Arabidopsis late-flowering fve mutants are affected in both vegetative and reproductive development

The development of wild-type Arabidopsis thaliana (L.) Heyhn and two late-flowering fve mutants has been analysed under different environmental conditions. In wild-type plants, short-day photoperiods delay the floral transition as a consequence of lengthening all the developmental phases of the plant. Moreover, short days also alter the inflorescence structure by reducing the internode elongation and delaying the establishment of the floral developmental programme in the lateral meristems of the inflorescence and co-florescences. Mutations at the FVE locus cause a delay in flowering time, and a change in the inflorescence structure, similar to the effect of short photoperiods on wild-type plants. However, the effect of the fve mutations is additive to the effect of short days, and all the aspects of the Fve phenotype are corrected by vernalization. These results seem to indicate that FVE is not simply involved in timing the transition from vegetative to reproductive growth, but that it could play a role during all stages of plant development.     

白桦开花位点Flowering Locus T（FT）基因的分离及其表达

FT及其同源基因在促进植物成花和发育阶段转变过程中起重要作用。应用RT-PCR和RACE技术分离了白桦FT基因的cDNA,全长为928 bp,其开放阅读框为525 bp,编码174个氨基酸。预测的蛋白质分子量为19.6 kDa,理论等电点为7.73。该预测蛋白序列含有保守的PEBP蛋白结构域,命名为BplFT,并在GenBank注册,登录号为JQ409561。该基因序列同其它16种植物的相似性为74%～93%,其中与无花果（Ficus carica）的相似度最高为93%,与拟南芥（Arabidopsis thaliana）的相似度最低为74%,并构建了该基因序列的进化树。通过qRT-PCR的方法检测BplFT基因在白桦不同时期不同组织中的转录表达,在营养器官的表达高于花器官,成熟组织要高于幼嫩的组织,在成熟茎中的表达量最高,推测BplFT基因在成熟的营养器官发育中起重要作用,并可能参与调控次生细胞壁的形成。另外,选择了白桦雄花序突变体进行该基因的转录表达分析,该基因在突变体雌花序、雄花序、幼叶及幼茎中均为上调表达,预示着BplFT基因不仅仅参与营养组织发育,在花器官发育中也具有一定的作用。     

二型花柱植株金荞麦繁殖特征

开花物候及繁殖分配是植物适应环境的重要因素。对金荞麦开花物候、繁殖分配及策略进行了研究。结果如下:金荞麦的花果期为每年的8—11月,9月集中开花,其集中开花模式有助于吸引昆虫传粉,提高繁殖成功率;金荞麦单花开花持续时间为1—2 d,种群花期均为85d。L型花序花期为15—26d,S型花序花期为14—27d,两者没有显著差异;L型单花序开花数为26—131朵,S型单花序开花数为36—147朵,两者没有显著差异。L型和S型花序开花动态呈现单峰曲线,在花序开花后第11天L型和S型都达到最大值,分别为7.30%和7.20%,且两种花型具有较高的开花同步性,这有助于其繁殖适应性的提高。同一个花型中,雌蕊长、雄蕊长之间存在极显著负相关,但雌雄总长不存在显著差异,表明雌蕊长、雄蕊长可能存在权衡关系;金荞麦的繁殖器官和营养器官生物量在L型和S型间不存在显著差异,但其花生物量与植株生物量表现出极显著正相关关系。金荞麦L型花生物量分配极显著大于S型,而总生物量不存在显著差异,说明金荞麦植株的营养生长与有性繁殖间存在权衡关系。     

拟南芥成花调控LFY基因的选择性剪接

为研究拟南芥成花调控基因LFY,我们采用RT-PCR方法分离克隆了三种选择性剪接的片段,分别命名为LFY1239,LFY1263和LFY1275。序列分析表明LFY1263包含一个大小为1 263bp的开放阅读框,与之前报道的LFY基因片段大小相同,而LFY1239在第一外显子的3′端缺失了36bp,LFY1275在第一内含子的3′末端插入了12bp。对几种片段表达部位的分析显示,LFY1239只能在营养生长期的莲座叶中表达,而LFY1263和LFY1275在营养生长期和花期的花器官和莲座叶中都可以检测到,并且,LFY1263呈现出主导地位,LFY1275与LFY1263表达的比例表现为花器官高于莲座叶,该比例的变化可能预示着与成花调控有关。     

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.     

A MRG-operated chromatin switch at SOC1 attenuates abiotic stress responses during the floral transition

Plants react to environmental challenges by integrating external cues with endogenous signals to optimize survival and reproductive success. However, the mechanisms underlying this integration remain obscure. While stress conditions are known to impact plant development, how developmental transitions influence responses to adverse conditions has not been addressed. Here, we reveal a molecular mechanism of stress response attenuation during the onset of flowering in Arabidopsis (Arabidopsis thaliana). We show that Arabidopsis MORF-RELATED GENE (MRG) proteins, components of the NuA4 histone acetyltransferase complex that bind trimethylated-lysine 36 in histone H3 (H3K36me3), function as a chromatin switch on the floral integrator SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1 (SOC1) to coordinate flowering initiation with plant responsiveness to hostile environments. MRG proteins are required to activate SOC1 expression during flowering induction by promoting histone H4 acetylation. In turn, SOC1 represses a broad array of genes that mediate abiotic stress responses. We propose that during the transition from vegetative to reproductive growth, the MRG-SOC1 module constitutes a central hub in a mechanism that tunes down stress responses to enhance the reproductive success and plant fitness at the expense of costly efforts for adaptation to challenging environments.

A chromatin switch coordinates flowering initiation with plant responsiveness to adverse conditions, tuning down costly stress responses during flowering for optimal plant reproductive success.     

The role of EMF1 in regulating the vegetative and reproductive transition in Arabidopsis thaliana (Brassicaceae)

To understand the genetic regulation of vegetative to reproductive transition in higher plants, further characterization of the Arabidopsis mutant embryonic flower1, emf1, was conducted. Using three flowering symptoms, we showed that emf1 mutants could only grow reproductive and not rosette shoots under five different growth conditions. The mutant embryos did not produce the typical tunica–corpus shoot apical structures at the heart-, torpedo-, and mature stages. The divergent shoot apical development during mutant and wild-type embryogenesis indicated that the wild-type EMF1 gene was expressed in early embryogenesis. Mutations in the EMF1 gene affected the embryonic shoot apical development and caused the germinating embryo and regenerating callus to grow inflorescence, instead of rosette, shoots. Our results support the hypothesis that the EMF1 gene regulates the switch between vegetative and reproductive growth in Arabidopsis.     

Comparative Analysis of FLC Homologues in Brassicaceae Provides Insight into Their Role in the Evolution of Oilseed Rape

We identified nine FLOWERING LOCUS C homologues (BnFLC) in Brassica napus and found that the coding sequences of all BnFLCs were relatively conserved but the intronic and promoter regions were more divergent. The BnFLC homologues were mapped to six of 19 chromosomes. All of the BnFLC homologues were located in the collinear region of FLC in the Arabidopsis genome except BnFLC.A3b and BnFLC.C3b, which were mapped to noncollinear regions of chromosome A3 and C3, respectively. Four of the homologues were associated significantly with quantitative trait loci for flowering time in two mapping populations. The BnFLC homologues showed distinct expression patterns in vegetative and reproductive organs, and at different developmental stages. BnFLC.A3b was differentially expressed between the winter-type and semi-winter-type cultivars. Microsynteny analysis indicated that BnFLC.A3b might have been translocated to the present segment in a cluster with other flowering-time regulators, such as a homologue of FRIGIDA in Arabidopsis. This cluster of flowering-time genes might have conferred a selective advantage to Brassica species in terms of increased adaptability to diverse environments during their evolution and domestication process.     

Complex Genetic Effects on Early Vegetative Development Shape Resource Allocation Differences Between Arabidopsis lyrata Populations

Costs of reproduction due to resource allocation trade-offs have long been recognized as key forces in life history evolution, but little is known about their functional or genetic basis. Arabidopsis lyrata, a perennial relative of the annual model plant A. thaliana with a wide climatic distribution, has populations that are strongly diverged in resource allocation. In this study, we evaluated the genetic and functional basis for variation in resource allocation in a reciprocal transplant experiment, using four A. lyrata populations and F₂ progeny from a cross between North Carolina (NC) and Norway parents, which had the most divergent resource allocation patterns. Local alleles at quantitative trait loci (QTL) at a North Carolina field site increased reproductive output while reducing vegetative growth. These QTL had little overlap with flowering date QTL. Structural equation models incorporating QTL genotypes and traits indicated that resource allocation differences result primarily from QTL effects on early vegetative growth patterns, with cascading effects on later vegetative and reproductive development. At a Norway field site, North Carolina alleles at some of the same QTL regions reduced survival and reproductive output components, but these effects were not associated with resource allocation trade-offs in the Norway environment. Our results indicate that resource allocation in perennial plants may involve important adaptive mechanisms largely independent of flowering time. Moreover, the contributions of resource allocation QTL to local adaptation appear to result from their effects on developmental timing and its interaction with environmental constraints, and not from simple models of reproductive costs.     

CnFL,a FLORICAULA/LEAFY homolog in Chrysanthemum nankingense is dramatically upregulated in induced shoot apical meristems

A FLORICOULA/LEAFY (FLO/LFY) homolog CnFL gene was isolated from the flower bud of a short-day Chrysanthemum nankingense plant during the flowering induction period. The sequence of CnFL contained a 1236 bp open reading frame that encoded a putative protein of 412 amino acids, which shared 68.67% homology with FLO and 60.23% homology with LFY. The spatial expression patterns of CnFL were analyzed using quantitative real-time PCR in different tissues and the apical meristem during short-day flowering induction. The results indicated that CnFL was highly expressed in the flower buds while its expression was also detected in the stems, young leaves, and vegetative apical meristem. During the period of flowering induction, CnFL expression increased remarkably and reached its highest levels after 15 days of induction. The expression of CnFL in the apical shoot after short-day flowering induction indicates that CnFL regulation is controlled primarily by photoperiodicity.     

The Chloroplast Genome Sequence of Date Palm (Phoenix dactylifera L. cv. ‘Aseel’)

Date palm (Phoenix dactylifera L.) is an economically important and widely cultivated palm of the family Arecaceae. We sequenced the complete date palm chloroplast genome (cpDNA) from Pakistani cv. ??Aseel??, using a combination of Sanger-based and next-generation sequencing technologies. Being very similar to a sequence from a Saudi Arabian date palm cultivar ??Khalas?? published recently, the size of the genome was 158,458?bp with a pair of inverted repeat (IR) regions of 27,276?bp that were separated by a large single-copy (LSC) region of 86,195?bp and a small single-copy (SSC) region of 17,711?bp. Genome annotation demonstrated a total of 138 genes, of which 89 were protein coding, 39 were tRNA, and eight were rRNA genes. Comparison of cpDNA sequences of cultivars ??Aseel?? and ??Khalas?? showed following intervarietal variations in the LSC region; (a) two SNPs in intergenic spacers and one SNP in the rpoc1 gene, (b) polymorphism in two mono-nucleotide simple sequence repeats (SSR), and (c) a 4-bp indel in the accD-psaI intergenic spacer. The SSC region has a polymorphic site in the mono-nucleotide SSR located at position 120,710. We also compared cv. ??Aseel?? cpDNA sequence with partial P. dactylifera cpDNA sequence entries deposited in Genbank and identified a number of potentially useful polymorphisms in this species. Analysis of date palm cpDNA sequences revealed a close relationship with Typha latifolia. Occurrence of small numbers of forward and inverted repeats in date palm cpDNA indicated conserved genome arrangement.