integration of genes and developed into plants. Transgenic character of tissues was confirmed by GUS assay and Southern analysis. Histological analysis of GUS gene expression directly after cocultivation revealed a high competence of subepidermal cell layers of cotyledonary node and associated cotyledons for transformation with Agrobacterium.     

发根农杆菌介导的长春花高效转基因体系的建立

以长春花幼叶为外植体建立了发根农杆菌介导的长春花高效遗传转化体系,主要技术环节为：用携带有基因表达载体的发根农杆菌R1000侵染幼嫩叶片,侵染的叶片外植体与发根农杆菌共培养2d,外植体移至除菌培养基除菌培养2～3周,切取外植体上诱导长出的毛状根置于筛选培养基上培养1-2周,最后对筛选出的阳性毛状根无性系进行扩繁。筛选出的阳性毛状根经GUS染色和PCR分子鉴定表明,该方法的发根诱导率和阳性转化率分别为82％±2．49％和100％。该转化方法所获得的毛状根系数量大、质量高、遗传稳定且所需时间短,明显优于现有的长春花遗传转化技术,是长春花遗传转化的高效便捷体系。     

Transformation and regeneration of transgenic aspen plants via shoot formation from stem explants

An Agrobacterium -mediated transformation procedure for aspen ( Populus tremula L.), involving the direct regeneration of shoot-buds from stem explants, is described. Disarmed Agrobacterium tumefaciens strain EHA101 harboring the binary plasmid pKIW1105 (which carries the uidA and nptII genes, coding for β-glucuronidase [GUS] and neomycin phosphotransferase II, respectively) was used for the transformation of stem explants. An incubation period of 48 to 72 h was found to be most effective in terms of transient GUS expression on the cut surface of the stem explants. Adventitious shoots regenerated after 2–3 weeks of culture in a woody plant medium (WPM) supplemented with TDZ (1-phenyl-3-[1,2,3-thiadiazol-5-yl]-urea, Thidiazuron) and carbenicillin. Three different kanamycin-based selection schemes were evaluated for optimization of transformation efficiency: (1) Kanamycin was added only to the rooting medium (5 to 6 weeks post-inoculation), or (2) to the regeneration medium 10–14 days after inoculation, or (3) after 2 days of co-cultivation. The third selection scheme was found to be optimal for adventitious shoots with regard to both the time required and the transformation efficiency, the latter being much higher than with the other schemes. Leaf samples from kanamycin-resistant shoots and plantlets were tested for GUS expression, and subjected to polymerase chain reaction (PCR) analysis of uidA and nptII genes. A Southern blot of the corresponding PCR-amplified fragments confirmed their authenticity and Southern blots of total plant DNA confirmed integration of the nptII gene into the plant genome.     

Factors affecting genetic transformation and shoot organogenesis of Bacopa monnieri (L.) Wettst

Efficient Agrobacterium tumefaciens mediated T-DNA delivery and subsequent shoot organogenesis has been achieved from Bacopa monnieri. Various factors influenced T-DNA delivery as evident from transient GUS assay. The transient GUS expression was significantly higher (97.7 %) in explants that were pre-cultured before bacterial infection on medium supplemented with 100 μM acetosyringone. Incorporation of acetosyringone into the co-cultivation medium also enhanced transient GUS activity. Explant injury with carborundum paper, co-cultivation period of 2 days and a bacterial density of 0.4 OD₆₀₀ showed higher transient GUS expression. Following co-cultivation, shoot organogenesis was achieved from leaf segments on basal Murashige and Skoog medium containing 58 mM sucrose. Supplementation of antibiotics (cefotaxime or carbenicillin) at > 250 μg/ml into the medium significantly promoted shoot organogenesis from leaf explants (71.5 % in control and > 83.0 % on medium containing 500 μg/ml of carbenicillin or cefotaxime). Stable transformation of regenerated shoots was confirmed on the basis of GUS activity and PCR amplification of DNA fragments specific to reporter gene (uidA) and selection marker gene (nptII). The expression level of nptII gene in independent transgenic lines was studied using quantitative real time-PCR. Stable transformed shoots after rooting were successfully established in the pots.     

Preliminary studies on tissue culture and agrobacterium-medicated transformation of Brassica campestris ssp. chinensis]

The hypocotyls and cotyledons of the asepetic seedling of Brassica campestris ssp. chinensis L cv. Pudongaijiecai) were used as explants for tissue culture. Adventitious buds were differentiated on modified MS medium supplemented with TDZ 1-2 mg/L, NAA 0.2-1 mg/L and AgNO3 7.5 mg/L. The percentage of explants which formed buds of cotyledons was about 56%, and that of hypocotyls was about 37%. When the regenerated explants were transferred onto MS medium with 2 i.p. 5 mg/L and NAA 0.1 mg/L for two weeks, whole plantlets were obtained by culturing the regenerated shoots on 1/2 MS medium with NAA 0.1 mg/L. Agrobacterium tumefaciens strain (LBA 4404/PBI 121) carrying the GUS gene and Npt II gene was used for transformation. After 2 days of coculture, the hypocotyls and cotyledons were transferred onto regenerated medium containing CP 300 mg/L for bud formation. After 4-5 weeks, the differentiated buds were transferred onto selection medium with CP 200 mg/L and Km 10 mg/L for 1 month, then the green shoots were transferred onto the rooting medium containing Cef 100 mg/L and Km 20 mg/L. 4-5 weeks later, plantlets with Km resistance were obtained and some of them showed higher enzymatic activities of beta-glucuronidase than control ones.     

Agrobacterium tumefaciens-mediated transformation of Solanum gilo Raddi as influenced by explant type

An efficient system for Agrobacterium tumefaciens-mediated transformation of Solanum gilo was established. The marker genes for kanamycin resistance and ß-glucuronidase expression were introduced. A comparison between cotyledon and hypocotyl explants showed that while regeneration was better from hypocotyl explants, cotyledon explants gave better transformation efficiency (46% vs. 32%). Four levels of kanamycin selection (100, 150, 200 and 250 mg/l) were tested for effect on transformation efficiency with each type of explant. Lower levels of kanamycin worked better using cotyledon explants, while higher levels of kanamycin worked better for hypocotyl explants. All nine t₀ plants tested for expression of the kan ^r gene were positive. The progeny of three of these plants showed a pattern of classical Mendelian inheritance (3 to 1) for both the kan ^r and the ß-glucuronidase genes.Abbreviations MS Murashige and Skoog (1962) medium - 2,4-D 2,4-Dichlorophenoxyacetic acid - NPTII neomycin phosphotransferase - GUS ß-glucuronidase     

Evaluation of a cotyledonary node regeneration system forAgrobacterium-mediated transformation of pea (Pisum sativum L.)

Summary A rapid regeneration system was used for studies ofAgrobacterium-mediated transformation inPisum sativum L. Cotyledonary node explants were inoculated withAgrobacterium tumefaciens strains containing binary vectors carrying genes for nopaline synthase (NOS),β-glucuronidase (GUS), and neomycin phosphotransferase (NPTII) and placed on selection medium containing either 75 or 150 mg/liter kanamycin. A GUS encoding gene (uidA) containing an intron was used to monitor gene expression from 6 to 21 days postinoculation. GUS activity could be observed 6 days after inoculation in the area of the explant in which regeneration-occurred. Regenerating tissue containing transformed cells was observed in explants on selection medium 21 days postinoculation. Using this system, a single transgenic plant was obtained. Progeny of this plant, which contained two T-DNA inserts, demonstrated segregation for the inserts and for expression of the NOS gene in the selfed R₁ progeny. NPTII activity was observed in the R₂ generation, indicating inheritance and expression of the foreign DNA over at least two generations. Attempts to repeat this procedure were unsuccessful.