盾叶薯蓣类原球茎发育的形态解剖学观察

为探讨盾叶薯蓣类原球茎形态建成的发育机理及植株移栽成活率高的原因,对盾叶薯蓣离体培养条件下形成类原球茎的形态发生过程进行形态学和石蜡切片组织学观察,并与不定芽的发生进行比较。结果表明：类原球茎是由愈伤组织中致密的卵圆形胚性细胞团分化出芽原基和鳞片叶,随后出现初生增厚分生组织和原形成层（维管束原）,其类原球茎形态建成。不定根的发生为内起源,其维管组织与类原球茎的维管组织相连接,故移栽成活率高。而不定芽为愈伤组织表面的胚性细胞分裂产生的分生细胞团分化而来,其不定根通常发生在茎基部形成的愈伤组织表面,故不易成活。     

多胺对宁夏枸杞愈伤组织器官发生和体细胞胚发生的影响

利用已建立的宁夏枸杞(Lycium barbarum L.)愈伤组织器官发生和体细胞胚发生体系,对多胺在其离体形态发生中的作用进行研究.通过检测内源多胺含量发现,在所研究的三种多胺中,Put是器官发生途径的主要多胺,而在体细胞胚发生途径Spd含量占优势.Put含量变化在两条途径中相似在愈伤组织分化的早期迅速积累不久又下降,随着芽原基和球形胚的形成含量又进一步上升.器官发生中Spd最高含量仅在培养的第一天出现;而从诱导愈伤组织发生体细胞胚的第一天后,Spd含量才开始上升,到第十天时达到最高值.三种外源多胺的添加均能有效地促进两条离体分化途径的形态建成Spd(100μmol/L)能显著增加不定芽数,而体细胞胚发生中Spd(10μmol/L)或Put(100μmol/L)的单独处理能最好地促进体细胞胚形成和进一步发育成苗;尽管Spm在离体形态发生中含量较低,但添加外源Spm也促进了不定芽形成和体细胞胚形成然后成苗.多胺生物合成抑制剂CHA处理阻碍不定芽形成和体细胞胚的进一步发育;但是MGBG对器官发生途径中的形态建成没有影响,却降低体细胞胚的发生频率及再生苗数.添加Spd(50μmol/L)能部分逆转CHA、MGBG的抑制效应.以上结果表明,多胺对宁夏枸杞器官发生和体细胞胚发生途径的离体形态建成有一定影响.     

多胺对宁夏枸杞愈伤组织器官发生和体细胞胚发生的影响

利用已建立的宁夏枸杞（Lycium barbarumL.)愈伤组织器官发生和体细胞胚发生体系,对多胺在其离体形态发生中的作用进行研究。通过检测内源多胺含量发现,在所研究的三种多胺中,Put是器官发生途径的主要多胺,而在体细胞胚发生途径Spd含量占优势。Put含量变化在两条途径中相似：在愈伤组织分化的早期迅速积累不仅又下降,随着芽原基和球形胚的形成含量又进一步上升。器官发生中Spd最高含量仅在培养的第一天后,Spd含量才开始上升,到第十天时达到最高值。三种外源多胺的添加均有有效地促进两种离体分化途径的形态建成：Spd(100 μmol/L）能显著增加不定芽数,而体细胞胚发生中Spd(100μmol/L）而Put（100μmol/L）的单独处理能最好地促进体细胞胚形成和进一步发育成苗;尽管Spm在离体形态发生中含量较低,但添加外源Spm也促进了不定芽形成和体细胞胚形成然后成苗。多胺生物合成抑制剂CHA处理阻碍不定芽形成和和体细胞胚的进一步发育;但是MGBG对器官发生途径中的形态建成没有影响,即降低体细胞胚的发生频率及再生苗数。添加Spd(50μmol/L)能部分逆转CHA、MGBG的抑制效应。以上结果表明,多胺对宁夏枸杞器官发生和体细胞胚发生途径的离体形态建成有一定影响。     

香根草体细胞胚胎发生的细胞学特点与形成条件

香根草是一种优良的生态环境治理植物,但也存在着一些局限性。为了对香根草进行遗传改良,选育出性状更优、抗性更强的新品种,开展了香根草离体培养研究。离体培养采用了两种外植体,一是带腋芽的节,二是由器官发生方式所产生的无菌不定芽。基本培养基为MS,根据不同的目的附加不同种类或配比的生长素与细胞分裂素。观察到香根草的外植体的离体发育途径,有器官发生和体细胞胚胎发生两种,依培养基中所含细胞分裂素或生长素的种类和用量不同而异。结果表明,香根草的这两种离体发育途径的植株再生能力均可以长期保持。细胞学的研究显示,香根草离体发育的启动可在外植体的表皮细胞或薄壁细胞中进行,这些细胞逐渐发育成为胚性细胞。胚性细胞分裂活跃,经二细胞、四细胞而发育成为多细胞的胚性细胞团。由显微观察可知,香根草的体细胞胚胎发生是单细胞起源的,成熟的体细胞胚具有单子叶植物典型的胚胎结构。在分化培养基的作用下,体细胞胚组织上所有的胚状体可以出芽而形成再生植株。所建立的香根草体细胞胚胎发生的植株再生体系,完全适用于遗传转化等生物工程方法对离体培养要求。此外,还观察到一些一般只有在双子叶植物才出现的鱼雷形体细胞胚,这是体细胞胚胎发生中的异常现象。认为这种异常胚是离体培养所引起的。     

亚洲百合花丝离体培养器官形成的细胞形态学研究

对亚洲百合的花丝进行离体培养,并利用常规石蜡制片技术对诱导效果最好的材料进行细胞形态学观察,研究花丝在离体培养过程中器官形成的细胞形态学变化。结果表明:花丝在MS+BA0.5 mg/L+NAA0.5 mg/L的培养基上诱导效果最好。离体培养后其形态学下端切口内方的1～3层细胞首先启动脱分化,然后是内方的10～12层细胞,而其他部位的细胞自始至终未启动脱分化。亚洲百合的再生方式为器官发生型,器官通过胚性愈伤组织间接产生,在胚性愈伤组织团表面附近形成芽原基,或在胚性愈伤组织团内部形成根原基,有时同时分别在内、外形成根原基和芽原基后再通过维管组织连接成完整的植株。本研究为亚洲百合的人工调控提供基础理论依据。     

宁夏枸杞器官发生和体细胞胚胎发生过程中DNA、RNA和蛋白质合成动态的比较研究

宁夏枸杞(Lycium barbarum L.)叶外植体来源的愈伤组织经筛选、繁殖后,将来源相同、状态较为一致的淡黄色愈伤组织转移至O型或E型培养基上,可以诱导出器官发生和体细胞胚胎发生。利用该体系,对两条离体再生途径进行了比较研究。结果表明:(1)在拟分生组织和胚性细胞形成之前,RNA合成首先被激活,随后DNA、蛋白质合成加速;而球形胚形成期间,先是DNA合成的加快,接着RNA、蛋白质的合成高峰出现,在不定芽形成期间却正好相反;(2)可溶性蛋白组分发生规律性变化;器官发生和体细胞胚胎发生的启动阶段都有-153.6kD多肽出现,一些多肽分子在分化早期逐渐消失,而随芽原基或球形胚的形成又重新合成;与形态发生相对应,两种再生体系都有作为各自分子标记的特异多肽(84.9kD、46.3kD和44kD、36.2kD)的表达。此外,还对两种离体再生体系之间的关系和发生机制进行了讨论。     

番茄叶组织培养中愈伤组织形成和器官发生的细胞学和微形态学研究

以番茄叶外植体为材料,研究了不同的生长素和细胞分裂素及其浓度配比对叶外植体培养行为的影响;同时,利用细胞学和扫描电子显微镜技术观察了愈伤组织形成和器官发生过程。结果表明,不同种类及浓度配比的生长素和细胞分裂素直接影响愈伤组织的物理状态、大小和形成的速度以及器官分化的频率和速度。叶外植体切口处的叶肉细胞,维管薄壁细胞和维管束上方的少数叶肉细胞首先启动脱分化而开始分裂,这些细胞的活跃分裂和分化导致在外植体表层形成由薄壁细胞、维管组织和无分化状态的表层分生细胞团组成的愈伤组织。而不定芽则通过愈伤组织的薄壁细胞再次脱分化和再分化活动而形成,为“外起源”。认为存在由植物激素决定的“无分化活性”和“有分化活性”二种性质的愈伤组织。     

细枝木麻黄离体培养过程中愈伤组织和再生芽的细胞组织学观察

为探讨细枝木麻黄(Casuarina cunninghamianaMiq.)愈伤组织分化过程的细胞组织学,对离体培养条件下的愈伤组织进行扫描电子显微镜和石蜡切片观察,分析愈伤组织的细胞分裂、分化以及芽再生的发生过程。结果表明,新鲜外植体培养于愈伤组织诱导培养基上,伤口处的薄壁细胞开始脱分化,培养1周后形成明显的愈伤组织;继续培养2周后,胚性愈伤组织形成,且表层细胞启动分化形成芽原基;培养4周,可肉眼观察到胚性芽原基,数量增多并逐渐分化形成不定芽;培养至第6周,生成不定芽,并大量增殖和分化。因此,细枝木麻黄是通过愈伤组织分化形成胚状体的途径进行植株再生的,为建立细枝木麻黄组织培养高效再生体系提供了理论依据。     

福录考体细胞胚胎发生的观察

福录考（ＰｈｌｏｘｄｒｕｍｍｏｎｄｉｉＨｏｏｋ）体细胞胚胎发生的方式有两种：一是由叶外植体具有一定功能的特化细胞脱化为胚性细胞,如叶表皮细胞,维管束鞘及韬皮薄壁细胞均可发生脱分化进行分裂,形成胚性细胞或分细胞团;二是叶外植体先脱分化形成愈伤组织。     

槐树子叶组织培养中的形态发生研究

槐树子叶在MS附加0.1～5 mg/L BA 和0.1—5 mg/L 2,4-D的培养丛上培养两周,获得了灰色疏松型及白、绿色紧密型两种类型的愈伤组织。后者经培养产生不定芽并再生植株。子叶切块在MS 附加0.1～8 mg/L 2,4-D等培养基上培养3周,在切口处形成愈伤组织的同时,由其表面直接分化产生胚状体。组织学观察表明,胚状体来源于子叶的表皮及叶肉细胞,胚状体产生通过单细胞起源及多细胞出芽两种方式发生。胚状体发育依次通过球形胚、心形胚、鱼雷形胚和子叶胚等阶段形成再生植株,其发育过程与合子胚相似。     

杨树叶薄层培养中不定芽形态发生的细胞组织学研究

将杂种杨树(Populus nigra var.betulifolia×P.trichocarpe)NE299叶主脉用振动切片机横切成400μm或800μm的薄切片,培养在附加0.2mg/L BA和0.01mg/L NAA的木本植物培养基上。培养后,位于主脉维管束两侧中上部的维管束鞘薄壁细胞首先启动分裂。几乎同时,与其邻接的一些栅栏组织细胞也分裂,并很快形成胚性分生细胞团。主脉的愈伤组织主要由维管束鞘薄壁细胞,以及与其邻接的一些栅栏组织细胞和韧皮部的薄壁细胞分裂而来。不定芽通常发生在愈伤组织的周边区,也可以起源于维管组织结节(vascular nodules)周围的形成层状细胞。侧脉的维管束鞘细胞分裂活动很强,可不经愈伤组织直接长成不定芽。杨树叶主脉处的维管束鞘薄壁细胞在与叶肉组织相邻接的细胞中,通常含有少量较小的叶绿体,而位于背腹面的细胞中含有贮藏的淀粉。对形态发生的特定部位及其细胞进行了讨论。     

槐树组织培养中再生植株的比较解剖学研究

本文对组织培养过程中,槐树(Sophora japonica L.)再生植株正常苗和玻璃苗的叶、茎及茎端的解剖结构进行了比较研究。结果表明:正常苗结构基本类似于实生苗,玻璃苗结构变异较大;玻璃苗叶片变厚,表皮细胞形状不规则,气孔保卫细胞萎缩变形,叶肉无明显的栅栏组织与海绵组织分化,叶绿体含量较少,叶维管组织发育不良;茎横切面形状不规则,表皮上气孔数目较多,皮层厚角组织不明显,维营束大致分布成一轮,形成不规则维管柱;茎端分生组织细胞层数较少,不呈现典型的原套原体结构。     

Histology of somatic embryogenesis in cultured leaf segments of sugarcane plantlets

Calli have been initiated from young leaves of in vitro grown sugarcane shoots. Histological examination has shown that the two types of calli induced (nodular and friable) originated from different regions of the explants and were cytologically different.This study has shown an obvious relation between the developmental stage of the excised tissue and the potential of plant regeneration of the in vitro initiated callus culture. Nodular calli were obtained from bases of the fast-growing young leaves while their more mature parts of the older leaves only produced friable calli. High-frequency plant regeneration via somatic embryogenesis was obtained from nodular calli while friable calli rarely produced plantlets.     

Somatic embryogenesis in peach palm using the thin cell layer technique: induction, morpho-histological aspects and AFLP analysis of somaclonal variation

BACKGROUND AND AIMS: The thin cell layer (TCL) technique is based on the use of very small explants and has allowed enhanced in vitro morphogenesis in several plant species. The present study evaluated the TCL technique as a procedure for somatic embryo production and plantlet regeneration of peach palm. METHODS: TCL explants from different positions in the shoot apex and leaf sheath of peach palm were cultivated in MS culture medium supplemented with 0-600 microM Picloram in the presence of activated charcoal. The production of primary calli and embryogenic calli was evaluated in these different conditions. Histological and amplified fragment length polymorphism (AFLP) analyses were conducted to study in vitro morphogenetic responses and genetic stability, respectively, of the regenerated plantlets. KEY RESULTS: Abundant primary callus induction was observed from TCLs of the shoot meristem in culture media supplemented with 150-600 microM Picloram (83-97%, respectively). The production of embryogenic calli depends on Picloram concentration and explant position. The best response observed was 43% embryogenic callus production from shoot meristem TCL on 300 microM Picloram. In maturation conditions, 34+/-4 somatic embryos per embryogenic callus were obtained, and 45.0+/-3.4% of these fully developed somatic embryos were converted, resulting in plantlets ready for acclimatization, of which 80% survived. Histological studies revealed that the first cellular division events occurred in cells adjacent to vascular tissue, resulting in primary calli, whose growth was ensured by a meristematic zone. A multicellular origin of the resulting somatic embryos arising from the meristematic zone is suggested. During maturation, histological analyses revealed bipolarization of the somatic embryos, as well as the development of new somatic embryos. AFLP analyses revealed that 92% of the regenerated plantlets were true to type. The use of TCL explants considerably improves the number of calli and somatic embryos produced in comparison with previously described protocols for in vitro regeneration of peach palm. CONCLUSIONS: The present study suggests that the TCL somatic embryogenesis protocol developed is feasible, although it still requires further optimization for in vitro multiplication of peach palm, especially the use of similar explants obtained from adult palm trees.     

LEAF ANATOMY OF TISSUE-CULTURED LIQUIDAMBAR STYRACIFLUA (HAMAMELIDACEAE) DURING ACCLIMATIZATION

Structural changes accompanying the acclimation process were observed in leaves of sweetgum, Liquidambar styraciflua, using light and transmission electron microscopy (TEM). Comparisons were made of leaves obtained from tissue culture, plantlets acclimated after transfer from the in vitro environment to soil, and field grown trees. Leaves of cultured plantlets lacked a differentiated palisade parenchyma and had spongy parenchyma interspersed with large air spaces. Field grown leaves showed distinct palisade and spongy tissues and a high cell density. New leaves from acclimated plantlets showed an elongation of the upper mesophyll with fewer intercellular spaces than cultured plants. Cells from leaves from in vitro plantlets had large vacuoles, limited cytoplasmic content and flattened chloroplast with an irregularly arranged internal membrane system. Acclimated and field leaf cells had a greater cytoplasmic content than cultured leaves, with the former having more dominate vacuoles. Chloroplasts had evident grana. Acclimated and field leaves had a well developed cuticle unlike leaves from culture.     

细叶黄芪叶肉原生质体植株再生

从细叶黄芪(Astragalus tenuis)外植体愈伤组织分化出的再生苗叶片分离原生质体。原生质体培养在改良 K8p 培养基中形成了愈伤组织。增殖后的愈伤组织转入分化培养基中分化出苗。幼苗在生根培养基中长出不定根,再生成为完整植株。再生苗叶肉原生质体在 AY培养基中,种子无菌苗叶肉原生质体在改良 K8p 或 AY 培养基中均不能形成愈伤组织。较低的2,4-D 浓度有利于原生质体愈伤组织的形成和分化,过高的2,4-D 浓度对愈伤组织的形成和分化有不利的影响。     

青海野生黑果枸杞再生体系的建立及遗传稳定性分析

以野生黑果枸杞(Lycium ruthenicum Murr.)的无菌苗叶片作为外植体,建立了两条再生体系:一条是经愈伤组织再分化的间接再生体系,一条是不经愈伤组织再分化的直接再生体系。并采用流式细胞术(FCM)及ISSR分子标记技术对两种途径再生苗进行了遗传稳定性分析。结果表明:(1)最佳愈伤组织诱导培养基为MS+1.5 mg·L-12,4-二氯苯氧乙酸(2,4-D),诱导率达100%;最佳分化培养基为MS+1.5 mg·L-16-苄氨基腺嘌呤(6-BA)+0.1 mg·L-1吲哚-3-丁酸(IBA),1 g愈伤组织上的平均不定芽数为39.4个。(2)叶片直接诱导不定芽的最佳培养基为MS+0.5 mg·L-16-BA+0.3 mg·L-1α-萘乙酸(NAA),不定芽诱导率为92.9%,每个外植体上平均不定芽数为18.1个。(3)两条途径再生的不定芽在不含植物生长调节剂的MS培养基上,2周内均可正常生根。(4)FCM结果显示亲本苗及2种再生苗均为二倍体。(5)ISSR分析表明,间接再生苗的平均遗传相似性系数为0.84,直接再生苗的平均遗传相似性系数为0.91,直接再生体系是一种更加快速高效的繁殖方法。     

High growth rate and regeneration capacity of hypocotyl protoplasts in some Brassicaceae

Protoplasts isolated from 4-day-old hypocotyls of various species of Brassica (Brassica napus, B. campestris and B. oleracea ) produced callus with high efficiency in media containing casein hydrolysate and high concentrations of the auxin 2,4-D (4.5 μM). Cell division began after 24 h and 60% of the cells had divided after 48 h. In contrast, protoplasts isolated from stem and mesophyll of plants grown in vitro or in the greenhouse began to divide after a delay of 3–5 days. In these cases 40–50% of the cells had divided after 5 days as compared to 70% for hypocotyl protoplasts. To obtain a high frequency of regeneration, rapidly growing calli were transferred to media having a high cytokinin:auxin ratio as early as possible, usually 3 weeks after protoplast isolation. The average regeneration frequency for calli obtained from mesophyll protoplasts was 50%, while as many as 70% of the calli derived from hypocotyl protoplasts of B. napus regenerated plantlets on a medium containing zeatin (9.1 μM) and IAA (0.6 μM). On the same medium regeneration of Brassica oleracea was obtained. A low percentage of calli (1%) from Brassica campestris formed shoots when cultured on a combination of zeatin (4.6 μM), BA (4.4 μM) and IAA (0.6 μM).     

Structural and metabolic properties of green tissue cultures from a CAM plant, Kalanchoë blossfeldiana hybr. Montezuma

Abstract Crassulacean acid metabolism (CAM) was studied in mixotrophic callus tissue cultures of Kalanchoë blossfeldiana hybr. Montezuma and compared with plants propagated from the calli. The ultrastructural properties of the green callus cells are similar to mesophyll cells of CAM plants except that occasionally abnormal mitochondria were observed. There was permanent net CO₂ output by the calli in light and darkness, which was lower in darkness than in light. The calli exhibited a diurnal rhythm of malic acid, with accumulation during the night and depletion during the day. ¹⁴C previously incorporated by dark CO₂ fixation into malate was transferred upon subsequent illumination into end products of photosynthesis. All these data indicate that CAM operates in the calli tissue. The results revealed that the capacity for CAM is obviously lower in the calli compared with plantlets developing from the calli, or with ‘adult’ plants. The data suggest also that CAM in the calli was not limited by the activities of CAM enzymes.     

The tropical legume Sesbania rostrata: Tissue culture, plant regeneration and infection with Agrobacterium tumefaciens and Rhizogenes strains

Conditions were examined for callus induction and in vitro morphogenesis of Sesbania rostrata. A protocol for organogenesis from different S. rostrata explants (cotyledons, hypocotyls, immature embryos) was established and used to regenerate plants. The cytokinin BAP was found to be essential for shoot formation at concentrations of 0.2–1.0 mg/l. SH medium, free of hormones or supplemented with 0.1 mg/l naphthaleneacetic acid (NAA), was found to stimulate root development of the regenerated plantlets. The susceptibility of S. rostrata to Agrobacterium mediated infection/transformation was tested using different wild type A. tumefaciens (C58 and B6S3) and A. rhizogenes (15834) strains. An extensive systemic infection of S. rostrata by the agrobacterial strains was observed, presumably occurring via spread of the bacteria in the vascular bundles.