番茄离体培养过程中器官发生的细胞组织学观察

对番茄下胚轴、子叶、茎段、叶片、叶柄不同类型外植体离体培养中有关细胞启动、分裂、分化以及器官发生作了细胞组织学观察。研究结果表明番茄不同类型外植体在同样的培养条件下,愈伤组织生长表现出明显差异,其中下胚轴、子叶诱导产生愈伤组织时,细胞启动最早,生长最快,其分裂方式基本为无丝分裂,未见有丝分裂,因此我们认为以不定芽方式获得转基因植株时,植株的所有性状变化,是否纯属目的基因所为,应该反复考察,不能忽视不定芽产生过程中的种种变化;下胚轴诱导愈伤组织形成时,细胞不规则的无丝分裂少于子叶,故下胚轴离体培养得到的正常芽的比例高于子叶的;番茄离体培养中不定芽通常发生在愈伤组织的周边区,也可起源于维管组织结节周围的形成层状细胞。不定根则由茎中柱鞘处发生。     

百合鳞片细胞形态发生中生理生化特性研究

四倍体百合鳞片外植体脱分化形成愈伤组织过程其蛋白质、核酸含量与蛋白酶、淀粉酶、过氧化物酶ＰＯＤ、酸性磷酸酯酶活性先升高后降低,淀粉与ＡＴＰ含量呈降－升－降变化,ＳＯＤ活性先降低后升高,愈伤组织分化芽过程,除ＡＴＰ含量降低外,其余指标均不断升高．鳞片外植体直接分化发育不定芽过程中,仅见蛋白质、淀粉、ＡＴＰ含量与ＳＯＤ、酸性磷酸酯酶活性在５ｄ前降低,其它时间各项指标均升高,直到不定芽发育完成再下降．器官发生型比器官型经历了更为深刻的内部生理生化变化．     

植物激素在松树离体快速繁殖中的作用

本文从生理生化机制的角度阐述了植物激素在松树离体快速繁殖中的调控作用。目前已经明确在不定芽分化期间,细胞分裂素控制靶细胞发生一系列变化,并使子叶成芽区合成特殊的核酸和蛋白质。这些新合成的蛋白质大多数都是酶,它们在淀粉和类脂的代谢中发挥作用,从而改变子叶的正常发育途径并在子叶的特定区域形成分生组织,最终产生丛生芽。植物激素的种类,浓度、相关配比和处理方式都是影响松树器官分化和脱分化的重要因素。细胞分裂素和生长素在提高营养繁殖速率方面是必需的。     

番茄离体培养过程中器官发生的细胞组织观察

对番茄下胚轴、子叶、茎段、叶片、叶柄不同类型外植体离体培养中有关细胞启动、分裂、分化以及器官发生作了细胞组织学观察。研究结果表明：番茄不同类型外植体在同样的培养条件下,愈伤组织生长表现出明显差异,其中下胚轴、子叶诱导产生愈伤组织时,细胞启动最早,生长最快,其分裂方式基本为无丝分裂,未见有丝分裂,因此我们认为以不定芽方式获得转基因植株时,植株的所有性状变化,是否纯属目的基因所为,应该反复考察,不能忽视不定芽产生过程中的种种变化;下胚轴诱导愈伤组织形成时,细胞不规则的无丝分裂少于子叶,故下胚轴离体培养得到的正常芽的比例高于子叶的;蕃茴离体培养中不定芽通常发生在愈伤组织的周边区,也可起源于维管组织结节周围的形成层状细胞。不定根则由茎中柱鞘处发生。     

苦瓜离体培养过程中内源激素含量的变化

针对苦瓜(Momordica charantia)离体培养中外植体易于产生愈伤组织而难以再生不定芽的问题,本文采用酶联免疫吸附法, 研究了苦瓜组织培养过程中不同发育阶段各外植体内源激素含量的变化, 以探讨不定芽分化与激素水平变化之间的关系, 以及苦瓜难以再生不定芽的内在制约因素。结果表明: (1)苦瓜外植体中IAA含量较高, 而iPAs含量过低, 是苦瓜易于产生愈伤组织而不定芽再生困难的主要原因;(2)不定芽的分化与IAA/iPAs的变化有密切的关系; (3)在离体培养过程中, 保持外源细胞分裂素类物质(如ZT)的适当浓度并及时继代, 有利于苦瓜不定芽的分化。     

苦瓜离体培养过程中内源激素含量的变化

针对苦瓜（Momordica charantia）离体培养中外植体易于产生愈伤组织而难以再生不定芽的问题,本文采用酶联免疫吸附法,研究了苦瓜组织培养过程中不同发育阶段各外植体内源激素含量的变化,以探讨不定芽分化与激素水平变化之间的关系,以及苦瓜难以再生不定芽的内在制约因素。结果表明：（1）苦瓜外植体中LAA含量较高,而iPAs含量过低,是苦瓜易于产生愈伤组织而不定芽再生困难的主要原因;（2）不定芽的分化与IAA／iPAs的变化有密切的关系;（3）在离体培养过程中,保持外源细胞分裂素类物质（如ZT）的适当浓度并及时继代,有利于苦瓜不定芽的分化。     

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.     

兔眼蓝莓离体叶片再生组织细胞学观察

离体叶片再生是兔眼蓝莓离体快繁和遗传转化的重要途径。为了探明兔眼蓝莓离体叶片再生途径,以兔眼蓝莓杰兔品种的试管苗叶片为外植体,对离体叶片再生途径进行细胞学观察。结果表明,离体叶片不定芽在30 d内基本完成其发生、发育和形成的全过程。离体叶片以直接再生途径发生不定芽,且属于多起源,其分生组织起源于离体叶片切口附近与维管束相邻的上表皮细胞、维管组织薄壁细胞及周围薄壁细胞,通过细胞分裂和分化形成分生细胞团,直接形成芽,再发育成苗。此外,兔眼蓝莓离体叶片不定芽的形成具有特定的时空特性,多个不定芽先后在离体叶片上形成单芽或丛生芽。     

不结球白菜离体培养与植株再生体系研究

以4个不结球白菜品种为试材,对外植体、苗龄、激素的组配、培养基中琼脂和AgNO3浓度等再生因素进行了筛选优化,并探讨了抗坏血酸(AsA)对不结球白菜不定芽分化的影响。结果显示:以4~7d苗龄的带柄子叶为外植体诱导不定芽效果较好;MN培养基中4mg/L6-BA与0.5mg/LNAA的搭配有利于不定芽形成;琼脂的浓度变化对不定芽分化影响较大,以9g/L琼脂为宜;培养基中添加5~7.5mg/L的AgNO3、0.1~0.5mmol/L的AsA可显著提高不定芽的发生频率和质量。通过不定芽继代培养、生根培养和驯化移栽建立了能够获得较高再生频率的不结球白菜离体再生体系。     

禿杉组织培养研究

本文详细报道了从秃杉(Taiwania flousiana Gaussen)离体胚诱导不定芽、不定根及从无菌苗茎端培养再生植株的过程。诱导不定芽要求较低的蔗糖浓度(以3％最好);同时BA是必须的,在附加0.1—3 mg/1 BA的White培养基上,从离体胚的子叶或胚轴上诱导了不定芽的发生(以1 mg/1最好);NAA与BA结合使用,对不定芽诱导无促进作用;适当提高光照有利于不定芽的诱导。在诱导不定芽的同时,在子叶表面还观察到有许多无结构的“不定突起”。不定芽起源于子叶表皮下1—2层细胞。IBA对诱导离体胚上产生不定根效果较好。在有或无生长素的培养基上,从生长1月龄的无菌苗茎端培养获得了不定根的产生,在加有细胞分裂索的培养基上,从无菌苗上产生了腋芽。     

滤光膜对黄檗离体再生能力及其生理生化指标影响

以黄檗（Phellodendron amurense）无菌苗茎段为材料,MS附加1.5 mg·L^-1 BA和0.5 mg·L^-1 NAA为基本培养基,研究了不同滤光膜对黄檗茎段离体再生影响,并对再生过程中生理生化指标变化进行了研究。结果表明,蓝膜对不定芽再生有着明显的促进作用,再生频率达75.4%,平均每个外植体再生的不定芽数为14.7,其次为荧光和黄膜,红膜和绿膜不利于芽的分化。同时发现,蓝膜和荧光有较高的叶绿素含量、较低的chla/b比值。抗氧化酶的活性和可溶性蛋白的含量以蓝膜最高,荧光次之,绿膜最低。     

Sucrose and starch metabolism during Fargesia yunnanensis shoot growth

Bamboo is one of the fastest growing plants in the world, but their shoot buds develop very slowly. Information about the sugar storage and metabolism during the shoot growth is lacking. In the present study, we determined the activity of sucrose and starch metabolizing enzymes during the developmental period of Fargesia yunnanensis from shoot buds to the young culms that have achieved their full height. The soluble sugars and starch contents were also determined and analyzed in shoot buds and shoots at different developmental stages. The results showed that there were higher sucrose contents in shoot buds than shoots, which coincides with the sweeter taste of shoot buds. As the shoot buds sprouted out of the ground, the starch and sucrose were depleted sharply. Coupled with this, the activity of soluble acid invertase (SAI), cell wall-bound invertase (CWI), sucrose synthase at cleavage direction (SUSYC) and starch phosphorylase (STP) increased significantly in the rapidly elongating internodes. These enzymes dominated the rapid elongation of internodes. The activities of SAI, CWI, SUSYC and STP and adenosine diphosphate-glucose pyrophosphorylase were higher as compared to other enzymes in the shoot buds, but were far lower than those in the developing shoots. The slow growth of shoot buds was correlated with the low activity of these enzymes. These results complement our understanding of the physiological differences between shoot buds and elongating shoots and ascertain the physiological mechanism for the rapid growth of bamboo shoots.     

In Vitro Shoot Regeneration from Callus, Leaf Axils and Petioles of Sugar Beet (Beta vulgaris L.)

Procedures are described for producing axillary shoots fromseedling apices and adventitious shoots from petioles and leaf-derivedcallus of sugar beet cultivars. The rate of adventitious shootregeneration from petioles was influenced by temperature, BAPconcentration of the medium, and the time in culture of theseedling apices from which the petioles were excised. Petiolesectioning confirmed that adventitious shoots originated inthe sub-epidermal parenchyma. Two distinct types of callus wereproduced from leaf explants, but only white friable callus wascapable of shoot development. This callus developed from browntissue and was composed of thin-walled cells with dense cytoplasmand prominent nuclei. Green compact callus with thick-walledlignified cells developed from green tissue, but did not produceshoots. Successful seed sterilization and shoot regenerationfrom petiole explants and callus was cultivar-dependent. Adventitiousshoots were rooted and successfully transplanted to pottingcompost under glasshouse conditions. Key words: Adventitious shoots, axillary shoots, callus, sugar beet (Beta vulgaris L.)     

Regeneration from Phylloclade Explants and Callus Cultures of Schlumbergera and Rhipsalidopsis

Phylloclade explants of Schlumbergera and Rhipsalidopsis were cultured in vitro to produce axillary and adventitious shoots. The explants of both species, taken from greenhouse-grown plants, produced only axillary shoots. There was a pronounced improvement in adventitious shoot formation in phylloclade explants of cultivar CB4 of Rhipsalidopsis by increasing numbers of subcultures of axillary shoots used as donor plants. The axillary shoots generated from the explants were either subcultured to produce successive generations of axillary shoot cultures or made into phylloclade explants and tested for adventitious shoot formation at each subculture. The duration of each subculture varied from 6 to 12 weeks. After the first subculture, sporadic adventitious shoot formation began, and after the third subculture 87% explants of cultivar CB4 produced adventitious shoots at a frequency of about 12 shoots per explant. In contrast, there was no improvement in regenerative ability in explants of cultivar Thor-Olga of Schlumbergera up to third subculture. Adventitious shoots could be produced by callus culture too. Cultivar CB4 was highly regenerative, producing as many as 10 adventitious shoots per square cm of callus. In vitro grown plantlets, when transferred to pots continued to show prolific growth.     

Morphogenesis in dormant embryonic shoots of Picea abies: Influence of the crown and cold treatment

Retention of the crown, a plate of homogeneously thickened collenchymatous cells at the base of the embryonic shoot of Picea abies (L.) Karst., has marked effects on the induction of adventitious buds from the needle primordia. These effects were observed on embryonic shoots of three clones which were cold-treated at 4 ± 1°C for nil, two, four and six months; and then excised either with or without the crown, before subculturing either directly on a medium lacking plant growth regulators or after application of 125 μM benzyladenine (BA) as a 3-h pulse. Embryonic shoots retaining the crown and treated with BA responded reproducibly better than those lacking it. This was true both for the number of shoots that produced adventitious buds and for the numbers of adventitious buds per shoot. Differentiation of as many as five adventitious buds in a single needle primordium was observed, with development occurring nearly twice as early (7 as compared with 12 weeks) in the presence as in the absence of the crown. The response decreased progressively with increasing exposure to cold treatment.
A number of anatomical changes occurred during culture in vitro. After 3 to 4 weeks a band of sclerenchymatous cells commenced differentiation at the centre of the crown. In embryonic shoots without the crown, a tissue which was identified as a wound periderm formed at the excision surface. Vascular unions were observed between the tissues of the newly — formed shoots induced from the needle primordia and those of the original shoot explants.     

中林美荷杨不定芽分化的因素分析与植株再生

对中林美荷杨进行组织培养,采用不同外植体为组织培养材料,以6-BA和NAA或IBA不同激素组合,比较1/2MS与MS不同盐浓度培养基诱导不定芽产生的情况。结果表明叶柄不定芽诱导优于茎段和叶片,茎段形成层不定芽诱导效果也较好。叶柄诱导不定芽的最佳培养基及激素组合是：1/2MS + 6-BA0.5 mg·L^-1+ NAA0.05 mg·L^-1,较MS基本培养基不定芽生长正常,芽诱导率高(76%),增殖倍数达4.7个/叶柄。通过不定芽的继代培养及壮苗、生根,形成完整植株,炼苗移栽成活率高。     

盐地碱蓬幼嫩花序的组织培养及植株再生

选用盐地碱蓬(Suaeda salsa)幼嫩花序为外植体, 建立了快速而高效的离体培养体系。在附加1.0mg.L-16-BA和0.4 mg.L-1 IAA的MS培养基上培养25天可诱导出不定芽, 诱导频率达到82.1%; 不定芽在此培养基上可快速扩增和长期继代培养。不定芽转至MS培养基中培养2~3周生根形成完整植株。     

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。     

The influence of FeEDDHA in red raspberry cultures during shoot multiplication and adventitious regeneration from leaf explants

We examined the effect of FeEDDHA on multiplication via axillary branching and adventitious shoot regeneration from leaf explants in five red raspberry cultivars. When applied during multiplication, FeEDDHA reduced chlorosis, increased content of chlorophyll and iron but had no effect on the number of side shoots in four of the five cultivars. Addition of FeEDDHA to regeneration medium increased the percentage of regenerating leaves in some cultivars and the number of adventitious shoots in all five cultivars.