Overexpression of the Arabidopsis NPR1 gene confers enhanced salt tolerance by regulating antioxidant and starch accumulation in citrus

Plant Cell, Tissue and Organ Culture (PCTOC) - The Non-Expresser of Pathogenesis-Related Genes 1 (NPR1) is a principal regulator of plant responses to biotic and abiotic stresses. In this...     

Overexpression of the aspartic protease ASPG1 gene confers drought avoidance in Arabidopsis

Drought is one of the most severe environmental stresses affecting plant growth and limiting crop production. Although many genes involved in adaptation to drought stress have been disclosed, the relevant molecular mechanisms are far from understood. This study describes an Arabidopsis gene, ASPG1 (ASPARTIC PROTEASE IN GUARD CELL 1), that may function in drought avoidance through abscisic acid (ABA) signalling in guard cells. Overexpression of the ASPG1 gene enhanced ABA sensitivity in guard cells and reduced water loss in ectopically overexpressing ASPG1 (ASPG1-OE) transgenic plants. In ASPG1-OE plants, some downstream targets in ABA and/or drought-signalling pathways were altered at various levels, suggesting the involvement of ASPG1 in ABA-dependent drought avoidance in Arabidopsis. By analysing the activities of several antioxidases including superoxide dismutase and catalase in ASPG1-OE plants, the existence was demonstrated of an effective detoxification system for drought avoidance in these plants. Analysis of ProASPG1-GUS lines showed a predominant guard cell expression pattern in various aerial tissues. Moreover, the protease activity of ASPG1 was characterized in vitro, and two aspartic acid sites, D180 and D379, were found to be key residues for ASPG1 aspartic protease activity in response to ABA. In summary, these findings suggest that functional ASPG1 may be involved in ABA-dependent responsiveness and that overexpression of the ASPG1 gene can confer drought avoidance in Arabidopsis.     

Overexpression of Arabidopsis ABF3 gene confers enhanced tolerance to drought and heat stress in creeping bentgrass

The Arabidopsis, abscisic acid responsive element-binding factor 3, ABF3 is known to play an important role in stress responses via regulating the expression of stress-responsive genes. In this study, we introduced pCAMBIA3301 vector harboring the ABF3 gene into creeping bentgrass (Agrostis stolonifera) through Agrobacterium-mediated transformation in order to develop a stress-tolerant variety of turfgrass. After transformation, putative transgenic plants were selected using the herbicide resistance assay. Genomic integration of the transgene was confirmed by genomic PCR and Southern blot analysis, and gene expression was validated by northern blot analysis. Under drought-stressed condition, the transgenic plants overexpressing ABF3 displayed significantly enhanced drought tolerance with higher water content and slower water loss rate than the control plants. Furthermore, the stomata of the ABF3 transgenic plants closed more than those of wild-type creeping bentgrass plants, under both non-stressed and ABA treatment conditions. In addition, the transgenic plants showed enhanced tolerance to heat stress. These results suggest that the overexpression of the ABF3 gene in creeping bentgrass might enhance survival in water-limiting and high temperature environments through increased stomatal closure and reduced water losses.     

Overexpression of Camellia sinensis H1 histone gene confers abiotic stress tolerance in transgenic tobacco

Key message

Overexpression of CsHis in tobacco promoted chromatin condensation, but did not affect the phenotype. It also conferred tolerance to low-temperature, high-salinity, ABA, drought and oxidative stress in transgenic tobacco.

Abstract

H1 histone, as a major structural protein of higher-order chromatin, is associated with stress responses in plants. Here, we describe the functions of the Camellia sinensis H1 Histone gene (CsHis) to illustrate its roles in plant responses to stresses. Subcellular localization and prokaryotic expression assays showed that the CsHis protein is localized in the nucleus, and its molecular size is approximately 22.5 kD. The expression levels of CsHis in C. sinensis leaves under various conditions were investigated by qRT-PCR, and the results indicated that CsHis was strongly induced by various abiotic stresses such as low-temperature, high-salinity, ABA, drought and oxidative stress. Overexpression of CsHis in tobacco (Nicotiana tabacum) promoted chromatin condensation, while there were almost no changes in the growth and development of transgenic tobacco plants. Phylogenetic analysis showed that CsHis belongs to the H1C and H1D variants of H1 histones, which are stress-induced variants and not the key variants required for growth and development. Stress tolerance analysis indicated that the transgenic tobacco plants exhibited higher tolerance than the WT plants upon exposure to various abiotic stresses; the transgenic plants displayed reduced wilting and senescence and exhibited greater net photosynthetic rate (Pn), stomatal conductance (Gs) and maximal photochemical efficiency (Fv/Fm) values. All the above results suggest that CsHis is a stress-induced gene and that its overexpression improves the tolerance to various abiotic stresses in the transgenic tobacco plants, possibly through the maintenance of photosynthetic efficiency.     

Overexpression of soybean ubiquitin-conjugating enzyme gene GmUBC2 confers enhanced drought and salt tolerance through modulating abiotic stress-responsive gene expression in Arabidopsis

Previous studies have shown that ubiquitination plays important roles in plant abiotic stress responses. In the present study, the ubiquitin-conjugating enzyme gene GmUBC2, a homologue of yeast RAD6, was cloned from soybean and functionally characterized. GmUBC2 was expressed in all tissues in soybean and was up-regulated by drought and salt stress. Arabidopsis plants overexpressing GmUBC2 were more tolerant to salinity and drought stresses compared with the control plants. Through expression analyses of putative downstream genes in the transgenic plants, we found that the expression levels of two ion antiporter genes AtNHX1 and AtCLCa, a key gene involved in the biosynthesis of proline, AtP5CS, and the copper chaperone for superoxide dismutase gene AtCCS, were all increased significantly in the transgenic plants. These results suggest that GmUBC2 is involved in the regulation of ion homeostasis, osmolyte synthesis, and oxidative stress responses. Our results also suggest that modulation of the ubiquitination pathway could be an effective means of improving salt and drought tolerance in plants through genetic engineering.     

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.     

Physiological function of NbRanBP1 in Nicotiana benthamiana

This study addresses the physiological functions of the Ran-binding protein homolog NbRanBP1 in Nicotiana benthamiana. Virus-induced gene silencing (VIGS) of NbRanBP1 caused stunted growth, leaf yellowing, and abnormal leaf morphology. The NbRanBP1 gene was constitutively expressed in diverse tissues and an NbRanBP1:GFP fusion protein was primarily localized to the nuclear rim and the cytosol. BiFC analysis revealed in vivo interaction between NbRanBP1 and NbRan1 in the nuclear envelope and the cytosol. Depletion of NbRanBP1 or NbRan1 reduced nuclear accumulation of a NbBTF3:GFP marker protein. In the later stages of development, NbRanBP1 VIGS plants showed stress responses such as reduced mitochondrial membrane potential, excessive production of reactive oxygen species, and induction of defense-related genes. The molecular role of RanBP1 in plants is discussed in comparison with RanBP1 function in yeast and mammals.     

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 of a NTR1 in transgenic soybean confers tolerance to water stress

Methyl jasmonate (MeJA) is an important plant regulator that involves in plant development and regulates the expression of plant defense genes in response to various stresses such as wounding, drought, and pathogens. In order to determine the physiological role of endogenous MeJA in plants, a NTR1 from Brassica campestris encoding a jasmonic acid carboxyl methyltransferase that produces methyl jasmonate was constructed under the control of CaMV 35S promoter and transformed into soybean [Glycine max (L) Merrill]. The transgenic soybean plants constitutively expressed the NTR1 and accumulated more MeJA levels than wild type plants. Overexpression of the gene in transgenic soybean conferred tolerance to dehydration during seed germination and seedling growth as reflected by the percentage of the fresh weight of seedlings. In addition, the transgenic soybean plants also conferred better capacity to retain water than wild type plants when drought tolerance was tested using detached leaves.     

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 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.