Ethylene hormone receptor action in Arabidopsis.

Small gaseous molecules play important roles in biological signaling in both animal and plant physiology. The hydrocarbon gas ethylene has long been known to regulate diverse aspects of plant growth and development, including fruit ripening, leaf senescence and flower abscission. Recent progress has been made toward identifying components involved in ethylene signal transduction in the plant Arabidopsis thaliana. Ethylene is perceived by five receptors that have similarity to two-component signaling proteins. The hydrophobic amino-terminus of the receptors binds ethylene, and mutations in this domain both prevent ethylene binding and confer ethylene insensitivity to the plant; the carboxyl-terminal portion of the receptors has similarity to bacterial his tidine protein kinases. Genetic data suggest a model in which ethylene binding inhibits receptor signaling, yet precisely how these receptors function is unclear. Two of the receptors have been found to associate with a negative regulator of ethylene responses called CTR1, which appears to be a mitogen-activated protein kinase (MAPK) kinase kinase.     

Comparison of phytohormone signaling mechanisms

Plant hormones are crucial signaling molecules that coordinate all aspects of plant growth, development and defense. A great deal of attention has been attracted from biologists to study the molecular mechanisms for perception and signal transduction of plant hormones during the last two decades. Tremendous progress has been made in identifying receptors and key signaling components of plant hormones. The holistic picture of hormone signaling pathways is extremely complicated, this review will give a general overview of perception and signal transduction mechanisms of auxin, gibberellin, cytokinin, abscisic acid, ethylene, brassinosteroid, and jasmonate.     

VOCs-mediated hormonal signaling and crosstalk with plant growth promoting microbes

In the natural environment, plants communicate with various microorganisms (pathogenic or beneficial) and exhibit differential responses. In recent years, research on microbial volatile compounds (MVCs) has revealed them to be simple, effective and efficient groups of compounds that modulate plant growth and developmental processes. They also interfere with the signaling process. Different MVCs have been shown to promote plant growth via improved photosynthesis rates, increased plant resistance to pathogens, activated phytohormone signaling pathways, or, in some cases, inhibit plant growth, leading to death. Regardless of these exhibited roles, the molecules responsible, the underlying mechanisms, and induced specific metabolic/molecular changes are not fully understood. Here, we review current knowledge on the effects of MVCs on plants, with particular emphasis on their modulation of the salicylic acid, jasmonic acid/ethylene, and auxin signaling pathways. Additionally, opportunities for further research and potential practical applications presented.     

Perspective of plant growth promoting rhizobacteria (PGPR) containing ACC deaminase in stress agriculture

Ethylene is a gaseous plant growth hormone produced endogenously by almost all plants. It is also produced in soil through a variety of biotic and abiotic mechanisms, and plays a key role in inducing multifarious physiological changes in plants at molecular level. Apart from being a plant growth regulator, ethylene has also been established as a stress hormone. Under stress conditions like those generated by salinity, drought, waterlogging, heavy metals and pathogenicity, the endogenous production of ethylene is accelerated substantially which adversely affects the root growth and consequently the growth of the plant as a whole. Certain plant growth promoting rhizobacteria (PGPR) contain a vital enzyme, 1-aminocyclopropane-1-carboxylate (ACC) deaminase, which regulates ethylene production by metabolizing ACC (an immediate precursor of ethylene biosynthesis in higher plants) into α-ketobutyrate and ammonia. Inoculation with PGPR containing ACC deaminase activity could be helpful in sustaining plant growth and development under stress conditions by reducing stress-induced ethylene production. Lately, efforts have been made to introduce ACC deaminase genes into plants to regulate ethylene level in the plants for optimum growth, particularly under stressed conditions. In this review, the primary focus is on giving account of all aspects of PGPR containing ACC deaminase regarding alleviation of impact of both biotic and abiotic stresses onto plants and of recent trends in terms of introduction of ACC deaminase genes into plant and microbial species.     

Chemical root to shoot signaling under drought

Chemical signals are important for plant adaptation to water stress. As soils become dry, root-sourced signals are transported via the xylem to leaves and result in reduced water loss and decreased leaf growth. The presence of chemical signals in xylem sap is accepted, but the identity of these signals is controversial. Abscisic acid (ABA), pH, cytokinins, a precursor of ethylene, malate and other unidentified factors have all been implicated in root to shoot signaling under drought. This review describes current knowledge of, and advances in, research on chemical signals that are sent from roots under drought. The contribution of these different potential signals is discussed within the context of their role in stress signaling.     

植物激素乙烯作用机制的最新进展

气体植物激素乙烯在植物生长发育及应对胁迫的防御反应中起重要调控作用．通过20多年的研究,利用模式植物拟南芥,勾画出一条自内质网膜受体至细胞核内转录因子的线性乙烯信号转导通路．本文概述了研究乙烯信号转导的方法及乙烯信号转导的基本过程;阐述了最新发现的乙烯信号从内质网膜传递到细胞核的分子机制,即原本定位于内质网膜上的EIN2蛋白其C端被剪切之后进入细胞核,然后通过抑制EBF1／2而稳定转录因子EIN3／EIL1;根据最近多个小组报道EIN3／EIL1直接调控除乙烯响应基因之外的其他生物学过程相关基因,提出了EIN3／EIL1可以作为网络节点整合多条信号通路的新观点;通过分析不同信号通路调控EIN3／EIL1的方式,发现不仅EIN3／EIL1的蛋白稳定性受到调控,而且其转录活性还受到诸如JAZ,DELLA等转录调节因子的调控．本文展望了未来乙烯信号转导通路的研究方向与研究热点．     

乙烯的生物合成与信号传递

乙烯是气体植物激素, 它在植物的生长发育过程中有很多作用。所以了解乙烯的生物合成及其信号转导是非常重要的。二十年来, 通过筛选有异于正常三重反应的突变体, 人们发现了乙烯信号转导的粗略轮廓。在拟南芥中, 有5个受体蛋白感受乙烯, ETR1、ERS1、ETR2、ERS2、EIN4。它们表现出功能冗余, 是乙烯信号的负调控因子, 在植物体内以二聚体的形式存在。ETR1的N端与乙烯结合时需要 铜离子(Ⅰ)的参与。尽管已经发现ETR1有组氨酸激酶活性, 而其它受体有丝氨酸/苏氨酸激酶活性, 但受体参与乙烯信号转导的机制还不是很清楚。受体与Raf类蛋白激酶CTR1相互作用, CTR1是乙烯反应的负调控因子。CTR1蛋白失活使EIN2蛋白活化。EIN2的N端是跨膜结构域, 与Nramp家族金属离子转运蛋白的跨膜结构域类似。EIN2的C端是一个新的未知结构域, 与乙烯信号途径的下游组分相互作用。EIN3位于EIN2的下游, EIN3和EILs诱导ERF1和其它转录因子的表达, 这些转录因子依次激活乙烯反应目的基因的表达, 表现出乙烯的反应。EIN3受到蛋白酶体介导的蛋白降解途径的调节。由于乙烯是一种多功能的植物激素, 其信号途径与其它信号途径有多重的交叉。     

Ethylene in vegetative development: a tale with a riddle

The vegetative development of plants is strongly dependent on the action of phytohormones. For over a century, the effects of ethylene on plants have been studied, illustrating the profound impact of this gaseous hormone on plant growth, development and stress responses. Ethylene signaling is under tight self-control at various levels. Feedback regulation occurs on both biosynthesis and signaling. For its role in developmental processes, ethylene has a close and reciprocal relation with auxin, another major determinant of plant architecture. Here, we discuss, in view of novel findings mainly in the reference plant Arabidopsis, how ethylene is distributed and perceived throughout the plant at the organ, tissue and cellular levels, and reflect on how plants benefit from the complex interaction of ethylene and auxin, determining their shape. Furthermore, we elaborate on the implications of recent discoveries on the control of ethylene signaling.     

Deciphering the Role of Ethylene in Plant–Herbivore Interactions

Most plants emit ethylene in response to herbivory by insects from many different feeding guilds. The elicitors of these ethylene emissions are thought to be microorganisms or oral secretion-specific compounds that are transferred when the attacking insect feeds. To find the receptors for these elicitors and describe the signaling cascades that are subsequently activated will be the challenge of future research. Past experiments on the function of herbivore-induced ethylene, which were biased toward the use of chemical treatments to manipulate ethylene, identified seven ethylene-dependent defense responses. In contrast, a genetic toolbox that consists of several mutants has rarely been used and to date, mutants have helped to identify only one additional ethylene-dependent defense response. Ethylene-dependent responses include the emission of specific volatile organic compounds as indirect defense, the accumulation of phenolic compounds, and proteinase inhibitor activity. Besides being ethylene regulated, these defenses depend strongly on the wound-hormone jasmonic acid (JA). That ethylene requires the concomitant induction of JA, or other signals, appears to be decisive. Rather than being the principal elicitor of defense responses, ethylene modulates the sensitivity to a second signal and its downstream responses. Given this modulator role, and the artifacts associated with the use of chemical treatments to manipulate ethylene production and perception, future advances in the study of ethylene’s function in plant–herbivore interactions will likely come from the use of signaling mutants or transgenic plants. It will be exciting to see if adaptive phenotypic plasticity is largely an ethylene-mediated response.     

Studies on plant growth-regulating substances: XXXV. Ethylene production by coleoptiles treated with auxin-type chemicals

Wheat coleoptile sections were treated with a range of auxins and with compounds of related chemical structure which do not exhibit auxin properties. Methods used for measuring the rates of elongation and ethylene evolution of these sections are described. Ethylene was evolved some time after elongation in all cases and increased ethylene production occurred only with compounds showing auxin activity. The results indicate that ethylene evolution was related exponentially to growth. Simultaneous applications of mannitol and 2, 4-dichloro-phenoxyacetic acid (2, 4-D) to wheat sections markedly reduced ethylene evolution compared with the 2, 4-D controls, even though the level of 2, 4-D in the tissue apparently remained unchanged. Ethylene significantly inhibited the elongation of wheat coleoptile sections, and it is suggested that ethylene is a natural plant growth inhibitor which becomes mobilised to limit excessive growth.     

拟南芥乙烯信号传递途径

植物激素乙烯早在一百多年前就已经被确认,相关的研究使得乙烯广泛地被应用于农业上.一直到十年前第一个植物激素乙烯受体拟南芥ETR1基因被发现之后,人们对于乙烯信号传递的研究并才真正开始有所突破.以遗传学为基础对乙烯反应突变体所做的分析,使得乙烯信号传递已经成为目前植物信号传递领域中被研究得最清楚的信号传递途径之一.该文着重于回顾乙烯信号传递途径上各个元件的发现和确认,以及如何利用遗传学的方法将现有的突变体相关基因构建出目前广为接受的信号传递的遗传模式.最后,该文就目前所知的乙烯信号传递理论及相关研究,做了总结和深入的讨论.     

生长素与乙烯信号途径及其相互关系研究进展

长期的研究表明,生长素在调节植物生长发育的各种生理活动中起关键作用,但对它如何调控这些生理活动却缺乏系统和深入的了解。最近,细胞核内生长素信号途径的发现为揭示其作用机制带来了曙光。乙烯参与果实成熟及植物对逆境的反应等生理活动,其信号途径也已得到部分阐明。越来越多的证据表明,乙烯的作用与生长素对植物生长发育的调控之间有密切的联系。该文概述了生长素与乙烯信号途径的研究进展及其相互关系,讨论了生长素在植物三重反应中的作用;并对生长素与乙烯相互关系研究中存在的问题及研究前景进行了探讨。     

Recent advances in ABA signaling

Abscisic acid (ABA) is a major plant hormone that controls germination, seedling growth, and seed development. During the vegetative phase, ABA plays a key regulatory role in adaptive responses to common abiotic stresses, such as drought, high salinity, and cold. In seeds, ABA modulates the synthesis of storage components and prevents the precocious germination of embryos. ABA-regulated processes are critical for plant growth and survival, especially under unfavorable environmental conditions. Numerous genetic and biochemical studies to delineate signal transduction pathways have led to the identification of a large number of ABA signaling components. However, our knowledge about specific response pathways is still fragmentary. Over the past several years, significant progress has been made in identifying key regulators of early events in the ABA response. In this short review, new advances in ABA signaling research, especially those focused on ABA receptors, will be summarized.     

Signal transmission in the plant immune response

Genetic and biochemical dissection of signaling pathways regulating plant pathogen defense has revealed remarkable similarities with the innate immune system of mammals and Drosophila. Numerous plant proteins resembling eukaryotic receptors have been implicated in the perception of pathogen-derived signal molecules. Receptor-mediated changes in levels of free calcium in the cytoplasm and production of reactive oxygen species and nitric oxide constitute early events generally observed in plant-pathogen interactions. Positive and negative regulation of plant pathogen defense responses has been attributed to mitogen-activated protein kinase cascades. In addition, salicylic acid, jasmonic acid and ethylene are components of signaling networks that provide the molecular basis for specificity of plant defense responses. This article reviews recent advances in our understanding of early signaling events involved in the establishment of plant disease resistance.     

Use of plant growth-promoting rhizobacteria to control stress responses of plant roots

Ethylene is a key gaseous hormone that controls various physiological processes in plants including growth, senescence, fruit ripening, and responses to abiotic and biotic stresses. In spite of some of these positive effects, the gas usually inhibits plant growth. While chemical fertilizers help plants grow better by providing soil-limited nutrients such as nitrogen and phosphate, over-usage often results in growth inhibition by soil contamination and subsequent stress responses in plants. Therefore, controlling ethylene production in plants becomes one of the attractive challenges to increase crop yields. Some soil bacteria among plant growth-promoting rhizobacteria (PGPRs) can stimulate plant growth even under stressful conditions by reducing ethylene levels in plants, hence the term “stress controllers” for these bacteria. Thus, manipulation of relevant genes or gene products might not only help clear polluted soil of contaminants but contribute to elevating the crop productivity. In this article, the beneficial soil bacteria and the mechanisms of reduced ethylene production in plants by stress controllers are discussed.     

生长素与乙烯信号途径及其相互关系研究进展

长期的研究表明, 生长素在调节植物生长发育的各种生理活动中起关键作用, 但对它如何调控这些生理活动却缺乏系统和深入的了解。最近, 细胞核内生长素信号途径的发现为揭示其作用机制带来了曙光。乙烯参与果实成熟及植物对逆境的反应等生理活动, 其信号途径也已得到部分阐明。越来越多的证据表明, 乙烯的作用与生长素对植物生长发育的调控之间有密切的联系。该文概述了生长素与乙烯信号途径的研究进展及其相互关系, 讨论了生长素在植物三重反应中的作用; 并对生长素与乙烯相互关系研究中存在的问题及研究前景进行了探讨。