几种白菜类蔬菜卡那霉素抗性的研究

标记基因的利用是筛选和鉴定基因转化的细胞、组织和转基因植株的有效方法。针对目前遗传转化中常用的卡那霉素(Km)抗性基因,对几种白菜类蔬菜的卡那霉素抗性作了较系统的探索,发现5.0 mg/L Km可完全抑制大白菜、小白菜及菜心子叶的再生;幼苗Km抗性测验表明各品种均表现出随着Km浓度的提高,子叶黄化率升高、根茎变短、鲜重减轻的趋势。白菜类蔬菜的卡那霉素抗性检测为遗传转化和阳性后代筛选奠定了基础。     

干旱耐逆基因（HS1）转化甘薯获得转基因植株

以甘薯（1pomoeabatatas（L.）Lam．）品种栗子香的胚性悬浮细胞为受体材料,用根癌农杆菌介导法,获得了表达除草剂抗性基因bar基因的转HSl基因甘薯植株。共计380个遗传转化的胚性细胞团,在添加2mg／L2．4-D、100mg／L Carb和10mg／L Glu（glufosinate）的固体Ms培养基上选择培养9周后,得到了12个Glu抗性愈伤组织。将这些抗性愈伤组织转移到添加1mg／L ABA、100mg／L羧苄青霉素和10mg／L Glu的固体MS培养基上,其中的3个抗性愈伤组织再生出拟转基因植株。PCR鉴定它们为转基因植株。Southern blot分析表明,HS1基因已整合到基因组中。转基因植株具有稳定的除草剂抗性。结薯观察实验结果表明,转基因植株结薯正常。     

通过根瘤农杆菌介导法获得菊花转基因植株

以带叶茎段为外植体,通过根癌农杆菌介导法,将兔防御素NP－1基因导入菊花品种“001”中。经梯度卡那霉素（kanamycin,Km）筛选,获得了大量Km抗性植株,其中部分Km抗性植株经Southem杂交鉴定为转基因植株。从而成功地建立了菊花遗传转化系统,为菊花分子育种奠定了基础。     

影响根癌农杆菌介导甜瓜转化NP-1基因的外部因子研究

以新疆伽师、皇后两个甜瓜品种的子叶切块与农杆菌共培养,将NP-1基因导入甜瓜。以再生植株的PCR检测阳性和卡那霉素抗性作为转化植株的初步判定。研究了甜瓜转化的外部因子：甜瓜子叶外植体经3d预培养,重悬于MS液体培养基使菌液浓度达OD600为0．6后进行侵染8～12min,再经3d共培养对转化最为有利;在侵染前进行0．2mg／L甘露醇高渗处理可提高转化率6．6％,乙酰丁香酮在甜瓜的转化中并未有显著影响。转化中卡那霉素合适筛选压力为100mg／L,转化后抑菌氨苄青霉素浓度为500mg／L有利于获取转化植株,转化率可达到12％。     

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.     

根癌农杆菌介导D32基因

以烟草品种'中烟99'的无菌苗叶片为转化受体材料,通过根癌农杆菌C58C1介导对大豆中克隆的抗逆性基因D32进行转化,获得了抗卡那霉素的再生植株,并对转化植株进行了PCR检测.结果表明,烟草叶片分化和再生的卡那霉素选择压力为150 mg/L;外植体预培养对转化率有影响;优化的烟草转化方法是:经预培养2 d的外植体用OD600值为0.7的菌液侵染5 min, 共培养2 d后用无菌水冲洗5～6次,羧苄青霉素(Cb)和头孢霉素(Cef)浓度为400 mg/L的脱菌液浸泡120 min,超净工作台上吹风60 min,于筛选分化培养基生长50 d,可获得26.7%卡那抗性苗.对抗性植株经PCR检测证明,外源D32基因已初步整合到烟草基因组中.     

根癌农杆菌介导的高羊茅遗传转化研究

采用携带卡那霉素抗性基因nptⅡ和Na^ ／H^ 反向运输AtNHX1基因的表达载体pROK2／AtNHX1(带有35S启动子)和pROK2U／AtNHX1(带有ubi1启动子)的根癌农杆菌AGL1和GV3101,对4个品种高羊茅下胚轴来源的胚性愈伤组织进行了遗传转化。胚性愈伤组织经根癌农杆菌感染和共培养后,用50～150mg／L巴龙霉素筛选抗性愈伤组织,获得1126棵再生植株,用10～20mg／L卡那霉素进一步筛选再生植株,总共得到525棵绿色抗性植株。抗性植株的总DNA用AtNHX1基因的特异引物进行PCR检测,其中21棵为PCR阳性,最高转化频率为1．77％。Southern杂交结果证实,外源基因以低拷贝整合到高羊茅的基因组中,实验发现,在不同品种之间转化效率有所差异。     

根癌农杆菌对健康和患丛枝病泡桐的遗传转化

选取健康及患丛枝病泡桐（Paulownia spp.)为材料,建立组织培养和植株再生系统,以茎段作为转化受体,诱导分化和生根的最佳激素组合分别是MS＋BA4mg/L NAA0.2mg/L和1／2MS＋KT0.5mg/L IBA0.25mg/L。芽分化频率可达22．8％。健康和患病泡桐的茎段经农杆菌共培养3d后,在附加50mg/Lm的选择分化培养基上培养20d左右再生出抗性芽,经培养、诱导生根,获得了转基因再生植株,建立了泡桐的遗传转化体系。PCR和Southern杂交检测证明外源基因已整合到泡桐的基因组,标记基因ITPⅡ在再生植株中也得到表达,同时对影响转化的一因素进行了探讨。     

苏云金杆菌内毒素蛋白基因转入葡萄胚性愈伤组织细胞及转基因植株再生的研究

以葡萄的胚性愈伤组织作为农杆菌介导,Ti质粒转化材料,利用共培养法将苏云金杆菌内毒素蛋白基因转入葡萄胚性愈伤组织细胞,通过胚状体发生途径再生转基因植株。实验发现:80μmol/L的乙酰丁香酮诱导处理农杆菌和葡萄愈伤组织后可将转化效率提高50倍。OD值为0.8的农杆菌菌液稀释8—10信后与在G培养基预培养10天的胚性愈伤组织共培养2—3夭,Ti质粒对葡萄愈伤组织细胞的转化效率可达50%左右。筛选得到的转基因植株在含Km 30 mg/L的选择培养基上继代存活6个月,生长正常;提取叶片染色体DNA做Southern blot,杂交结果为阳性。将转基因植株各部分切段置于含Km 50 mg/L的选择培养基上,能够脱分化产生抗性愈伤组织并能增殖。     

毛白杨高效转化系统的研究(英文)

毛白杨是一种具有多种优良特性、用途广泛并有重要经济价值的杨属树种,又是农杆菌的天然寄主植物。因此,毛白杨一直是进行木本植物组培及遗传转化研究的重要对象。本研究通过比较培养基组成(Table 1)、外植体类型(Table 2)、农杆菌侵染浓度以及预培养(Table 3&4, Fig.1)和共培养条件(Table 5)等影响农杆菌转化及植株再生效率的诸多重要条件后,建立了毛白杨的农杆菌高效转化系统。实验选用毛白杨叶片为外植体,在MS + 4.0 mg/L 2,4-D + 1.0 mg/L 6-BA培养基上预培养2 d后制成叶盘,并做戳伤处理,再与5×108 Cell/mL浓度的农杆菌新鲜菌液共培养2 d,然后以MS + 4.0 mg/L 2,4-D + 1.0 mg/L 6-BA附加50 mg/L Km和1 000 mg/L AP为筛选培养基(Table 6, Fig.4) ,获得最佳转化效果。2－3周后,在叶盘周围长出许多Km抗性愈伤组织,转入分化培养基分化后,再转入生根培养基3－4周,获得完整植株(Fig.3)。经PCR扩增实验鉴定,转化愈伤组织的阳性率达到83.8％(Fig.2)。多次重复实验结果表明,该转化系统与以往的文献报道相比,其遗传转化率大大提高。抗性愈伤组织的平均转化率高达56.2%,最终得到的再生转化植株的比率达19.9%。其中,毛白杨叶盘经戳伤处理,其转化率可提高至20~40% (Table 7)。利用此转化系统     

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。     

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.     

甘蓝型油菜抗虫转基因植株及其抗性分析

通过油菜子叶外植体－农杆菌共培养法将苏云金杆菌杀虫蛋白基因导入甘蓝型油菜,获得抗虫的转基因植株。带有１￣２ｍｍ子叶柄的油菜子叶经农杆菌感染后,共培养２￣３天,然后转移到附加１５ｍｇ／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２０￣５０ｍｇ／Ｌ卡那霉素的选择培养基上继代培养,再转移到含２５ｍｇ／Ｌ卡那霉素的生根培养基上诱导生根。以苏云金杆菌杀虫蛋白基因为探针,进行１     

Resistance to Potato Virus X Infection in Transgenic Tobacco Plants with Coat Protein Gene of Virus

A major commercial cultivar of tobacco was transformed via Agrobacterium mediated procedure. Tobacco leaves started to form shoots on shoot inducing medium containing kanamycin after infected by Agrobacterium containing the plasmid with PVX CP gene. Regenerated plants were obtained in two weeks on hormone-free MS medium containing kanamycin. The transgenic tobacco plants were identified with nopaline detection,enzyme-linked immunosorbent assay and western blot analysis, symptom appearance was significantly delayed and virus accumulation was either absent or reduced in PVX CP gene transformed plants. Progenies of transgenic tobacco plants also gained resistance to PVX infection to a certain degree. These experiments demonstrate that CP protection is effective against PVX.     

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。     

<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.     

Combination of kanamycin resistance and nitrate reductase deficiency as selectable markers in one nuclear genome provides a universal somatic hybridizer in plants

Summary The combination in the nuclear genome of a dominant resistance marker (to select against unfused wild-type cells) and a recessive deficiency marker (to select against unfused mutant cells) in a cell line should provide a system for selecting fusion hybrids between the mutant line and any wild-type line. To test this idea, we fused protoplasts from a non-morphogenic cell line of Nicotiana tabacum which was kanamycin resistant (by transformation) and deficient in nitrate reductase (NR^-K⁺) with protoplasts from N. tabacum cv. Petit Havana clone SR1, which provided resistance against streptomycin as an additional selectable marker (NR⁺K^-SR⁺). Putative hybrids were selected using a culture medium containing no available reduced nitrogen source and 50 mg/l kanamycin sulphate. After regeneration into plants, the hybrid character was demonstrated from: (i) the morphological variation of the regenerants; (ii) the chromosome number; (iii) the ability to grow on medium without a reduced nitrogen source and containing kanamycin sulphate at 50 mg/l; (iv) the presence of nitrate reductase activity; (v) the presence of the gene coding for neomycin phosphotransferase, which provides resistance to kanamycin sulphate; (vi) callus formation from leaves on medium containing 1 g/l streptomycin or 50 mg/l kanamycin sulphate; (vii) F₁ plants containing nitrate reductase and the gene for neomycin phosphotransferase. Fusions between the mutant cell line (NR^-K⁺) and three wild-type tobacco species and subsequent cultivation on medium containing no available nitrogen source but 50 mg/l kanamycin sulphate resulted in callus formation with all combinations, while hybrid plants were only regenerated when N. sylvestris was the fusion partner.     

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.     

Agrobacterium-mediated genetic transformation of groundnut (arachis hypogaea L.): An assessment of factors affecting regeneration of transgenic plants

Transgenic groundnut (Arachis hypogaea L.) plants were produced efficiently by inoculating different explants withAgrobacterium tumefaciens strain LBA4404 harbouring a binary vector pBM21 containinguidA (GUS) andnptll (neomycin phosphotransferase) genes. Genetic transformation frequency was found to be high with cotyledonary node explants followed by 4 d cocultivation. This method required 3 days of precultivation period before cocultivation withAgrobacterium. A concentration of 75 mg/l kanamycin sulfate was added to regeneration medium in order to select transformed shoots. Shoot regeneration occurred within 4 weeks; excised shoots were rooted on MS medium containing 50 mg/I kanamycin sulfate before transferring to soil. The expression of GUS gene (uidA gene) in the regenerated plants was verified by histochemical and fluorimetric assays. The presence ofuidA andnptll genes in the putative transgenic lines was confirmed by PCR analysis. Insertion of thenptll gene in the nuclear genome of transgenic plants was verified by genomic Southern hybridization analysis. Factors affecting transformation efficiency are discussed.     

Expression of mouse metallothionein-I gene confers cadmium resistance in transgenic tobacco plants

Transgenic tobacco plants containing a mouse metallothionein-I (MT-I) gene fused to the cauliflower mosaic virus 35S (CaMV 35S) promoter and nopaline synthase (nos) polyadenylation site were obtained by transforming tobacco leaf discs with an Agrobacterium tumefaciens strain carrying the chimaeric gene. Transformants were directly selected and rooted on medium containing cadmium and kanamycin. A total of 49 individual transgenic tobacco plants were regenerated. Among them 20% showed a very high expression level and their growth was unaffected by up to 200 M cadmium, whereas the growth of control plants was severely affected leaf chlorosis occurred on medium containing only 10 M cadmium. The concentration of MT-I in leaves of control and transgenic tobacco was determined with Cd/haemoglobin saturation assay, a polarographic method and western blotting. In addition, seeds from self-fertilized transgenic plants were germinated on medium containing toxic levels of cadmium and scored for tolerance/susceptibility to this heavy metal. The ratio of tolerant to susceptible plants was 3:1 indicating that the metallothionein gene is inherited as a single locus.