Molecular control of early cone development inPinus radiata

Summary A family of genes expressed during early stages of shoot development were isolated fromPinus radiata. A homologue of theLEAFY/FLORICAULA flower meristem-identity genes,NEEDLY (NLY), and three MADS-box genes,PrMADS1, PrMADS2 andPrMADS3 (Pinus radiata MADS-box genes), were expressed at early stages of initiation and differentiation of reproductive (male and female) cone buds, as well as vegetative buds. Expression ofNLY in transgenicArabidopsis thaliana promoted floral fate, demonstrating that it encodes a functional ortholog of theFLORICAUL A/LEAFY genes of angiosperms.Abbreviations DSB dwarf shoot bud - LSTB long-shoot terminal bud - PCB pollen cone bud - SCB seed cone bud - LD long day - SD short day     

SYMMETRY AND DEVELOPMENT OF BUTOMUS UMBELLATUS (BUTOMACEAE) AND LIMNOCHARIS FLAVA (LIMNOCHARITACEAE)

The prostrate rhizome of Butomus umbellatus produces branch primordia of two sorts, inflorescence primordia and nonprecocious vegetative lateral buds. The inflorescence primordia form precociously by the bifurcation of the apical meristem of the rhizome, whereas the non-precocious vegetative buds are formed away from the apical meristem. The rhizome normally produces a branch in the axial of each foliage leaf. However, it is unclear whether the rhizome is a monopodial or a sympodial structure. Lateral buds are produced on the inflorescence of B. umbellatus either by the bifurcation or trifurcation of apical meristems. The inflorescence consists of monochasial units as well as units of greater complexity, and certain of the flower buds lack subtending bracts. The upright vegetative axis of Limnocharis flava has sympodial growth and produces evicted branch primordia solely by meristematic bifurcation. Only certain leaves of the axis are associated with evicted branch primordia and each such primordium gives rise to an inflorescence. The flowers of L. flava are borne in a cincinnus and, although the inflorescence is simpler than that of Butomus umbellatus, the two inflorescences appear to conform to a fundamental body plan. The ultimate bud on the inflorescence of Limnocharis flava always forms a vegetative shoot, and the inflorescence may also produce supernumerary vegetative buds. Butomus umbellatus and Limnocharis flava exhibit a high degree of mirror image symmetry.     

Identification and functional characterization of SOC1-like genes in Pyrus bretschneideri

Flowering is a prerequisite for pear fruit production. Therefore, the development of flower buds and the control of flowering time are important for pear trees. However, the molecular mechanism of pear flowering is unclear. SOC1, a member of MADS-box family, is known as a flowering signal integrator in Arabidopsis. We identified eight SOC1-like genes in Pyrus bretschneideri and analyzed their basic information and expression patterns. Some pear SOC1-like genes were regulated by photoperiod in leaves. Moreover, the expression patterns were diverse during the development of pear flower buds. Two members of the pear SOC1-like genes, PbSOC1d and PbSOC1g, could lead to early flowering phenotype when overexpressed in Arabidopsis. PbSOC1d and PbSOC1g were identified as activators of the floral meristem identity genes AtAP1 and AtLFY and promote flowering time. These results suggest that PbSOC1d and PbSOC1g are promoters of flowering time and may be involved in flower bud development in pear.     

Role of hormones on flower bud formation in thin-layer expiants of tobacco

Flower bud formation was studied in thin-layer tissue expiants of epidermis plus subepidermal cortex from the inflorescence ramifications ofNicotiana tabacum cv. Samsun. With appropriate hormone concentrations of BA and NAA expiants from flowerv and fruitbearing stalks regenerate flower buds only, while those from the internodes of the inflorescence ramifications produce generative as well as vegetative buds. In both types of expiants the number of buds formed depend mainly on the hormone concentrations but, in addition, the age of stalks and internodes from which expiants are taken also affects bud formation. Both ABA and JA inhibit flower bud formation in expiants of flower stalks. JA was shown to particularly inhibit bud initiation.     

The Cold Awakening of <Emphasis Type="Italic">Doritaenopsis</Emphasis> ‘Tinny Tender’ Orchid Flowers: The Role of Leaves in Cold-induced Bud Dormancy Release

Massive flowering of tropical Phalaenopsis orchids is coordinated by the cold-induced release of reproductive bud dormancy. Light and temperature are the two key factors integrated by the dormancy mechanism to both stop and reactivate the meristem development of many other angiosperm species, including fruit trees and ornamental plants. It is well established that leaves and roots play a major role in inducing flower development; however, currently, knowledge of molecular events associated with reproductive bud dormancy release in organs other than the bud is limited. Using differential gene expression, we have shown that the leaves of a hybrid of Phalaenopsis species, Doritaenopsis ‘Tinny Tender’, undergo major metabolic modifications. These changes result in the production of sucrose and amino acids, both of which can sustain bud outgrowth, and auxin and ethylene, which may play important roles in awaking the dormant buds. Intake of abscisic acid and synthesis of the hormone jasmonate may also explain the inhibition of vegetative growth that coincides with bud growth. Interestingly, many genes that were upregulated by cold treatment are homologous for genes involved in flower induction and vernalization in Arabidopsis, indicating that processes regulating flowering induction and those regulating reproductive bud dormancy release may use similar pathways and effector molecules.     

Seed traits are pleiotropically regulated by the flowering time gene PERPETUAL FLOWERING 1 (PEP1) in the perennial Arabis alpina

The life cycles of plants are characterized by two major life history transitions—germination and the initiation of flowering—the timing of which are important determinants of fitness. Unlike annuals, which make the transition from the vegetative to reproductive phase only once, perennials iterate reproduction in successive years. The floral repressor PERPETUAL FLOWERING 1 (PEP1), an ortholog of FLOWERING LOCUS C, in the alpine perennial Arabis alpina ensures the continuation of vegetative growth after flowering and thereby restricts the duration of the flowering episode. We performed greenhouse and garden experiments to compare flowering phenology, fecundity and seed traits between A. alpina accessions that have a functional PEP1 allele and flower seasonally and pep1 mutants and accessions that carry lesions in PEP1 and flower perpetually. In the garden, perpetual genotypes flower asynchronously and show higher winter mortality than seasonal ones. PEP1 also pleiotropically regulates seed dormancy and longevity in a way that is functionally divergent from FLC. Seeds from perpetual genotypes have shallow dormancy and reduced longevity regardless of whether they after‐ripened in plants grown in the greenhouse or in the experimental garden. These results suggest that perpetual genotypes have higher mortality during winter but compensate by showing higher seedling establishment. Differences in seed traits between seasonal and perpetual genotypes are also coupled with differences in hormone sensitivity and expression of genes involved in hormonal pathways. Our study highlights the existence of pleiotropic regulation of seed traits by hub developmental regulators such as PEP1, suggesting that seed and flowering traits in perennial plants might be optimized in a coordinated fashion.     

Seasonal variation in the competence of the buds of three cultivars from different Citrus species to flower

The role of bud competence in the determination of flowering seasonality was studied in three Citrus cultivars, Bearss lime (Citrus latifolia Tan.), Fino lemon (C. limon [L.] Burm. f.) and Owari satsuma (C. unshiu (Mak.) Marc.), which differ in their adaptation to hot climates and their propensity to produce off-season blooms. Potted plants were kept in a greenhouse under non-inductive conditions (minimum temperature higher than 20°C), and periodically the flowering response was determined of a group of trees exposed for 30 days to an inductive temperature regime (15/8°C). A seasonal change in bud competence was demonstrated, and both bud sprouting and flower formation were highest when the low temperature regime was imposed during February and March. During the summer months, the low temperature regime resulted in a small increase in bud sprouting as compared to non-chilled trees, but only vegetative buds developed and no flowers were formed. The influence of environmental factors on the determination of bud competence was further studied. No effect of photoperiod was found, but raising the minimum air temperature above 25°C during 60 days, eliminated bud competence in Owari satsuma. In Bearss lime trees, the buds reacquired the competence after 4 months at 25/20°C, a temperature regime that does not induce flower formation. The reacquisition of competence was much faster at a lower temperature (15/8°C). A consistent relationship between the flowering response and DNA methylation in buds could not be demonstrated in all cultivars.     

In vitro photoinduction of leaf tissue ofStreptocarpus nobilis

Leaf expiants from vegetative plants of the short-day plantStreptocarpus nobilis (C. B. Clarke) developed flower budsin vitro when cultured in 8 h photoperiods. Tn non-inductive photoperiods only vegetative buds were formed.In vitro photoinduction was demonstrated by giving the expiants short-day (SD) cycles and then transferring them to non-inductive photoperiods for expression of flowering. On medium containing 6-benzylaminopurine (BAP) organogenesis was initiated during the photoinductive treatments. Photoinduction of leaf tissue without adventitious bud development was obtained on medium without BAP. The photoinductive state of the leaf tissue was fairly stable, being expressed after 2–3 weeks in non-inductive photoperiods when adventitious buds were formed. The quantitativein vitro flowering response to the endogenous floral stimuli, resulting from photoinduction, could provide the basis of a bioassay for presumptive flower inducing chemicals.     

薇甘菊花芽分化前后内源激素及相关基因表达的研究

以云南省瑞丽市勐秀林场扦插种植的薇甘菊为试材,采用液相色谱串联质谱(LC-MS/MS)技术对花芽未分化期和花序原基分化期花芽中的生长素(IAA)、赤霉素(GA)、脱落酸(ABA)、反式玉米素(tZ)、异戊烯腺嘌呤(IP)、1-氨基环丙烷羧酸(ACC)、茉莉酸(JA)和水杨酸(SA)含量进行定量分析,同时基于转录组基因功能注释数据对内源激素合成、代谢及信号转导途径相关基因进行表达分析,以探讨不同内源激素对薇甘菊花芽形成的调控作用,以及内源激素合成和信号转导途径相关基因调控薇甘菊花芽分化的机制,为后期通过外源激素调控薇甘菊内源激素水平的方式来控制薇甘菊的有性繁殖提供理论和技术支持。结果表明：(1)薇甘菊未分化期花芽中GA₁₅、GA₁₉、GA₂₀、GA₂₄、IAA、ABA和ETH含量低于花序原基分化期,而未分化期花芽中两种细胞分裂素tZ和IP含量显著高于花序原基分化期。(2)基于RNA-seq测序结果,在薇甘菊两个花芽分化时期共获得7 116个差异表达基因(DEGs),其中上调3 907个,下调3 209个。(3)在内源激素合成方面,参与GA₁₅、GA₁₉、GA₂₀、GA₂₄、IAA、ABA和ACC合成的大量DEGs在花序原基分化期上调表达,这与它们在薇甘菊花序原基分化期的高含量趋势相一致;参与IAA合成的YUCCA基因家族和ACC合成的ACS基因在花序原基分化期的高表达也可能参与促进薇甘菊花芽分化。(4)在植物激素转导途径中,在花序原基分化期,生长素信号转导途径通过AUX/IAA(gene-E3N88_07743)的下调表达和ARF(gene-E3N88_41119)的上调表达,乙烯信号转导途径通过ERF(gene-E3N88_41547)的上调表达,赤霉素信号转导途径通过GID1(gene-E3N88_19448)基因的上调表达,细胞分裂素信号转导途径通过B-ARR(gene-E3N88_28086)和A-RRR(gene-E3N88_40764)基因的下调表达,脱落酸途径通过AREB(gene-E3N88_18558)基因的上调表达,茉莉酸信号转导途径通过JAZ(gene-E3N88_05628)的上调表达和MYC2(gene-E3N88_32405)的下调表达来调控薇甘菊花芽分化。研究发现,高水平的GA₁₅、GA₁₉、GA₂₀、GA₂₄、IAA、ABA和ACC有利于薇甘菊的花芽分化;薇甘菊在花芽分化过程中通过改变不同种类内源激素合成、代谢基因的表达来调控激素浓度,而激素又通过信号转导途径引起下游基因的表达,进而调控薇甘菊的花芽分化。     

A morphological study of the development of the second inflorescences in strawberry (Fragaria×ananassa Duch.)

To clarify the timing of the differentiation of the first and second inflorescences in strawberry (Fragaria × ananassa Duch.), morphological changes on shoot apices during short day and low night temperature treatments were observed by scanning electron microscopy (SEM) and optical microscopy. Axillary buds just below the first inflorescence (axillary bud 1) became visible when sepal primordia of the primary flower were differentiated. By this time, other axillary buds had already developed. Axillary bud 1 developed four leaf primordia, and then a differentiated inflorescence at its summit. The phase transition of shoot apices from the vegetative to the reproductive phase may therefore trigger the differentiation of axillary bud 1 which is destined to develop into extension crowns.     

Characterization of the potato MADS-box gene STMADS16 and expression analysis in tobacco transgenic plants

A new MADS-box gene, STMADS16, has been cloned in Solanum tuberosum L. that is expressed in all vegetative tissues of the plant, mainly in the stem, but not in flower organs. STMADS16 expression is established early during vegetative development and is not regulated by light. Sequence similarity besides the spatial and temporal expression patterns allow to define a novel MADS-box subfamily comprising STMADS16 and the gene STMADS11. Expression of the STMADS16 sense cDNA under the control of the 35S cauliflower mosaic virus promoter modifies the inflorescence structure by increasing both internode length and flower proliferation of the inflorescence meristems, and confers vegetative features to the flower. Moreover, STMADS16 ectopic expression overcomes the increase in flowering time and node number produced under short-day photoperiod, while the flowering time is not affected in long-day conditions. These results are discussed in terms of a possible role for STMADS16 in promoting vegetative development.     

In vitro flowering of Boronia megastigma Nees. and the effect of 6-benzylaminopurine

Successful flower bud initiation and development was achieved on Boronia megastigma in vitro. The effect of cytokinin on flowering was investigated in environmental conditions that promote flowering as well as under conditions that stimulate vegetative growth (nonfloral promotory conditions). Flower initiation and differentiation was enhanced by cytokinin; however, many flower buds reverted when the media contained high levels of cytokinin. Anthesis occurred only on media that had no cytokinin added and under floral promotory conditions.     

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。     

The AGL6-like Gene CpAGL6, a Potential Regulator of Floral Time and Organ Identity in Wintersweet (Chimonanthus praecox)

Wintersweet (Chimonanthus praecox), a deciduous aromatic shrub endemic to China, has high ornamental value for developing beautiful flowers with strong fragrance. The transition from the vegetative to the reproductive phase in wintersweet takes 4-5 years. The molecular mechanism regulating flower development in this basal angiosperm is largely unknown. Here we characterized the molecular features and expression patterns of the C. praecox AGL6-like gene CpAGL6 and investigated its potential role in regulating floral time and organ development via ectopic expression in Arabidopsis thaliana. The expression of CpAGL6 is highly tissue-specific, with the highest level in the middle tepals, moderate levels in inner tepals and carpels, and weak levels in stamen and young leaf tissues. Its dynamic expression in the flower is coincident with tepal opening. Ectopic expression of CpAGL6 in Arabidopsis retarded the vegetative growth and led to precocious flowering, mainly correlated with the inhibition of the floral repressor FLC and promotion of the floral promoters AP1 and FT. Although no ectopic floral organs have been observed, transgenic plants exhibited abnormal stamen and carpel development in later-developing flowers, with fertility reduced to varying degrees. These results suggest that CpAGL6, the AGL6-like gene from the basal angiosperm C. praecox, is a potential E-function regulator involved in specifying floral time and organ identity, functionally homologous to those AGL6-like genes from higher eudicots and monocots.