小分子RNA在植物激素信号通路中的调控功能

植物激素是调控植物生长发育的信号分子。近年来的研究发现,小分子RNA作为基因表达调控网络的组分,参与植物激素信号途径,在植物生长发育和胁迫反应方面发挥重要作用。本文综述了miRNA和次级siRNA(Short interfering RNAs)介导的基因调控与植物激素信号通路相互作用的研究进展,主要包括生长素、赤霉素、油菜素内酯和脱落酸途径涉及的miRNA及其功能,并对不同发育过程中miRNA参与的不同激素信号通路的交叉和互作进行了讨论。     

《新发现的植物激素》书评

植物激素是植物体内合成的一批微量信号分子,通过整合不断变化的外界环境与内部发育信号,从分子、细胞、组织和器官水平上调控植物的生理生化反应和形态建成,确保植物正常的生长发育。近年来,有关植物激素作用机理的研究十分活跃,并在植物激素受体和信号转导途径等研究领域取得了重要进展,植物激素已由＂经典＂的5大类（生长素类、赤霉素类、     

油菜素内酯、赤霉素与光共同调控拟南芥的细胞伸长和光形态建成

在植物的生长发育过程中,植物激素发挥着重要的作用. 最新研究对油菜素内酯、赤霉素两类植物激素与光的信号通路共同调控植物的细胞伸长和光形态建成的分子机制给予了精确的阐述,这也为提高农作物产量提拱了理论基础.     

茉莉酸调控植物生长发育和胁迫的研究进展

植物作为不可移动的生物，感知外界刺激通过改变自身信号转导对其做出反应。植物激素作为重要的信号分子，在植物应对不同生物和非生物胁迫反应中发挥作用，以调节植物生长发育并适应不断变化的环境。茉莉酸是植物体内的重要激素之一，目前它的合成途径、生理作用等已有大量研究，但对其感知环境变化并做出反应的信号转导途径以及与其他植物激素的相互作用方面的研究还有空白之处。本文主要阐述茉莉酸在调控植物生长发育、胁迫应答及其与其他植物激素的相互作用方面的研究进展。     

植物荫蔽胁迫的激素信号响应

植物的生长发育与光信号密切相关, 外界光强、光质的变化会改变植物的生长发育状态。在自然或人工生态系统中, 植株个体的光环境往往会被其周围植物所影响, 导致荫蔽胁迫, 其主要表现为光合有效辐射以及红光与远红光比值(R:FR)降低。荫蔽胁迫对植物生长发育的多个时期均有影响, 如抑制种子萌发、促进幼苗下胚轴伸长及促进植物花期提前等, 这对农业生产不利, 会导致作物产量以及品质的降低。植物激素是调控植物生长发育的关键内源因子。大量研究表明, 生长素(IAA)、赤霉素(GA)及油菜素甾醇(BR)等植物激素均参与介导植物的荫蔽胁迫响应。当植物处于荫蔽胁迫时, 光信号的改变会影响植物激素的合成及信号转导。不同植物激素对荫蔽胁迫的响应各不相同, 但其信号通路之间却存在互作关系, 从而形成复杂的网络状调控路径。该文总结了几种主要植物激素(生长素、赤霉素、油菜素甾醇及乙烯)响应荫蔽胁迫的机理, 重点论述了荫蔽胁迫对植物激素合成及信号通路的影响, 以及植物激素调控荫蔽胁迫下植物生长的分子机理, 并对未来潜在的研究热点进行了分析。     

脱落调节物质对植物器官脱落的调控

器官脱落是植物生命过程中重要的生理现象.植物体内的许多激素和非激素类物质(扩展蛋白、H_2O_2、细胞壁水解酶等)都参与脱落过程的调控,而且是相互协同配合,共同发挥作用.本文综述了生长素、乙烯、脱落酸、赤霉素和茉莉酸等植物激素,以及非激素类物质扩展蛋白、H_2O_2和两种主要的细胞壁水解酶(纤维素酶和多聚半乳糖醛酸酶)在植物器官脱落过程中的调控作用,并对它们在植物器官脱落调控中的相互作用进行分析,以期为相关研究提供信息.     

高等植物赤霉素代谢及其信号转导通路

赤霉素是一类重要的植物激素,对植物的生长发育,如种子的萌发、茎的延展、叶片的生长、休眠芽的萌发以及植物的花和种子的发育等生理具有重要的调控作用。从1926年被发现至今,阐明了赤霉素代谢机理及调控机制,明确了赤霉素在植物体内的信号转导途径。本文综述了赤霉素的生物合成途径及其平衡的调节;赤霉素受体GID1、DELLA蛋白在赤霉素信号转导途径中的作用及相关研究;泛素介导的DELLA蛋白降解在赤霉素信号转导中的研究进展。     

高等植物赤霉素生物合成及其信号转导途径

赤霉素是一种重要的植物激素,调节植物生长和发育的各个阶段,如促进种子萌发、茎杆伸长、叶片展开、花的发生及果实与种子的发育。综述了赤霉素合成、信号转导途径、与其他植物激素间的相互作用、对环境信号的响应以及DELLA泛素化降解过程的研究进展,这将有助于人们对赤霉素生理作用和分子调节机制的了解,有利于对赤霉素各方面的机理进行深入地研究。     

受赤霉素调节的拟南芥F-box基因筛选分析

赤霉素(Gibberellins,GAs)作为一种植物激素,对植物的生长发育具有重要调控作用,但其作用机制有待进一步完善。F-box蛋白是SCF复合体的一个亚基,通过特异性识别底物来调控植物的生长发育。本研究采用生物信息学方法,通过分析拟南芥基因芯片数据库提供的数据筛选到38个受GA调节的候选F-box基因,并对其中6个基因进行了实时荧光定量PCR验证。Plant CARE分析显示,其中30个基因的启动子区具有GA响应元件、以及IAA、ABA、光、温度干旱胁迫、或生物钟相关的顺式作用元件。通过分析Bio Grid数据库提供的相互作用对象,发现其中18个候选F-box蛋白与GA2ox1,GA3ox1和GA3ox3具有相互作用关系。基因表达谱分析表明,这些候选F-box基因在拟南芥各个组织器官中都有不同程度的表达,对IAA、ABA、光、温度干旱等胁迫或不同光周期都具有一定的响应。为深入研究GA调控植物生长发育的分子机制提供了重要线索。     

植物非经典生长素信号转导通路解析

植物激素生长素参与调控植物生长发育的各个过程,包括胚胎发育、器官发生和向性运动等。植物通过协调生长素的合成代谢、极性运输以及信号转导来实现对不同生长发育过程的精准调控。生长素的功能依赖于其信号被感知后经由信号转导通路转换为下游复杂多样的反应。经典的生长素信号转导通路阐明了细胞核内从SCF~(TIR1/AFB)受体到Aux/IAA蛋白的泛素化降解最终通过ARF转录因子调控基因转录的完整生长素响应过程。该核内信号通路揭示了生长素转录调控生长发育的诸多分子机制,但植物生长发育调控过程中仍有许多生长素响应过程无法通过该经典信号通路解析。重点阐述生长素非经典信号通路的调控机制及其对植物生长发育的重要作用,并讨论和展望生长素非经典信号通路研究目前所面临的挑战以及研究前景。     

Gibberellic acid in plant: Still a mystery unresolved

Gibberellic acid (GA), a plant hormone stimulating plant growth and development, is a tetracyclic di-terpenoid compound. GAs stimulate seed germination, trigger transitions from meristem to shoot growth, juvenile to adult leaf stage, vegetative to flowering, determines sex expression and grain development along with an interaction of different environmental factors viz., light, temperature and water. The major site of bioactive GA is stamens that influence male flower production and pedicel growth. However, this opens up the question of how female flowers regulate growth and development, since regulatory mechanisms/organs other than those in male flowers are mandatory. Although GAs are thought to act occasionally like paracrine signals do, it is still a mystery to understand the GA biosynthesis and its movement. It has not yet confirmed the appropriate site of bioactive GA in plants or which tissues targeted by bioactive GAs to initiate their action. Presently, it is a great challenge for scientific community to understand the appropriate mechanism of GA movement in plant’s growth, floral development, sex expression, grain development and seed germination. The appropriate elucidation of GA transport mechanism is essential for the survival of plant species and successful crop production.     

Evolutionarilv Conserved DELLA-mediated Gibberellin Signaling in Plants

Gibberellins (GAs) play important roles in many essential plant growth and development processes. A family of nuclear growth-repressing DELLA proteins is the key component in GA signaling. GA perception is mediated by GID1, and the key event of GA signaling is the degradation of DELLA proteins via the 26S proteasome pathway. DELLA proteins integrating other plant hormones signaling and environmental cue modulating plant growth and development have been revealed. GA turning on the de-DELLA-repressing system is conserved, and independently establishes step-by-step recruitment of GAstimulated GID1-DELLA interaction and DELLA growth-repression functions during land plant evolution. These discoveries open new prospects for the understanding of GA action and DELLA-mediated signaling in plants.     

Evolutionarily conserved DELLA-mediated gibberellin signaling in plants

Gibberellins (GAs) play important roles in many essential plant growth and development processes. A family of nuclear growth-repressing DELLA proteins is the key component in GA signaling. GA perception is mediated by GID1, and the key event of GA signaling is the degradation of DELLA proteins via the 26S proteasome pathway. DELLA proteins integrating other plant hormones signaling and environmental cue modulating plant growth and development have been revealed. GA turning on the de-DELLA-repressing system is conserved, and independently establishes step-by-step recruitment of GA-stimulated GID1-DELLA interaction and DELLA growth-repression functions during land plant evolution. These discoveries open new prospects for the understanding of GA action and DELLA-mediated signaling in plants.     

StGA2ox1 is induced prior to stolon swelling and controls GA levels during potato tuber development

The formation and growth of a potato ( Solanum tuberosum ) tuber is a complex process regulated by different environmental signals and plant hormones. In particular, the action of gibberellins (GAs) has been implicated in different aspects of potato tuber formation. Here we report on the isolation and functional analysis of a potato GA 2-oxidase gene ( StGA2ox1 ) and its role in tuber formation. StGA2ox1 is upregulated during the early stages of potato tuber development prior to visible swelling and is predominantly expressed in the subapical region of the stolon and growing tuber. 35S-over-expression transformants exhibit a dwarf phenotype, reduced stolon growth and earlier in vitro tuberization. Transgenic plants with reduced expression levels of StGA2ox1 showed normal plant growth, an altered stolon swelling phenotype and delayed in vitro tuberization. Tubers of the StGA2ox1 suppression clones contain increased levels of GA₂₀, indicating altered GA metabolism. We propose a role for StGA2ox1 in early tuber initiation by modifying GA levels in the subapical stolon region at the onset of tuberization, thereby facilitating normal tuber development and growth.     

高等植物赤霉素2-氧化酶基因的克隆、表达及其调控

赤霉素(GA)是一类重要的植物激素,对高等植物整个生命周期的生长发育起关键作用。调控赤霉素生物合成和代谢途径中的关键酶基因的表达可以控制植物体内赤霉素的含量。GA2-氧化酶是调节赤霉素合成和代谢的关键酶之一,使活性GA失活。本文主要对GA2-氧化酶基因的克隆、表达调控及其在植物基因工程中的应用等方面进行综述,为通过基因工程技术调控植物体内活性赤霉素的含量从而得到改良品种提供思路。     

Gibberellin biosynthesis: its regulation by endogenous and environmental signals

The hormone gibberellin (GA) plays an essential role in many aspects of plant growth and development, such as seed germination, stem elongation and flower development. In recent years, exciting progress has been made in understanding how the biosynthesis of this hormone is regulated by endogenous and environmental factors. This has resulted from isolation of genes encoding enzymes involved in GA biosynthesis and metabolism, which also enabled us to manipulate the pathway by modifying the expression of these genes in transgenic plants. In addition, new GA response mutants provided information about how signaling components are involved in feedback regulation of the GA biosynthetic pathway.     

Tall or short? Slender or thick? A plant strategy for regulating elongation growth of roots by low concentrations of gibberellin

Background

Since the plant hormone gibberellin (GA) was discovered as a fungal toxin that caused abnormal elongation of rice shoots, the physiological function of GA has mainly been investigated in relation to the regulation of plant height. However, an indispensable role for GA in root growth has been elucidated by using severely GA-depleted plants, either with a gene mutation in GA biosynthesis or which have been treated by an inhibitor of GA biosynthesis. The molecular sequence of GA signalling has also been studied to understand GA functions in root growth.

Scope

This review addresses research progress on the physiological functions of GA in root growth. Concentration-dependent stimulation of elongation growth by GA is important for the regulation of plant height and root length. Thus the endogenous level of GA and/or the GA sensitivity of shoots and roots plays a role in determining the shoot-to-root ratio of the plant body. Since the shoot-to-root ratio is an important parameter for agricultural production, control of GA production and GA sensitivity may provide a strategy for improving agricultural productivity. The sequence of GA signal transduction has recently been unveiled, and some component molecules are suggested as candidate in planta regulatory sites and as points for the artificial manipulation of GA-mediated growth control.

Conclusions

This paper reviews: (1) the breakthrough dose–response experiments that show that root growth is regulated by GA in a lower concentration range than is required for shoot growth; (2) research on the regulation of GA biosynthesis pathways that are known predominantly to control shoot growth; and (3) recent research on GA signalling pathways, including GA receptors, which have been suggested to participate in GA-mediated growth regulation. This provides useful information to suggest a possible strategy for the selective control of shoot and root growth, and to explain how GA plays a role in rosette and liana plants with tall or short, and slender or thick axial organs.