Overexpression of the AtSTK gene increases salt, PEG and ABA tolerance in Arabidopsis

AtSTK (At5g02800), which is a serine-threonine protein kinase gene of Arabidopsis thaliana, was cloned, and its function was studied. The study found that the overexpression of AtSTK could significantly improve the ability of A. thaliana to tolerate salt, PEG, and ABA stresses. RT-PCR analysis revealed that the expression of the AtSTK gene could be obviously induced by salt, PEG, and ABA. The examination of the physiological characteristics showed that the overexpression of AtSTK in Arabidopsis significantly reduced the plasma membrane permeability, significantly increased the proline content, and decreased the MDA content. These changes may reflect the physiological mechanisms through which AtSTK overexpression improves stress resistance in Arabidopsis. In addition, the overexpression of the AtSTK gene significantly antagonised the inhibitory effect of high concentrations of exogenous ABA on Arabidopsis seed germination. The subcellular localisation results showed that AtSTK is located in both the cytosol and the nucleus. The examination of its tissue-specific expression showed that AtSTK is expressed in various Arabidopsis tissues and is particularly strongly expressed in the vessels. The signalling pathway analysis indicated that AtSTK might transfer the salt stress signal in Arabidopsis through the MAPK pathway.     

Overexpression ofENA1 from yeast increases salt tolerance inArabidopsis

In yeast, the plasma membrane Na⁺/H⁺ antiporter and Na⁺-ATPase are key enzymes for salt tolerance.Saccharomyces cerevisiae Na⁺-ATPase (Enalp ATPase) is encoded by theENA1/PMR2A gene; expression ofENA1 is tightly regulated by Na⁺ and depends on ambient pH. Although Enalp is active mainly at alkaline pH values inS. cerevisiae, no Na⁺-ATPase has been found in flowering plants. To test whether this yeast enzyme would improve salt tolerance in plants, we introducedENA1 intoArabidopsis (cv. Columbia) under the control of the cauliflower mosaic virus 35S promoter. Transformants were selected for their ability to grow on a medium containing kanamyin. Southern blot analyses confirmed thatENA1 was transferred into theArabidopsis genome and northern blot analyses showed thatENA1 was expressed in the transformants. Several transgenic homozygous lines and wild-type (WT) plants were evaluated for salt tolerance. No obvious morphological or developmental differences existed between the transgenic and WT plants in the absence of stress. However, overexpression ofENA1 inArabidopsis improved seed germination rates and salt tolerance in seedlings. Under saline conditions, transgenic plants accumulated a lower amount of Na⁺ than did the wild type, and fresh and dry weights of the former were higher. Other experiments revealed that expression ofENA1 promoted salt tolerance in transgenicArabidopsis under both acidic and alkaline conditions. These authors contributed equally to this article.     

过表达TaLEA1和TaLEA2基因提高转基因拟南芥的耐盐性

我国土壤盐碱化日益严重,对我国的粮食安全造成了严重威胁。耐盐基因挖掘对作物耐盐育种非常重要。LEA蛋白家族是一个多基因家族,在植物应对非生物胁迫中发挥重要作用。本课题组前期研究阐明小麦TaLEA1基因在拟南芥中过表达可以提高转基因植物的耐盐性和抗旱性。本研究系统分析了小麦TaLEA2基因表达蛋白的理化性质、基因表达模式及启动子功能区域,并在拟南芥中过表达TaLEA2基因及共表达TaLEA1和TaLEA2基因,分析TaLEA2基因的抗逆功能及2个LEA基因的抗逆效果。结果表明,TaLEA2基因的表达产物属于第3组LEA蛋白,是稳定的亲水蛋白,富含α-螺旋、β-转角等结构。TaLEA2基因在小麦根、茎、叶、花、种子等不同组织中均有表达,盐胁迫条件诱导其高表达。在拟南芥中过表达TaLEA2基因,或过表达TaLEA1和TaLEA2基因都能够提高转基因拟南芥的耐盐性和抗旱性,转基因株系的种子萌发率、根长及叶绿素含量显著高于野生型,且双基因过表达的转基因植物的抗逆能力高于单个基因过表达株系。本研究结果为LEA基因抗逆机理的研究和多基因共转提高植物抗逆性提供了重要信息。     

Overexpression of glutathione S-transferase gene increases salt tolerance of arabidopsis

The Suaeda salsa glutathione S-transferase gene (GST) was introduced into arabidopsis under the control of the cauliflower mosaic virus 35S promoter. Transformants were selected for their ability to grow on medium containing kanamycin. Southern and northern blot analyses confirmed that GST was transferred into the arabidopsis genome, and the GST and GPX activities in transgenic plants (GT) were much higher than in wild-type plants (WT). There were no obvious morphological or developmental differences between transgenic and wild-type plants. One transgenic homozygous line (GT_6–8) and WT plants were evaluated for salt tolerance and gene expression. Seed germination and seedling salt tolerance were improved after overexpression of GST in arabidopsis; the photosynthesis rate and the fresh weight of the GT_6–8 line were distinctly higher than those of WT plants after NaCl treatment. Glutathione content increased substantially in salt-stressed arabidopsis plants of both genotypes, and the glutathione pool in GT_6–8 plants was more oxidized than in WT plants under both control and stressful conditions. The MDA content, an indicator of lipid peroxidation, increased in WT plants but was not affected distinctly in GT_6–8 seedlings after NaCl treatment. Results from different tests indicated that the expression of the GST gene promoted a higher level of salt tolerance in vivo in transgenic arabidopsis plants.     

Overexpression of the wheat salt tolerance-related gene TaSC enhances salt tolerance in Arabidopsis

A novel gene named TaSC was cloned from salt-tolerant wheat. Northern blot showed that the expression of TaSC in salt-tolerant wheat was up-regulated after salt stress. Real-time quantitative PCR analyses showed that TaSC expression was induced by salt and ABA in wheat. Localization analysis showed that TaSC proteins were localized to the plasma membrane in transgenic Arabidopsis thaliana. The overexpression of TaSC in Col-0 and atsc (SALK_072220) Arabidopsis strains resulted in increased salt tolerance of the transgenic plants. TaSC overexpression in Col-0 and atsc signi?cantly up-regulated the expression of AtFRY1, AtSAD1, and AtCDPK2. AtCDPK2 overexpression in atsc rescued the salt-sensitive phenotype of atsc. The TaSC gene may improve plant salt tolerance by acting via the CDPK pathway.     

Overexpression of maize mitogen-activated protein kinase gene, ZmSIMK1 in Arabidopsis increases tolerance to salt stress

Mitogen-activated protein kinase (MAPK) cascades play a remarkably crucial role in plants. It has been studied intensively in model plants Arabidopsis, tobacco and rice. However, the function of MAPKs in maize (Zea mays L.) has not been well documented. ZmSIMK1 (Zea mays salt-induced mitogen-activated protein kinase 1) is a previously identified MAPK gene in maize. In this research, we charactered ZmSIMK1 and showed that ZmSIMK1 was involved in Arabidopsis salt stress. The genomic organization of ZmSIMK1 gene and its expression in maize have been analyzed. In order to investigate the function of ZmSIMK1, we generated transgenic Arabidopsis constitutively overexpressing ZmSIMK1. Ectopic expression of ZmSIMK1 in Arabidopsis resulted in increased resistance against salt stress. Importantly, ZmSIMK1-overexpressing Arabidopsis exhibited constitutive expression of stress-responsive marker genes, RD29A and P5CS1. Furthermore, RD29A and P5CS1 were upregulated under salt stress. These results suggest that ZmSIMK1 may play an important role in plant salt stress.     

Overexpression of SaRBP1 enhances tolerance of Arabidopsis to salt stress

Abiotic stresses are the major concern in recent years as their effect on world food production is constantly increasing. We have obtained salt tolerant Arabidopsis lines overexpressing SaRBP1 (Suaeda asparagoides RNA binding protein 1) of a Korean halophyte, S. asparagoides. Homozygous T3 Arabidopsis transgenic lines were developed and used for salt stress tolerance studies. The transgenic seedlings displayed tolerance to salt and mannitol compared to the wild type (WT) seedlings. Transgenic lines produced longer primary roots, more fresh weight, and higher number of lateral roots than WT. In planta stress tolerance assay results showed that the survival rates of transgenic plants were significantly higher than WT plants. Transgenic lines showed delayed germination under 200 mM NaCl stress. In addition, the transgenics showed higher water retention ability than WT. Subcellular localization results revealed that SaRBP1 was targeted to the cytoplasm. Northwestern blot analysis results confirmed the RNA binding property of SaRBP1. Quantitative Real-Time Polymerase Chain Reaction results revealed that many stress marker genes were upregulated by SaRBP1 overexpression. Thus, our data demonstrate that SaRBP1 overexpression lines are tolerant to salt stress. Hence, this is the first report for the functional characterization of SaRBP1, a novel RBP gene isolated from S. asparagoides cDNA library.     

Overexpression of selenocysteine methyltransferase in Arabidopsis and Indian mustard increases selenium tolerance and accumulation

A major goal of phytoremediation is to transform fast-growing plants with genes from plant species that hyperaccumulate toxic trace elements. We overexpressed the gene encoding selenocysteine methyltransferase (SMT) from the selenium (Se) hyperaccumulator Astragalus bisulcatus in Arabidopsis and Indian mustard (Brassica juncea). SMT detoxifies selenocysteine by methylating it to methylselenocysteine, a nonprotein amino acid, thereby diminishing the toxic misincorporation of Se into protein. Our Indian mustard transgenic plants accumulated more Se in the form of methylselenocysteine than the wild type. SMT transgenic seedlings tolerated Se, particularly selenite, significantly better than the wild type, producing 3- to 7-fold greater biomass and 3-fold longer root lengths. Moreover, SMT plants had significantly increased Se accumulation and volatilization. This is the first study, to our knowledge, in which a fast-growing plant was genetically engineered to overexpress a gene from a hyperaccumulator in order to increase phytoremediation potential.     

Overexpression of the Arabidopsis AtEm6 gene enhances salt tolerance in transgenic rice cell lines

The Arabidopsis thaliana late embryogenesis abundant gene AtEm6 is required for normal seed development and for buffering the rate of dehydration during the latter stages of seed maturation. However, its function in salt stress tolerance is not fully understood. In this investigation, cell suspension cultures of three plant species rice (Oryza sativa L.), cotton (Gossypium hirsutum L.), and white pine (Pinus strobes L.) were transformed using Agrobacterium tumefaciens strain LBA4404 harboring pBI-AtEm6. Integration of the AtEm6 gene into the genome of rice, cotton, and white pine has been confirmed by polymerase chain reaction, Southern blotting, and northern blotting analyses. Three transgenic cell lines from each of O. sativa, G. hirsutum, and P. strobus were used to analyze salt stress tolerance conferred by the overexpression of the AtEm6 gene. Our results demonstrated that expression of the AtEm6 gene enhanced salt tolerance in transgenic cell lines. A decrease in lipid peroxidation and an increment in antioxidant enzymes ascorbate peroxidase, glutathione reductase and superoxide dismutase activities were observed in the transgenic cell lines, compared to the non- transgenic control. In rice, AtEM6 increased expression of Ca²⁺-dependent protein kinase genes OsCPK6, OsCPK9, OsCPK10, OsCPK19, OsCPK25, and OsCPK26 under treatment of salt. These results suggested that overexpression of the AtEM6 gene in transgenic cell lines improved salt stress tolerance by regulating expression of Ca²⁺-dependent protein kinase genes. Overexpression of the AtEM6 gene could be an alternative choice for engineering plant abiotic stress tolerance.     

Overexpression of Arabidopsis thaliana LTL1, a salt-induced gene encoding a GDSL-motif lipase, increases salt tolerance in yeast and transgenic plants

Genes involved in the mechanisms of plant responses to salt stress may be used as biotechnological tools for the genetic improvement of salt tolerance in crop plants. This would help alleviate the increasing problem of salinization of lands cultivated under irrigation in arid and semi-arid regions. We have isolated a novel halotolerance gene from Arabidopsis thaliana, A. thaliana Li-tolerant lipase 1 (AtLTL1), on the basis of the phenotype of tolerance to LiCl conferred by its expression in yeast. AtLTL1 encodes a putative lipase of the GDSL-motif family, which includes bacterial and a very large number of plant proteins. In Arabidopsis, AtLTL1 expression is rapidly induced by LiCl or NaCl, but not by other abiotic stresses. Overexpression of AtLTL1 increases salt tolerance in transgenic Arabidopsis plants, compared to non-transformed controls, allowing germination of seeds in the presence of toxic concentrations of LiCl and NaCl, and stimulating vegetative growth, flowering and seed set in the presence of NaCl. These results clearly point to a role of AtLTL1 in the mechanisms of salt tolerance. In addition, we show that AtLTL1 expression is also activated, although only transiently, by salicylic acid (SA), suggesting that the lipase could also be involved in defence reactions against pathogens.     

Overexpression of the rice Osmyb4 gene increases chilling and freezing tolerance of Arabidopsis thaliana plants

The expression of the gene Osmyb4, detected at low level in rice (Oryza sativa) coleoptiles grown for 3 days at 29 degrees C, is strongly induced by treatments at 4 degrees C. At sublethal temperatures of 10 and 15 degrees C, its expression in rice seedlings is already evident, but this effect cannot be vicariated by other stresses or ABA treatment. We demonstrate by transient expression that Myb4 transactivates the PAL2, ScD9 SAD and COR15a cold-inducible promoters. The Osmyb4 function in vivo is demonstrated overexpressing its cDNA in Arabidopsis thaliana plants (ecotype Wassilewskija) under the control of the constitutive CaMV 35S promoter. Myb4 overexpressing plants show a significant increased cold and freezing tolerance, measured as membrane or Photosystem II (PSII) stability and as whole plant tolerance. Finally, in Osmyb4 transgenic plants, the expression of genes participating in different cold-induced pathways is affected, suggesting that Myb4 represents a master switch in cold tolerance.     

Suppressed expression of the apoplastic ascorbate oxidase gene increases salt tolerance in tobacco and Arabidopsis plants

Transgenic tobacco plants expressing the ascorbate oxidase (AAO) gene in sense and antisense orientations, and an Arabidopsis mutant in which the T-DNA was inserted into a putative AAO gene, were used to examine the potential roles of AAO for salt-stress tolerance in plants. AAO activities in the transgenic tobacco plants expressing the gene in sense and antisense orientations were, respectively, about 16-fold and 0.2-fold of those in the wild type. Under normal growth conditions, no significant differences in phenotypes were observed, except for a delay in flowering time in the antisense plants. However, at high salinity, the percentage germination, photosynthetic activity, and seed yields were higher in antisense plants, with progressively lower levels in the wild type and the sense plants. The redox state of apoplastic ascorbate in sense plants was very low even under normal growth conditions. Upon salt stress, the redox state of symplastic and apoplastic ascorbate decreased among the three types of plants, but was lowest in the sense plants. The hydrogen peroxide contents in the symplastic and apoplastic spaces were higher in sense plants, progressively lower in the wild type, followed by the antisense plants. The Arabidopsis T-DNA inserted mutant exhibited very low ascorbate oxidase activity, and its phenotype was similar to that of antisense tobacco plants. These results suggest that the suppressed expression of apoplastic AAO under salt-stress conditions leads to a relatively low level of hydrogen peroxide accumulation and a high redox state of symplastic and apoplastic ascorbate which, in turn, permits a higher seed yield.