高效诱导甜菜再生植株的研究

研究了栽培甜菜(Beta vulgaris L.)4倍体品系405叶柄外植体的离体培养。成功地建立了一套高频率诱导再生芽的程序。外植体取自生长在改良MS(MSB)附加BA和NAA或者单加BA的培养基中。经过30d以上预培养后的幼苗叶柄,在MS附加BA 1．0mg／L或NAA0．3mg／L,Bal．0mg／L培养基上直接诱导再生芽,并发育成苗．诱导频率最高可达51．3％。在1／2MS(MS培养基大量元素减半)附加NAA0．5～1．0mg／L的培养基上诱导生根．这一程序为甜菜扩大繁殖和遗传转化提供了一个良好的试验系统。     

秦美猕猴桃叶片最佳再生系统的建立

利用正交等试验,系统开展了秦美猕猴桃叶片再生系统建立研究,确定了秦美猕猴桃叶片不定芽诱导最佳培养基及激素配比为MS＋6－BA 5mg/L NAA 0.1mg/L,不定芽诱导生根最佳培养基及激素配比为1／2MS＋NAA 0．01mg/L IBA0.5mg/L GA 1mg/L,该实验结果为通过叶盘法开展农杆菌介导的猕猴桃遗传转化奠定了良好基础。     

西藏红景天组织培养研究

以西藏红景天嫩叶和幼茎为材料,研究西藏红景天不同外植体的离体培养技术。结果表明：西藏红景天嫩叶是诱导愈伤组织和芽的理想外植体,诱导松散型愈伤组织有两种培养基,分别是黑暗培养下MS 6-BA2．0 mg／L NAA0．2mg／L和MS 6-BA3．0mg／L NAA0．3mg／L;生芽培养基为MS 6-BA2．0mg／L IAA0．25mg／L;生根培养基为MS IAA0/5～1．0mg／L。     

香蕉草叶柄离体培养与快速繁殖(简报)

以香蕉草叶柄为外植体进行离体培养及快速繁殖条件研究。结果表明,叶柄外植体在培养基MS＋6-BA 2．0mg／L＋NAA 0．3mg／L＋蔗糖30g／L＋卡拉胶7g／L上诱导形成愈伤组织后,转入分化培养基MS＋KT 1．0mg/L＋NAA0．2mg/L可诱导不定芽分化;不定芽转入增殖培养基MS＋6-BA 1.0mg/L＋NAA 0．5mg／L可旺盛增殖,增殖系数4．5。不定根分化培养基为MS＋IBA 0．2mg／L＋NAA 0．05mg／L,生根苗在水族箱移栽成活率达98％。     

激素水平对84 K杨组培快繁的影响

本实验以84K杨腋芽和叶片为外植体,研究不同激素水平对84K杨组织培养的影响,探讨84K杨快速繁殖试管苗的有效途径。研究结果表明：84K杨腋芽增殖的最佳培养基为MS 6-BA2．0mg／L NAA0．5mg/L;叶片不定芽诱导初期的最佳培养基为MS 6-B1．0mg／L NAA0．5mg/L,MS KT1．0mg／L NAA0．1mg,L为不定芽壮苗的最佳培养基;从生根和移栽成活率上看不添加任何激素的1／2MS基本培养基和1/2MS NAA0．2mg/L IBA0．5mg/L为84K杨最佳生根培养基。     

丹参离体微繁技术研究

以丹参(Salvia miltiorrhiza Bunge)离体幼茎、叶、叶柄为外植体,对其丛生芽、不定芽的诱导和增殖、生根、移栽等方面进行系统研究,探讨了有关丹参的离体快速微繁技术。试验表明：MS 6-BA1．0mg／L是诱导初代培养的芽产生丛生芽的最佳培养基,其诱导生芽率为100％,丛生芽增殖的最佳培养基为MS 6-BA1．0mg／L NAA0．01mg／L;以叶为外植体,用MS 6-BA 0．5～2．0mg／L诱导不定芽可取得较好效果,其诱导生芽率为100％,不定芽增殖的最佳培养基为MS 6-BA1．0mg／L,其增殖倍数达24倍;诱导生根较好的培养基为1／2MS 0．1mg／L IBA,移栽先水培再土培,成活率可达100％。     

山茱英的组织培养与植株再生

目的：建立山茱萸的组织培养及植株再生体系。方法：分别以山茱萸的叶片、花柄和花托为材料,进行山茱萸不同外植体的离体培养研究,筛选最佳培养基组成。结果：适宜山茱萸叶片愈伤组织诱导的培养基组合为1／2MS,附加BA2．0mg/L、IBA0,5—1．0mg／L;适宜山茱萸花柄、花托愈伤组织诱导的培养基组合为1／2MS,附加BA1．0mg／L、2,4-D0．5mg／L;在1／2MS附加BA2．0mg／L、IBA0．05mg／L的培养基上,可诱导不定芽的产生;1／2MS附加IBA2．0mg／L的培养基有利于山茱萸试管苗生根。讨论：山茱萸的花托是进行组织培养的最适外植体,白色或翠绿色、结构致密的愈伤组织较易分化产生不定芽。     

丽格海棠的离体快繁

取丽格海棠幼叶为外植体,在诱导培养基MS＋BA 0．5mg/L NAA 1.0mm/L上培养20d左右,开始分化花芽,培养40d丛生芽长满整个外植体,丛生芽的增殖培养以MS＋BA 0．5mg/L为佳,芽长得大且粗壮,粗壮芽转入无激素的1／2MS生根培养基,生根率达100％。     

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。     

‘贵长’猕猴桃叶片高效直接再生体系的建立

以‘贵长’猕猴桃叶片为外植体,直接脱分化产生不定芽,并对不定芽增殖以及生根体系进行优化,建立了其高效直接再生体系。结果表明,叶片在MS+4. 0mg/L 6-BA+0. 4mg/L NAA培养基中,不定芽诱导率达95. 8%,平均出芽数达15. 7个/叶片;不定芽在MS+3. 0mg/L 6-BA+0. 3mg/L NAA+0. 2mg/L GA3培养基中,增殖率达100%,且1～6代平均繁殖系数达8. 15;不定芽先在添加1. 0mg/L IBA的1/2 MS固体培养基中诱导7d,然后再先后在1/2 MS固体培养基和充分吸附1/2 MS培养液的珍珠岩中各培养14d,生根率达98. 61%,且根系发育良好; 50株试管苗移栽到以珍珠岩和田间土壤(其体积比为1∶4)为基质的营养钵中,2周后成活49株,成活率达98%。该研究成功建立了‘贵长’猕猴桃叶片高效再生体系,该方法不定芽诱导周期短,出芽率高且数目多,不定芽增殖系数大,生根率高且试管苗根系发达,为‘贵长’猕猴桃离体快速繁殖和遗传转化奠定了基础。     

根癌农杆菌介导蓝猪耳转化的影响因素研究

研究了根癌农杆菌介导蓝猪耳转化的影响因子。结果表明,以蓝色花类型蓝猪耳5~6周的叶片为外植体,在OD₆₀₀为0.5~0.6的活化菌液中浸染5~10min,暗培养4d后,在愈伤组织诱导培养基(MS+BA 1.0mg/L+2,4-D 0.1mg/L)上生长14d,获得抗性愈伤组织;经芽诱导培养基(1/2MS+BA 1.0mg/L+NAA 0.1mg/L)培养28d得到抗性芽;生根培养基(1/2MS)上培养14d得到抗性植株。经PCR检测证实外源基因已整合到蓝猪耳基因组中,转化率达13%~14%。Cef和Hyg浓度对转化影响较大,转化的不同阶段其适宜浓度不同。     

药用植物金荞麦愈伤组织诱导与植株再生

目前转基因技术已成为植物定向遗传改良的重要手段,而建立稳定高频的离体再生系统是实现遗传转化的基础和前提.本试验以25 ～30 d苗龄的金养麦(Fagopyrum dibotrys)无菌苗叶片、茎节间、叶柄为外植体进行愈伤组织诱导与植株再生研究.结果表明:叶片在MS +2,4-D 4.0 mg/L +6-BA 1.0 mg/L培养基上愈伤组织诱导率达到89％.茎节间在MS +2,4-D 2.0 mg/L +6-BA 2.0 mg/L培养基上愈伤组织诱导率为87％.叶柄在MS +2,4-D 4.0 mg/L +6-BA 2.0 mg/L+ IBA 0.2 mg/L培养基上的最高诱导率仅为54％.愈伤组织分化不定芽的适宜培养基为MS +6- BA2.0 mg/L +TDZ0.2 mg/L +NAA0.2 mg/L;金荞麦不定芽在1/2 MS +NAA 0.5 mg/L的培养基上生根效果最好.组培再生植株经炼苗后移栽到田间成活率达80％以上,且生长表现正常.高频完整再生体系的建立,为金荞麦进一步遗传操作和扩大药材资源奠定了基础.     

Micropropagation of sweet orange, Citrus sinensis Osbeck. for the development of nucellar seedlings

Protocol for micropropagation of elite plants of sweet orange (Citrus sinensis) through nucellar embryo culture has been standardized. Three to four nucellar embryos and a zygotic embryo could be excised from a single mature seed and successfully generated as healthy plants in basal MS medium. MS medium supplemented with NAA (1 mg/L) or 2, 4.D (1 mg/L) promoted callus development in both nucellar and zygotic embryos. GA3 (1 mg/L) enriched medium induced plantlets initiation but their growth was very poor. No significant differences were observed between initial growth patterns of nucellar and zygotic seedlings developing from the same ovule. Five to six shoots were obtained from collar region of both category of embryos in MS medium supplemented with BAP (1 mg/L) within 60 days of inoculation. The number of plantlets were almost doubled after their transfer in the same medium and culture for another 30 days. Higher doses of BAP resulted in initiation of callus directly from the embryos. The regenerated shoots (2-3 cm) could be rooted in MS medium supplemented with either only NAA (0.75 mg/L) or NAA (0.50 mg/L) and IBA (2.0 mg/L). A number of plantlets could be obtained from a nucellar embryo grown shoot within a limited time period.     

草木樨状黄芪高频离体再生体系的建立

以草木樨状黄芪无菌苗茎切段为材料,在含１－２mg/L2,4-D和０－０．５mg/L６ＢＡ的MS培养基上培养获得大量愈伤组织,愈伤组织诱导率在９５％以上,愈伤组织在附加０．２mg/LＫＴ,１mg/L６ＢＡ,０或０．５mg/LＮＡＡ,５００mg/LＣＨ 和２００mg/L ＹＥ的ＭＳ培养基上诱导丛生芽,并进而发育成苗。苗的分化频率为１００％。分化苗或其茎的切段在不国源植物激素的１／２ＭＳ培养基上可出现根的分化,分化频率达９０％以上,再生植株经炼苗后移栽成活率达８０％以上。     

以根为外植体建立大蒜的组织培养体系

以国内4个大蒜栽培品种为材料,建立了以根为外植体的再生体系。将蒜瓣去皮后灭菌消毒,萌发后选取苗龄为5~7 d的无菌苗的根接种到含不同激素配比的培养基中进行愈伤组织诱导,发现MS+2,4-D 1 mg/L+2ip 0.1 mg/L组合愈伤诱导效率最高,平均为56.06%;愈伤组织经过2~3次继代培养,选取胚性愈伤组织置于不同分化培养基上进行培养,2~3个月后可见小芽产生,分化培养基为MS+KT 1 mg/L时,植株再生效率最高,平均达到35.01 %。本研究建立了一种以根为外植体的高效的大蒜愈伤诱导和再生体系,为大蒜遗传转化体系的建立打下良好基础。     

香石竹毛状根诱导、离体培养及其植株再生

为了探讨利用发根农杆菌遗传转化所产生的毛状根来创新香石竹种质的可能性,本文采用叶盘法,建立了发根农杆菌Agrobacterium rhizogenes对香石竹Dianthus caryophyllus L.叶片外植体的遗传转化及其植株再生体系。结果表明,发根农杆菌ATCC15834感染香石竹幼嫩叶片外植体12 d后,从叶片外植体切口中脉处产生白色毛状根,21 d后约90%的叶片外植体产生毛状根。所获得的无菌毛状根能在无外源激素的MS固体和液体培养基中快速自主生长。PCR扩增和硅胶薄层层析结果显示发根农杆菌Ri质粒的rol B和rol C基因以及冠瘿碱合成酶基因已在香石竹毛状根基因组中整合并得到表达。将毛状根置于MS+6-BA 1.0-3.0 mg/L+NAA 0.1-0.2 mg/L中培养15 d后产生淡黄绿色的疏松愈伤组织。愈伤组织不定芽分化的最适培养基为MS+6-BA 2.0 mg/L+NAA 0.02 mg/L,培养6周后不定芽分化率为100%;平均每个愈伤组织产生30-40个不定芽;将不定芽转至1/2 MS或1/2 MS+0.5 mg/L NAA的培养基中10 d后产生不定根,发育成再生植株。再生植株移植于栽培基质中20 d后,成活率达95%以上。     

Plant Regeneration and Transformation of Sweet Papper (Capsicum frutescens)

Three strains of sweet pepper, (Capsicum frutescens) “Shuang Feng”, “Zhong Jiao No. 2” and “Zhong Jiao No.3” were screened out of six Chinese cuhivars for their high capacity of regeneration. The normal flowering and fertile regenerated plants have been obtained from cotyledons of seedlings from 10 to 16 days old by a four-step culture procedure; short induction, shoot elongation, rooting of excised shoot and transplanting into soil. MS was the basal medium in all steps, supplemented with different kind and different concentration Of phytohomores. Optimal shoot ioduction medium is MS +4–6mg/LBA+0.5mg/LIAA which gives rise a shoot regeneration frequency of 100%. 35% of the induced shoots elongated on the medium of MS+2mg/L Zeatin or 2mg/L. BA+l–3mg/L GA, and subsequently rooted on MS medium or in addition of 0.1–0.5mg/LNAA. The regenerants were transplanted into soil and developed into normal plants. In the transformation of sweet pepper using the leaf disc method, two kinds of wild type Agrobacterium tumefaciens, C58 and GV3111, have been screened out in regard to their high infection capacity. The transient expression of GUS gene was detected and Kanamycin-resistant shoots from infected cotyledons have been obtained. Further assay and transfering the TMV-resistant and CMV-resistant genes into sweet pepper are in progress.     

海石竹的离体快繁及核型分析

以海石竹 (Armeriamaritima)的叶片为外植体 ,经离体培养诱导产生愈伤组织 ,再分化形成不定芽 ,并经过继代增殖和壮苗生根 ,获得完整的再生植株 ,最后对其再生植株进行核型分析。结果表明 ,海石竹叶片的愈伤组织诱导和分化的适宜培养基为MS +BA 1 .0mg/L +NAA 0 .2mg/L ,诱导初期进行 7d暗培养 ,最佳增殖培养基为MS+BA 1 .0mg/L +NAA 0 .1mg/L ,生根培养基为MS+NAA 0 .2mg/L。以上培养基均含蔗糖3 0 g/L ,琼脂 5g/L ,pH 5 .8。海石竹的核型公式为 2n=2x=1 8=1 0m +8sm ,存在染色体数目变异的现象。     

菘蓝花药培养及单倍体的诱导

探讨菘蓝花药处于单核晚期的形态指标,并以适宜发育时期的花药为外植体,进行花药培养及单倍体诱导。实验结果表明,4℃低温处理2d后,在含有6-BA0．5mg·L-1和NAA1．0mg·L-1。的Ms培养基上,花药愈伤组织的诱导率为23．35％;将其转接到Ms附加6．BA1．0mg·L-1,NAA0．5mg·L-1的分化培养基上,80．00％以上的愈伤组织可以诱导产生不定芽;再将分化出的试管苗转接到1／2MS＋NAA1．0mg·L-1的生根培养基上,3d左右即可获得完整植株。经叶边缘压片检查染色体数目,花药培养所得的弱小绿苗为单倍体植株。     

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.