高羊茅FaCONSTANS基因的表达及功能分析

植物由营养生长向生殖生长转变过程中光周期调控起着重要的作用。CONSTANS (CO) 是光周期途径中的特有基因,为探讨高羊茅FaCONSTANS (FaCO) 基因响应日照长短从而启动植物开花的机理,利用实时荧光定量qRT-PCR技术分析在长日照、短日照、持续光照、持续黑暗条件下FaCO基因的表达水平。构建过表达载体p1300-FaCO,利用农杆菌介导法遗传转化拟南芥,构建沉默载体p1300-FaCO-RNAi遗传转化高羊茅。结果表明,FaCO基因的表达受光周期调控,与生物钟控制的昼夜节律相关。在长日照条件下FaCO基因促进拟南芥开花,且恢复拟南芥突变体开花表型。RNAi沉默FaCO基因的高羊茅转基因植株晚花或者一直处于营养生长阶段。本研究初步探究高羊茅FaCO基因对开花过程的调控,这将有助于更进一步了解该基因的生物学功能。     

光周期影响植物花时的分子机制

日长感知是植物所具有的重要的生物学功能,光周期是决定植物开花时间的关键环境因子之一。光周期的暗期长度是决定植物成花的决定因素。通过形态学和遗传学研究,揭示了光周期敏感的一些遗传特性,并确定了光敏感指数的标准。构建了光周期性状相关的分子标记连锁图谱,是进行基因定位、克隆和分子标记辅助选择的重要基础工作,也是进行光周期机理研究的有效途径。通过模式植物拟南芥的研究,建立了一个长日促进开花的遗传途径。它的机理可以综合为:光和感光信息体系结合产生信号并传导,CO表达被激活。在每日日长循环、光体系及遗传背景的变化基础上,如果CO的表达和日长状况协调,那么CO激活FT表达,随后开花。水稻、小麦、玉米等作物在光周期机理研究方面也取得了一些进展。     

观赏植物花期调控途径及其分子机制

开花期控制对观赏植物的生产和应用具有重要意义。目前关于高等植物成花机理的研究已经取得了突破性进展, 为观赏植物花期调控开辟了新途径。该文总结了观赏植物花期调控的途径和方法, 并对改良观赏植物花期的技术思路做了初步分析。通过与高等植物成花机制研究的对比分析发现, 观赏植物开花机理的研究已有了长足发展, 一些观赏植物的转基因研究也取得了丰硕成果。利用分子设计育种途径改良观赏植物的开花期, 突破了传统方法的局限性, 其研究和应用前景非常广阔。     

观赏植物花期调控途径及其分子机制

开花期控制对观赏植物的生产和应用具有重要意义。目前关于高等植物成花机理的研究已经取得了突破性进展,为观赏植物花期调控开辟了新途径。该文总结了观赏植物花期调控的途径和方法,并对改良观赏植物花期的技术思路做了初步分析。通过与高等植物成花机制研究的对比分析发现,观赏植物开花机理的研究已有了长足发展,一些观赏植物的转基因研究也取得了丰硕成果。利用分子设计育种途径改良观赏植物的开花期,突破了传统方法的局限性,其研究和应用前景非常广阔。     

拟南芥开花诱导途径分子机制研究进展

拟南芥是分子和遗传学研究的模式植物,对植物花发育及控制花形态建成的分子遗传机制的研究进展主要是建立在对拟南芥研究的基础之上,拟南芥开花主要受到4个途径(自主途径、赤霉素途径、春化作用和光周期途径)的内源和外界信号的同时诱导.该文对近年来国内外有关拟南芥开花诱导的4个途径的分子机制研究进展进行综述,并初步绘制出各开花诱导途径基因间的调控网络图,以进一步明确基因间的相互作用模式及其在整个开花过程中的作用地位.     

高等植物开花诱导研究进展

高等植物由营养生长向生殖生长转换的过程称为开花诱导。开花诱导过程由遗传和外界环境两个因素决定, 受错综复杂的网络信号传导途径调控。近年来, 在双子叶模式植物拟南芥中, 开花诱导研究取得了很大进展, 探明了控制开花诱导的4条主要途径(光周期途径、春化途径、自主途径和GA途径)及调控机制。研究也表明, 开花基因在拟南芥、水稻以及其他高等植物之间具有很高的保守性。文章对相关研究的最新进展作一综述, 并指出了目前研究中存在的问题及相应的研究对策。     

水稻SDG736抑制拟南芥FLC表达调控开花时间

130～150个氨基酸组成SET (Su (var) 3-9, Enhancer-of-zeste, Trithorax)结构域构成了组蛋白赖氨酸甲基转移酶特异性催化位点。SET结构域蛋白在进化上高度保守,广泛调控植物的生长发育。进化分析结果显示水稻SET结构域家族成员可分为7个不同的亚家族(KMT1, KMT2, KMT3, KMT6, KMT7, S-ET和RMT)。KMT3亚家族可能涉及开花调控或花的发育,其中包含5个拟南芥基因和5个水稻同源基因。拟南芥SDG4通过H3K4/K36甲基化的活性调控花发育,结果表明水稻同源基因SDG736超量表达,可促进拟南芥开花。对拟南芥开花途径相关的基因进行定量分析显示,超量表达的SDG736拟南芥植株中FLC基因表达量降低,而SCO1基因的表达量增加。     

模式植物拟南芥开花时间分子调控研究进展

植物从营养生长到生殖生长的转变是开花发育的关键,在合适的时间开花对植物的生长和繁衍极为重要,植物开花时间的调控对农业生产发展意义重大。植物开花是由遗传因子和环境因子协同调节的一个复杂过程。近年来,对不同植物开花调控的研究,特别是对模式植物拟南芥（Arabidopsis thaliana（L.） Heynh.）的开花调控研究取得了显著进展,已探明开花时间分子调控的6条主要途径分别是光周期途径、春化途径、自主途径、温度途径、赤霉素途径和年龄途径。各遗传调控途径既相互独立又相互联系,构成一个复杂的开花调控网络。本文综述了模式植物拟南芥开花时间调控分子机制相关研究的最新进展,并对未来的研究进行了展望。     

温度和光周期对水稻抽穗期调控的交互作用

光周期和温度是植物开花的2个关键的调控因素,植物成花转变决定于植物对光周期和温度变化的精确测量.作为短日照植物,水稻在长日低温条件下抽穗期推迟,为了阐明温度和光周期对水稻开花时间的调控效应,本文利用1个光周期不敏感的突变体及其野生型,系统地分析了不同温度和光周期处理条件下,调控水稻开花时间几个关键基因（Hd3a,RFT1,Ehd1,Ghd7,RID1/Ehd2/OsId1,Se5）的表达调控模式,结果表明Ehd1-Hd3a/RFT1通路在光周期和温度调控水稻开花途径中保守.Ehd1,Hd3a和RFT1的表达在低温（23℃）条件下急剧下降,表明Ehd1,Hd3a和RFT1表达阻抑是低温条件下水稻开花推迟的主要原因.另外,在长日照条件下,低温（23℃）处理促进了水稻开花抑制子Ghd7的表达,表明低温条件和长日照条件对Ghd7的表达具有协同作用.此外,本文还分析了Hd1与光周期开花调控途径中几个关键基因的调控关系,发现Hd1在长日照条件下负向调控Ehd1的表达而正向调控Ghd7的表达,表明在长日照条件下,Hd1-Ghd7-Ehd1-RFT1通路也是水稻抽穗期调控的一条重要途径.     

MADS-box基因控制植物成花的分子机理

植物花器官的发育和开花是植物生殖发育中最重要的过程,植物在长期的进化过程中产生了春化(低温)途径、自主途径、光周期途径以及不依赖于光温环境条件的赤霉素信号途径来适应多变的环境和调控植物开花过程。本文综述了模式植物拟南芥中由LEAFY(LFY)、CONSTANS(CO)、FLOWERING LOCUSC(FLC)、FLOW ERING LOCUS T(FT)和SUPPRESSOR OF OVEREXPRESSION OF CO1(SOC1)等基因构成的双子叶植物响应光温条件变化的开花调控网络;以及大麦、小麦中由VERNALIZATION1(VRN1)、VRN2、ODD-SOC2(OS2)和拟南芥CO、FT同源基因构成的禾本科植物开花调控网络。其中最重要的是转录调控因子MADS-box基因FLC、SOC1、VRN1和OS2,并发现组蛋白的乙酰化/脱乙酰化,赖氨酸的甲基化/脱甲基化在调控FLC、VRN1染色质活性状态及基因表达,从而产生开花控制的机理。这些研究发现将有助于对具有重要经济价值的单双子叶植物,通过生物技术手段改良其品种特性以应对非生物逆境,特别是低温胁迫的指导。     

Functional conservation and divergence of FVE genes that control flowering time and cold response in rice and Arabidopsis

Recent molecular and genetic studies in rice, a short-day plant, have elucidated both conservation and divergence of photoperiod pathway genes and their regulators. However, the biological roles of rice genes that act within the autonomous pathway are still largely unknown. In order to better understand the function of the autonomous pathway genes in rice, we conducted molecular genetic analyses of OsFVE, a rice gene homologous to Arabidopsis FVE. OsFVE was found to be ubiquitously expressed in vegetative and reproductive organs. Overexpression of OsFVE could rescue the flowering time phenotype of the Arabidopsis fve mutants by up-regulating expression of the SUPPRESSOR OF OVEREXPRESSION OF CO1 (SOC1) and down-regulating FLOWERING LOCUS C (FLC) expression. These results suggest that there may be a conserved function between OsFVE and FVE in the control of flowering time. However, OsFVE overexpression in the fve mutants did not rescue the flowering time phenotype in in relation to the response to intermittent cold treatment.     

Phloem transport of flowering signals

Seasonal variability in environmental parameters such as day length regulates many aspects of plant development. The transition from vegetative growth to flowering in Arabidopsis is regulated by seasonal changes in day length through a genetically defined molecular cascade known as the photoperiod pathway. Recent advances were made in understanding the tissues in which different components of the photoperiod pathway act to regulate floral induction. These studies highlighted the key role of the FT protein, which is produced in the leaves in response to inductive day lengths and traffics through the phloem to initiate flowering at the shoot apex. Unveiling the cellular and molecular details of this systemic signaling process will be required for a complete understanding of flowering regulation and other photoperiodic processes.     

Role of VIN3-LIKE 2 in facultative photoperiodic flowering response in Arabidopsis

In Arabidopsis, expression of FLC and FLC-related genes (collectively called FLC clade) contributes to flowering time in response to environmental changes, such as day length and temperature, by acting as floral repressors. VIN3 is required for vernalization-mediated FLC repression and a VIN3 related protein, VIN3-LIKE 1/VERNALIZATION 5 (VIL1/VRN5), acts to regulate FLC and FLM in response to vernalization.^1–3 VIN3 also exists as a small family of PHD finger proteins in Arabidopsis, including VIL1/VRN5, VIL2/VEL1, VIL3/VEL2 and VIL4/VEL3. We showed that the PHD finger protein, VIL2, is required for proper repression of MAF5, an FLC clade member, to accelerate flowering under non-inductive photoperiods. VIL2 acts together with POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) to repress MAF5 in a photoperiod dependent manner.Key words: photoperiod, chromatin, floweringThe decision to flower is critical to the survival of flowering plants. Thus, plants sense environmental cues to initiate floral transition at a time that both ensures and optimizes their own reproductive fitness. Using a model plant, Arabidopsis thaliana, genetic studies have shown that the regulation of floral transition mainly consists of four genetic pathways: the inductive photoperiod pathway, the autonomous pathway, the vernalization pathway and the gibberellin pathway.⁴ In Arabidopsis, these four flowering pathways eventually merge into a group of genes called floral integrators, including FLOWERING LOCUS T (FT), SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1 (SOC1) and LEAFY (LFY). Based on the response to specific photoperiod conditions, the flowering behaviors of plants can be classified into three groups: long day (LD), short day (SD) and day neutral response.^5,6 Depending on the requirement of day length, plants show either obligate or facultative responses. For example, henbane, carnation and ryegrass are obligate long day (LD) flowering plants which flower under increasing inductive photoperiod but do not flower at all under non-inductive photoperiod.⁵ On the other hand, plants including Arabidopsis, wheat, lettuce and barley, are considered to be facultative flowering plants. Thus, these plants exhibit early flowering under LD and late-flowering under non-inductive short days (SD). Studies on photoperiodic flowering time mainly focus on the inductive LD-photoperiod pathway in Arabidopsis.     

Photoperiod regulates flower meristem development in Arabidopsis thaliana

Photoperiod has been known to regulate flowering time in many plant species. In Arabidopsis, genes in the long day (LD) pathway detect photoperiod and promote flowering under LD. It was previously reported that clavata2 (clv2) mutants grown under short day (SD) conditions showed suppression of the flower meristem defects, namely the accumulation of stem cells and the resulting production of extra floral organs. Detailed analysis of this phenomenon presented here demonstrates that the suppression is a true photoperiodic response mediated by the inactivation of the LD pathway under SD. Inactivation of the LD pathway was sufficient to suppress the clv2 defects under LD, and activation of the LD pathway under SD conditions restored clv2 phenotypes. These results reveal a novel role of photoperiod in flower meristem development in Arabidopsis. Flower meristem defects of clv1 and clv3 mutants are also suppressed under SD, and 35S:CO enhanced the defects of clv3, indicating that the LD pathway works independently from the CLV genes. A model is proposed to explain the interactions between photoperiod and the CLV genes.     

Can a late bloomer become an early bird? Tools for flowering time adjustment

The transition from the vegetative to reproductive stage followed by inflorescence is a critical step in plant life; therefore, studies of the genes that influence flowering time have always been of great interest to scientists. Flowering is a process controlled by many genes interacting mutually in a genetic network, and several hypothesis and models of flowering have been suggested so far. Plants in temperate climatic conditions must respond mainly to changes in the day length (photoperiod) and unfavourable winter temperatures. To avoid flowering before winter, some plants exploit a specific mechanism called vernalization. This review summarises current achievements in the study of genes controlling flowering in the dicot model species thale cress (Arabidopsis thaliana), as well as in monocot model species rice (Oryza sativa) and temperate cereals such as barley (Hordeum vulgare L.) and wheat (Triticum aestivum L.). The control of flowering in crops is an attractive target for modern plant breeding efforts aiming to prepare locally well-adapted cultivars. The recent progress in genomics revealed the importance of minor-effect genes (QTLs) and natural allelic variation of genes for fine-tuning flowering and better cultivar adaptation. We briefly describe the up-to-date technologies and approaches that scientists may employ and we also indicate how these modern biotechnological tools and “-omics” can expand our knowledge of flowering in agronomically important crops.     

Independent control of gibberellin biosynthesis and flowering time by the circadian clock in Arabidopsis

Flowering of the facultative long-day plant Arabidopsis is controlled by several endogenous and environmental factors, among them gibberellins (GAs) and day length. The promotion of flowering by long days involves an endogenous clock that interacts with light cues provided by the environment. Light, and specifically photoperiod, is also known to regulate the biosynthesis of GAs, but the effects of GAs and photoperiod on flowering are at least partially separable. Here, we have used a short-period mutant, toc1, to investigate the role of the circadian clock in the control of flowering time by GAs and photoperiod. We show that toc1 affects expression of several floral regulators and a GA biosynthetic gene, but that these effects are independent.