油菜素甾醇类与生长素的相互作用

油菜素甾醇类(brassinosteroid,BR)和生长素是两类重要的植物激素,二者在许多生理功能上存在相关性。近年来的研究表明,BR与生长素能协同调节基因表达,二者在代谢、运输和信号转导途径等不同层次上存在相互作用,并且这两种信号与其他信号转导途径,如激素信号转导途径和光信号转导途径之间也存在信号对话。现对BR与生长素之间这种复杂的相互作用进行评述。     

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.     

Nitric oxide: promoter or suppressor of programmed cell death?

Nitric oxide (NO) is a short-lived gaseous free radical that predominantly functions as a messenger and effector molecule. It affects a variety of physiological processes, including programmed cell death (PCD) through cyclic guanosine monophosphate (cGMP)-dependent and-independent pathways. In this field, dominant discoveries are the diverse apoptosis networks in mammalian cells, which involve signals primarily via death receptors (extrinsic pathway) or the mitochondria (intrinsic pathway) that recruit caspases as effector molecules. In plants, PCD shares some similarities with animal cells, but NO is involved in PCD induction via interacting with pathways of phytohormones. NO has both promoting and suppressing effects on cell death, depending on a variety of factors, such as cell type, cellular redox status, and the flux and dose of local NO. In this article, we focus on how NO regulates the apoptotic signal cascade through protein S-nitrosylation and review the recent progress on mechanisms of PCD in both mammalian and plant cells.     

甘蓝型油菜的BR响应及BnBZL2基因的功能分析

对甘蓝型油菜(Brassica napus L.)与拟南芥(Arabidopsis thaliana L.)中保守的油菜素甾醇(Brassinosteroids,BR)信号相关基因进行对比分析,并以甘蓝型油菜品种‘沪油15’为材料,对BR信号通路相关同源基因进行了组织表达分析。结果显示,BR合成基因与信号组分在花和幼嫩种子中表达量更高;低浓度BR处理可以促进幼苗根的生长,高浓度BR处理则起抑制作用; BR合成抑制剂(Brassinozole,BRZ)处理可抑制黑暗条件下幼苗下胚轴的伸长; BR处理可以降低BR合成基因的表达水平,而BRZ处理则相反,表明甘蓝型油菜中BR信号增加能反馈抑制BR的合成。烟草(Nicotiana tabacum L.)瞬时表达实验结果发现,与拟南芥BZR1基因同源的甘蓝型油菜BnBZL2编码蛋白定位在细胞质和细胞核中,BR处理可增加BnBZL2的核定位。蛋白质免疫印迹检测结果显示,BR处理可增加去磷酸化BnBZL2的比例。本研究进一步模拟了拟南芥bzr1-1D功能获得性突变体对BnBZL2蛋白进行点突变(BnBZL2*),并构建载体转化拟南芥,黑暗条件下转基因植株幼苗对BRZ处理不敏感,提示BnBZL2*可提高转基因植株的BR信号水平。本研究结果表明甘蓝型油菜中存在与拟南芥相似且保守的BR信号通路和调控机制。     

Brassinosteroid Signal Transduction: A Mix of Conservation and Novelty

Brassinosteroids (BRs) are a unique class of plant steroids that are structurally similar to animal steroid hormones and play important roles in plant growth and development. Unlike the animal steroids, which bind to classical intracellular steroid receptors that directly modulate gene activities after translocation into the nucleus, the plant steroids rely on transmembrane receptor kinases to activate a phosphorylation cascade to regulate gene expression. Recent genetic and biochemical studies have identified several critical BR signaling components and revealed a striking mechanistic similarity between the plant steroid signaling pathway and several well-studied animal signaling cascades involving a receptor kinase and glycogen synthase kinase 3 (GSK3). A working model for BR signal transduction proposes that BR initiates its signaling pathway by promoting heterodimerization of two transmembrane receptor-like kinases at the cell surface, leading to inhibition of a GSK3 kinase and subsequent stabilization and nuclear accumulation of two GSK3 substrates that regulate BR-responsive genes. Such a simple model provides a framework for continued investigation of molecular mechanism(s) of plant steroid signaling.     

Role of Phytohormones in Regulating Heat Stress Acclimation in Agricultural Crops

Heat stress (HS) seriously affects crop growth, causing significant crop yield losses worldwide. The regulatory mechanisms controlling HS tolerance in plants are not well understood. Phytohormones are important molecules for coordinating myriad of phenomena related to plant growth and development. They are also essential endogenous signaling molecules that actively mediate numerous physiological responses under abiotic stress by triggering stress-responsive regulatory genes involved in plant growth. This review updates the central role of various phytohormones—indole acetic acid, gibberellic acid, abscisic acid, cytokinins, ethylene, salicylic acid, brassinosteroids, strigolactone, and jasmonic acid—in regulating the HS response so that plants can adapt to increasing temperature stress. We also reveal how these stress-responsive phytohormones switch on various regulatory gene(s) and genes encoding antioxidants and heat shock proteins (HSPs) to combat HS in various plant species.

     

Mutations in the HvDWARF,HvCPD and HvBRI1 Genes-Involved in Brassinosteroid Biosynthesis/Signalling: Altered Photosynthetic Efficiency,Hormonal Homeostasis and Tolerance to High/Low Temperatures in Barley

Brassinosteroids (BR) are steroid phytohormones that are involved in the growth and stress response in plants, but the precise mechanisms of their action are still being discovered. In our study we have used BR-deficient barley mutants 522DK and BW084 (which carry missense mutations in the HvDWARF and HvCPD genes, respectively). We have also used a BR-signalling mutant that harbors missense substitutions in the HvBRI1 gene. Our aim was (1) to find out if the content of phytohormones in the mutants grown at 20 °C is different than in the wild types and whether/how the content of phytohormones changes after plant acclimation at temperatures of 5 °C and 27 °C?, (2) to characterise the effectiveness of the light reactions of photosynthesis of the barley mutants in comparison to wild types at various temperatures, and (3) to verify the impact of mutations on the tolerance of barley to high and low temperatures. Hormonal characteristics of the BR mutants of barley show the complexity of the interactions between BR and other plant hormones that are additionally modified by temperature and possibly by other factors. The results suggest the participation of BR in auxin catabolism. Further, BR appears to play a role in maintaining the ABA–ABAGlc balance. As for the gibberellin content in plants at a temperature of 20 °C, more in-depth studies will be required to explain the contradictory effects regarding the accumulation of GA3, GA4 and GA5, which appears to be dependent on the type of mutation and connected to the BR level. A fast-kinetic chlorophyll a fluorescence analysis has revealed that the mutants had lower values of energy absorption than the wild types, but the values of the energy transferred via the electron-transport chain was maintained at the wild-type level. We presumed that BR are involved in regulating plant acclimation to extreme (low/high) temperatures, thus the BR-deficient and BR-signalling mutants should be less tolerant to low/high temperatures when compared to the wild types. Unexpectedly, all of the mutants showed a higher tolerance to high temperatures than the wild types. The BW084 and BW312 mutants were less tolerant to frost than the wild type, but 522DK had a similar frost tolerance as the reference wild-type cultivar.

     

Brassinosteroids Regulate Growth in Plants Under Stressful Environments and Crosstalk with Other Potential Phytohormones

Brassinosteroids (BRs) are an important group of plant steroidal hormones that are actively involved in a myriad of key growth and developmental processes from germination to senescence. Moreover, BRs are known for their effective role in alleviation of stress-induced changes in normal metabolism via the activation of different tolerance mechanisms. Efforts to improve plant growth through exogenous application of BRs (through different modes such as foliar spray, presowing seed treatment, or through root growing medium) have gained considerable ground world over. It has been widely demonstrated that the exogenous application of BRs to stressed plants imparts the stress tolerance mechanisms. In BR-induced regulation of physio-biochemical processes in plants, interaction (crosstalk) of BRs with other phytohormones has been reported. This crosstalk may fine-tune the effective roles of other hormones in regulating stress tolerance. The multifaceted role of BRs consolidated so far has reflected their immense potential to help plants in counteracting the stress-induced changes. The effects of introgression and up- and down-regulation of BR-related genes reported so far to improve crop productivity have been presented here. Strong evidence exists that BRs are involved in signal transduction particularly in the regulation of the mitogen-activated protein kinase (MAPK) cascade, which in turn is involved in controlled development, cell death, and the perception of pathogen-associated molecular pattern (PAMP) signaling. How far BRs are involved in signal transduction pathways operative under stressful environments has also been comprehensively discussed in this review.