Overexpression of <Emphasis Type="Italic">SlERF1</Emphasis> tomato gene encoding an ERF-type transcription activator enhances salt tolerance

Ethylene-responsive factors (ERFs) play an important role in plant responses to stresses. For this study, we obtained sense- and antisense-SlERF1 transgenic tomato plants to analyze the function of the SlERF1 gene in tomato plants. Overexpression of SlERF1 in tomato plants enhanced salt tolerance during tomato seedling root development. In addition, tomato seedlings overexpressing SlERF1 showed the higher relative water content and lower MDA content and electrolyte leakage; they accumulated more free proline and soluble sugars, as compared with wild-type and antisense-SlERF1 transgenic tomato plants under salt stress. Moreover, SlERF1 activated the expression of stress-related genes, including LEA, P5CS, DREB3-1, and ltpg2 in tomato plants under salt stress. Thus, SlERF1 played a positive role in the salt tolerance of tomato plants.     

Comparative physiological responses of the yeast halotolerance genes expressed in transgenic lines of tomato cv Rio Grande under saline conditions

We previously analyzed the transgenic lines of tomato cv Rio Grande over-expressing the yeast HAL I and HAL II genes for their response to salt stress under in vitro conditions. In this study, six homozygous tomato lines harbouring the yeast HAL I or HAL II genes with highest expression level were selected for exploring their physiological responses against different salt stresses in the field. These transgenic plants showed significant growth and improved water content in comparison with control under 100 and 150 mM salt stress conditions. The HAL I and HAL II lines showed better Ca²⁺ content than their control counterparts. Furthermore, the transgenic lines exhibited lower values of relative electrical conductivity and improved resistance against the fungal pathogens Fusarium oxysporum and Alternaria solani when tested by detached leaf and agar tube dilution assays. Physiological analyses carried out in this study suggest an involvement of multiple mechanisms in transgenic tomato plants harbouring yeast genes to confer biotic and abiotic tolerance under stress conditions.     

A salt-inducible chloroplastic monodehydroascorbate reductase from halophyte Avicennia marina confers salt stress tolerance on transgenic plants

Plant growth and productivity are adversely affected by various abiotic stress factors. In our previous study, we used Avicennia marina, a halophytic mangrove, as a model plant system for isolating genes functioning in salt stress tolerance. A large scale random EST sequencing from a salt stressed leaf tissue cDNA library of one month old A. marina plants resulted in identification of a clone showing maximum homology to Monodehydroascorbate reductase (Am-MDAR). MDAR plays a key role in regeneration of ascorbate from monodehydroascorbate for ROS scavenging. In this paper, we report the cellular localization and the ability to confer salt stress tolerance in transgenic tobacco of this salt inducible Am-MDAR. A transit peptide at the N-terminal region of Am-MDAR suggested that it encodes a chloroplastic isoform. The chloroplastic localization was confirmed by stable transformation and expression of the Am-MDAR-GFP fusion protein in tobacco. Transgenic tobacco plants overexpressing Am-MDAR survived better under conditions of salt stress compared to untransformed control plants. Assays of enzymes involved in ascorbate–glutathione cycle revealed an enhanced activity of MDAR and ascorbate peroxidase whereas the activity of dehyroascorbate reductase was reduced under salt stressed and unstressed conditions in Am-MDAR transgenic lines. The transgenic lines showed an enhanced redox state of ascorbate and reduced levels of malondialdehyde indicating its enhanced tolerance to oxidative stress. The results of our studies could be used as a starting point for genetic engineering of economically important plants tolerant to salt stress.     

Overexpression of osmotin gene confers tolerance to salt and drought stresses in transgenic tomato (Solanum lycopersicum L.)

Abiotic stresses, especially salinity and drought, are major limiting factors for plant growth and crop productivity. In an attempt to develop salt and drought tolerant tomato, a DNA cassette containing tobacco osmotin gene driven by a cauliflower mosaic virus 35S promoter was transferred to tomato (Solanum lycopersicum) via Agrobacterium-mediated transformation. Putative T0 transgenic plants were screened by PCR analysis. The selected transformants were evaluated for salt and drought stress tolerance by physiological analysis at T1 and T2 generations. Integration of the osmotin gene in transgenic T1 plants was verified by Southern blot hybridization. Transgenic expression of the osmotin gene was verified by RT-PCR and northern blotting in T1 plants. T1 progenies from both transformed and untransformed plants were tested for salt and drought tolerance by subjecting them to different levels of NaCl stress and by withholding water supply, respectively. Results from different physiological tests demonstrated enhanced tolerance to salt and drought stresses in transgenic plants harboring the osmotin gene as compared to the wild-type plants. The transgenic lines showed significantly higher relative water content, chlorophyll content, proline content, and leaf expansion than the wild-type plants under stress conditions. The present investigation clearly shows that overexpression of osmotin gene enhances salt and drought stress tolerance in transgenic tomato plants.     

Transgenic tomato plants expressing strawberry <Emphasis Type="ItalicSmallCaps">d</Emphasis>-<Emphasis Type="Italic">galacturonic acid reductase</Emphasis> gene display enhanced tolerance to abiotic stresses

After analyzing tomato plants transformed with GalUR gene for their ascorbic acid contents, it was found that some transgenic lines contained higher levels of ascorbic acid compared to control plants. In the present study, callus induction rate was 50.2 % in the explant and shoot regeneration rate was 51.5 % from the callus with transformation efficiency of 3.0 %. Based on PCR and Southern blot analysis, three independent transformants containing the insert gene were selected. Phenotypic traits of these transgenic progeny were similar to those of control tomatoes. Tomatoes (H15) with high fruit ascorbic acid contents were selected for next generation (GalUR T₃) analysis. Transgenic tomatoes with increased ascorbic acid contents were found to be more tolerant to abiotic stresses induced by viologen, NaCl, or mannitol than non-transformed plants. In leaf disc senescence assay, the tolerance of these transgenic plants was better than control plants because they could retain higher chlorophyll contents. Under salt stress of less than 200 mM NaCl, these transgenic plants survived. However, control plants were unable to survive such high salt stress. Ascorbic acid contents in the transgenic plants were inversely correlated with MDA contents, especially under salt stress conditions. The GalUR gene was expressed in H15 tomatoes, but not in control plants. Higher expression levels of antioxidant genes (APX and CAT) were also found in these transgenic plants compared to that in the control plants. However, no detectable difference in SOD expression was found between transgenic plants and control plants. Results from this study suggest that the increase in ascorbic acid contents in plants could up-regulate the antioxidant system to enhance the tolerance of transgenic tomato plants to various abiotic stresses.     

Enhancing salt tolerance in a crop plant by overexpression of glyoxalase II

Earlier we have shown the role of glyoxalase overexpression in conferring salinity tolerance in transgenic tobacco. We now demonstrate the feasibility of same in a crop like rice through overproduction of glyoxalase II. The rice glyoxalase II was cloned in pCAMBIA1304 and transformed into rice (Oryza sativa cv PB1) via Agrobacterium. The transgenic plants showed higher constitutive activity of glyoxalase II that increased further upon salt stress, reflecting the upregulation of endogenous glyoxalase II. The transgenic rice showed higher tolerance to toxic concentrations of methylglyoxal (MG) and NaCl. Compared with non-transgenics, transgenic plants at the T1 generation exhibited sustained growth and more favorable ion balance under salt stress conditions. Sneh L. Singla-Pareek and Sudesh Kumar Yadav have contributed equally to this work.     

An Ipomoea batatas Iron-Sulfur Cluster Scaffold Protein Gene,IbNFU1, Is Involved in Salt Tolerance

Iron-sulfur cluster biosynthesis involving the nitrogen fixation (Nif) proteins has been proposed as a general mechanism acting in various organisms. NifU-like protein may play an important role in protecting plants against abiotic and biotic stresses. An iron-sulfur cluster scaffold protein gene, IbNFU1, was isolated from a salt-tolerant sweetpotato (Ipomoea batatas (L.) Lam.) line LM79 in our previous study, but its role in sweetpotato stress tolerance was not investigated. In the present study, the IbNFU1 gene was introduced into a salt-sensitive sweetpotato cv. Lizixiang to characterize its function in salt tolerance. The IbNFU1-overexpressing sweetpotato plants exhibited significantly higher salt tolerance compared with the wild-type. Proline and reduced ascorbate content were significantly increased, whereas malonaldehyde (MDA) content was significantly decreased in the transgenic plants. The activities of superoxide dismutase (SOD) and photosynthesis were significantly enhanced in the transgenic plants. H₂O₂ was also found to be significantly less accumulated in the transgenic plants than in the wild-type. Overexpression of IbNFU1 up-regulated pyrroline-5-carboxylate synthase (P5CS) and pyrroline-5-carboxylate reductase (P5CR) genes under salt stress. The systemic up-regulation of reactive oxygen species (ROS) scavenging genes was found in the transgenic plants under salt stress. These findings suggest that IbNFU1gene is involved in sweetpotato salt tolerance and enhances salt tolerance of the transgenic sweetpotato plants by regulating osmotic balance, protecting membrane integrity and photosynthesis and activating ROS scavenging system.     

Ectopic over-expression of peroxisomal ascorbate peroxidase (SbpAPX) gene confers salt stress tolerance in transgenic peanut (Arachis hypogaea)

Peroxisomal ascorbate peroxidase gene (SbpAPX) of an extreme halophyte Salicornia brachiata imparts abiotic stress endurance and plays a key role in the protection against oxidative stress. The cloned SbpAPX gene was transformed to local variety of peanut and about 100 transgenic plants were developed using optimized in vitro regeneration and Agrobacterium mediated genetic transformation method. The T₀ transgenic plants were confirmed for the gene integration; grown under controlled condition in containment green house facility; seeds were harvested and T₁ plants were raised. Transgenic plants (T₁) were further confirmed by PCR using gene specific primers and histochemical GUS assay. About 40 transgenic plants (T₁) were selected randomly and subjected for salt stress tolerance study. Transgenic plants remained green however non-transgenic plants showed bleaching and yellowish leaves under salt stress conditions. Under stress condition, transgenic plants continued normal growth and completed their life cycle. Transgenic peanut plants exhibited adequate tolerance under salt stress condition and thus could be explored for the cultivation in salt affected areas for the sustainable agriculture.     

Ectopic overexpression of vacuolar and apoplastic <Emphasis Type="Italic">Catharanthus roseus</Emphasis> peroxidases confers differential tolerance to salt and dehydration stress in transgenic tobacco

CrPrx and CrPrx1 are class III peroxidases previously cloned and characterized from Catharanthus roseus. CrPrx is known to be apoplastic in nature, while CrPrx1 is targeted to vacuoles. In order to study their role in planta, these two peroxidases were expressed in Nicotiana tabacum. The transformed plants exhibited increased peroxidase activity. Increased oxidative stress tolerance was also observed in transgenics when treated with H₂O₂ under strong light conditions. However, differential tolerance to salt and dehydration stress was observed during germination of T1 transgenic seeds. Under these stresses, the seed germination of CrPrx-transformed plants and wild-type plants was clearly suppressed, whereas CrPrx1 transgenic lines showed improved germination. CrPrx-transformed lines exhibited better cold tolerance than CrPrx1-transformed lines. These results indicate that vacuolar peroxidase plays an important role in salt and dehydration stress over cell wall-targeted peroxidase, while cell wall-targeted peroxidase renders cold stress tolerance.     

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 TaLEA Gene from Tamarix androssowii Improves Salt and Drought Tolerance in Transgenic Poplar (Populus simonii × P. nigra)

Late embryogenesis abundant (LEA) genes were confirmed to confer resistance to drought and water deficiency. An LEA gene from Tamarix androssowii (named TaLEA) was transformed into Xiaohei poplar ( Populus simonii × P. nigra) via Agrobacterium . Twenty-five independent transgenic lines were obtained that were resistant to kanamycin, and 11 transgenic lines were randomly selected for further analysis. The polymerase chain reaction (PCR) and ribonucleic acid (RNA) gel blot indicated that the TaLEA gene had been integrated into the poplar genome. The height growth rate, malondialdehyde (MDA) content, relative electrolyte leakage and damages due to salt or drought to transgenic and non-transgenic plants were compared under salt and drought stress conditions. The results showed that the constitutive expression of the TaLEA gene in transgenic poplars could induce an increase in height growth rate and a decrease in number and severity of wilted leaves under the salt and drought stresses. The MDA content and relative electrolyte leakage in transgenic lines under salt and drought stresses were significantly lower compared to those in non-transgenic plants, indicating that the TaLEA gene may enhance salt and drought tolerance by protecting cell membranes from damage. Moreover, amongst the lines analyzed for stress tolerance, the transgenic line 11 (T11) showed the highest tolerance levels under both salinity and drought stress conditions. These results indicated that the TaLEA gene could be a salt and drought tolerance candidate gene and could confer a broad spectrum of tolerance under abiotic stresses in poplars.     

Improved yield,fruit quality,and salt resistance in tomato co-overexpressing LeNHX2 and SlSOS2 genes

The K⁺, Na⁺/H⁺ antiporter LeNHX2 and the regulatory kinase SlSOS2 are important determinants of salt tolerance in tomato plants and their fruit production ability. In this work, we have analyzed the effects of LeNHX2 and SlSOS2 co-overexpression on fruit production, quality in tomato plants (Solanum lycopersicum L. cv. MicroTom), and analyzed physiological parameters related to salt tolerance. Plants overexpressing LeNHX2, SlSOS2 or both were grown in greenhouse. They were treated with 125 mM NaCl or left untreated and their salt tolerance was analyzed in terms of plant biomass and fruit yield. Under NaCl cultivation conditions, transgenic tomato plants overexpressing either SlSOS2 or LeNHX2 or both grew better and showed a higher biomass compared to their wild-type plants. Proline, glucose and protein content in leaves as well as pH and total soluble solid (TSS) in fruits were analyzed. Our results indicate that salinity tolerance of transgenic lines is associated with an increased proline, glucose and protein content in leaves of plants grown either with or without NaCl. Salt treatment significantly reduced yield, pH and TSS in fruits of WT plants but increased yield, pH and TSS in fruits of transgenic plants, especially those overexpressing both LeNHX2 and SlSOS2. All these results indicate that the co-overexpression of LeNHX2 and SlSOS2 improve yield and fruit quality of tomato grown under saline conditions.