生长素极性运输抑制剂（TIBA）对烟草离体花柄花芽分化的影响

在只含６－ＢＡ（２ｍｇ／Ｌ）的ＭＳ培养基上，烟草花柄外植体形态学基端膨大，上着生再生花芽，而花柄中部大多都形成俞伤组织。添加ＩＡＡ（２，１０，２０ｍｇ／Ｌ）后，花柄基端膨胀大的现象依然存在，但再生花芽的分布并不限于基端，在花柄中部顶端都可见再生花芽。     

色氨酸促进烟草离体花柄翘尾的效应(简报)

L型和D型色氨酸均能促使离体烟草花柄翘尾，即花柄生理性基部向培养基上方弯曲，翘尾率达100％。不同浓度的IAA均不出现色氨酸引起的高翘尾率。生长素极性运输抑制剂（TIBA）有效地抑制花柄表面愈伤组织的形成，但不提高IAA引起的花柄翘尾的百分率。     

黄花菜不同外植体形成的愈伤组织再生苗观察

研究了黄花菜不同外植体愈伤组织的形成与植株再生。结果表明,出愈率是花柄>花茎>叶片。愈伤组织在MS+6-BA 2mg/L的培养基上出现致密愈伤组织颗粒,经增殖→分割→增殖的程序逐渐形成“球状体”似的愈伤组织。叶片、花茎形成的球状体经20代继代培养,再生能力没有减退,苗形态正常,根尖细胞染色体数目为2n=2x=22。该球状体经秋水仙素处理获得多种形态的四倍体苗和少数重复加倍现象。花柄球状体再生苗中出现了叶片花瓣状或类似花蕾状的形态异常苗,其频率与花柄所处的花期及花蕾大小有密切关系。再生异常苗的球状体继代培养,或者由异常苗叶片重新形成的球状体仍然再生异常苗。花柄球状体经秋水仙素处理,获得的变异株其染色体数目类型较多。因而不宜用花柄作黄花菜快速繁殖的外植体。     

罗汉果不同器官直接分化再生苗的研究

以青皮果品种的叶片、叶柄和无芽茎段作为外植体,研究其直接分化再生苗能力的差异。结果表明:⑴MS 6-BA1.0mg/L IAA0.1mg/L和MS 6-BA2.0mg/L IAA0.1mg/L两组培养基均可使叶片外植体直接分化出芽并建成再生苗。叶片基部的分化能力最强,中部稍次,尖部最弱。⑵MS 6-BA3.0mg/L IAA0.1mg/L则诱导叶片外植体首先脱分化形成愈伤组织,继而再分化成再生苗,,且畸形苗居多,无应用价值。⑶叶柄和无芽茎段在三组培养基中都只能脱分化形成大量愈伤组织,难以分化再生苗。     

新型分裂素PBU对尾巨桉胚性愈伤组织诱导及植株再生的影响

以尾巨桉优良无性系无菌苗茎段为外植体,通过对噻唑基脲类新型分裂素（N-phenyl-N′-[6-（2-chlorobenzothiazol）-yl]urea,PBU）等多种不同浓度生长调节剂组合的优化,进行胚性愈伤组织诱导及植株再生研究。结果表明,在添加了2mg·L^-1PBU和0.05mg·L^-1IAA的改良MS培养基上,茎段外植体培养5d后愈伤组织诱导率达96%以上。将愈伤组织接种在添加1mg·L^-16-BA和0.05mg·L^-1NAA的MS培养基上,诱芽率达90.8%。随后在添加了0.8mg·L^-1PBU与0.05mg·L^-1IAA的1/2MS培养基上诱导芽伸长,用1/2MS培养基附加0.5mg·L^-1IBA诱导生根,移栽后得到完整再生植株。     

生长素极性运输的抑制对叶生长发育模式的影响

以烟草 ( Nicotiana tabacum L.品种“革新一号”)无菌幼苗叶片为材料 ,在 MS培养基中分别加不同浓度的生长素极性运输抑制剂 (三碘苯甲酸、反式肉桂酸、9-羟基芴 - 9-羧酸 )和 2 mg/ L BA ,探讨不定芽分化的情况 ,在这些培养基上都观察到不同形态的喇叭状叶片形成。结果表明 ,再生喇叭叶的发生频率与培养基中抑制剂一定范围内的浓度密切有关。当三碘苯甲酸浓度为 7.5 mg/ L 时 ,喇叭叶的发生频率最高可达到 82 .1 % ,在再生不定芽的不同位置均观察到有喇叭叶的发生。实验证明 ,抑制生长素的极性运输可导致叶形态发生改变 ,说明生长素的极性运输在叶片两侧对称性生长中有重要作用     

大车前体外再生体系的建立和优化

大车前不仅有很高的药用价值,在生态学研究方面也是重要模式植物。关于大车前的组培,目前报道很少。我们通过不定芽直接再生和愈伤组织诱导两种途径,建立了大车前（Plantago major L. ‘Giant Turkish.’）的快速高效组培再生系统。完整的成熟种子培养在添加IAA和TDZ的MS培养基中,不经过愈伤的分化阶段,从子叶节的部位产生不定芽,直接不定芽的诱导频率达到100%。在0.2mg/L IAA和1.0mg/L TDZ作用下,培养4～5周后平均每个外植体产生再生芽的数目达到14.6个。对同一个外植体诱导得到的9株再生植株进行的RAPD检测表明,部分植株在DNA水平上发生了变异。以叶片作为外植体,在添加1.0mg/L NAA的MS固体培养基中培养3周后,伤口处形成愈伤组织,产生愈伤的频率平均为98%。愈伤组织在添加4.0mg/L 6BA的MS固体培养基中分化得到再生芽,分化频率为25%,平均每块愈伤产生再生芽2.8个。两种途径得到的再生芽转到1/2 MS培养基上均可生根、长成完整植株,小苗移栽到温室90%能够存活。     

贯叶金丝桃组织培养的研究

分别以甘肃天水贯叶金丝桃的幼根、幼茎、幼叶为外植体．在1／2MS培养基上附加各类激素,进行贯叶金丝桃的组培实验。研究发现各外植体的增殖速率由高到低分别为幼茎、幼根、幼叶,且得到贯叶金丝桃组培各阶段的最佳培养基成分。诱导愈伤组织的培养基为1／2MS 1．3～1．6mg／L BA 0．2mg／L NAA;培养基1／2MS 1．3～1．6mg／L BA 0．15mg／L NAA有利于不定芽的形成;诱导不定根的培养基为l／2MS IBA0．5～O．8mg／L 蔗糖2．0％。向1／2MS培养基中添加不同的生长素(IAA,IBA,NAA,2．4-D)．在不同浓度梯度的培养基上进行诱导贯叶金丝桃的愈伤组织及不定根的试验,结果表明：生长素IAA,IBA既可诱导愈伤组织,又可以诱导不定根的产生。生长素NAA,2,4-D可诱导产生愈伤组织,但对不定根的诱导作用较差。     

尾叶桉茎段再生系统的建立

本文以尾叶桉(Eucalypt urophylla)U6的无菌苗茎段为材料,选用MS培养基为基本培养基,研究不同IAA浓度对尾叶桉茎段愈伤组织诱导,不同IAA、6-BA浓度对尾叶桉茎段愈伤组织诱导芽、生根的影响。结果表明,当外植体的接种数一样,IAA的浓度为20.0mg/L时,愈伤组织诱导率达到最高,为95%,且此浓度下,出芽率、生根率最高,分别达43.3%和100%,而添加0.5mg/L6-BA则会抑制芽的再生、不能产生根。因此最适合诱导尾叶桉愈伤组织、再生芽和再生根的培养体系是MS+20.0mg/L IAA+30g/L蔗糖+8g/L琼脂。该再生系统的建立将为转基因技术改良桉树性状提供前提条件。     

植物生长物质对大花红景天愈伤组织诱导及苗再生的影响

以大花红景天植物的茎、叶、芽、种子为材料,采用DPS软件正交设计法,通过添加不同植物生长物质,考察其对大花红景天愈伤组织形成及苗再生的影响,为低海拔条件下建立大花红景天植株再生体系提供数据基础。结果表明：种子和芽是诱导愈伤组织最适宜的外植体;植物生长物质对愈伤组织形成的影响大小为6-BA〉KT〉2,4-D〉NAA〉IAA,愈伤组织形成的最佳培养基为MS＋6-BA 4.0 mg.L-1＋KT 0.1 mg.L-1＋NAA 0.1 mg.L-1＋IAA 0.2 mg.L-1;不定芽分化的最佳培养基为MS＋TDZ 0.5 mg.L-1＋NAA 0.5 mg.L-1,诱导率达63.14%,不定芽数平均为11.4。本试验获得的最佳培养基配方,适宜在低海拔条件下进行快速诱导大花红景天的愈伤组织和植株再生。     

烟草花柄愈伤组织花芽分化的能力(简报)

来源于开花植株的外植体(如花柄、花序轴等)具有在离体培养条件下直接分化花芽的能力,这一现象已在数十种植物的组织培养中得到证实。但是,这种成花能力能否保留在由这些外植体形成的愈伤组织之中?已有报道在风信子、布罗瓦利亚花、石龙芮、大蒜、矮通泉草等值物的愈伤组织中得到无     

STUDIES ON THE FLORAL HISTOGENESIS AND PHYSIOLOGY OF PERILLA. III. EFFECTS OF INDOLEACETIC ACID ON THE FLOWERING OF APICAL BUDS AND EXPLANTS IN CULTURE

Raghavan , V. (Princeton U., Princeton, N. J.) Studies on the floral histogenesis and physiology of Perilla. III. Effects of indoleacetic acid on the flowering of apical buds and explants in culture. Amer. Jour. Bot. 48(10): 870–876. Illus. 1961.—The responses of apical buds and explants of a short-day plant, Perilla frutescens (L.) Britt. var. 'Tall Late,' when grown in vitro in White's medium supplemented with indoleacetic acid (IAA) and subjected to short-days (SD) or long-days (LD), are described. Additions of varying concentrations of IAA to the medium inhibited the flowering of the photoinduced apical buds in 2 ways. There was a progressive delay in the appearance of the first signs at the apex and a gradual transition from the more flower-like structures in lower concentrations of IAA (0.1 mg/liter) to sterile cones in higher doses. The sterile cones had florets with well-developed calyx and corolla lobes, but lacked the sporogenous tissues. When subjected to LD, visible signs were observed only in buds grown in 0.1 and 1.0 mg/liter IAA, the pronounced effect of the auxin being in the step-wise inhibition in the formation of the non-sporogenous tissues of the differentiating florets. Flowering of the explants with the 1st pair of unfolded leaves was also inhibited by IAA in either SD or LD, but the 1st signs appeared relatively faster than in apical buds. When photoinduced, explants with the 1st and 2nd pairs of unfolded leaves flowered in all concentrations of IAA tried (up to 100 mg/liter) while those kept in LD remained entirely vegetative.     

THE EFFECTS OF HORMONES UPON THE DEVELOPMENT OF EXCISED FLORAL BUDS OF AQUILEGIA

Young excised floral buds of Aquilegia were grown on defined medium containing kinetin, indoleacetic acid (IAA), or gibberellic acid (GA₃). Only when 10⁻⁶ or 10⁻⁷ m kinetin was added to the basal medium was there a significant increase in the number of initiated whorls of primordia. Buds on the basal medium or on medium with IAA or GA₃ failed to initiate carpels. On medium with 10⁻⁶ or 10⁻⁷ m kinetin, buds successfully initiated a normal whorl of five carpels. A high level of inorganic nitrogen was also required for the initiation of carpels. With 10⁻⁵ m kinetin, individual buds initiated from 6–18 carpels. Staminodial primordia of these buds were replaced with carpels, or the floral apex enlarged to accommodate a single whorl of many carpels. Kinetin did not support the further differentiation of the floral organs. Sepals, petals, and carpels did differentiate on medium with GA₃, but stamens aborted. However, on medium with GA₃ and kinetin, stamen primordia differentiated into short filaments and anthers. Further unknown growth factors appear to be required for the complete differentiation of floral primordia into mature organs.     

THE EFFECTS OF AMINO ACIDS UPON THE DEVELOPMENT OF EXCISED FLORAL BUDS OF AQUILEGIA

Young excised floral buds of Aquilegia were grown on a chemically defined medium containing various concentrations of single amino acids or mixtures of amino acids. γ-Amino butyric acid significantly promoted floral development through the initiation and differentiation of carpels. These floral organs were generally absent on the basal medium. Alanine, glutamic acid, and aspartic acid had no effect upon floral development. All other amino acids were either ineffective at lower concentrations and inhibitory at higher concentrations or were inhibitory at all concentrations. Casein hydrolysate and a mixture of amino acids found in coconut milk were ineffective. The addition of both γ-amino butyric acid and alanine to the basal medium promoted development approaching that achieved on the coconut-milk medium. However, further growth factors appear to be required before development on coconut-milk medium is equalled or exceeded.     

Inhibition of Auxin Polar Transport Affecting the Model of Leaf Growth and Development

Tobacco (Nicotiana tabacum L. cv. Gexin No. 1) leaf slices were cultured in MS medium with different concentrations of auxin polar transport inhibitors (2, 3, 5-triiodobenzoic acid (TIBA), trans-cinnamic acid (CA), and 9-hydooxyflurence-9-carboxylic acid (HFCA)) and their effects on bud formation were observed. Although the effective concentrations vary with different inhibitors, all of them induced the formation of trumpet-shaped leaves. The frequencies of trumpet-shaped leaves were increased with the concentrations of inhibitors in media, and it was up to 82.1% when cultured in the medium containing 7.5 mg/L TIBA. The trumpet-shaped leaves were formed in different sites of the adventitious buds. These results indicated that inhibition of auxin polar transport could affect the morphogenesis of leaves, so the polar transport of auxin is essential for the bilateral symmetry of leaf growth.     

提高西瓜离体培养植株再生效率的研究

本文以“京欣1号”母本和“伊选”西瓜4天苗龄子叶为外植体,研究离体培养植株高频率再生体系。结果表明：“伊选”子叶远轴端外植体的再生频率仅为10％,子叶近轴端外植体在5mg／LBA 0．1mg／L IAA的激素组合下植株再生频率为100％,平均每个外植体的丛生芽数在所有组合中最多,为10.3个;“京欣1号”母本子叶近轴端外植体在2mg／LBA 0．5mg／L IAA激素组合下植株再生频率为100％,平均每个外植体的丛生芽数在所有组合中最多,达6．9个。本试验条件下,子叶近轴端外植体接种4天即分化出不定芽,至再生苗的移栽仅需40天,在MS 0．1mg／L NAA的生根培养基上的生根率为97．3％,移栽成活率达98．5％。     

Hormonal Control of Sex Differentiation of Potentially Female Floral Buds of Lagenaria siceraria var. hispida In Vitro

In the present study, several kinds of phytohormones were used for the control of sex differentiation of the potentially female floral buds of Lagenaria siceraria var. hispida in vitro. It was shown that both GA3 and STS (silver thiosulphate) could effectively change the direction of sex differentiation of the potentially female floral buds in vitro. In the MS medium, supplemented with IAA, BA and ACC(1-aminocyclopropane-l-carboxylic acid) at l nmol/L, male flowers would be induced from the potentially female floral buds by the addition of GA3 (1–500μmol/L). Herein the male flowers were induced more effectively by GA3 within 5–-20 μmol/L but it was not as effective as STS. In the MS medium supplemented with IAA, BA and ACC at 1 nmol/L and with GA3 at 20 nmol/L more male flowers were differentiated from the potentially female floral buds with the addition of STS within 100–500 μmol/L. On the contrary, when the MS medium were supplemented with IAA and ACC at 1 nmol/L and with BA increased to 100 nmol/L more female flowers were differentiated from the potentially female floral buds, even with addition of 10–50 nmol/L of GA3.     

无融合生殖油菜AMR—1花托离体培养的研究

报道了不同激素浓度对无融合生殖没菜花托器官分化效果的研究,结果显示：（１）以ＭＳ为基本培养基,以带有子房和花柄的花托为外植体离体培养,花托、花柄切口部位直接芽诱导的最佳激素配比为４．０ｍｇ／Ｌ６－ＢＡ＋０．０１ｍｇ／Ｌ ＮＡＡ,频率为５８．８２％,花托、花柄部位先形成愈伤组织,继而分化出丛生芽的最佳激素配比为５．０ｍｇ／Ｌ ６－ＢＡ＋０．５ｍｇ／Ｌ ＮＡＡ,频率为８４．００％;（２）腋芽增殖的最佳     

赤霉素对大岩桐花蕾离体培养直接再生花芽的影响（简报）

植物经过一定时期的营养生长(或感受外界信号)后,就能产生成花刺激物。成花刺激物被运输到茎尖,诱导发生一系列的反应。随后其分生组织在一定时期内处于一个相对稳定的状态,即成花决定态。植物成花决定态建立的过程称为成花决定。对成花决定的研究进行了许多年,但是其确切的机理仍不清楚.     

石斛离体培养中ABA对诱导花芽形成的影响

由兰科植物铁皮石斛（Ｄｅｎｄｒｏｂｉｕｍ ｃａｎｄｉｄｕｍ Ｗａｌｌ．ｅｘ Ｌｉｎｄｌ．）种子诱导形成的愈伤组织,在光照下置于ＭＳ附加０．３ ｍ ｇ／ＬＮＡＡ 的培养基上繁殖,可以形成原球茎。将原球茎转入ＭＳ含２ ｍ ｇ／Ｌ ６－ＢＡ 和０．５ ｍ ｇ／ＬＮＡＡ 的培养基上,花芽形成频率为２７．０％ 。原球茎先在０．５ ｍ ｇ／ＬＡＢＡ的培养基上预培养１５ ｄ,再转入含２ ｍ ｇ／Ｌ６－ＢＡ 的ＭＳ培养基上培养,花芽形成频率明显提高,可达８４．４％ ,而且每株植株花的数目增加;但是在仅有ＡＢＡ 的ＭＳ培养基上培养的原球茎再生的植株未见花芽形成