Plant hormones and plant growth regulators in plant tissue culture

Summary This is a short review of the classical and new, natural and synthetic plant hormones and growth regulators (phytohormones) and highlights some of their uses in plant tissue culture. Plant hormones rarely act alone, and for most processes— at least those that are observed at the organ level—many of these regulators have interacted in order to produce the final effect. The following substances are discussed: (a) Classical plant hormones (auxins, cytokinins, gibberellins, abscisic acid, ethylene and growth regulatory substances with similar biological effects. New, naturally occurring substances in these categories are still being discovered. At the same time, novel structurally related compounds are constantly being synthesized. There are also many new but chemically unrelated compounds with similar hormone-like activity being produced. A better knowledge of the uptake, transport, metabolism, and mode of action of phytohormones and the appearance of chemicals that inhibit synthesis, transport, and action of the native plant hormones has increased our knowledge of the role of these hormones in growth and development. (b) More recently discovered natural growth substances that have phytohormonal-like regulatory roles (polyamines, oligosaccharins, salicylates, jasmonates, sterols, brassinosteroids, dehydrodiconiferyl alcohol glucosides, turgorins, systemin, unrelated natural stimulators and inhibitors), as well as myoinositol. Many of these growth active substances have not yet been examined in relation to growth and organized developmentin vitro.     

植物激素在苔藓生长发育与逆境响应过程中的作用机制研究进展

植物激素是由植物自身代谢产生的一类从产生部位移动到作用部位发挥调控功能的微量小分子有机物质,在植物生长发育、响应环境胁迫过程中起到关键作用.苔藓植物作为早期登陆的非维管植物,处于陆生植物进化早期的阶段,具有许多不同于维管植物的形态和生理特征.大部分苔藓中普遍存在8种主要的植物激素及其衍生物(包括ABA、JA、ET、SA...     

Hormones and hormone-like substances of microorganisms: A review

Data from the literature on the ability of microorganisms to form plant hormones have been reviewed. The substances covered include abscisic acid, ethylene and other compounds with phytohormone-like properties (brassinosteroids, oligosaccharines) and analogues of animal neurotransmitters (biogenic amines). Pathways whereby the substances are metabolized and their effects on the development and activity (physiological and biochemical) of the microorganisms are considered. The role of phytohormones and hormone-like substances in the formation of association (microorganism-host) interactions are analyzed. The potential utilities of microorganisms producing hormones and hormone-like substances are discussed.     

Hormones and hormone-like substances of microorganisms: a review

Data from the literature on the ability of microorganisms to form plant hormones have been reviewed. The substances covered include abscisic acid, ethylene and other compounds with phytohormone-like properties (brassinosteroids, oligosaccharines) and analogues of animal neurotransmitters (biogenic amines). Pathways whereby the substances are metabolized and their effects on the development and activity (physiological and biochemical) of the microorganisms are considered. The role of phytohormones and hormone-like substances in the formation of association (microorganism-host) interactions are analyzed. The potential utilities of microorganisms producing hormones and hormone-like substances are discussed.     

Conjugates of auxin and cytokinin

Plant growth and developmental processes as well as environmental responses require the action and cross talk of phytohormones including auxins and cytokinins. Active phytohormones are changed into multiple forms by acylation, esterification or glycosylation, for example. It seems that conjugated compounds could serve as pool of inactive phytohormones that can be converted to active forms by de-conjugation reactions. The concept of reversible conjugation of auxins and cytokinins suggests that under changeable environmental, developmental or physiological conditions these compounds can be a source of free hormones. Phytohormones metabolism may result in a loss of activity and decrease the size of the bioactive pool. All metabolic steps are in principle irreversible, except for some processes such as the formation of ester, glucoside and amide conjugates, where the free compound can be liberated by enzymatic hydrolysis. The role, chemistry, synthesis and hydrolysis of conjugated forms of two classes of plant hormones are discussed.     

Extracellular ATP and other nucleotides—ubiquitous triggers of intercellular messenger release

Extracellular nucleotides, and ATP in particular, are cellular signal substances involved in the control of numerous (patho)physiological mechanisms. They provoke nucleotide receptor-mediated mechanisms in select target cells. But nucleotides can considerably expand their range of action. They function as primary messengers in intercellular communication by stimulating the release of other extracellular messenger substances. These in turn activate additional cellular mechanisms through their own receptors. While this applies also to other extracellular messengers, its omnipresence in the vertebrate organism is an outstanding feature of nucleotide signaling. Intercellular messenger substances released by nucleotides include neurotransmitters, hormones, growth factors, a considerable variety of other proteins including enzymes, numerous cytokines, lipid mediators, nitric oxide, and reactive oxygen species. Moreover, nucleotides activate or co-activate growth factor receptors. In the case of hormone release, the initially paracrine or autocrine nucleotide-mediated signal spreads through to the entire organism. The examples highlighted in this commentary suggest that acting as ubiquitous triggers of intercellular messenger release is one of the major functional roles of extracellular nucleotides. While initiation of messenger release by nucleotides has been unraveled in many contexts, it may have been overlooked in others. It can be anticipated that additional nucleotide-driven messenger functions will be uncovered with relevance for both understanding physiology and development of therapy.     

Changing concepts in plant hormone action

Summary A plant hormone is not, in the classic animal sense, a chemical synthesized in one organ, transported to a second organ to exert a chemical action to control a physiological event. Any phytohormone can be synthesized everywhere and can influence different growth and development processes at different places. The concept of physiological activity under hormonal control cannot be dissociated from changes in concentrations at the site of action, from spatial differences and changes in the tissue's sensitivity to the compound, from its transport and its metabolism, from balances and interactions with the other phytohormones, or in their metabolic relationships, and in their signaling pathways as well. Secondary messengers are also involved. Hormonal involvement in physiological processes can appear through several distinct manifestations (as environmental sensors, homeostatic regulators and spatio-temporal synchronizers, resource allocators, biotime adjusters, etc.), dependent on or integrated with the primary biochemical pathways. The time has also passed for the hypothesized ‘specific’ developmental hormones, rhizocaline, canlocaline, and florigen: root, stem, and flower formation result from a sequential control of specific events at the right places through a coordinated control by electrical signals, the known phytohormones and nonspecific molecules of primary and secondary metabolism, and involve both cytoplasmic and apoplastic compartments. These contemporary views are examined in this review.     

种子休眠与破眠机理研究进展

种子休眠机理主要围绕透性、抑制剂作用和光敏素转化等方面的研究而建立。种皮的阻碍作用可能是由于种皮的物理或化学特性引起．可导致对水、光、气体或溶质的透性改变。抑制剂作用机理是抑制物质可抵消促进细胞分裂和生长发育的激素的作用。光敏素转化机理来源于与休眠有关的生物活性化学物质的合成、活化或破坏受光诱导的观点,由于发现了光敏素蓝色蛋白的活化型（Pfr）和钝化型（Pr）而得到强有力的支持,种子光休眠取决于光敏素蓝色蛋白的活化型（Pfr）含量和Pfr／（Pr＋Pfr）比值。目前,打破休眠的方法一般有机械破皮法、激素处理法、分子生物学技术法、物理处理法（如激光、烟、热等处理技术）、CO2处理法等。激素的平衡由抑制剂占优势向促进物占优势的变化是打破休眠的决定因素。研究破眠机理的分子生物学技术有多种,包括ABA突变体的利用、分子标记、转基因技术、用反义RAN阻止基因的表达、cDNA克隆技术等。用激光照射种子,把适宜的光射入细胞,可增加细胞生物能,促进种子发育,从而可能打破休眠。热处理的机理是由于加热可以增加种皮的透气性。CO2之所以能提高某些物种的萌发率,在于其影响了种子内部乙烯的敏感性。     

Physiology and molecular mode of action of brassinosteroids

Brassinosteroids (BRs) comprise a group of polyhydroxysteroids, which show close structural similarity to steroid hormones from arthropods and mammals. BRs are now accepted as a new class of phytohormones due to their ubiquitous occurrence in plants, their highly effective elicitation of various responses and the identification of mutants defective in BR-biosynthesis or -response. Important steps of BR-biosynthesis were elucidated with precursor-feeding experiments and by the analysis of BR-biosynthesis-deficient mutants. The altered phenotypes of these mutants, particularly in Arabidopsis, revealed the essential nature of BRs for normal growth and development. A major role of BRs is the positive regulation of cell expansion. Furthermore, BRs modulate plant responses to biotic and abiotic stresses and to other phytohormones, and influence differentiation processes of cells and tissues. BR-insensitive mutants such as bri1 hold the potential for uncovering BR-signalling pathway(s) at the molecular level. The identification of BR-regulated genes demonstrates a genetic basis for BR mode of action with reference to their multiple effects. This review focuses on the relevance of BRs to the control of various physiological processes, BR-signalling and underlying molecular mechanisms by considering known mutants.     

Modern aspects of studying phytohormones. Cytokinins

The review presents current data on mechanisms of cytokinin action in plants. By analogy with the first part (Ivanova et al., 1999), in which general principles of phytohormone action and cardinal trends of phytohormone investigations were examined, here the relevant information on mechanisms of action of auxins and gibberellins has been given, and taking cytokines as example an attempt has been done to summarize the literature data on the number of questions offered for analysing hormones of high animals (Gudwin, Merser, 1986). The review demonstrates that mechanisms of cytokine action at the cellular level are not known in many cases. One of the most significant factors in the action of phytohormones of this class on plants is their concentration, determined by their synthesis, transportation and further chemical conversions. This paper points to a poor knowledge of the relative role of these processes in regulation of cytokinin contents and their distribution among plant organs. Two possible ways of studying cytokinin action at the present day stage of investigations have been designated: 1) revealing the cytokinin expressed genes and establishing mechanisms of their action; 2) estimation of endogenous cytokinin alteration and the influence of this alteration on definite processes in the cell with the help of ipt-gene from t-DNA of Agrobacterium tumefaciens.     

Molecular Aspects of MicroRNAs and Phytohormonal Signaling in Response to Drought Stress: A Review

Phytohormones play an essential role in plant growth and development in response to environmental stresses. However, plant hormones require a complex signaling network combined with other signaling pathways to perform their proper functions. Thus, multiple phytohormonal signaling pathways are a prerequisite for understanding plant defense mechanism against stressful conditions. MicroRNAs (miRNAs) are master regulators of eukaryotic gene expression and are also influenced by a wide range of plant development events by suppressing their target genes. In recent decades, the mechanisms of phytohormone biosynthesis, signaling, pathways of miRNA biosynthesis and regulation were profoundly characterized. Recent findings have shown that miRNAs and plant hormones are integrated with the regulation of environmental stress. miRNAs target several components of phytohormone pathways, and plant hormones also regulate the expression of miRNAs or their target genes inversely. In this article, recent developments related to molecular linkages between miRNAs and phytohormones were reviewed, focusing on drought stress.     

The role of phytohormone signaling in ozone-induced cell death in plants

Ozone is the main photochemical oxidant that causes leaf damage in many plant species, and can thereby significantly decrease the productivity of crops and forests. When ozone is incorporated into plants, it produces reactive oxygen species (ROS), such as superoxide radicals and hydrogen peroxide. These ROS induce the synthesis of several plant hormones, such as ethylene, salicylic acid, and jasmonic acid. These phytohormones are required for plant growth, development, and defense responses, and regulate the extent of leaf injury in ozone-fumigated plants. Recently, responses to ozone have been studied using genetically modified plants and mutants with altered hormone levels or signaling pathways. These researches have clarified the roles of phytohormones and the complexity of their signaling pathways. The present paper reviews the biosynthesis of the phytohormones ethylene, salicylic acid, and jasmonic acid, their roles in plant responses to ozone, and multiple interactions between these phytohormones in ozone-exposed plants.Key words: cross-talk, ethylene, jasmonic acid, ozone, phytohormones, programmed cell death, salicylic acid, signaling pathways     

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。     

NON-HORMONAL STIMULATORS AND INHIBITORS OF PLANT GROWTH AND DEVELOPMENT

1. Plants contain growth regulators that are non-hormonal in nature. These regulators change in concentration during ontogeny and when applied exogenously, can either stimulate or depress growth. While the bulk of either the phenolic or terpenoid regulators are localized within the vacuole, they can also be found within other cellular compartments where they may act upon metabolic pathways, modifying either cell multiplication or elongation. 2. Non-hormonal growth regulators may affect the synthesis and/or destruction of phytohormones, mainly indole-3-acetic acid (IAA). These regulators behave non-specifically, modifying the actions of auxins, gibberellins and cytokinins upon growth. 3. A variety of both uncertainties and unresolved contradictions exist that have prevented a thorough elucidation of the mechanisms of actions of both phenolic and terpenoid regulators. These uncertainties and unresolved contradictions include lack of data regarding compartmentalization of many of the inhibitors. This raises the question of whether their intracellular concentrations become elevated sufficiently to affect metabolic pathways in vivo. Exogenously applied regulators of non-hormonal nature usually interfere with growth only at high concentrations. Therefore, the possibility cannot be excluded that under these conditions, reactions occur within the cell that are absent in vivo. 4. The specific properties of natural non-hormonal regulators are similar in certain respects to phytohormones. For example, both of them may be biogenetically bound within metabolic centres: shikimate (phenolics, indoles, alkaloids), bi-benzi (coumarins) or acetate-mevalonate (terpenoids, fluorens, sesquiterpenes, cytokinins). In addition, both non-hormonal regulators and phytohormones exhibit biological activity in growth bioassays. 5. Non-hormonal regulators may possess a number of useful purposes, e.g. test substances such as fusicoccin permit the investigation of the mode of action of phytohormones, specific inhibitors blocking special forms of growth and protectors of phytohormone activity in culture.     

Simultaneous P-solubilizing and biocontrol activity of microorganisms: potentials and future trends

Phosphate (P)-solubilizing microorganisms as a group form an important part of the microorganisms, which benefit plant growth and development. Growth promotion and increased uptake of phosphate are not the only mechanisms by which these microorganisms exert a positive effect on plants. Microbially mediated solubilization of insoluble phosphates through release of organic acids is often combined with production of other metabolites, which take part in biological control against soilborne phytopathogens. In vitro studies show the potential of P-solubilizing microorganisms for the simultaneous synthesis and release of pathogen-suppressing metabolites, mainly siderophores, phytohormones, and lytic enzymes. Further trends in this field are discussed, suggesting a number of biotechnological approaches through physiological and biochemical studies using various microorganisms.     

Hormonal Control of Sucrose Phosphate Synthase and Sucrose Synthase in Sugar Beet

We studied the effects of synthetic analogs of phytohormones (benzyladenine, IAA, and GA) on the activities of the enzymes catalyzing sucrose synthesis and metabolism, sucrose phosphate synthase (SPS, EC 2.4.1.14) and sucrose synthase (SS, EC 2.4.1.13), and on the content of chlorophyll and protein during the sugar-beet (Beta vulgaris L.) ontogeny. Plant spraying with phytohormonal preparations activated SPS in leaves; direct interaction between phytohormones and the enzyme also increased its activity. The degree of this activation differed during the ontogeny and in dependence on the compound used for treatment. Analogs of phytohormones maintained high protein level in leaves, retarded chlorophyll breakdown, and, thus, prolonged leaf functional activity during development. Phytohormonal preparations practically did not affect the SS activity both after plant treatment and at their direct interaction with the enzyme. It is supposed that the SS activity in sugar-beet roots is controlled by sucrose synthesized in leaves rather than by phytohormones. The effects of hormones on leaf metabolism were mainly manifested in growth activation.     

Biosynthesis and beneficial effects of microbial gibberellins on crops for sustainable agriculture

Soil microbes promote plant growth through several mechanisms such as secretion of chemical compounds including plant growth hormones. Among the phytohormones, auxins, ethylene, cytokinins, abscisic acid and gibberellins are the best understood compounds. Gibberellins were first isolated in 1935 from the fungus Gibberella fujikuroi and are synthesized by several soil microbes. The effect of gibberellins on plant growth and development has been studied, as has the biosynthesis pathways, enzymes, genes and their regulation. This review revisits the history of gibberellin research highlighting microbial gibberellins and their effects on plant health with an emphasis on the early discoveries and current advances that can find vital applications in agricultural practices.     

植物源活性物质对昆虫生殖的干扰作用

昆虫的繁盛与其强大的生殖能力密切相关,而环境友好的植物源活性物质是可持续的害虫防治方法之一,能够通过多种作用机制影响昆虫的生殖发育。本文从昆虫生殖行为、生长发育、生殖细胞或器官、生殖地位与性比、共生微生物等方面,综述了植物源活性物质对昆虫生殖干扰机理的研究进展及相关的应用情况,以期为昆虫生殖发育干扰的进一步研究与害虫综合防控技术的研发提供参考。     

Effect of exogenous cytokinins on dynamics of development and differentiation of infectious structures of the pathogen of wheat powdery mildew

The infectious structures for the development and differentiation of Erysiphe graminis DC. f. sp. tritici March., the pathogen of wheat powdery mildew, under the effects of exogenous zeatin was studied by methods of light and electron scanning microscopy. It was shown for the first time that physiologically active substances, specifically phytohormones of the cytokinin type, can affect dimensions of the halo revealed in the pathogen penetration site at cytochemical staining. Treatment with zeatin affected conidia germination and pathogen growth in the ectophytic stage. The concentration curve of the action of zeatin for the number of mature pathogen colonies (6 days after infection) was represented by a multiphase curve with two maxima (1 and 3 μM) and one minimum (1.5 μM). Similar curves have been obtained for the number of normal appressoria and for large halo diameters, which possibly indicates the existence of the factors affecting these both parameters, as well as the final number of pathogen colonies. The obtained data indicate that the origin of the multiphase dose response curve for effect of cytokinins on the development of powdery mildew pathogen is connected with factors that are active at the early stages of pathogenesis.