草莓叶片再生不定芽的研究(简报)

利用丰香草莓叶片作外植体,通过体外实验培养的方法,进行组织培养与再生,研究不同培养基配比对草莓叶片不定芽诱导的影响。结果表明,诱导叶盘再生不定芽的最佳外植体培养基为MS 6-BA（1.5mg/l) IAA(1.5mg/l)。表明只有细胞分裂素和生长素的浓度相当时,才能有效的诱导不定芽再生。     

"全明星"草莓叶片再生体系的建立

以“全明星”草莓叶片为外植体,探讨植物激素、基本培养基、pH值、叶片放置方式等对叶片再生的影响,得出在MS＋BA2．0mg／l＋NAA0．2mg／l的培养基上,叶片不定芽再生率达64％,最适pH值为5．8,叶片背面接触培养基有利于芽的再生。建立了“全明星”叶片再生系统,为草莓的微繁和基因转化打下基础。     

大白菜下胚轴离体不定芽高效再生体系的研究

以大白菜的下胚轴为外植体,比较了不同浓度TDZ和6-BA两种细胞分裂素与不同浓度NAA相配合的培养基上不定芽再生的差异,并利用筛选出的高效再生培养基研究外植体苗龄、切段来源、接种方式以及品种对不定芽再生的影响。结果表明:与6-BA相比,TDZ对诱导下胚轴不定芽再生更有效,在M S+TDZ 0.3 m g.L-1+NAA0.5 m g.L-1+A gNO35 m g.L-1的培养基上,下胚轴不定芽再生频率高达87.8%,平均每下胚轴再生不定芽数也达到15.1个;3~5 d苗龄之间的下胚轴不定芽再生能力无显著差异,再生频率均达到80%以上,此后随着苗龄的增加,不定芽分化频率快速下降,苗龄为7 d时再生频率只有51.1%;下胚轴不同切段不定芽再生能力由强到弱表现为:上部切段>中部切段>下部切段;以正插(形态学下端插入培养基)方式接种的外植体不定芽再生能力显著大于反插(形态学上端插入培养基)和平放的;不同品种大白菜下胚轴的不定芽再生能力有一定差异。     

南瓜高效再生体系的建立

南瓜(Cucurbita moschata)再生率较低, 为建立高效的南瓜再生体系, 以南瓜子叶为外植体, 进行35组不同激素浓度的不定芽诱导研究。结果表明, 南瓜再生受培养基中激素浓度和配比的影响, 适宜浓度6-苄氨基腺嘌呤(6-BA)能有效促进不定芽形成; 单独使用脱落酸(ABA)诱导使南瓜子叶发黄, 但与6-BA组合使用可显著提高外植体的再生能力, 1.0 mg?L ^-16-BA与0.5 mg?L ^-1ABA组合南瓜芽再生率高达90.26%。将不定芽置于MS培养基中进行生根培养, 再生苗移栽易成活。从子叶接种到苗再生约需70天。     

南瓜高效再生体系的建立

南瓜(Cucurbita moschata)再生率较低, 为建立高效的南瓜再生体系, 以南瓜子叶为外植体, 进行35组不同激素浓度的不定芽诱导研究。结果表明, 南瓜再生受培养基中激素浓度和配比的影响, 适宜浓度6-苄氨基腺嘌呤(6-BA)能有效促进不定芽形成; 单独使用脱落酸(ABA)诱导使南瓜子叶发黄, 但与6-BA组合使用可显著提高外植体的再生能力, 1.0 mg∙L ^-16-BA与0.5 mg∙L ^-1ABA组合南瓜芽再生率高达90.26%。将不定芽置于MS培养基中进行生根培养, 再生苗移栽易成活。从子叶接种到苗再生约需70天。     

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.     

中国传统菊花品种‘小林静’再生及转化体系的建立

以中国传统菊花品种‘小林静’叶片为外植体,建立了‘小林静’较好的再生体系及遗传转化体系.结果表明,‘小林静’叶盘最适不定芽分化培养基为MS+2.0 mg/L 6-BA+1.5 mg/L NAA,不定芽分化率为92.76％,平均再生不定芽数为2.3767个;试管苗最佳生根培养基为1/2MS,生根率达100％.移栽采用灭菌的蛭石,再生苗移栽成活率达90％以上.采用根癌农杆菌C58C1介导的叶盘转化法进行‘小林静’的遗传转化试验,农杆菌OD600=0.5-0.6,侵染10 min后,将叶片外植体接种到MS+2.0 mg/L 6-BA+1.5mg/L NAA的培养基中黑暗共培养2d,之后转接到附加10 mg/L硫酸卡那霉素和400 mg/L羧苄青霉素的分化筛选培养基中进行转化细胞的筛选,待长出抗性芽后转接至生根培养基中进行培养,最终建立了菊花品种‘小林静’的遗传转化体系.     

结球白菜带柄子叶外植体不定芽离体再生能力的遗传分析

解析控制植物不定芽离体再生能力的遗传因素,有助于从根本上提高离体培养困难材料的不定芽再生能力,是植物基因工程遗传改良的基础.本研究以结球白菜4个纯合亲本及其杂交后代的带柄子叶为外植体,建立了高频率离体不定芽再生技术.据此我们还对白菜不定芽再生能力进行遗传分析,并开展亲本与后代杂种的离体培养及反应研究,包括对培养基的激素需求,不定芽形成频率,不定芽形成数量,芽形态等系列特征.研究结果表明,杂种与亲本在培养基的激素浓度上有类似需求;杂交后代的不定芽再生率均至少高于一方亲本,在一些组合中可以高于双亲;在适宜的杂交组合及培养条件下,结球白菜带柄子叶外植体的不定芽再生率可以达100%,每一外植体上的不定芽数达3～7个.方差分析表明,结球白菜的不定芽离体再生能力存在基因的加性效应.     

观赏羽衣甘蓝高频再生体系的建立

观赏羽衣甘蓝是一种赏食兼用的耐冻优良景观植物.为了通过基因工程手段赋予其抗虫性,并进一步提高其低温耐受性,获得新的抗性种质,本研究以优良育种品系为试材,详细探讨了影响离体培养不定芽再生的因素,建立了高效再生体系.以8份不同类型羽衣甘蓝基因型的带柄子叶、子叶、下胚轴为外植体,研究了不同基因型、不同外植体、不同的培养基激素浓度配比及添加AgNO3对不定芽诱导的影响.结果表明:无论基因型及使用的培养基,带柄子叶均为最佳外植体;不同的基因型、不同外植体其最佳的芽诱导培养基不同;筛选出两份材料,其带柄子叶分别在L6(MS+6-BA 1.0 mg/L+NAA 0.1mg/L)及L3(MS+6-BA 1.5 mg/L)培养基中不定芽诱导率为100%,下胚轴诱导率最高也能达88.33%;培养基中添加4 mg/L AgNO3不利于羽衣甘蓝的不定芽诱导;再生株生根以MS+NAA 0.1 mg/L效果好,生根率可达100%.     

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%.     

Formation of shoots from leaf axils of Alstroemeria: The effect of the position on the stem

Direct shoot regeneration was induced from leaf explants of Alstroemeria. The explants contained a leaf blade and a small portion of stem node, which were cut from the erect shoots of in vitro multiplicated plantlets. The shoot regeneration capacity of the excised leaf explants was significantly related to the position of the explant on the stem. The youngest explant which was located closest to the shoot apex gave the highest response. A gradient response toward the shoot apex was observed in percentage of shoot regeneration and in the number of shoots per regenerating explant. Histological studies revealed that the shoots were initiated at the leaf axils. The origin of the adventitious buds was located at the epidermal layer of stem peripheral cells. This revised version was published online in June 2006 with corrections to the Cover Date.     

Source, etiolation and orientation of explants affect in vitro regeneration of Venus fly-trap (Dionaea muscipula)

In vitro culture of Venus fly-trap (Dionaea muscipula) was initiated using flower stalk explants. Activated charcoal was required for bud initiation, but omitted in the subculture of regenerated plantlets. Regenerated plants were subsequently used as explant source for investigations concerning effects of source of tissue, etiolation, orientation and illumination of leaf explants on plant regeneration. Etiolation of source plantlets increased the rate of regeneration from explants and decreased explant failure. Generally, adventitious buds developed at the adaxial side and proximal end of an explant. However, when explants were incubated in the dark, 20–30% of bud initiation occurred at the distal end. The site of shoot regeneration on a leaf explant was affected by both illumination and orientation of explants. Placing an explant adaxial side up resulted in the highest rate of regeneration. The most effective condition for plantlet regeneration was found with etiolated petioles incubated with the adaxial side facing the light. Received: 18 March 1998 / Revision received: 12 August 1998 / Accepted: 7 September 1998     

Pretreatment in thidiazuron improves the in vitro shoot induction from leaves in Curculigo orchioides Gaertn., an endangered medicinal plant

Leaf regeneration via direct induction of adventitious shoots obtained from an endangered medicinal plant, Curculigo orchioides Gaertn. by pretreating with thidiazuron. C. orchioides is an endangered medicinal herb belonging to the family Hypoxidaceae. Direct inoculation of leaf pieces on MS medium supplemented with various concentrations of BAP (2–8 μM) or TDZ (2–8 μM) alone or in combination with NAA (0.5 and 1.0 μM) produced low shoot induction both in terms of % response and number of shoots per explant. Hence, leaf explants were pretreated with 15, 25 or 50 μM thidiazuron (TDZ), for 6, 24 or 48 h with the aim of improving shoot regeneration from cultured explants. After pretreatment, explants were transferred to an agar solidified MS medium that was supplemented with BAP (4 μM), TDZ (6 μM), BAP (4 μM) + NAA (1.0 μM), TDZ (6 μM) + NAA (0.5 μM). Control explants were incubated directly on the medium without any pretreatment. The pretreatment of explants with 15 μM TDZ for 24 h significantly promoted the formation of adventitious shoots and the maximum response was observed on MS medium supplemented with 6 μM TDZ. In this medium, 96 % cultures responded with an average number of 16.2 adventitious shoots per explant. The percentage of leaf explants producing shoots and the average number of shoots per explant were significantly improved when TDZ pretreated leaves were cultured onto MS medium supplemented with BAP or TDZ alone or in combination with NAA. The rooted plantlets were successfully transplanted to soil with 90% success. The present investigation indicated the stimulatory role of TDZ pretreatment in regulating shoot regeneration from leaf explants of C. orchioides.     

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.     

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。     

<Emphasis Type="Italic">In vitro</Emphasis> regeneration of <Emphasis Type="Italic">Echinacea pallida</Emphasis> from leaf explants

Summary A method has been developed for the induction of adventitious shoots from leaf tissue of Echinacea pallida with subsequent whole-plant regeneration. Proliferating callus and shoot cultures were derived from leaf tissue explants placed on Murashige and Skoog medium supplemented with 6-benzylaminopurine and naphthaleneacetic acid combinations. The optimum shoot regeneration frequency (63%) and number of shoots per explant (2.3 shoots per explant) was achieved using media supplemented with 26.6 μM 6-benzylaminopurine and 0.11 μM naphthaleneacetic acid. Rooting of regenerated shoot explants was successful on Murashige and Skoog medium, both with and without the addition of indole-3-butyric acid. All plantlets survived acclimatization, producing phenotypically normal plants in the greenhouse. This study demonstrates that leaf tissue of E. pallida is competent for adventitious shoot regeneration and establishes a useful method for the micropropagation of this important medicinal plant.     

Cells within the nodal region of carnation shoots exhibit a high potential for adventitious shoot formation

Adventitious shoot formation was studied with leaf, stem and axillary bud explants of carnation (Dianthus caryophyllus L.). The shoot regeneration procedures were applicable for a wide range of cultivars and shoot regeneration percentages were high for all explant types. Using axillary bud explants, shoot regeneration efficiency was independent of the size of the bud and of its original position in the plant. In contrast, shoot regeneration from stem and leaf explants was strongly dependent on their original position on the plant. The most distal explants (just below the apex) showed the highest level of shoot regeneration. The adventitious shoot primordia developed at the periphery of the stem segment and at the base of leaf explants. In axillary bud, stem and leaf explants, shoot regeneration originated from node cells, located at the transition area between leaf and stem tissue. Moreover, a gradient in shoot regeneration response was observed, increasing towards the apical meristem.Abbreviations BA benzyladenine - NAA naphthaleneacetic acid     

The influence of thidiazuron on shoot regeneration from leaf explants of fifteen cultivars of Rhododendron

The influence of cytokinin thidiazuron (TDZ) and auxin indole-3-acetic acid (IAA) on in vitro shoot organogenesis of fifteen Rhododendron genotypes was investigated and a protocol for high frequency adventitious shoot regeneration from leaf explants was developed. High genotypic variation was observed and regeneration frequencies ranged from 0 to 100 %. Genotype Ovation had the highest number of shoots (26.4 per explant) after 12 weeks on medium with 0.57 μM IAA and 1.20 μM TDZ, but only 65 % of explants regenerated. Catawbiense Grandiflorum had 17.7 shoots per explant and 75 % regeneration on medium with 5.70 μM IAA and 0.45 μM TDZ and Van Werden Poelman had 14.3 shoots per explant and 100 % regeneration on medium with 0 57 μM IAA and 0.45 μM TDZ.     

Developmental and hormonal regulation of direct shoot organogenesis and somatic embryogenesis in sugarcane (Saccharum spp. interspecific hybrids) leaf culture

Rapid and efficient in vitro regeneration methods that minimise somaclonal variation are critical for the genetic transformation and mass propagation of commercial varieties. Using a transverse thin cell layer culture system, we have identified some of the developmental and physiological constraints that limit high-frequency regeneration in sugarcane leaf tissue. Tissue polarity and consequently the orientation of the explant in culture, size and developmental phase of explant, and auxin concentration play a significant role in determining the organogenic potential of leaf tissue in culture. Both adventitious shoot production and somatic embryogenesis occurred on the proximal cut surface of the explant, and a regeneration gradient, decreasing gradually from the basal to the distal end, exists in the leaf roll. Importantly, auxin, when added to the culture medium, reduced this spatial developmental constraint, as well as the effect of genotype on plant regeneration. Transverse sections (1-2 mm thick) obtained from young leaf spindle rolls and orienting explants with its distal end facing the medium (directly in contact with medium) are critical for maximum regeneration. Shoot regeneration was observed as early as 3 weeks on MS medium supplemented with alpha-naphthalenencetic acid (NAA) and 6-benzyladenine, while somatic embryogenesis or both adventitious shoot organogenesis and somatic embryogenesis occurred on medium with NAA and chlorophenoxyacetic acid. Twenty shoots or more could be generated from a single transverse section explant. These shoots regenerated roots and successfully established after transplanted to pots. Large numbers of plantlets can be regenerated directly and rapidly using this system. SmartSett, the registered name for this process and the plants produced, will have significant practical applications for the mass propagation of new cultivars and in genetic modification programs. The SmartSett system has already been used commercially to produce substantial numbers of plants of orange rust-resistant and new cultivars in Australia.     

Thidiazuron-induced high-frequency plant regeneration from leaf explants of Paulownia tomentosa mature trees

Attempts were made to study the effect of thidiazuron (TDZ) on adventitious shoot induction and plant development in Paulownia tomentosa explants derived from mature trees. Media with different concentrations of TDZ in combination with an auxin were used to induce adventitious shoot-buds in two explant types: basal leaf halves with the petiole attached (leaf explant) and intact petioles. Optimal shoot regeneration was obtained in leaf explants cultured on induction medium containing TDZ (22.7 or 27.3 μM) in combination with 2.9 μM indole-3-acetic acid (IAA) for 2 weeks, and subsequent culture in TDZ-free shoot development medium including 0.44 μM BA for a further 4-week period. The addition of IAA to the TDZ induction medium enhanced the shoot-forming capacity of explants. The caulogenic response varied significantly with the position of the explant along the shoot axis. The highest regeneration potential (85–87%) and shoot number (up to 17.6 shoots/explant) were obtained in leaf explants harvested from the most apical node exhibiting unfolded leaves (node 1). An analogous trend was also observed in intact petiole explants, although shoot regeneration ability was considerably lower, with values ranging from 15% for petioles isolated from node 1 to 5% for those of nodes 2 and 3. Shoot formation capacity was influenced by the genotype, with regeneration frequencies ranging from 50% to 70%. It was possible to root elongated shoots (20 mm) in basal medium without growth regulators; however, rooting frequency was significantly increased up to 90% by a 7-day treatment with 0.5 μM indole-3-butyric acid, regardless of the previous culture period in shoot development medium (4 or 8 weeks). Shoot quality of rooted plantlets was improved not only by IBA treatment but also by using material derived from the 4-week culture period. Regenerated plantlets were successfully acclimatized in the greenhouse 8 weeks after transplanting.