油菜素内酯调控作物农艺性状和非生物胁迫响应的研究进展

植物对不利环境的适应依赖于将外部胁迫信号传递到内部信号通路中,在进化过程中形成一系列的胁迫响应机制。其中,油菜素内酯(brassinosteroids, BRs)是一种类固醇激素,广泛参与植物生长发育和逆境响应过程。BRs被包括受体BRI1和共受体BAK1在内的细胞表面受体感知,继而触发信号级联,导致蛋白激酶BIN2的抑制和转录因子BES1/BZR1的激活,BES1/BZR1可直接调控数千个下游响应基因的表达。在模式植物拟南芥中的研究表明,BR的生物合成和信号转导通路成员,特别是BIN2和其下游的转录因子BES1/BZR1,可以被各种环境因子广泛地调节。本文系统总结了BR相关的最新研究进展,对BR的生物合成和信号转导是如何被复杂的环境因子所调节,以及BR与环境因子如何协同调控作物重要农艺性状、冷胁迫和盐胁迫的响应进行了综述。     

AtCPK23 functions in <Emphasis Type="Italic">Arabidopsis</Emphasis> responses to drought and salt stresses

Calcium-dependent protein kinases (CDPKs) are unique serine/threonine kinases in plants and there are 34 CDPKs in Arabidopsis genome alone. Although several CDPKs have been demonstrated to be critical calcium signaling mediators for plant responses to various environmental stresses, the biological functions of most CDPKs in stress signaling remain unclear. In this study, we provide the evidences to demonstrate that AtCPK23 plays important role in Arabidopsis responses to drought and salt stresses. The cpk23 mutant, a T-DNA insertion mutant for AtCPK23 gene, showed greatly enhanced tolerance to drought and salt stresses, while the AtCPK23 overexpression lines became more sensitive to drought and salt stresses and the complementary line of the cpk23 mutant displayed similar phenotype as wild-type plants. The results of stomatal aperture measurement showed that the disruption of AtCPK23 expression reduced stomatal apertures, while overexpression of AtCPK23 increased stomatal apertures. The alteration of stomatal apertures by changes in AtCPK23 expression may account, at least in partial, for the modified Arabidopsis response to drought stress. In consistent with the enhanced salt-tolerance by disruption of AtCPK23 expression, K⁺ content in the cpk23 mutant was not reduced under high NaCl stress compared with wild-type plants, which indicates that the AtCPK23 may also regulate plant K⁺-uptake. The possible mechanisms by which AtCPK23 mediates drought and salt stresses signaling are discussed.     

Antagonistic Regulation of Arabidopsis Growth by Brassinosteroids and Abiotic Stresses

To withstand ever-changing environmental stresses, plants are equipped with phytohormone-mediated stress resistance mechanisms. Salt stress triggers abscisic acid (ABA) signaling, which enhances stress tolerance at the expense of growth. ABA is thought to inhibit the action of growth-promoting hormones, including brassinosteroids (BRs). However, the regulatory mechanisms that coordinate ABA and BR activity remain to be discovered. We noticed that ABA-treated seedlings exhibited small, round leaves and short roots, a phenotype that is characteristic of the BR signaling mutant, brassinosteroid insensitive1-9 (bri1-9). To identify genes that are antagonistically regulated by ABA and BRs, we examined published Arabidopsis microarray data sets. Of the list of genes identified, those upregulated by ABA but downregulated by BRs were enriched with a BRRE motif in their promoter sequences. After validating the microarray data using quantitative RT-PCR, we focused on RD26, which is induced by salt stress. Histochemical analysis of transgenic Arabidopsis plants expressing RD26pro:GUS revealed that the induction of GUS expression after NaCl treatment was suppressed by co-treatment with BRs, but enhanced by co-treatment with propiconazole, a BR biosynthetic inhibitor. Similarly, treatment with bikinin, an inhibitor of BIN2 kinase, not only inhibited RD26 expression, but also reduced the survival rate of the plant following exposure to salt stress. Our results suggest that ABA and BRs act antagonistically on their target genes at or after the BIN2 step in BR signaling pathways, and suggest a mechanism by which plants fine-tune their growth, particularly when stress responses and growth compete for resources.     

Putrescine metabolism modulates the biphasic effects of brassinosteroids on canola and Arabidopsis salt tolerance

Brassinosteroids (BRs) are known to improve salt tolerance of plants, but not in all situations. Here, we show that a certain concentration of 24-epibrassinolide (EBL), an active BR, can promote the tolerance of canola under high-salt stress, but the same concentration is disadvantageous under low-salt stress. We define this phenomenon as hormonal stress-level-dependent biphasic (SLDB) effects. The SLDB effects of EBL on salt tolerance in canola are closely related to H₂O₂ accumulation, which is regulated by polyamine metabolism, especially putrescine (Put) oxidation. The inhibition of EBL on canola under low-salt stress can be ameliorated by repressing Put biosynthesis or diamine oxidase activity to reduce H₂O₂ production. Genetic and phenotypic results of bri1-9, bak1, bes1-D, and bzr1-1D mutants and overexpression lines of BRI1 and BAK1 in Arabidopsis indicate that a proper enhancement of BR signaling benefits plants in countering salt stress, whereas excessive enhancement is just as harmful as a deficiency. These results highlight the involvement of crosstalk between BR signaling and Put metabolism in H₂O₂ accumulation, which underlies the dual role of BR in plant salt tolerance.     

Abiotic stress response in the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>: evidence for an evolutionary alteration in signaling pathways in land plants

The mechanisms plants use to adapt to abiotic stress have been widely studied in a number of seed plants. Major research has been focused on the isolation of stress-responsive genes as a means to understand the molecular events underlying the adaptation process. To study stress-related gene regulation in the moss Physcomitrella patens we have isolated two cDNAs showing homology to highly conserved small hydrophobic proteins from different seed plants. The corresponding genes are up-regulated by dehydration, salt, sorbitol, cold and the hormone abscisic acid, indicating overlapping pathways are involved in the control of these genes. Based on the molecular characterization of the moss homologs we propose that signaling pathways in response to abiotic stress may have been altered during the evolution of land plants.Abbreviation ABA Abscisic acid - EST Expressed sequence tag     

GA signaling and <Emphasis Type="Italic">CO/FT</Emphasis> regulatory module mediate salt-induced late flowering in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Flowering timing is very important for the reproductive success of higher plants. However, effects of salt on plant flowering and the underlying molecular mechanisms are largely unknown. Here, we show that salt stress delays flowering in Arabidopsis in a dose-dependent manner. Mild salt stress (≤50 mM NaCl) promoted and prolonged the vegetative growth, whereas high salinity (≥100 mM NaCl) largely delayed or inhibited the transition from vegetative growth to reproductive development. The gibberellin (GA)-pathway plays an important role in this phenotype, and application of exogenous GA could restore late flowering induced by salt. In addition, the CONSTANS (CO)/FLOWERING LOCUS T (FT) module may also play a critical role in mediating the effects of salt on flowering. The mRNA abundance of CO was significantly reduced by salt stress in a dose-dependent manner. The constans (co-2) mutants did not respond to moderate salt stress, whereas over-expressing CO manifested no delay in flowering time in response to salinity. Expression of FT, SOC1 and LFY in the downstream of the pathways was also reduced by salt according to dose. Moreover, salt-sensitive mutant salt overly sensitive3 (sos3) exhibited greater sensitivity in flowering, further suggesting that ion disequilibrium mediates salt-induced late flowering. Kexue Li and Youning Wang contributed equally to this report.     

蕾期土壤盐度降低后棉花叶片的生理功能恢复

试验于2011—2012年在江苏南京江苏省农业科学院经济作物研究所试验田进行,采用盆栽方法,以鲁棉研37号和苏棉22号为供试材料,设置土壤盐度降低试验(初始土壤含盐量为0.2%,棉花进入二叶期后每7d加入混合盐1次,每次增加0.1%,使土壤含盐量逐渐达到0.5%,蕾期进行盐度降低处理,使土壤含盐量降低到0.2%左右),研究蕾期土壤盐度降低后棉花叶片的生理代谢动态特征。结果表明:土壤盐度降低后,棉花叶片叶绿素(Chl)、类胡萝卜素(Car)含量和Chl/Car升高;净光合速率和气孔导度升高,且分别在土壤盐度降低后第14天和7天接近于低盐对照;土壤盐度降低后棉花叶片超氧化物歧化酶(SOD)和过氧化物酶(POD)活性升高,过氧化氢酶(CAT)活性和丙二醛(MDA)含量降低,MDA含量在土壤盐度降低后第14天接近于低盐对照;土壤盐度降低后棉花叶片中可溶性糖、游离氨基酸和脯氨酸含量降低,且接近于低盐对照。上述结果表明土壤盐度降低后,棉花叶片生理功能逐渐恢复,进而实现棉花生长发育的恢复补偿。棉花叶片生理功能在土壤盐度降低后的恢复能力存在品种间差异,鲁棉研37号较苏棉22号叶片生理功能表现出更强的恢复能力。     

盐胁迫下盐穗木甘油醛-3-磷酸脱氢酶基因的表达与亚细胞定位分析

为研究盐胁迫下植物甘油醛-3-磷酸脱氢酶(GAPDH)的作用机制,该研究利用RACE技术,从藜科盐生植物盐穗木中克隆获得1 381bp GAPDH基因(HcGAPDH)全长cDNA序列,其开放阅读框(ORF)编码314氨基酸。序列分析表明,HcGAPDH属于胞质GAPDH家族成员。实时定量PCR结果显示,HcGAPDH的转录水平受盐胁迫和ABA上调。通过荧光共聚焦显微技术,检测到绿色荧光蛋白标记的HcGAPDH在正常情况下定位于细胞质中,盐胁迫可促使其从细胞质转移至细胞核中,此过程与细胞内碳水化合物代谢的信号途径不具有相关性。研究表明,HcGAPDH通过细胞质和细胞核之间的信号传导在植物盐胁迫中发挥一定作用,为进一步揭示盐穗木耐盐分子机制奠定了一定基础。     

The wheat TaGBF1 gene is involved in the blue‐light response and salt tolerance

Light and abiotic stress both strongly modulate plant growth and development. However, the effect of light‐responsive factors on growth and abiotic stress responses in wheat (Triticum aestivum) is unknown. G–box binding factors (GBFs) are blue light‐specific components, but their function in abiotic stress responses has not been studied. Here we identified a wheat GBF1 gene that mediated both the blue light‐ and abiotic stress‐responsive signaling pathways. TaGBF1 was inducible by blue light, salt and exposure to abscisic acid (ABA). TaGBF1 interacted with a G–box light‐responsive element in vitro and promoted a blue‐light response in wheat and Aradidopsis thaliana. Both TaGBF1 over‐expression in wheat and its heterologous expression in A. thaliana heighten sensitivity to salinity and ABA, but its knockdown in wheat conferred resistance to high salinity and ABA. The expression of AtABI5, a key component of the ABA signaling pathway in A. thaliana, and its homolog Wabi5 in wheat was increased by transgenic expression of TaGBF1. The hypersensitivity to salt and ABA caused by TaGBF1 was not observed in the abi5 mutant background, showing that ABI5 is the mediator in TaGBF1‐induced abiotic stress responses. However, the hypersensitivity to salt conferred by TaGBF1 is not dependent on light. This suggests that TaGBF1 is a common component of blue light‐ and abiotic stress‐responsive signaling pathways.     

Histone acetyltransferase GCN5 contributes to cell wall integrity and salt stress tolerance by altering the expression of cellulose synthesis genes

Excess soluble salts in soil are harmful to the growth and development of most plants. Evidence is emerging that the plant cell wall is involved in sensing and responding to salt stress, but the underlying mechanisms are not well understood. We reveal that the histone acetyltransferase General control non‐repressed protein 5 (GCN5) is required for the maintenance of cell wall integrity and salt stress tolerance. The levels of GCN5 mRNA are increased in response to salt stress. The gcn5 mutants exhibited severe growth inhibition and defects in cell wall integrity under salt stress conditions. Combining RNA sequencing and chromatin immunoprecipitation assays, we identified the chitinase‐like gene CTL1, polygalacturonase involved in expansion‐3 (PGX3) and MYB domain protein‐54 (MYB54) as direct targets of GCN5. Acetylation of H3K9 and H3K14 mediated by GCN5 is associated with activation of CTL1, PGX3 and MYB54 under salt stress. Moreover, constitutive expression of CTL1 in the gcn5 mutant restores salt tolerance and cell wall integrity. In addition, the expression of the wheat TaGCN5 gene in Arabidopsis gcn5 mutant plants complemented the salt tolerance and cell wall integrity phenotypes, suggesting that GCN5‐mediated salt tolerance is conserved between Arabidopsis and wheat. Taken together, our data indicate that GCN5 plays a key role in the preservation of salt tolerance via versatile regulation in plants.     

Comparative effects of salt and alkali stresses on growth, osmotic adjustment and ionic balance of an alkali-resistant halophyte Suaeda glauca (Bge.)

Effects of salt and alkali stresses on growth, osmotic adjustment and ionic balance of Suaeda glauca (Bge.), an alkali-resistant succulent halophyte, were compared. The results showed that alkali stress clearly inhibited the growth of S. glauca. Moreover, the concentrations of Na⁺ and K⁺ both increased with increasing salinity under both stresses, suggesting no competitive inhibition between absorptions of Na⁺ and K⁺. The mechanism underlying osmotic adjustment during salt stress was similar to alkali stress in shoots. The shared essential features were that organic acids, betaine and inorganic ions (dominated by Na⁺) mostly accumulated. On the other hand, the mechanisms governing ionic balance under both stresses were different. Under salt stress, S. glauca accumulated organic acids and inorganic anions to maintain the intracellular ionic equilibrium, but the anion contribution of inorganic ions was greater than that of organic acids. However, the concentrations of inorganic anions under alkali stress were significantly lower than those under salt stress of the same intensity, suggesting that alkali stress might inhibit uptake of anions, such as NO₃ ^– and H₂PO₄ ^–. Under alkali stress, organic acids were the dominant factor in maintaining ionic equilibrium. The contribution of organic acids to anions was 74.1%, while that of inorganic anions was only 25.9%. S. glauca enhanced the synthesis of organic acids, dominated by oxalic acid, to compensate for the shortage of inorganic anions.     

Histone deacetylase OsHDA706 increases salt tolerance via H4K5/K8 deacetylation of OsPP2C49 in rice

High salt is a major environmental factor that threatens plant growth and development. Increasing evidence indicates that histone acetylation is involved in plant responses to various abiotic stress; however, the underlying epigenetic regulatory mechanisms remain poorly understood. In this study, we revealed that the histone deacetylase OsHDA706 epigenetically regulates the expression of salt stress response genes in rice (Oryza sativa L.). OsHDA706 localizes to the nucleus and cytoplasm and OsHDA706 expression is significantly induced under salt stress. Moreover, oshda706 mutants showed a higher sensitivity to salt stress than the wild-type. In vivo and in vitro enzymatic activity assays demonstrated that OsHDA706 specifically regulates the deacetylation of lysines 5 and 8 on histone H4 (H4K5 and H4K8). By combining chromatin immunoprecipitation and mRNA sequencing, we identified the clade A protein phosphatase 2 C gene, OsPP2C49, which is involved in the salt response as a direct target of H4K5 and H4K8 acetylation. We found that the expression of OsPP2C49 is induced in the oshda706 mutant under salt stress. Furthermore, the knockout of OsPP2C49 enhances plant tolerance to salt stress, while its overexpression has the opposite effect. Taken together, our results indicate that OsHDA706, a histone H4 deacetylase, participates in the salt stress response by regulating the expression of OsPP2C49 via H4K5 and H4K8 deacetylation.