农杆菌介导的墨兰遗传转化

转基因育种是快速定向改良兰花育种目标性状的有效方法,但迄今未见有关墨兰转基因育种的研究报道。试验以‘企剑白墨’墨兰Cymbidium sinensis cv.‘Qijianbaimo’的根状茎为受体材料,研究了影响农杆菌介导墨兰遗传转化效率的因素,以建立有实用价值的墨兰遗传转化技术体系。结果表明,受体的预培养时间、乙酰丁香酮的添加方式及浓度、农杆菌工程菌液浓度(OD600)、侵染时间和共培养时间均对‘企剑白墨’根状茎的GUS瞬时表达率有显著影响。以预培养39 d的根状茎尖为材料,在添加200μmol/L乙酰丁香酮,OD600为0.9的工程菌液中侵染35 min后,转入添加200μmol/L乙酰丁香酮的共培养基中培养7 d时,‘企剑白墨’根状茎的GUS瞬时表达率最高,为11.67%。采用上述条件对‘企剑白墨’墨兰进行遗传转化,经PCR鉴定和GUS染色检测,从400株再生植株中获得了3株转基因植株,转化率为0.75%。研究表明通过农杆菌介导法对墨兰进行遗传改良是可行的。     

根癌农杆菌介导转化谷子的影响因素

利用GUS报告基因,建立了农杆菌介导的谷子(Setaria italica)遗传转化体系,并研究了多种影响因素对转化效率的影响,包括受体基因型、外植体类型、菌液浓度、培养基中乙酰丁香酮的浓度、侵染时间和共培养时间.确定了最优的转化条件为:以谷子幼穗诱导的愈伤组织为外植体,用低浓度的农杆菌菌液侵染30～40min,然后在含有0.1mmol/L乙酰丁香酮的LS培养基上共培养2d.     

影响农杆菌介导的大豆子叶节遗传转化的因素

利用携带pCAMBIA1301质粒（含hpt和gus基因）的超毒根癌农杆菌菌株EHA105对大豆子叶节外植体进行遗传转化,研究了影响农杆菌介导的大豆子叶节遗传转化的因素。研究结果表明．农杆菌侵染液和共培养培养基中添加200μmok/L乙酰丁香酮和50mg／L抗坏血酸可以有效促进农杆菌对大豆子叶节的转化。农杆菌与子叶节共培养后羧苄青霉素（250mr／L）和头孢霉素（100mg／L）结合使用能有效抑制农杆菌过度繁殖并提高转化芽诱导频率;在转化细胞的分化和转化芽伸长过程中,改进的筛选策略可以明显改善对转化芽的筛选效果,从而提高转化频率。应用优化后的转化体系．获得了3个国内大豆主栽品种的转基因植株,PCR阳性植株频率为3．8％～7．6％。转化植株叶片总DNA的PCR和Southern blot实验表明,T-DNA上的外源基因已经整合到大豆基因组中。     

EuFPS基因表达载体构建及对杜仲遗传转化的研究

本实验用EcoRⅠ和BamHⅠ双酶切植物表达载体pSH737和含有目的基因的pUC-FPS,定向连接得到重组质粒pSH-FPS,将其导入农杆菌EHA105.采用农杆菌介导法对杜仲进行遗传转化,研究了卡那霉素(kanamycin,Km)浓度、预培养时间、菌液浓度及侵染时间、乙酰丁香酮(acetosyringone,AS)浓度、共培养时间等对杜仲遗传转化效率的影响.结果表明,选择无菌苗苗龄15 d的杜仲下胚轴,卡那霉素浓度50mg/L,农杆菌浓度OD600值0.3-0.6,侵染时间8 min,侵染时菌体重悬液中添加50 μmol/L乙酰丁香酮,共培养时间3 d,抗性芽的获得率最高.对再生植株进行GUS检测发现有45%的植株呈阳性.     

新疆杨高效遗传转化系统的建立

选择新疆杨(Populus alba L.var．pyramidalis Bge．)为遗传转化受体材料,为建立根癌农杆菌介导新疆杨高效遗传转化系统,从预培养时间、侵染时间、共培养时间、添加乙酰丁香酮(AS)的时机、共培养培养基中添加乙酰丁香酮浓度、侵染菌液的制备方法、外植体继代方式等7个方面优化筛选。结果显示较合适的转化系统为：预培养8h,农杆菌菌液(OD600=0．4)侵染15min,共培养5d,侵染菌液的最优制备方法是液体培养活化农杆菌2次加离心收集菌体重悬,共培养培养基中添加乙酰丁香酮80μmol／L。新疆杨叶盘转化频率可达38．10％。     

宁夏枸杞发根农杆菌转化系的建立及影响转化因素的研究

以发根农杆菌Ａ４菌株介导,对宁夏枸杞叶片和茎切段的遗传转化进行了初步研究,建立了发状根体系,并优化了转化条件。乙酰丁香酮的添加、农杆菌液的浓度、共培养时间、外植体取材部位及时间,均可以影响发状根的诱导频率。采用添加１００μｍｏｌ／Ｌ的 乙酰丁香酮、振荡培养２４ｈ的Ａ４菌液感染３周龄的叶片切段,并共培养３ｄ,可以得到最佳的转化效果,发状根的诱导率为４８．９％。在同样的转化条件下,只有１３．６％的茎切     

不同理化因子对黄芩毛状根诱导的影响

目的:利用发根农杆菌1.2556诱导黄芩,得到毛状根.方法:采用共培养法诱导黄芩毛状根,研究不同外植体,不同预培养时间,不同菌液浓度,不同感染时间,乙酰丁香酮,抗生素浓度等条件对转化率的影响.结果:利用预培养2d后的茎段为转化材料,当发根农杆菌浓度在OD600值为0.5时感染10min,转化率最高.在菌液中或培养基中添加100umol/L,乙酰丁香酮可以提高黄芩毛状根的转化效率.培养基中加入250mg/L抗生素Cef能较好地抑制发根农杆菌生长.结论:用共培养法诱导出黄芩毛状根,并确定了最佳诱导条件,以提高黄芩外植体的诱导率.     

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

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.     

根癌农杆菌介导的金发草遗传转化条件的优化

金发草(Pogonatherum paniceum)是一种多年生岩生草本植物,在生态恢复和景观建设中起着重要的作用。利用根癌农杆菌介导转化金发草胚性愈伤组织,通过GUS(β-葡萄糖苷酸酶)瞬时表达率研究菌液浓度、浸染时间、乙酰丁香酮(AS)浓度、葡萄糖浓度、共培养时间等因素对金发草转化的影响,并利用确定的最佳条件将GUS基因转入金发草,获得稳定表达转化植株。结果表明:菌液浓度(OD₆₀₀)为0.6,浸染时间为10min,添加20mg/L的乙酰丁香酮(AS)和10g/L的葡萄糖,共培养时间5d为最佳条件,GUS瞬时表达率最高。经过抗性筛选后最终获得阳性转基因植株频率为57%。再生植株经GUS染色和PCR检测证明,GUS基因已成功整合到金发草基因组中。此转化体系的建立为金发草的遗传改良及相关功能基因的研究奠定了基础。     

农杆菌介导的紫花苜蓿高效遗传转化体系的研究

为建立高效的农杆菌介导的紫花苜蓿的遗传转化体系,对影响转化体系的若干因素进行了研究.结果表明,最适宜的条件分别为抗菌素为350 mg/L的羧苄青霉素(Carb);卡那霉素(Kan)筛选的浓度为60 mg/L;基因型为WL-323;外植体为下胚轴;农杆菌菌液浓度OD600值为0.4-0.6;侵染时间10 min;乙酰丁香酮(AS)的浓度为10 mg/L.     

Efficient<Emphasis Type="Italic"> Agrobacterium tumefaciens</Emphasis>-mediated transformation of soybeans using an embryonic tip regeneration system

Here, we report the establishment of an efficient, in vitro, shoot organogenesis, regeneration system for soybeans [Glycine max (L.) Merr.]. Mature soybean seeds were soaked for 24 h, the embryonic tips were collected and cultured on MSB5 medium supplemented with 3.5 mg l^–1 N⁶-benzylaminopurine (BAP) for 24 h, and explants were transferred to MSB5 medium supplemented with 0.2 mg l^–1 BAP and 0.2 mg l^–1 indolebutyric acid. Use of embryonic tips yielded a higher regeneration frequency (87.7%) than regeneration systems using cotyledonary nodes (40.3%) and hypocotyl segments (56.4%) as starting materials. Regenerated embryonic tips were inoculated with Agrobacterium tumefaciens strain EHA105, which contains the binary vector pCAMBIA2301, and cultured for 20 h. Our results showed that the T-DNA transfer efficiency reached up to 78.2% and the transformation efficiency reached up to 15.8%. These data indicate that the embryonic tip regeneration system can be used for efficient, effective Agrobacterium-mediated transformation.Abbreviations GUS -Glucuronidase - T-DNA Transferred DNA - BAP N⁶-Benzylaminopurine - IBA Indolebutyric acid     

大豆胚尖遗传转化体系优化及抗逆基因GmPK转化研究

采用GUS基因瞬时表达检测方法,通过正交试验以AS浓度、侵染菌液OD值、侵染时间、共培养时间和恢复培养时间5个因素在4个水平上进行分析,优化了农杆菌介导的大豆胚尖遗传转化体系,并在此基础上进行了抗逆基因GmPK的遗传转化。结果表明,采用共培养培养基中添加100μmol/L AS、侵染菌液OD600值0.9、侵染15h、共培养5d和恢复培养3d的转化条件最佳,GUS阳性率达74.59%,经PCR及RT-PCR进一步验证获得了转基因阳性植株。利用优化的最佳条件进行抗逆基因GmPK的转化,炼苗移栽成活的再生植株经PCR及PCR-Southern blotting验证,初步证明外源基因已经整合至大豆基因组,转化率为0.6%。     

Competence of Arabidopsis thaliana genotypes and mutants for Agrobacterium tumefaciens-mediated gene transfer: role of phytohormones

Many plant species and/or genotypes are highly recalcitrant to Agrobacterium-mediated genetic transformation, and yet little is known about this phenomenon. Using several Arabidopsis: genotypes/ecotypes, the results of this study indicated that phytohormone pretreatment could overcome this recalcitrance by increasing the transformation rate in the known recalcitrant genotypes. Transient expression of a T-DNA encoded ss-glucuronidase (GUS) gene and stable kanamycin resistance were obtained for the ten ARABIDOPSIS: genotypes tested as well as for the mutant uvh1 (up to 69% of petioles with blue spots and up to 42% resistant calli). Cultivation of Arabidopsis: tissues on phytohormones for 2-8 d before co-cultivation with Agrobacterium tumefaciens significantly increased transient GUS gene expression by 2-11-fold and stable T-DNA integration with petiole explants. Different Arabidopsis ecotypes revealed differences in their susceptibility to Agrobacterium-mediated transformation and in their type of reaction to pre-cultivation (three types of reactions were defined by gathering ecotypes into three groups). The Arabidopsis uvh1 mutant described as defective in a DNA repair system showed slightly lower competence to transformation than did its progenitor Colombia. This reduced transformation competence, however, could be overcome by 4-d pre-culture with phytohormones. The importance of pre-cultivation with phytohormones for genetic transformation is discussed.     

根癌农杆菌介导的高效大豆遗传转化体系的建立

利用根癌农杆菌对来自大豆成熟种子的胚尖进行遗传转化,研究了影响农杆菌介导大豆转化的各种因素,建立了一套优化的大豆遗传转化体系。研究结果表明:菌株KYRT1比EHA105和LBA4404具有更强的侵染能力;较酸的共培养基(pH5.4)、较低的培养温度(22℃)均有利于提高转化效率;恢复培养和分步抗性筛选方式有利于提高抗性组织的存活率和分化率。同时应用这种优化的遗传转化体系,获得了7个大豆品系的转基因植株,转化频率为4.29%-18%。经过PCR和Southern分析证明外源的双价抗虫基因cryIA(c)和pta已经整合到大豆的基因组中。     

T-DNA transfer and T-DNA integration efficiencies upon Arabidopsis thaliana root explant cocultivation and floral dip transformation

T-DNA transfer and integration frequencies during Agrobacterium-mediated root explant cocultivation and floral dip transformations of Arabidopsis thaliana were analyzed with and without selection for transformation-competent cells. Based on the presence or absence of CRE recombinase activity without or with the CRE T-DNA being integrated, transient expression versus stable transformation was differentiated. During root explant cocultivation, continuous light enhanced the number of plant cells competent for interaction with Agrobacterium and thus the number of transient gene expression events. However, in transformation competent plant cells, continuous light did not further enhance cotransfer or cointegration frequencies. Upon selection for root transformants expressing a first T-DNA, 43–69 % of these transformants showed cotransfer of another non-selected T-DNA in two different light regimes. However, integration of the non-selected cotransferred T-DNA occurred only in 19–46 % of these transformants, indicating that T-DNA integration in regenerating root cells limits the transformation frequencies. After floral dip transformation, transient T-DNA expression without integration could not be detected, while stable T-DNA transformation occurred in 0.5–1.3 % of the T1 seedlings. Upon selection for floral dip transformants with a first T-DNA, 8–34 % of the transformants showed cotransfer of the other non-selected T-DNA and in 93–100 % of them, the T-DNA was also integrated. Therefore, a productive interaction between the agrobacteria and the female gametophyte, rather than the T-DNA integration process, restricts the floral dip transformation frequencies.     

根癌农杆菌介导的苜蓿体胚转化

以苜蓿体细胞胚胎作为根癌农杆菌介导转化的受体,通过对GUS基因瞬时表达率的分析,研究该转化体系的最佳实验参数。实验结果显示,负压处理10min和共培养5d时表达率最高(可达17．4％)。以这一转化方法分别对带有3种不同启动于的表达载体进行比较,发现由CMV35S启动于驱动的GUS基因的瞬时表达率可达82．7％,Ubil启动于驱动的可达57．8％,而Actl启动于驱动的则未见表达。     

Determination of the T-DNA transfer and the T-DNA integration frequencies upon cocultivation of Arabidopsis thaliana root explants

Using the Cre/lox recombination system, we analyzed the extent to which T-DNA transfer to the plant cell and T-DNA integration into the plant genome determine the transformation and cotransformation frequencies of Arabidopsis root cells. Without selection for transformation competence, the stable transformation frequency of shoots obtained after cocultivation and regeneration on nonselective medium is below 0.5%. T-DNA transfer and expression occur in 5% of the shoots, indicating that the T-DNA integrates in less than 10% of the transiently expressing plant cells. A limited fraction of root cells, predominantly located at the wounded sites and in the pericycle, are competent for interaction with agrobacteria and the uptake of a T-DNA, as demonstrated by histochemical GUS staining. When selection for transformation competence is applied, the picture is completely different. Then, approximately 50% of the transformants show transient expression of a second, nonselected T-DNA and almost 50% of these cotransferred T-DNAs are integrated into the plant genome. Our results indicate that both T-DNA transfer and T-DNA integration limit the transformation and cotransformation frequencies and that plant cell competence for transformation is based on these two factors.     

Factors influencing Agrobacterium-mediated transient expression of uidA in wheat inflorescence tissue.

A critical step in the development of Agrobacterium tumifaciens-mediated transformation is the establishment of optimal conditions for T-DNA delivery into tissue from which whole plants can be regenerated. The efficient transformation of inflorescence tissue from 'Baldus', a commercial wheat variety, using the Agrobacterium strain AGLI harbouring the binary vector pAL156 is reported here. The effects of various factors on delivery and the transient expression of the uidA gene were studied including the duration of preculture, vacuum infiltration, the effect of sonication treatments, and Agrobacterium cell density. Optimal T-DNA delivery (as measured by uidA activity) was obtained from inflorescence tissues precultured for 21 d and sonicated. Increasing Agrobacterium cell density, the duration of inoculation/co-cultivation, and vacuum pressure, up to a threshold, increased uidA expression. The investigation of factors that influence T-DNA delivery is an important first step in the utilization of Agrobacterium in the transformation of immature wheat inflorescence tissue.     

Extracellular VirB5 enhances T-DNA transfer from Agrobacterium to the host plant

VirB5 is a type 4 secretion system protein of Agrobacterium located on the surface of the bacterial cell. This localization pattern suggests a function for VirB5 which is beyond its known role in biogenesis and/or stabilization of the T-pilus and which may involve early interactions between Agrobacterium and the host cell. Here, we identify VirB5 as the first Agrobacterium virulence protein that can enhance infectivity extracellularly. Specifically, we show that elevating the amounts of the extracellular VirB5--by exogenous addition of the purified protein, its overexpression in the bacterium, or transgenic expression in and secretion out of the host cell--enhances the efficiency the Agrobacterium-mediated T-DNA transfer, as measured by transient expression of genes contained on the transferred T-DNA molecule. Importantly, the exogenous VirB5 enhanced transient T-DNA expression in sugar beet, a major crop recalcitrant to genetic manipulation. Increasing the pool of the extracellular VirB5 did not complement an Agrobacterium virB5 mutant, suggesting a dual function for VirB5: in the bacterium and at the bacterium-host cell interface. Consistent with this idea, VirB5 expressed in the host cell, but not secreted, had no effect on the transformation efficiency. That the increase in T-DNA expression promoted by the exogenous VirB5 was not due to its effects on bacterial growth, virulence gene induction, bacterial attachment to plant tissue, or host cell defense response suggests that VirB5 participates in the early steps of the T-DNA transfer to the plant cell.     

大豆离体培养及高频再生基因型的筛选

为建立一个高效的大豆再生体系用于大豆的遗传转化,选用3个东北主栽品种‘黑农35’、‘黑农41’和‘黑农58’的子叶节和胚尖作为外植体,分别建立了3个品种的子叶节和胚尖再生体系,并研究了6-BA对大豆再生的影响。结果表明,‘黑农41’子叶节最适芽诱导培养基为MSB5＋1.0mg·L-16-BA＋0.2mg·L-1IBA,胚尖最适芽诱导培养基为MSB5＋0.2mg·L-16-BA＋0.2mg·L-1IBA。‘黑农41’再生体系在出芽率、出芽数和芽伸长数上均远高于‘黑农35’和‘黑农58’,是一个优秀的大豆转基因受体材料。