黑莓品种‘Arapaho’离体叶片不定芽诱导影响因素分析及再生体系建立

以黑莓(Rubus spp.)品种‘Arapaho’无菌苗叶片为外植体,通过正交和单因素实验分别研究了基本培养基类型、6-BA和1BA质量浓度以及暗培养时间、外植体的叶位和接种方式对不定芽诱导的影响,并研究了IBA质量浓度对不定芽生根的影响;在此基础上,初步建立了黑莓品种‘Arapaho’离体叶片的再生体系.正交实验结果表明:基本培养基类型对叶片不定芽诱导率及平均不定芽数的影响最大,而IBA质量浓度对叶片不定芽诱导率及6-BA质量浓度对平均不定芽数的影响较小;适宜‘Arapaho’叶片不定芽诱导的最佳培养基为含有2.0mg·L-16-BA和1.0 mg·L-1IBA的MS培养基.单因素实验结果表明:暗培养时间、外植体的叶位及接种方式对不定芽诱导率有显著影响;最适宜的暗培养时间为21 d;植株中、上部叶片的再生能力较强,其中第3和第4位叶的不定芽诱导效果最佳;叶面朝上接种更有利于不定芽的诱导.在含0.2 mg·L-1 IBA的MS培养基中,不定芽生根率达100.0％,且根数多、长势良好.黑莓品种‘Arapaho’离体叶片的再生体系为:以无菌苗的第3和第4位叶为外植体,经过适当修剪后叶面朝上接种于含有2.0 mg·L-16-BA和1.0 mg·L-1IBA的MS培养基上,暗培养21 d后置于光照条件下培养30 d;将不定芽转接到含有0.5 mg·L-16-BA和0.3mg·L-1 NAA的MS培养基上进行继代培养;当不定芽高约2 cm时转接到含有0.2 mg·L-1IBA的MS培养基上进行生根培养,最终获得完整植株.     

细胞分裂素种类及添加量对蓝浆果叶片离体再生的影响

以南方高丛蓝浆果(Vaccinium corymbosum hybrids)品种‘南月’(‘Southmoon’)优选系A18和兔眼蓝浆果(V.ashei Reade)品种‘灿烂’(‘Brightwell’)离体叶片为外植体,研究了培养基中添加不同浓度TDZ(0.5、1.0和2.0mg·L-1)、CPPU(2.0、4.0和8.0 mg·L-1)、ZT(2.0、4.0和8.0 mg·L-1)和2iP(4.0、8.0和16.0 mg·L-1)对叶片不定芽再生的影响.结果表明:在培养基中添加TDZ和CPPU对叶片不定芽的诱导效果优于ZT和2iP,再生率有显著差异(P＜0.05).TDZ诱导不定芽出现所需的时间最短且再生率最高,不定芽密集并呈深绿色;其中,在添加0.5 ～2.0 mg·L-1TDZ的培养基上,A18叶片再生率均为100.00％,‘灿烂’叶片再生率最高达79.17％.CPPU也有较强的诱导能力但不定芽出现所需的时间推迟3～5d,且不定芽的密集程度也有所降低;其中,在添加2.0～8.0 mg·L-1CPPU的培养基上,A18叶片再生率为100.00％～93.75％;而‘灿烂’叶片再生率随CPPU质量浓度提高呈下降趋势(72.91％ ～47.91％).ZT和2iP诱导能力差,在添加不同质量浓度ZT和2iP的培养基上A18和‘灿烂’叶片再生率均为0.00％.此外,A18和‘灿烂’的再生能力有差异,在相同条件下A18叶片的再生能力优于‘灿烂’叶片.研究结果显示:基因型以及培养基中细胞分裂素的种类和添加量是影响不同品种蓝浆果叶片不定芽再生的主要因素.     

草莓高频离体再生体系的研究

以6个草莓品种为试材,研究了影响草莓不定芽再生的各种因素,建立离体叶片高效再生系统。结果表明,外植体基因型、激素种类及配比、叶龄等是影响草莓再生的主要因子,其中‘鬼露甘’叶片最佳芽诱导培养基为MS 2.0 mg/L 6-BA 0.1 mg/L IBA,‘嫜姬’叶片愈伤组织的诱导以MS 3 mg/L 6-BA 0.2 mg/L 2,4-D较好,而且1周左右的暗培养可以防止外植体的褐化。芽伸长的最适培养基为MS 0.5 mg/L 6-BA 0.5 mg/L IBA,生根的最适培养基为MS 0.2 mg/L IBA,试管苗移栽后成活率为87%。     

不同激素配比和AgNO3对两种基因型大白菜子叶离体再生的影响

以‘08S555’和‘陕秋白’大白菜子叶为外植体,研究了激素配比和AgNO3对不定芽再生的影响。结果表明：‘陕秋白’的再生率高于‘08S555’,但出芽系数比‘08S555’低。在6-BA与NAA组合时,‘陕秋白’再生率最高,为68.33%,‘08S555’为28.33%;再生系数分别为1.09和2.81。在TDZ与NAA组合时,二者不定芽的再生频率分别为79.17%和45.83%;再生系数分别为1.24和2.55。这说明与6-BA相比,TDZ与NAA组合对两个大白菜子叶再生率的效果更好。AgNO3与细胞分裂素及生长素配合使用,能提高‘陕秋白’子叶不定芽的再生频率。当TDZ浓度为0.3mg·L^-1、NAA为0.5mg·L^-1和AgNO3为6mg·L^-1时,‘陕秋白’再生率最高,达到87.50%。     

苹果矮化砧木‘JM7’的组织培养及其离体叶片不定梢再生

以苹果优良矮化砧木‘JM7’ （Malus prunifolia×M. pumila ‘Malling 9’）为试材, 研究了基本培养基对试管苗增殖生长的影响、蔗糖浓度对试管苗生根的影响及基本培养基、细胞分裂素种类和浓度对离体叶片不定梢再生的影响。结果表明： 基本培养基MS比QL显著提高增殖梢数, 但QL比MS更有利于获得健壮生长的绿苗。3%蔗糖浓度比2%的不定根发生速度快。叶片不定梢再生最适宜的基本培养基是QL。在QL培养基上, 6-BA和TDZ对离体叶片不定梢再生率的影响无显著差异, 但6-BA诱导产生的不定芽在不定梢诱导培养基上可直接伸长生长形成不定梢, 而TDZ诱导产生的不定芽需转移到不加TDZ而加低浓度6-BA的培养基上形成伸长生长的不定梢。     

草莓高效离体叶片再生体系的建立

以草莓'明宝(Meiho)'和'红颊(Benihope)'的叶片为外植体,研究了不同基本培养基、暗培养时间、植物生长调节剂、叶龄、不同放置方式对其不定芽再生的影响.结果表明:各品种叶片不定芽离体再生的最佳条件不同.'明宝'叶片的最佳不定芽再生培养基为MS+2.5 mg/L TDZ+0.1 mg/L IBA+0.1 mg/L 2,4-D,叶片再生的最佳叶龄为30～40 d,再生率可达82.8%;'红颊'叶片的最佳不定芽再生培养基为MS+2.0 mg/L TDZ+0.1 mg/L IBA+0.1 mg/L 2,4-D,叶片再生的最佳叶龄在10～20 d,再生率可达79.8%.2个品种叶片暗培养14 d可以提高不定芽再生率;叶片正放比反放再生效果好;添加8 mg/L AgNO3和1 000 mg/L活性炭可有效提高再生率.     

辣椒再生体系不定芽发生因素的优化研究

以辣椒(Capsicum annuum L)品种"哈椒一号"为试材,选用无菌苗子叶、下胚轴和带柄子叶为外植体,采用正交设计探讨不同外植体、激素组合和AgNO_2浓度等因素对不定芽分化的影响,筛选出了三种外植体不定芽诱导的最适培养基。试验结果表明:在不定芽的分化中,6-BA与IAA相配合使叶片不定芽分化频率明显提高,BA/IAA的比例对不定芽分化有明显影响。并且6-BA 6 mg/L+IAA 2 mg/L的组合能够达到最高的诱导率。AgNO_3不但显著提高了不定芽诱导的频率,并且还缩短了不定芽的发生时间。另外,三种外植体的不定芽诱导率,带柄子叶最高,其次是子叶,下胚轴最差。最适不定芽培养基:MS+6-BA 6 mg/L+IAA 2 mg/L+AgNO_2 4 mg/L,pH 5.8,最高不定芽分化率达88.2%。     

蝴蝶兰组培快繁及热激处理抑制褐变的研究

以9个蝴蝶兰品种的花梗和无菌苗叶片为试材,研究了不同品种间不定芽诱导率及增殖系数的差异,并选出增殖系数高、中、低的3个代表性品种‘内山姑娘’、‘梦幻兄弟’和‘万花筒’,对不定芽增殖条件进行优化,并对培养过程中褐变严重的品种‘内山姑娘’进行了热激处理抑制褐变的研究。结果表明:(1)相同条件下,不同蝴蝶兰品种间不定芽诱导率和增殖(分化)系数存在显著差异,且花梗芽诱导率和繁殖系数高的品种,其叶片的不定芽诱导率和分化系数也较高。(2)6-BA是影响蝴蝶兰不定芽增殖的主要因素,椰汁次之。培养基1/2MS+7.0mg.L-16-BA+0.2mg.L-1 NAA+100mL.L-1椰汁适于‘内山姑娘’和‘梦幻兄弟’品种的不定芽增殖,1/2MS+5.0mg.L-1 6-BA+0.2mg.L-1 NAA+50mL.L-1椰汁适合‘万花筒’品种的不定芽增殖。(3)40℃热激处理9min恢复48h后再切割接种能够显著减轻蝴蝶兰‘内山姑娘’叶片的褐变程度,热激处理后叶片组培过程中的褐变指数、总酚含量以及苯丙氨酸解氨酶(PAL)活性均显著低于对照,且三者的两两之间均具有极显著正相关关系,证明短时间的热激处理可降低酚合成酶PAL的活性,减少酚类化合物的积累,从而减轻组培过程中的褐变伤害。     

泰山酸枣离体叶片再生体系的建立

以泰山酸枣叶片为外植体,以WPM为基本培养基,研究了植物生长调节剂种类、浓度及培养方法等因素对离体叶片不定芽再生的影响,结果表明:不定芽启动的最佳培养基激素组合为1.0 mg·L-1 TDZ+0.5 mg·L-1 IAA;不定芽诱导伸长最佳培养基的激素组合为0.1 mg·L-1 IAA+0.5 mg·L-1 GA3.暗培养是不定芽再生的必需条件,在最适宜的不定芽再生培养基上,叶片连续光培养,不定芽不能再生;叶片先进行暗培养3周后转入光下培养,叶片不定芽再生效果最好,再生率最高可达100%.     

马兜铃不含腋芽茎段不定芽的诱导

为建立马兜铃(Aristolochia debilis Sieb.et Zucc)不含腋芽茎段的不定芽诱导体系,采用正交设计方法研究植物生长调节剂、预培养方式和AgNO3对不定芽诱导的影响。结果表明:植物生长调节物质对不定芽诱导的影响以TDZ6-BAIAA,其中TDZ的影响极显著(P0.01),6-BA的影响显著(P0.05)。不定芽诱导的最适培养基为MS+0.5 mg L–1 TDZ+0.1 mg L–1IAA+0.5 mg L–1 6-BA+2 mg L–1 AgNO3+3%蔗糖+0.6%琼脂(pH 5.8);预培养方式为在MS+0.1 mg L–1 2,4-D+3%蔗糖+0.6%琼脂培养基上暗培养2 d。马兜铃不含腋芽茎段的不定芽诱导率最高可达37.5%。     

Induction and origin of adventitious shoots from chimeras of <Emphasis Type="Italic">Brassica juncea</Emphasis> and <Emphasis Type="Italic">Brassica oleracea</Emphasis>

The chimeras between tuber mustard (Brassica juncea) and red cabbage (B. oleracea) were artificially synthesized in our previous study. Adventitious shoots were induced from nodal segments and leaf discs of TCC (LI-LII-LIII, LI -the outmost layer of shoot apical meristem; LII -the middle layer; LIII -the innermost layer. T = Tuber mustard, C = Red cabbage) chimeras. The origin of the shoots was analyzed by histology and molecular biology. As a result, the frequency of adventitious shoot induction rose with the increase of BA in MS medium in the area of the nodes. However, there was no different induction frequency of adventitious shoots from nodal segment bases in media with different BA concentrations. Most adventitious shoots (clustered shoots) arising from the node area were TTT (Tuber mustard- Tuber mustard- Tuber mustard) and only 4 shoots were chimeras, which indicated that more shoots originated from LI than from LII and LIII. All shoots from nodal segment bases were CCC (Red cabbage-Red cabbage- Red cabbage), indicating that the shoots originated from LII or LII and LIII. There were significant differences in the regeneration rate in the margin of the leaf discs among the three combinations of BA and NAA. Most adventitious shoots from the margin of leaf discs were CCC but 2 out of 70 were chimeras, which indicated that more shoots originated from LII or LII and LIII than from LI. All chimeras obtained by regeneration were different from the original explant donor in type in the present study. The origin of the adventitious shoots varied with the site of origin on the donor plant, and could be multicellular and multihistogenic.     

Effects of X-irradiation on adventitious bud regeneration from in vitro leaf explants of Rosa hybrida

The effectiveness of X-radiation on regeneration of adventitious buds on in vitro leaf explants of three Rosa hybrida L. genotypes was studied. In vitro leaflet explants of roses produced adventitious buds when cultured in the dark for 1 week on Murashige and Skoog (MS) induction medium containing 6.8 μM thidiazuron (TDZ) + 0.49 μM indole-3-butyric acid (IBA) and subsequently transferred to MS regeneration medium containing 2.2 μM benzyladenine (BA) + 0.049 μM IBA in the presence of reduced light, at 15 μmol m-2 s-1 photosynthetically active radiation (PAR). Analysis of radiosensitivity by irradiating leaf explants with increasing doses of X-rays between 25 and 100 Gray (Gy) resulted in a decreasing rate of leaf explants regenerating buds from 47% to 0% respectively. The lethal dose for 50% of the regenerating explants (LD₅₀) in all the three genotypes was estimated to be 25 Gy at a dose rate 2 Gy/s. For the main experiment, doses of 5 and 15 Gy were selected and variations were observed between genotypes. Clone RUI 317 had the highest rate of adventitious bud regeneration, with 83.6% (2.5 buds/explant) at 5 Gy and 64% (1.8 buds/explant) at 15 Gy, compared to 89% (3.4 buds/explant) with the untreated control. Significant differences in the percentage of bud regeneration of the three genotypes were only observed at 15 Gy in comparison to the control and the number of buds formed per regenerating explant varied between 1 to 4. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effects of explant types and media salt strength on growth and secondary metabolite accumulation in adventitious roots of <Emphasis Type="Italic">Periploca sepium</Emphasis> Bunge

In order to study the capabilities of Periploca sepium adventitious root induction in different types of explants, we selected leaves, roots and stems with or without buds. The growth of adventitious roots and periplocin content in these roots were determined. In order to investigate the suitable media salt strength, we cultured the adventitious roots in different salt strength (0.25, 0.50, 1.0, 1.5, 2.0) of Murashige and Skoog (MS) media supplemented with 1 mg/l indole butyric acid (IBA) and 30 g/l sucrose. The results showed that both leaf and root explants were proven suitable for the adventitious root induction; however, the stems could hardly induce adventitious roots no matter whether the stems had buds or not. Further studies reported that adventitious root proliferation and periplocin production derived from root explants were higher than those derived from leaf explants. So the root explants were the optimum explants for adventitious root induction, growth and periplocin production. The salt strength experiment showed that with the increasing salt strength (1.0–2.0 MS), adventitious root growth decreased significantly, as well as periplocin content in comparison with lower (0.25–0.5 MS) salt strength media.     

Direct somatic embryogenesis and shoot organogenesis from leaf explants of Primulina tabacum

An efficient propagation system via somatic embryogenesis and shoot organogenesis and plant regeneration system for endangered species Primulina tabacum Hance was established. Thidiazuron (TDZ) was the key plant growth regulator for inducing somatic embryogenesis and kinetin (KIN) and 6-benzylaminopurine (BAP) were the key cytokinins for inducing shoot organogenesis from leaf explants. TDZ combined with BAP or KIN in the induction Murashige and Skoog medium induced both somatic embryos and adventitious shoots. Leaf explants with abaxial site in contact with the medium induced less somatic embryos or adventitious shoots compared to inversely placed leaf explants and the optimum pH was 6.5–7.0. Secondary somatic embryos or adventitious shoot could be induced from primary somatic embryos using TDZ and BAP. Shoots developed adventitious roots on rooting medium containing 0.5 μM indole-3-butyric acid and 0.2 % activated carbon. Over 90 % of plantlets survived following acclimatization and transfer to potting mixture (sand:Vermiculite:limestone; 1:2:1).     

小桐子的组织培养和植株再生

以小桐子（Jatropha curcas）的胚芽、子叶、下胚轴、叶柄、叶片和茎段作为外植体,用不同浓度的6-苄基腺嘌呤（6-BA）和α-萘乙酸（NAA）对其进行愈伤组织的诱导和植株再生的研究。结果表明：在MS培养基中加入5．0mg／L6-BA和1．0mg／LNAA对愈伤组织的诱导效果最好;加入5．0mg／L6-BA和0．1mg／LNAA对不定芽的诱导最为有效,加入0．1mg／L6-BA和1．0mg／LNAA有利于芽的生长;加入1．0mg／LNAA的1／2MS培养基对生根最为有利。     

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。     

Adaptive nature of the transition phases in development: the case of Sorghum bicolor

An increase in tolerance to salinity is induced in Sorghum bicolor by exposure to a sublethal concentration of NaCl during early vegetative development. The phase of competence for induction of this response, termed salt adaptation, is well defined in time and it coincides with the emergence of the first adventitious roots. The link between these events was investigated. Competence for salt adaptation varies among genotypes. It is shown that competence is especially high for genotypes in which the link between the seminal root and the shoot is reduced during emergence of the adventitious root. These data relate the capacity for salt adaptation with development in the absence of NaCl, suggesting that: (i) functional integration of the adventitious roots within the whole plant has an adaptive nature in normal development; (ii) salt adaptation results from an integration of the environmental constraint (NaCl) during this developmental readjustment. It is concluded that perturbations generated by emergence of a new organ are the cause of rapid variations in sensitivity required to open a competence window.     

Adventitious root induction in Ophiorrhiza prostrata: a tool for the production of camptothecin (an anticancer drug) and rapid propagation

Roots of Ophiorrhiza prostrata D. Don serve as a rich source of camptothecin (CPT), an anticancer drug. Because of the large-scale collection of its roots, the plant has become a threatened species. The present study accomplishes the induction of adventitious roots as a means for the production of CPT as well as for the large-scale propagation of this anticancer drug plant using leaf and internode explants. The biomass yield and CPT content of adventitious roots induced from different explants were compared to roots developed on ex vitro rooted stem cuttings. Adventitious roots were produced on half-strength Murashige and Skoog (MS) medium supplemented with 10.74 μM α-naphthaleneacetic acid and 2.32 μM kinetin at mean fresh weights of 0.753, 0.739 and 0.748 g roots from leaf, internode and shoot, respectively. CPT yield from in vitro derived roots after 50, 80 and 120 days of incubation (0.028, 0.06 and 0.1% dry weight, respectively) was not significantly different from those harvested at the same age from ex vitro rooted (0.03, 0.06 and 0.13%, respectively) stem cuttings. CPT from subcultured roots derived from solid (0.08%) medium was lower than from suspension culture medium (0.12%). Subsequent cultures of the adventitious roots showed a stable production of CPT (0.16%). The yield of CPT from 360-day-old plant-derived roots was 0.19%. Elicitation using methyl jasmonate and acetyl salicylic acid exhibited no enhancement in CPT yield. In vitro propagation through direct shoot regeneration was achieved from the adventitious roots upon transfer to MS medium with 8.87 μM N ⁶-benzyladenine (BA) and 2.46 μM indole-3-butyric acid (IBA) with a mean of 21.2 shoots per culture in 50 days. The shoots upon subculture on medium having the same level of BA and IBA underwent rapid proliferation. The shoots transferred to field conditions after in vitro rooting exhibited 95% survival. Adventitious root induction, from leaf and internode explants, enables the feasible production of CPT as well as the large-scale rapid propagation of this species which can safeguard it from extinction.     

Efficient procedures for callus induction and adventitious shoot organogenesis in sugar beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) breeding lines

Summary Improved in vitro tissue culture systems are needed to facilitate the application of transgene technology to the improvement of sugar beet germplasms. Several commercially important sugar beet breeding lines (SDM, 3, 5, 8, 9, 10, 11, HB 526, and CMS 22003) and commercial varieties (Roberta and Gala) were tested for their regeneration capacity through adventitious shoot organogenesis from cotyledons, hypocotyls, root/hypocotyl/shoot transition zone tissues, and leaf lamina and petiole via an intervening callus phase. Callus induction and adventitious shoot regeneration was dependent on genotype and combinations of plant growth regulators. With cotyledon or hypocotyl explants, SDM 3 and 10 showed a better response on adventitious shoot regeneration in medium containing benzyladenine (BA) and 2,3,5-triiodobenzoic acid or 1-naphthaleneacetic acid (NAA) than SDM 11, 5, and 9. Shoot regeneration was obtained from hypocytyl-root or hypocotyl-shoot transition zone tissue in SDM 9, 10, and HB 526 grown on PGo medium supplemented with BA to induce callus, and the regeneration frequency was 25%. Adventitious shoots were also regenerated from leaf explants of SDM 3 and 9 cultured on medium containing NAA for callus induction and BA and NAA to induce shoot regeneration, and in SDM 10 and CSM 22003 cultured on medium containing BA for callus induction and to induce shoot regeneration.     

以叶盘为外植体的白桦的再生

从不同的激素组成(BA, K T, 2, 4~D, NAA, GA₃)、基本培养基(MS, WP)、外植体放置的方向性进行了实验, 建立了以白桦叶盘为外植体的再生系统。当叶盘向轴面朝下放置在培养基上时, 三周后, 从叶盘边缘生出不定芽。不定芽的诱导率为64%, 平均每片叶盘可生出6 个不定芽。叶盘再生系统的建立为白桦的遗传转化提供了前提。