广藿香抗青枯病离体筛选技术的研究

以广藿香叶片及带节茎为材料,研究青枯菌粗毒素不同制备方法、青枯菌不同培养时间及不同菌液浓度对外植体离体再生的影响。结果表明:过滤灭菌法制备的青枯菌粗毒素致毒性比湿热灭菌法处理更强,外植体成活率明显降低;以培养12 h的青枯菌粗毒素对外植体有较大的致毒性,外植体变褐死亡现象较突出,培养30 d后,叶片及带节茎出芽率分别为10.33%及36.11%;浓度在1.41×10~8 cfu/ml以上的菌液粗毒素对外植体有明显的毒害作用,大多外植体枯黑死亡,出芽率较低,同时在该浓度时,大多数无根苗难以生根,植株基部变黑,叶片变黄,生长不良。确定了青枯菌粗毒素对广藿香不同离体培养阶段的致毒性,建立了以青枯菌粗毒素为选择压力的广藿香离体筛选体系。     

太子参‘柘参1号’离体快繁试验

以太子参‘柘参1号’叶片、茎段为外植体进行离体快繁试验,结果表明：带腋芽的茎段能够诱导出丛生芽,且诱导率较高,最佳诱导培养基为MS + 6-BA 1.0 mg/L + NAA 0.2 mg/L +蔗糖30 g/L;增殖培养基为MS + 6-BA 1.0 mg/L + NAA 0.2 mg/L +蔗糖30 g/L;生根培养基为MS + NAA 0.2 mg/L +蔗糖30 g/L。     

“菊花组织培养”实验选取不同部位为外植体的结果比较

以菊花带芽的茎段、节间中段及叶片为外植体进行组织培养,结果表明,在MS+6-BA 2 mg/L+NAA 0.5 mg/L的培养基中,带芽的茎段为外植体容易成活,且生长迅速,容易直接从芽生成幼苗;节间中段为外植体经过脱分化形成愈伤组织,然后再分化形成幼苗;叶片为外植体能观察到脱分化形成愈伤组织,但是再分化形成幼苗的成功率比较低。     

黄芩愈伤组织诱导研究(简报)

以黄芩带节茎段为外植体,在含6-BA1．0mg／L和NAA0．2mg／L的MS培养基上培养,可直接分化出芽,分化芽的茎段在相同培养基及培养条件下能够诱导形成愈伤组织。     

狭叶薰衣草的离体培养及挥发性成分的分析

为建立新疆狭叶薰衣草(Lavandula angustifolia)的快速繁殖体系,以种子、茎、叶为外植体,对种子萌发、愈伤组织诱导、丛芽分化和生根的最适培养条件进行了研究;用水蒸气蒸馏法提取狭叶薰衣草挥发油,采用气相色谱-质谱法测定挥发油成分。结果表明,种子浸泡的适宜时间为6 h,切开种皮培养,出芽时间最少为6 d;诱导种子出芽的适宜培养基为MS+6-BA2 mg/L;以茎为外植体诱导愈伤组织效果较好,适宜培养基为MS+6-BA 2 mg/L+2,4-D 1 mg/L;诱导分化丛芽的适宜培养基为MS+6-BA 1 mg/L+NAA 0.5 mg/L;生根的适宜培养基为1/2MS+NAA 1 mg/L+6-BA 0.5 mg/L;盆栽薰衣草和无菌苗薰衣草的挥发油主要成分相差较大,离体培养的薰衣草的主要挥发性成分有叶绿醇、丁香油烃、氧化石竹烯等。     

冬凌草离体培养体系的建立及主要次生代谢产物的测定

以冬凌草叶片为外植体,研究不同浓度激素组合对冬凌草愈伤组织诱导及植株再生的影响,并对不同外植体(茎、叶)诱导愈伤、芽的分化能力及再生植株内主要次生代谢产物的含量进行了比较研究。结果表明:在MS 2.0 mg/L 6-BA 1.0 mg/L NAA培养基上诱导愈伤组织效果较好;在MS 2.0 mg/L 6-BA的培养基上诱导芽的效果较好;叶片和茎段在愈伤诱导培养基上均能产生大量的愈伤组织,但其再分化能力以茎段最好;再生苗生根培养基以0.3 mg/L IBA最好;以叶为外植体诱导的再生植株中冬凌草甲素、迷迭香酸的含量均高于以茎为外植体诱导的再生植株。     

湖北双蝴蝶的组织培养研究

以湖北双蝴蝶带芽茎段、不带芽茎段及叶片为外植体,以MS为基本培养基,通过添加不同的植物生长物质种类和浓度配比,建立湖北双蝴蝶组培快繁体系。结果如下:在所有实验方案中,带芽茎段的出愈率最高,是理想的离体快繁材料。较适宜的初代培养基为MS+BA2.0mg/L+蔗糖3.0%,增殖培养基为MS+BA2.0mg/L+NAA0.1mg/L+蔗糖3.0%,而根的诱导则在1/2MS+NAA0.5mg/L+蔗糖1.5%的培养基上进行较为适宜。同时对组织培养过程中湖北双蝴蝶植株再生的方式进行了讨论。     

不同品种花叶芋的组织培养

采用12个不同品种花叶芋的叶片和叶柄进行组织培养,发现不同品种的最佳外植体并不一致,大叶型品种以叶片、小叶型品种以叶柄为佳。试管苗叶片和叶柄比栽培苗的叶片与叶柄更有利于作离体繁殖的外植体。不同外植体对培养基要求则差别不大。花叶芋离体叶片和叶柄在MS+BA 2mg/L+NAA 0.2～0.6mg/L培养基上可直接分化成小芋块,小芋块剖面坚实呈白色,以I-KI溶液染色呈现深蓝色,与盆栽苗芋块相同。小芋块在降低激素浓度培养基即于MS补加BA与NAA各0.1mg/L培养基上,即分化出大量的再生植株。在芋块上分化出芽,在芋块与苗之间分化出根。     

罗布麻离体培养及快繁技术的研究

采用野生罗布麻(Apocynum venetamL.)顶芽及芽下茎段为外植体进行离体培养及快繁技术优化的研究。结果表明:适宜罗布麻离体培养的基本培养基为MS,适宜外植体起始分化的培养基为:MS BA 1.8mg/L KT 0.5mg/L,分化率为88.9%以上;适宜茎段增殖的培养基为MS BA 2.0mg/L KT 0.5mg/L,繁殖系数最高达5.67倍,通过切段繁殖还可提高繁殖系数3倍;适宜生根的培养基为MS IBA 0.5mg/L NAA 0.02mg/L,生根率达90%以上。     

不同培养条件对南烛离体叶片不定芽再生的影响

以南烛( Vaccinium bracteatum Thunb.)组培苗离体叶片为实验材料,研究了不同培养条件对其不定芽再生状况的影响并筛选出最适培养条件。结果表明：基本培养基类型、生长调节剂种类及质量浓度、琼脂和蔗糖质量浓度、外植体类型、外植体接种方式和暗培养时间均对南烛离体叶片不定芽的出芽时间和再生率、外植体干枯率以及不定芽的生长状况有明显影响。南烛离体叶片不定芽再生的最佳培养条件为：以中脉横切2次的叶片为外植体,以近轴面面向培养基的方式接种;以1/2MS-1/2WPM为基本培养基,添加7.5 g·L-1琼脂、25.0 g·L-1蔗糖、0.5 mg·L-1 TDZ、5.0 mg·L-12ip或4.0 mg·L-1 ZT,暗培养21 d后转至光照度2000 lx、光照时间16 h·d-1的条件下培养。     

采用俄罗斯橄榄叶片和茎段诱导产生不定芽的高效再生方法

俄罗斯橄榄(Elaeagnus angustifolia L.)是一种具有很重要药用价值和生态意义的植物。以俄罗斯橄榄一年生幼苗的叶片和茎段为实验材料,探讨了细胞分裂素类(6-BA和Zt)和生长素类(NAA和IBA)两类激素不同组合以及不同配比对植株再生的影响,最后建立了一个高效的俄罗斯橄榄再生方法。结果表明,MS 培养基+ 0.5 mg/L 6-BA +0.2 mg/L NAA更适合叶片的再生,平均每个外植体能产生多达4.3个不定芽;而在MS培养基 + 1.0 mg/L Zt +0.5 mg/L NAA的条件下,茎段外植体再生出来的不定芽最多可以达到平均3.6个;再生芽在含有0.5 mg/L NAA的1/2 MS培养基上生根率达到100%。体外再生苗移栽到装有灭菌混合土(土∶泥炭∶沙子=1∶1∶1)的花盆中锻炼驯化,最后有77%的再生植株存活下来。此结果不仅对俄罗斯橄榄种质资源保护有重要的促进作用,另外也为其将来的遗传转化奠定了基础。     

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。     

一种快速有效的741杨离体叶片再生芽方法

在对杂交品种741杨(Populus alba(P.davidiana×P.simonii)×P.tomentosa)进行农杆菌介导法转基因的试验中发现了一种快速有效的叶片再生芽的方法.首先叶片外植体在培养基Ⅰ(MS培养基添加0.5 mg/L BA和1.0 mg/L 2,4-D)上培养2～3 d,再转移到培养基SH(MSmedium containing 2.0 mg/L of BA and 0.1 mg/L of NAA)上培养10 d,然后再转移到培养基Ⅱ(MSmedium with 0.5 mg/L of BA)上,培养大约5 d之后86.7%的叶片外植体产生的芽,每片叶片外植体(1 cm×1 cm)可产生40～50个芽.但是,如果叶片外植体在培养基Ⅰ上培养的时间长于5 d,再依次转移到培养基SH和Ⅱ上,则叶片会产生大量根.     

High Frequency of Shoot Regeneration from Hypocotyls and Stem Segments of Antirrhinum majus (Snapdragon)

A broadly applicable direct shoot regeneration method from hypocotyls and stem explants has been developed for six cultivars of Antirrhinum majus L. In order to establish a stable and high frequency of shoot regeneration system, leaves, hypocotyls and stem explants of six cultivars were tested with 72 combinations of auxin (naphthaleneacetic acid (NAA) or 3-indoleacetic acid (IAA)) and cytokinin (6-benzylaminopurine (BA) or zeatin (Z)). A few adventitious shoots were directly regenerated from hypocotyl segments of cv. Orchid on MS medium with NAA + BA, IAA + BA, NAA + Z and IAA + Z. High frequency of direct shoot regeneration was obtained from hypocotyl segments on MS medium with 0.05, 0.1 or 0.25 mg l⁻¹ NAA + 2 mg l⁻¹ Z and 0.5 mg l⁻¹ IAA + 2 mg l⁻¹ Z. Finally, stable and high frequency (92–100%) of shoot regeneration with more than 10 adventitious shoots per explant was achieved from the hypocotyls and stem explants of all six cultivars on MS medium with 0.25 mg l⁻¹ NAA + 2 mg l⁻¹ Z. The shoots emerged directly from the hypocotyls and stem segments 4 weeks after culture initiation.     

白花蛇舌草叶片离体培养及试管无性系的建立

以白花蛇舌草叶片为材料,建立了白花蛇舌草叶片高效不定芽发生、植株再生体系。研究了不同激素及其组合对外植体不定芽发生的效应。结果显示,在MS基本培养基中单纯添加6BA,当6BA浓度为0.1mg/L和0.5mg/L时,不能诱导离体叶片发生不定芽,6BA浓度在1.0～5.0mg/L范围内,诱导率随BA浓度升高而增加,适宜浓度为3.0mg/L;当6BA与NAA配合使用时,其诱导率随着培养基中6BA与NAA的相对比值的提高而提高;以MS+BA3mg/L+NAA0.01mg/L作为继代培养基,建立起白花蛇舌草高效、稳定的试管无性系,为白花蛇舌草遗传转化研究奠定了基础。     

Nitrosomethylurea induced streptomycin resistance in Lycopersicon esculentum Mill

High frequency of streptomycin resistant variants of Lycopersicon esculentum were isolated on selective shoot regeneration medium supplemented with IAA (0.5 mg/L), zeatin (1.5 mg/L) and streptomycin sulphate (500 mg/L). Nonmutagenized (controls) and NMU treated cotyledons were placed on shoot regeneration medium supplemented with antibiotic streptomycin. Resistant shoots appeared at a high frequency in mutagenized cotyledons, whereas in controls morphogenesis was suppressed, accompanied by bleaching. Shoot regeneration occurred from the nodular tissues developed at the cut ends of cotyledons. Resistant shoots developed into complete plantlets on rooting medium containing selective concentration of antibiotic. Stability of streptomycin resistance was confirmed by leaf assay and reciprocal crosses between streptomycin-resistant and sensitive plants.     

Shoot Regeneration from Cultured Leaf Explants of Lycium barbarumand Agrobacterium-Mediated Transformation1

A method for fast plant regeneration via organogenesis directly from Lycium barbarumleaf explants has been developed. The key factor for shoot regeneration was the presence of benzyladenine (BA) in the medium. NAA could only induce root formation and explant callusing. Murashige and Skoog (MS) medium supplemented with 2 mg/l BA and 0.5 mg/l NAA is the most efficient condition for shoot formation, with up to 92.6% shoot regeneration and no callus formation. All adventitious shoots cultured on MS medium supplemented with 1 mg/l IAA formed an extensive root system. Regenerated plants were morphologically normal and were also proved to be diploid (2n = 24). Using the optimized regeneration system, the genetic transformation of L. barbarumwas carried out mediated by Agrobacterium tumefaciensEHA101(pIG121Hm). 11.8% leaf explants produced kanamycin-resistant shoots after infection by A. tumefaciens.The putative transgenic nature of plants was confirmed by GUS assay and PCR analysis. Expression of the nptIIgene in the regenerated plants was also detected by observing the callus formation by leaf pieces on MS medium containing 0.2 mg/l 2,4-D and 0–100 mg/l kanamycin.     

影响四季桔器官发生的因素

对四季桔胚轴直接出芽、愈伤组织诱导及植株再生能力的研究表明：上、下胚轴在含有BA的MT培养基上,均能直接出芽,但上胚轴出芽能力明显高于下胚轴,最高出芽率为96．9％。外植体在培养基上的接种方式,对出芽也有一定影响,上胚轴切段以形态学下端垂直插入,出芽率高,且在培养前期表现尤为突出。胚轴愈伤诱导的适宜培养基为MT＋IBA0．5mg-1＋BAgmg-1。愈伤组织分化时,上、下胚轴愈伤组织所要求的BA浓度分别为4mgL-1及2mgL-1。在根的诱导中,附加的生长素种类,不仅影响生根率的高低,而且影响上部茎叶的生长,其中以加入lmgL-1IBA的效果最好,生根率达84．4％。     

In vitro plant regeneration from leaf explants of Ophiorrhiza japonica

An efficient in vitro plant regeneration system from leaves of Ophiorrhiza japonica Blume was established for the first time. Callus formation rate was more than 90.4 % from leaf segments on Murashige and Skoog (MS) supplemented with either α-naphthaleneacetic acid (NAA) alone or in combination with 6-benzyladenine (BA). The highest shoot regeneration (78.9 %) was achieved on MS medium containing 2.0 mg dm⁻³ BA and 0.2 mg dm⁻³ NAA, with an average of 9.4 shoots developed per leaf segment. Shoot regeneration was also improved when the leaf explants were cultured in MS basal medium supplemented with 0.5 % (m/v) polyvinylpyrrolidone (PVP). The leaf explants from seedlings with age of about 18–27 d showed the highest shoot regeneration. The regenerated shoots were rooted on half-strength basal MS medium supplemented with 0.5 mg dm⁻³ indole-3-butyric acid (IBA), which averagely produced 24.8 roots per shoot. The plantlets were transferred to soil, where 100 % survived after 1 month of acclimatization.