芥菜型油菜抗虫转基因植株及其后代株系的研究

带有１ ～２ ｍ ｍ 子叶柄的芥菜型油菜子叶经农杆菌感染后,培养在附加１０ ～２０ ｍｇ／ Ｌ卡那霉素的 Ｍ Ｓ 选择培养基上筛选转化愈伤组织及不定芽。卡那霉素抗性苗相继在含３０ ～５０ ｍ ｇ／ Ｌ 卡那霉素的选择培养基上继代培养,再转移到含２０ ｍｇ／ Ｌ 卡那霉素的生根培养基上诱导生根。以苏云金杆菌杀虫晶体蛋白基因为探针,进行 Ｓｏｕｔｈｅｒｎ ｂｌｏｔ 分子杂交,得到阳性结果。 Ｐ Ｃ Ｒ 分析也证明外源基因整合到油菜基因组并稳定传递到后代。转基因植株的抗虫性和卡那霉素抗性在自交后代中得到保持,筛选得到纯合的转基因植株后代株系     

根癌农杆菌对甘蓝型油菜的转化及转基因植的再生

用根癌农杆菌共培养法把外源基因导入甘蓝型油菜主要栽培品种“云北２号”,获得转基因植株。所用外植体为带有１－２ｍｍ子叶柄的完整子叶,根癌农杆菌为Ａ２０８ＳＥ（ｐＴｉＴ３７－ＳＥ,ｐＲＯＡ９３）。Ｔｉ质粒ｐＲＯＡ９３带有ＮＰＴⅡ及ＧＵＳ嵌合基因。共培养２天后转到附加２５ｍｇ／Ｌ卡那霉素的分化培养基（ＭＳ＋４．５ｍｇ／ＬＢＡＰ）上。ＡｇＮＯ３和羧苄青霉素促进芽的分化,头孢霉素则有抑制作用。最高转化频率为     

芥菜型油菜抗虫转基因植株及其后代株系的研究*

带有1～2mm子叶柄的芥菜型油菜子叶经农杆菌感染后,培养在附加10～20mg/L卡那霉素的MS选择培养基上筛选转化愈伤组织及不定芽。卡那霉素抗性苗相继在含30～50mg/L卡那霉素的选择培养基上继代培养,再转移到含20mg/L卡那霉素的生根培养基上诱导生根。以苏云金杆菌杀虫晶体蛋白基因为探针,进行Southern blot分子杂交,得到阳性结果。PCR分析也证明外源基因整合到油菜基因组并稳定传递到后代。转基因植株的抗虫性和卡那霉素抗性在自交后代中得到保持,筛选得到纯合的转基因植株后代株系。     

亚麻遗传转化体系的建立及几丁质酶基因导入的研究

报道了亚麻遗传转化体系的建立和几丁质酶基因对亚麻遗传转化的研究。亚麻下胚轴切段培养在不同激素浓度的ＭＳ培养基上,诱导分化出不定芽。最佳的激素组合是ＭＳ＋ＢＡ１ｍｇ／Ｌ＋ＩＡＡ０．５ｍｇ／Ｌ,分化频率可达９７％。亚麻的下胚轴经带有几丁质 根癌农杆菌感染后,在含有１００ｍｇ／Ｌ卡那霉素的选择分化培养基上,１４￣２１ｄ就能产生抗生小芽,小芽进一步伸长后可在１００ｍｇ／Ｌ卡那霉素的ＭＳ选择生根培养基（ＭＳ     

抗虫转基因甘蓝及其后代的研究

通过农杆菌感染法将苏云金杆菌杀虫蛋白基因转移进了甘蓝的基因组,带子叶柄的子叶作为外植体与农杆菌共培养.发生在子叶柄基部的愈伤组织在含卡那霉素(Km)15～30mg/L的MS培养基上进行筛选,约5%外植体上的愈伤组织继续长大,当移到含Km和6-BA的分化培养基上时,愈伤组织分化出绿色的芽.将芽分离培养,约80%在加有Km的培养基上被诱导生了根.未转化的对照组织在筛选培养基上不能分化出正常的芽和根系,并且逐渐褐化死亡.小菜粉蝶的幼虫被饲喂以转基因植株的叶片,幼虫出现中毒症状,表现为发育受阻和死亡.约20%受试植物的DNA与苏云金杆菌杀虫蛋白基因探针杂交显阳性带.由转基因植株的种子长成的第2代甘蓝幼苗的卡那霉素抗性和植株的抗小菜粉蝶的活力均符合孟德尔单基因分离规律.     

根癌农杆菌对甘蓝型油菜的转化及转基因植株的再生

用根癌农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ ｔｕｍ ｅｆａｃｉｅｎｓ）共培养法把外源基因导入甘蓝型油菜（Ｂｒａｓｓｉ－ｃａ ｎａｐｕｓＬ．）主要栽培品种“云北２ 号”,获得转基因植株。所用外植体为带有１—２ ｍ ｍ 子叶柄的完整子叶,根癌农杆菌为Ａ２０８ＳＥ（ｐＴｉＴ３７－ＳＥ, ｐＲＯＡ９３）。Ｔｉ质粒ｐＲＯＡ９３ 带有ＮＰＴⅡ及ＧＵＳ嵌合基因。共培养２ 天后转到附加２５ ｍ ｇ／Ｌ卡那霉素的分化培养基（ＭＳ＋ ４．５ ｍ ｇ／ＬＢＡＰ）上。ＡｇＮＯ３ 和羧苄青霉素促进芽的分化,头孢霉素则有抑制作用。最高转化频率为２７％ 。把分化出的茎芽切下,插入含有２５ ｍ ｇ／Ｌ卡那霉素的生根培养基中。羧苄青霉素不利于根的形成。把完整抗性植株移入盛土壤的盆中,生长状况良好。测定β－葡糖苷酸酶活性,８４％ 明显高于对照。以ＮＰＴⅡ基因作探针进行Ｓｏｕｔｈｅｒｎ ｂｌｏｔ分析,证实外源基因已插入到植物细胞基因组中     

辣椒转基因植株再生

用改建的农杆菌转化辣椒,已建立有效的转化两再生系统。辣椒无菌苗（１２天苗龄）子叶在再生培养基（ＭＳ＋３ｍｇ／Ｌ ＢＡ）上预培养２天,再用农杆菌感染,共培养２天,再转入含Ｋｍ（１００μｇ／ｍｌ）的再生培养基中培养２－３周后,子叶基部有多丛芽形成。分切多丛芽,将芽转选择性的芽伸长培养基（ＭＳ基本成分＋Ｂ５维生素类＋２ｍｇ／Ｌ ＢＡ＋７５μｇ／ｍｌ）上,待芽长至２－３ｃｍ后,切下并转入生根培养基（ＭＳ＋     

亚麻下胚轴离体培养和转化的研究

报道了亚麻（Ｌｉｎｕｍ　ｕｓｉｔａｔｉｓｓｉｍｕｍ）的高频率植株再生和细胞转化。亚麻下胚轴切段培养在ＭＳＢ分化培养基上,诱导分化出不定芽。最佳的激素组合是ＢＡ２ｍｇ／Ｌ＋ＩＡＡ０．５ｍｇ／Ｌ,分化频率可达９７％。在附加ＢＡ１ｍｇ／Ｌ和ＮＡＡ０．０２ｍｇ／Ｌ的ＭＳＢ培养基上,亚麻下胚轴外植体的不定芽分化频率也可达９０％以上。用根癌农杆菌（Ａｇｒｏｈａｃｔｅｒｉｕｍ　ｔｕｍｅｆａｃｉｅｎｓ）感染亚麻下胚轴外植体,在含卡那霉素５０ｍｇ／Ｌ的选择培养基上筛选获得卡那霉素抗性苗,并检测到ＧＵＳ基因活性表达。表明它们是转化植株,转化频率约为２％。     

深黄被孢霉Δ6—脂肪酸脱氢酶基因导入大豆

采用农杆菌介导的大豆子叶节转化系统成功地将深黄被孢霉Δ6-脂肪酸脱氢酶基因导入大豆。从发芽5—7d的大豆菌苗切取子叶节外植体,经农杆菌浸染和共培养后,在含50mg/L卡那霉素的选择培养基上培养2-4w后,从子叶节处诱导出抗性不定芽,将不定芽转移到伸长培养基上,4-6w后长至2-3cm高的再生苗,再将再生苗切下转入生根培养基,2-6w生根,生根后的再生植株经逐渐锻炼移入花盆中,部分移栽成活的T0植株能正常开花结荚。从T0植株上收获T1种子,按株系种植。T0和T1代经PCR检测和DNA分子杂交分析,证明外源基因已导入并整合到大豆的基因组内并能遗传给后代。     

深黄被孢霉△6-脂肪酸脱氢酶基因导入大豆

采用农杆菌介导的大豆子叶节转化系统成功地将深黄被孢霉△6-脂肪酸脱氢酶基因导入大豆.从发芽5-7d的大豆无菌苗切取子叶节外植体,经农杆菌浸染和共培养后,在含50 mg/L卡那霉素的选择培养基上培养2-4w后,从子叶节处诱导出抗性不定芽.将不定芽转移到伸长培养基上,4-6w后长至2-3em高的再生苗.再将再生苗切下转入生根培养基,2-6w生根.生根后的再生植株经逐步锻炼移入花盆中,部分移栽成活的T0植株能正常开花结荚.从T0植株上收获T1种子,按株系种植.T0和T1代经PCR检测和DNA分子杂交分析,证明外源基因已导入并整合到大豆的基因组内并能遗传给后代.     

Transformation of Brassica napus Using Agrobacterium tumefaciens and Regeneration of Transgenic Plants

Seeds of Brassica napus L. cv. "Yunbei 2" were surface-sterilized and germinated on hormone-free MS medium. After 4—5 days the cotyledons were excised in such a way that each has a 1—2 mm petiole was remained at its base. These cotyledons were used as the explants for tissue culture and genetic transformation. This paper first deals with the improvement of the medium for shoot regeneration. Of the elements tested, AgNO3 and carbenicillin enhanced shoot regeneration. The highest frequency (52 %) was obtained on MS medium containing 4.5 mg/L BAP, 20 μmol/L AgNOa and 500 mg/L earbenicillin. An efficient gene transfer system based on the regeneration procedure was established. After 2 days of cocultivation with Agrobacterium tumefaciens strain A208SE (pTi T37-SE, pROA93), the explants were transferred onto selection medium containing 25 mg/L kanamycin. After 1.5 months shoots emerged from 27% of the explants inoculated. They were excised and transferred onto rooting medium containing 25 mg/L kanamycin and 200 mg/L cefotaxime which is better than carbenicillin for root induction. Whole plants were transplanted into pots, and grew well in the phytotron. Transformation was confirmed by β-glueuronidase assay and Southern blotting analysis.     

ACC合成酶基因及其反义基因对西瓜的遗传转化

以2日龄西瓜(Citrullus lanatus(Thunb.)Mansfeld)无菌苗子叶为外植体,通过与根癌农杆菌(Agrobacterium tumefaciens)进行叶盘共培养建立了西瓜的遗传转化系统。所用根癌农杆菌中含有改建后分别携带嵌合NPTⅡ基因和番茄的ACC合成酶基因及其反义基因的质粒。外植体在MSA培养基(MS盐类、B_5维生素、1.0mg/L BA、0.2mg/L IAA)上预培养3～4d后,与根癌农杆菌共培养4d,随后转移外植体至附加100mg/L卡那霉素、300mg/L头孢菌素的MSA培养基上筛选转化芽。将带芽外植体移入含有100mg/L卡那霉素、300mg/L头孢菌素的伸长培养基(MS 0.2mg/L KT)上进行芽伸长,切取2～3cm高的伸长芽移入生根培养基(1/2MS 0.1mg/L NAA)生根。Southern blot结果证明获得转基因植株,乙烯释放指标表明转入的正义和反义ACC合成酶基因得到不同程度的表达。     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of niger [<Emphasis Type="Italic">Guizotia abyssinica</Emphasis> (L. f.) Cass.] using seedling explants

A protocol was developed for Agrobacterium-mediated genetic transformation of niger [ Guizotia abyssinica (L.f.) Cass.] using hypocotyl and cotyledon explants. Hypocotyls and cotyledons obtained from 7-day-old seedlings were co-cultivated with Agrobacterium tumefaciens strain EHA101/pIG121Hm that harbored genes for beta-glucuronidase (GUS), kanamycin, and hygromycin resistance. Following co-cultivation, the hypocotyl and cotyledon explants were cultivated on MS medium containing 1 mg/l 6-benzylaminopurine (BA) for 3 days in darkness. Subsequently, hypocotyl and cotyledon explants were transferred to selective MS medium containing 1 mg/l BA, 10 mg/l hygromycin, 10 mg/l kanamycin, and 500 mg/l cefotaxime. After 6 weeks, hypocotyls and cotyledons produced multiple adventitious shoot buds, and these explants were subcultured to MS medium containing 1 mg/l BA, 30 mg/l hygromycin, and 30 mg/l kanamycin. After a further 3 weeks, the explants (along with developing shoot buds) were subcultured to MS medium containing 1 mg/l BA, 50 mg/l kanamycin, and 50 mg/l hygromycin for further selection. Transgenic plants were obtained after rooting on half-strength MS medium supplemented with 0.1 mg/l alpha-naphthaleneacetic acid, 50 mg/l kanamycin, and 50 mg/l hygromycin and were confirmed by GUS histochemical assay and polymerase chain reaction analysis. Genomic Southern blot hybridization confirmed the incorporation of the neomycin phosphotransferase II gene into the host genome.     

根癌土壤杆菌介导转化诸葛菜子叶获得转基因植株

采用诸葛菜子叶为材料。在MS+BA 3mg／l,+NAA O．2mg／L培养基上诱导芽的再生,1／2 MS+IBA 0．03mg／L．上诱导生根,获得完整再生植株,建立了诸葛莱组织培养高频再生系统,其再生率可达100％。采用土壤杆菌介导转化诸葛菜子叶．在附加一定量的氨苄青霉索、头孢霉素和卡那霉素的相应培养基上进行筛选,进而培养出再生成苗。获得完整植株,经GUS和NPTI酶活测定,以及Southern blot分析．证实为转基因植株。转化子叶的芽再生率为51％．获得完整转基因植株的转化率为5．53％。在国内外首次建立了以根癌土壤杆菌(Agrobacterium tumefaciens)为载体,诸葛菜子叶为受体的遗传操作系统。     

高效烟草遗传转化体系的建立及甜蛋白基因的导入

以烟草无菌茁叶片为外植体,通过根癌农杆菌LBA4404介导法,将Thamnatin基因导人烟草中,经梯度卡那霉素(Kana-mycin,Km)筛选,获得可在含75mg／L、100mg／L Km选择生根培养基上再生的抗性植株,其中部分Km抗性植株经PCR检测为阳性,转化率为31．3％,初步鉴定已成功地建立了烟草遗传转化系统,为进一步探讨甜蛋白在植物中的转化和表达情况奠定基础。     

AtNHX1基因对荞麦的遗传转化及抗盐再生植株的获得

通过农杆菌介导法将拟南芥液泡膜Na /H 反向转运蛋白基因AtNHX1转入荞麦中,在2·0mg/L6-BA、0·1mg/LIAA、1mg/LKT、50mg/L卡那霉素和500mg/L头孢霉素的MS培养基上进行选择培养,从来源于864块外植体的36块抗性愈伤组织中共获得426棵再生植株(转化频率为4·17%)。经PCR、Southern印迹分析、RT-PCR和Northern检测,初步证实AtNHX1基因已整合至荞麦基因组中。用200mmol/L的盐水对转基因植株和对照植株进行胁迫处理6周,转基因植株能够生存,而对照植株死亡。用不同浓度的NaCl溶液处理转基因植株和对照植株,发现Na 及脯氨酸含量在转基因植株中的积累水平显著高于对照植株,而K 的含量在转基因植株中的积累水平低于对照植株。次生代谢产物黄酮类化合物芦丁在转基因植株根、茎和叶片中的含量也比对照植株明显要高。这些结果表明利用基因工程手段提高作物的耐盐性是可行的。     

PSAG12-ipt嵌合基因转化马铃薯体系的研究

以根癌农杆菌介导法将PSAG12-ipt嵌合基因导入马铃薯栽培品种,对影响马铃薯遗传转化的多种因素进行系统研究.结果表明:马铃薯茎段分化效率高于叶片,马铃薯愈伤诱导和芽分化最适培养基为MS+6-BA 0.25mg/L+NAA 0.25mg/L+2,4-D 0.25mg/L,添加1%Na2SO3能有效防止褐化;茎段愈伤诱导和分化苗生根最适的Kan浓度分别为50mg/L和75mg/L;外植体预培养2d,OD600为0.2～0.5的农杆菌浓度侵染8min、共培养3d后进行选择培养能有效地提高植株再生能力.用PSAG12和ipt双重PCR检测再生植株,阳性转化率为65.8%.Southern blotting结果表明,转基因植株多以单拷贝形式整合进马铃薯基因组中.     

Insect-resistant transgenic cabbage plants and their progenies

An insecticidal crystal protein gene of Bacillus thuringiensis was transferred into cabbage genome with the method of Agrobacterium infection. Cotyledons with petioles as explants were cocultivated with Agrobacterial suspension. Calli generated at the basis of petiole were subjected to selection on the MS medium containing 15-30 mg/L kanamycin (Km). About 5% explants produced calli growing continuously on the selective medium. Green shoots appeared on these calli when they were transplanted onto medium with Km and 6-BA for plant differentiation. The shoots were separated and cultivated on medium with kanamycin. About 80% shoots were rooted. Non-transformed control calli could not give normal shoots and roots and brownized and died gradually. Larvae of Pieris rapae showed poisonous symptoms: growth inhibition and mortality when fed with the leaf of the transgenic plants. About 80% of regenerated plants showed positive hybridization bands when their DNA were probed with crystal protein sequence of Bacillu     

石斛兰转ACS反义基因抗性原球茎及转化植株的筛选与鉴定

该试验就石斛兰转化ACS(1-氨基环丙烷-1-羧酸合成酶)反义基因的不同筛选方法和筛选处理对抗性原球茎筛选的影响,以及石斛兰转基因植株的再生与鉴定进行研究.结果表明:(1)石斛兰原球茎经带有gus报告基因和ACS反义基因的农杆菌LBA4404侵染共培养5d后除菌,采用逐渐提高选择压浓度的延迟筛选,并在低选择压浓度下切割而高选择压浓度下不切割的处理方式为抗性原球茎的最佳筛选途径,抗性原球茎获得率可达14.97％.(2)抗性原球茎繁殖时应逐渐降低选择压浓度,且在低选择压浓度下进行切割处理,繁殖倍数达到1.15倍,且原球茎生长势好.(3)抗性原球茎在1/2 MS+0.5 mg/L 6-BA培养基中的分化率达到73.85％;107株无根小苗培养于1/2 MS+1.0 mg/L NAA+50.0 mg/L Km(卡那霉素)+100.0 mg/L Cef(头孢霉素)培养基中进行生根培养,共获得了13株具有卡那霉素抗性的转化植株,转化效率达到12.15％.(4)转化植株经报告基因产物GUS组织化学检测和gus的PCR检测,证实带ACS反义基因的T-DNA已整合进石斛兰基因组中,且转基因植株在形态上与未转基因植株无明显差别,3株转基因植株移栽2个月后均已成活.