Induction of Continuous Tepal Differentiation from in Vitro Regenerated Flower Buds of Hyacinthus orientalis

Continuous differentiation of tepals was successively induced from regenerated flower buds in Hyacinthus orientalis L. cv. White Pearl by controlling the exogenous hormones and explant ages. In 250 days of subculture, each flower bud differentiated an average of more than 70 tepals, with a maximum of over 140 tepals. Studies on the morphogenesis and characteristics of growth and development of the flower buds indicate that the first whorled organ of the flower bud was perianth which consisted of perianth tube and tepals grown at the top of the perianth tube, which is the same as the flower bud of the wild type in H. orentalis. The second and third whorls of the flower bud, which should be stamen and pistil in the wild type, but remained as the tepals in the regenerated flower bud. Growth of the regenerated flower bud was faster in the first several months of culture, then slowed down gradually with time. After 150 days in culture the flower bud growth and organ differentiation became very slow. Other than the tepal differentiation the regenerated flower buds also differentiated at random positions some small flower buds that also differentiated the tepals only. Histological observation revealed that the origin of the regenerated flower buds was jointly participated by some cells in the epidermal and subepidermal layers at the inner surface of the perianth explant, and the inner small flower buds were originated from the meristem which was formed by the transformation of the parenchyma at the base of the very young tepal. The authors also compared and discussed the similarities and differences of the phenotypes between the regenerated flower bud in Hyacinthus and agamous flower in Arabidopsis, from which, they have hypothesized on the role of the hormones in the promotion and termination of the gene expressions by an order of development in plant.     

Isolation of <Emphasis Type="Italic">HAG1</Emphasis> and its regulation by plant hormones during in vitro floral organogenesis in <Emphasis Type="Italic">Hyacinthus orientalis</Emphasis> L.

Floral organs have been successfully induced from the regenerated floral buds of Hyacinthus orientalis L. by precisely controlling exogenous hormones in the medium. Under high concentrations of cytokinin and auxin, the regenerated floral bud produces only tepals. However, at reduced levels of the hormones, the regenerated floral bud can produce stamens and/or carpels with ovules. To understand the molecular mechanism of hormone-regulated flower development, a MADS-box gene, HAG1, which is homologous to AGAMOUS (AG) in Arabidopsis, was isolated from the floral tissues of Hyacinthus. Overexpression of HAG1 in Arabidopsis created flower phenotypes resembling those of the apetala2 mutant and AG transgenic Arabidopsis plants. Furthermore, the HAG1 expression pattern was similar to that of AG, confirming that HAG1 is the ortholog of AG in Hyacinthus. HAG1 mRNA was first detected in cultured explants at day 5 in the medium containing high levels of cytokinin and auxin, which could induce floral regeneration in vitro. However, no HAG1 mRNA was detected in the cultured explants until day 10 in media with low or no hormones. Further, HAG1 mRNA was detected in the stamens and carpels of regenerated floral buds, but not in the tepals. Our data support the hypothesis that hormone-regulated HAG1 activity is required for the induction of floral buds and the determination of floral organ types during the regeneration of floral buds.     

风信子花器官中HAP2基因的分离与表达研究(英文)

在离体条件下,以风信子花被片为外植体,通过控制激素的浓度可诱导花被片、雄蕊或胚珠的再生。近年来,在拟南芥和金鱼草等模式植物中已经分离出了许多控制花器官发育的同源异形基因,如AG,AP1,AP2,AP3等,其中AP2在控制花萼和花瓣形成过程中起重要作用,因此本文从风信子中分离AP2的同源基因,并对它在风信子再生系统中的表达进行了分析。根据AP2同源基因功能域的保守序列设计一对简并引物：5'-TGGGA（A/G）TC（G/T/C）CA（C/T）AT（C/T）TGGA-3'和5'-TCCCA(AGC)(CT)(GT)(AG)CC(AG) CA(CT)TT(AG)TG-3', 以再生的花被片为材料进行RT-PCR,扩增出大小约300bp的片段,序列分析表明该片段的氨基酸序列与AP2同源性高达89%。进而,利用5’和3’Race PCR,得到全长的cDNA。该基因命名为HAP2,GenBank登记号为AF134116,该基因全长1597bp,编码368个氨基酸(Fig.1）。与AP2相比,HAP2也含有10个氨基酸长的碱性功能域,其中KKSR为核定位信号。此外,HAP2也含有两个序列重复的68个氨基酸长的功能域（HAP2-R1,HAP2-R2）,HAP2-R1也含有能形成(-螺旋结构的核心区域,且与AP2-R1中的核心序列100%同源,而HAP2-R2中的核心区域与AP2-R2相比, 缺少9个氨基酸(Fig.2）。RT-PCR结合Southern 杂交结果表明(Fig.3）,HAP     

Inflorescence and floral ontogeny in Crocus sativus L. (Iridaceae)

Inflorescence and floral ontogeny of the perennial, herbaceous crop Crocus sativus L. were studied using epi-illumination light microscopy. After production of leaves with helical arrangement a determinate inflorescence forms which becomes completely transformed into a single terminal flower. In some cases, bifurcation of the inflorescence meristem yields two or three floral meristems. The order of floral organs initiation is outer tepals – stamens – inner tepals – carpels. Stamens and outer tepals are produced from the lateral bifurcation of three common stamen-tepal primordia. Within each whorl, organs start developing unidirectionally from the adaxial side, except for the stamens which begin to grow from the abaxial side. Specialized features during organ development include interprimordial growth between tepals forming a perianth tube, fusion at the base of stamen filaments, and formation of an inferior ovary with unfused styles.     

‘圣诞快乐’朱顶红花芽分化研究

采用解剖观测和石蜡切片技术,对朱顶红品种‘圣诞快乐’花芽生长情况、花器官分化和性细胞分化过程进行了研究,以明确朱顶红花芽分化特征,为其花发育、花期调控、杂交育种和系统分类研究提供理论依据。结果表明：‘圣诞快乐’朱顶红每年产生2个花序芽,在第2年完成其内花芽花器官分化,经过低温作用后于第3年盛开,其中第2个花序偶有败育发生;花器官分化过程包括花原基分化期、外花被原基分化期、内花被原基分化期、雄蕊原基分化期、心皮原基分化期,对应的花芽大小分别约为0.02、0.05、0.1、0.2、0.3 cm,所有花器官均为螺旋状向心式发生;朱顶红花药4室,花药壁从外至内由表皮、药室内壁、中层和绒毡层组成,绒毡层类型为分泌型,小孢子减数分裂类型为连续型,四分体排列方式为十字交叉型,成熟花粉粒为2-细胞型;朱顶红雌蕊3心皮,下位子房,中轴胎座,3心室,每室两列倒生胚珠,胚珠为双珠被,厚珠心,具葱型胚囊。     

Benzylaminopurine induces phenocopies of floral meristem and organ identity mutants in wild-typeArabidopsis plants

Arabidopsis thaliana (L.) Heynh. has been used as a model system to investigate the regulatory genes that control and coordinate the determination, differentiation and morphogenesis of the floral meristem and floral organs. We show here that benzylaminopurine (BAP), a cytokinin, influences flower development inArabidopsis and induces partial phenocopies of known floral homeotic mutants. Application of BAP to wild-type inflorescences at three developmental stages results in: (i) increase in floral organ number; (ii) formation of abnormal floral organs and (iii) induction of secondary floral buds in the axils of sepals. These abnormalities resemble the phenotypes of mutants,clv1 (increase in organ number),ap1,ap2,ap3 (abnormal floral organs) andap1 (secondary floral buds in the axils of first-whorl organs). In addition, BAP induces secondary floral buds in the axils of perianth members ofapt2-6, ap3-1 andag mutants, and accentuates the phenotype of theapt2-1 mutant to resemble theapt2-6 mutant. These observations suggest that exogenous BAP suppresses the normal functioning of the genes for floral meristem identity and thereby affects flower development and the later stages of floral organ differentiation.Abbreviations BAP N6-benzylaminopurine - CK cytokinin     

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     

穗花牡荆花芽分化过程中形态和生理指标变化

以穗花牡荆为研究材料,通过探究其花芽分化进程和生理特性,为花期调控技术提供成花机理。采用物候期观察和石蜡切片相结合的方法并测定花芽分化过程中相关生理指标,研究花发育过程中的形态和生理变化。结果表明,穗花牡荆花芽分化为一年多次分化型,其进程可划分为七个时期：未分化期、总轴花序原基分化期、初级分轴花序原基分化期、次级分轴花序原基分化期、小花原基分化期、花器官分化前期和花器官分化后期。同一植株不同位置花芽及同一花序中不同单花分化的进程不同,第一季花期后各阶段的花芽分化形态常存在重叠。花芽分化过程中不同时期叶片和花芽的可溶性糖和可溶性蛋白质含量均有上升下降的变化,总体上叶片中营养物质含量高于花芽保证营养供应。花芽分化过程中,IAA、ABA、CTK和GA3整体水平上先升后降有利于花芽分化进行。研究认为,花芽中大量的可溶性糖和蛋白质积累及较高的碳氮比,有利于穗花牡荆花芽形态分化顺利完成。低水平的GA3/ABA和IAA/CTK有利于花序的形成,ABA/CTK和ABA/IAA比值升高促进小花原基和小花萼片原基的分化, GA3/CTK、GA3/ABA和GA3/IAA比值升高促进花瓣原基、雄雌蕊原基发育。     

Role of Exogenous Hormones in Inducing Cells in different Positions of Perianth Explants to Regenerate Flower Buds in Hyacinthus orientalis

Role of the exogenous hormone in inducing different position cells of perianth explants of hyacinth to regenerate flower buds was studied. Experiments showed that (1) Exogenous hormones are necessary for inducing cells of the perianth explant to regenerate the flower buds; (2) Only cytokinine alone could induce the regeneration of the flower buds, the auxin was not necessary; (3) Exogenous hormones in different concentrations could induce cells in the different parts of the perianth explants to differentiate the flower buds: 6-BAP or zeatin 2 mg/L alone could induce cells located at the lower part of the perianth to differentiate flower buds. Combination of 6-BAP or zeatin 2 mg/L and 2, 4-D 0.1 mg/L was advantageous to cells located middle part of the perianth to regenerate the flower buds. Combination of 6-BAP or zeatin 2 mg/L and 2, 4-D 1.0 mg/L could promote cells located at the upper part of the perianth to differentiate flower buds.     

外源激素在诱导风信子花被外植体不同部位细胞再生花芽中的作用

外源激素诱导风信子（Ｈｙａｃｉｎｔｈｕｓ ｏｒｉｅｎｔａｌｉｓＬ．）同一发育时期花被外植体不同部位细胞再生花芽的实验表明∶１． 诱导花被外植体细胞再生花芽,外源激素是必需的;２． 仅有细胞分裂素就可以诱导花芽再生,生长素并不是必需的;３． 花被外植体上的不同部位的细胞再生花芽时,需要不同浓度的外源激素． 单独加６－ＢＡＰ或玉米素２ ｍ ｇ／Ｌ可以诱导花被下部的细胞再生花芽;６－ＢＡＰ或玉米素２ ｍ ｇ／Ｌ和２,４－Ｄ ０．１ ｍ ｇ／Ｌ的组合有利于花被中部的细胞再生花芽;６－ＢＡＰ或玉米素２ ｍ ｇ／Ｌ和２,４－Ｄ １．０ ｍ ｇ／Ｌ的组合能促进花被上部的细胞分化花芽     

The internal meristem layer (L3) determines floral meristem size and carpel number in tomato periclinal chimeras.

Cell-cell interactions are important during plant development. We have generated periclinal chimeras between plants that differ in the number of carpels per flower to determine the roles of cells occupying specific positions in the floral meristem in determining the number of carpels initiated. Intraspecific chimeras were generated between tomato (Lycopersicon esculentum) expressing the mutation fasciated, which causes an increased number of floral organs per whorl, and tomato wild type for fasciated. Interspecific chimeras were generated between tomato and L. peruvianum, which differ in number of carpels per flower. In both sets of chimeras, carpel number as well as the size of the floral meristem during carpel initiation were not determined by the genotype of cells in the outer two layers of the meristem (L1 and L2) but were determined by the genotype of cells occupying the inner layer (L3) of the meristem. We concluded from these experiments that during floral organ initiation, cells in certain layers of the meristem respond to information supplied to them from other cells in the meristem.     

Effect of lateral suppressor on petal initiation in tomato

Flowers developing on tomato ( Lycopersicon esculentum ) plants homozygous for the lateral suppressor ( ls ) mutation lack petals. Scanning electron micrographs revealed that in ls plants no second whorl organs were initiated. The initiation of first, third, and fourth whorl organs were unaffected by this mutation. To investigate interactions between the cells in different layers of the floral meristem during organ initiation, a periclinal chimera between wild-type and ls tomato was generated. Flowers of the chimera having ls cells in the outer meristem layer (L1) and wild-type cells in internal layers (L2 and L3) developed normally, including the initiation of organ primordia that differentiated as petals in normal positions within the second whorl. L1 of the chimera developed in a non-autonomous manner during petal development. Thus, wild-type cells occupying the internal meristem layers provided developmental cues necessary for initiation of petal primordia at appropriate positions on the floral meristem. L1 cells carrying the lateral suppressor mutation were fully capable of responding to this information and differentiated appropriately.     

Are Petals Sterile Stamens or Bracts? The Origin and Evolution of Petals in the Core Eudicots

BACKGROUND: The aim of this paper is to discuss the controversial origins of petals from tepals or stamens and the links between the morphological expression of petals and floral organ identity genes in the core eudicots. SCOPE: I challenge the widely held classical view that petals are morphologically derived from stamens in the core eudicots, and sepals from tepals or bracts. Morphological data suggest that tepal-derived petals have evolved independently in the major lineages of the core eudicots (i.e. asterids, Santalales and rosids) from Berberidopsis-like prototypes, and that staminodial petals have arisen only in few isolated cases where petals had been previously lost (Caryophyllales, Rosales). The clear correlation between continuous changes in petal morphology, and a scenario that indicates numerous duplications to have taken place in genes controlling floral organ development, can only be fully understood within a phylogenetic context. B-gene expression plays a fundamental role in the evolution of the petals by controlling petaloidy, but it does not clarify petal homology. CONCLUSIONS: An increased synorganization of the flower in the core eudicots linked with the establishment of floral whorls restricts the petaloid gene expression to the second whorl, reducing the similarities of petals with tepals from which they were originally derived. An increased flower size linked with secondary polyandry or polycarpelly may lead to a breakdown of the restricted gene expression and a reversal to ancestral characteristics of perianth development. An altered 'sliding boundary' hypothesis is proposed for the core eudicots to explain shifts in petaloidy of the perianth and the event of staminodial petals. The repetitive changes of function in the perianth of the core eudicots are linked with shifts in petaloidy to the outer perianth whorl, or losses of petal or sepal whorls that can be secondarily compensated for by the inclusion of bracts in the flower. The origin and evolution of petals appears to be as complex on a molecular basis as it is from a morphological point of view.     

‘神马’菊花花芽分化与内源多胺的关系

用薄层层析-荧光法测定菊花'神马'花芽分化期间顶芽和叶片中多胺的动态变化,分析了菊花花芽分化与多胺的关系.结果表明,花芽分化起始期顶芽中的腐胺(Put)含量急剧下降,此后在低水平上波动;叶片内Put则于总苞鳞片分化初期大幅上升,其后各阶段处于较低的水平.顶芽中精胺(Spm)与亚精胺(Spd)含量呈平行波动上升趋势,顶芽中Spin在小花原基分化初期直到花冠分化中期处于优势地位,而顶芽中Spd并无明显变化.顶芽、叶片中的Spin变化趋势相反,顶芽中Spm、Spd的含量变化趋势十分相似,但叶片中却呈交替性变化.结果显示,菊花花芽分化过程中,Put含量的降低有利于启动菊花花芽分化,后期Spm的增加有利于小花的分化,叶片可能向顶芽提供Spm,顶芽和叶片中的Spd与小花原基分化有密切关系.     

德国鸢尾‘常春黄’花芽分化的形态观察及两种代谢产物的动态变化

鸢尾是世界著名观赏花卉,为研究其花芽分化期的形态和生理指标变化情况,我们以德国鸢尾两季花品种‘常春黄’（Iris germanica cv. Lovely Again）为材料,运用扫描电镜（SEM）观察了德国鸢尾‘常春黄’的花芽分化过程。结果表明：整个形态分化过程可分为6个阶段：花序原基分化期、外轮花被分化期、雄蕊分化期、内轮花被分化期、雌蕊分化期、髯毛形成期。结合上述形态分化过程,分别取其二次花花芽分化时期的顶芽、根茎和叶片部位,以蒽酮比色法测定可溶性糖,以考马斯亮蓝G-250法测定蛋白质含量。结果表明：可溶性糖在花序原基分化的初始阶段含量最高,且在3个部位的含量大小关系始终是：根茎﹥叶片﹥顶芽;蛋白质含量呈先上升后下降的趋势,蛋白质含量的峰值出现于花序伸展初期。     

无花果花芽分化与内源激素含量的关系

在‘布兰瑞克’无花果花芽分化形态学研究的基础上,对花芽分化期无花果新梢第7或第8节位花芽中的玉米素核苷(ZRs)、脱落酸(ABA)、赤霉素(GA1 3)、生长素(IAA)4种内源激素含量的变化进行了探讨。结果表明,在无花果花芽分化阶段,GA1 3和IAA初期含量较高,后快速下降,后期稳定在较低水平;ZRs和ABA在初期含量较低,后大幅提高,后期稳定在较高水平。可见,较高水平的内源ZRs、ABA和较低水平的内源GA1 3、IAA,以及较高的ABA/IAA、ABA/GA1 3、ZRs/GA1 3和ZRs/IAA比值有利于无花果花芽分化。     

Floral organogenesis in Tetracentron sinense (Trochodendraceae) and its systematic significance

In Tetracentron sinense of the basal eudicot family Trochodendraceae, the flower primordium, together with the much retarded floral subtending bract primordium appear to form a common primordium. The four tepals and the four stamens are initiated in four distinct alternating pairs, the first tepal pair is in transverse position. The four carpels arise in a whorl and alternate with the stamens. This developmental pattern supports the interpretation of the flower as dimerous in the perianth and androecium, but tetramerous in the gynoecium. There is a relatively long temporal gap between the initiation of the stamens and the carpels. The carpel primordia are then squeezed into the narrow gaps between the four stamens. In contrast to Trochodendron, the residual floral apex after carpel formation is inconspicuous. In their distinct developmental dimery including four tepals and four stamens, flowers of Tetracentron are reminiscent of other, related basal eudicots, such as Buxaceae and Proteaceae.     

Ca2+对黄瓜子叶离体培养物花芽分化的影响

黄瓜子叶离体培养物分化培养 0～ 8d期间 ,添加Ca2 有利于花芽分化 ,花芽分化率可从Ca2 0mmol/L的 (7.9± 5 .6 ) %上升到Ca2 6mmol/L的(31.7± 4.0 ) % ;0～ 2d和 2～ 4d无钙脉冲处理不利于花芽分化 ,高钙脉冲处理的花芽分化率比对照略高 ;4～ 6d和 6～ 8d高钙脉冲不利花芽分化 ,而无钙脉冲处理使花芽分化率上升很多。尤其是在 4～ 6d ,高钙处理使花芽分化率从 (2 2± 1.5 ) %下降到 (15 .7±3 .5 ) %。而无钙处理使花芽分化率从 (2 2 .4± 1.4) %上升到 (4 3± 3 .5 ) %。表明 0～ 8d期间不同时间段对Ca2 的需求是有差别的。相关性分析表明 :0～ 8d期间外源Ca2 影响花芽分化率与总芽中花芽比例极显著相关 ,提示Ca2 可能影响子叶向花芽或营养芽分化的趋势。本文结合已报道的黄瓜子叶培养物花原基形成的时程 ,分析了Ca2 对花原基形成和分化的影响