Project description:In natural habitats, plants are often exposed to multiple stresses. Most studies, however, for plant abiotic stress responses analyzed those to individual stress but not combined stresses. In this report, we performed comparison analyses of gene expression to individual stresses, salt, osmotic and heat, and to a combination of these three stresses, which mimics arid conditions. We show here that the combined stress treatment induces unique gene expression pattern but not a simple reflection of the additive effects of individual stresses. First, the number of genes induced by combined stresses (150 mM NaCl, 200 mM mannitol and 35°C heat) was much smaller when compared to the sum of those induced by individual stress treatments, while the number of genes downregulated by multiple stresses was larger. A large number of genes induced by mannitol were not induced by multiple stresses, while those induced by salts were less affected in combined stress treatments. In addition, 125 genes, including13 for transcription factors, were found to be induced specifically by combined stress treatments. We report here that the plant response to a multi-stress environment represents an output of complex interactions between different stress aspects and signaling events of the various components of this environmental situation, and the determinative factor in this response is to avoid/minimize the antagonistic effects and to magnify the synergistic features of the imposed environmental challenges. Based on our results, we propose that genes that are highly induced by multiple treatments may be candidate for engineering stress tolerant crop plants. Wild-type plants of Arabidopsis thaliana were treated with three abiotic stresses, high salinity (150mM and 300mM), high osmotic pressure (200mM and 400mM mannitol) and heat (35°C), individually or simultaneously. Plants were treated with salt or mannitol for 16 hrs (first 1 hr and last 7 hrs are in light and other time in dark) or with heat for 4 hrs (in light) before sampling. There are three biologcal replicates.

Project description:Crop plants are often exposed to the combination of drought and pathogen stress. Transcriptome studies on Arabidopsis thaliana and other plants unveiled activation of shared molecular defense mechanisms between under individual and combined stresses. These shared plant responses are characterized by commonly regulated genes under individual and combined stresses. Based on the previous studies, G-box binding factor 3 (GBF3) is one of the regulatory components of such shared responses. However, the mechanistic understanding on the role of GBF3 under combined drought and pathogen stress is not yet decoded. Using genetic approaches, we demonstrated Atgbf3 mutant plants are more susceptible under individual and combined drought and Pseudomonas syringae pv. tomato DC3000 stresses as compared to the wild-type plants. We further analyzed the global transcriptome of Atgbf3 mutant under combined stress to identify its downstream targets to further validate the role of AtGBF3 in combined stress. We used microarrays to detail the global transcriptome reprogramming during AtGBF3-mediated regulation of combined stress.

Project description:Experiment to identify genes for responding to water stress in the moss Physcomitrella patens using various available water stresses such as mannitol, NaCl, and drought. Treatments were carried out on duplicate tissue samples. RNA isolated independently from each tissue sample and monitored for stress/hormone induction of the PpLea-2 gene by Northern blot hybridisation. Duplicate RNA samples bulked for Cy3/Cy5 labelling and array hybridisation. Two microarrays per treatment hybridised using a reciprocal dye swap (control -vs- treatment).

Project description:Environmental stresses such as drought, heat and salinity limit plant development and agricultural productivity. While individual stresses have been studied extensively, much less is known about the molecular interaction of responses to multiple stresses. To address this problem, we investigated molecular responses of Arabidopsis thaliana to single, double, and triple combinations of salt, osmotic, and heat stresses. A metabolite profiling analysis indicated the production of specific compatible solutes depending on the nature of the stress applied. We found that in combination with other stresses, heat has a dominant effect on global gene expression and metabolites level patterns. Treatments that include heat stress lead to strongly reduced transcription of genes coding for abundant photosynthetic proteins and proteins regulating the cell life cycle, while genes involved in protein degradation are upregulated. Under combined stress conditions, the plants shifted their metabolism to a survival state characterized by low productivity. Our work provides molecular evidence for the dangers for plant productivity and future world food security posed by heat waves resulting from global warming. We highlight candidate genes, many of which are functionally uncharacterized, for engineering plant abiotic stress tolerance.

Project description:We generated a comprehensive RNAseq expression atlas for several stress conditions in order to analyze changes in the gene expression during adaptation to mild stresses. The stresses are divided into two main groups: the “nutrient stresses” and the “environmental stresses”. Nutrient stresses include nutrient depletion (-N, -P, -S, -micronutrients), salt stress (+NaCl), osmotic stress (+mannitol) and control. The environmental stresses consist of high light, prolonged darkness, heat, cold and control.

Project description:Drought is one of the most detrimental environmental stresses to which plants are exposed. Especially mild drought is relevant to agriculture and significantly affects plant growth and development. In plant research, mannitol is often used to mimic drought stress and study the resulting responses. In growing leaf tissue of plants exposed to mannitol-induced stress, a highly-interconnected gene regulatory network is induced. However, early signaling and associated protein phosphorylation events that likely precede part of these transcriptional changes are largely unknown. Here, we performed a full proteome and phosphoproteome analysis on growing leaf tissue of Arabidopsis plants exposed to mild mannitol-induced stress and captured the fast (within the first half hour) events associated with this stress. Based on this in-depth data analysis, 167 and 172 differentially abundant and unique proteins and phosphorylated sites were found back, respectively. Finally, we identified H(+)-ATPASE 2 (AHA2) and CYSTEINE-RICH REPEAT SECRETORY PROTEIN 38 (CRRSP38) as novel regulators of shoot growth under osmotic stress.

Project description:Chickpea (Cicer arietinum) is the third largest legume grown worldwide and are prone to drought and various pathogen infections. These stresses often occur concurrently in the field conditions. Previous studies in other plant species indicated that plant senses concurrently occurring stresses as new state of stress however, the molecular events in response to that is largely unknown. In the present study, we studied the transcriptome changes in chickpea plants exposed to combination of drought stress and a potential wilt pathogen, Ralstonia solanacearum by microarray analysis. Chickpea plants were exposed to short duration individual drought (SD-drought, soil field capacity, FC-35%), long duration individual drought (LD-drought, FC-30%), short duration individual pathogen stress (SD-pathogen = 2 days pathogen infection), long duration individual pathogen stress (LD-pathogen = 4 days of infection) and short duration and long duration combined stress, SD-combined = 2 days of pathogen infection with progressive drought (FC-40% to FC- 35%), LD combined = 4 days of pathogen infection with progressive drought (FC-35% to 30%).Transcriptome analysis for the leaf samples from above treatment were done by microarray analysis using Agilent ChickpeaGXP_8X60K chip. Result indicated presence of specific molecular events and also some common but tailored events in response to combined stress. Global transcriptional analysis in chickpea leaves exposed to individual and combined drought stress and Ralstonia solanacearum infection.

Project description:Mannitol is a sugar alcohol that serves as a compatible solute contributing to exceptional salt tolerance in several plant species. Arabidopsis plants transformed with the mannose-6-phosphate reductase (M6PR) gene from celery were dramatically more salt tolerant. Following treatment with 100mM NaCl, transgenic plants, relative to wild type (WT), were more successful in bolting, flowering, and production of viable seed, were less chlorotic/necrotic, and with less inhibition of growth (leaf number, rosette diameter, plant height, stalk number, and dry weight). When irrigated with 200 mM NaCl, both transformants and WT plants died without producing seeds, but M6PR transformants bolted and showed significantly less chlorosis and necrosis and had higher survival rates and dry weights than those of WT. Under normal growth conditions there were no negative effects of the M6PR transgene on overall growth (leaf number, rosette diameter, plant height, stalk number, and dry weight), or time to bolting/flowering or seed production compared to wild type (WT). Despite the lack of effects on phenotype in the absence of salt stress, genome wide expression analyses indicated that expression levels of more than 2000 genes were altered by presence of the M6PR transgene: however, there were many fewer differences observed between the M6PR and non-transgenic plants in the presence of salt stress (459), suggesting that M6PR pre-conditioned the plants for exposure to salinity. Gene categories most affected in the M6PR transgenic plants were involved in DNA binding, signal transduction, metabolism/energy, cell structure, membrane transport, defense response, and transcription. Notably, a large number of known stress genes were induced, including those related to cell walls, biotic stress, and ABA- and ethylene-responses. Our work and that in other labs has suggested that mannitol acts as an osmoprotectant, but mannitol levels are invariably quite low, and perhaps inadequate to explain its effects as an osmoprotectant. The gene expression data here indicate that stress tolerance of mannitol-producing Arabidopsis is also due, at least in part, to enhanced expression of a number of stress inducible genes related to both biotic and abiotic stress tolerance. Both M6PR transgenic and Col WT plants were grown in the growth chamber in the absence and presence of salt stress. Plants from 20 days after sowing (6 days after salt treatment) were used for RNA extraction and hybridization on Affymetrix microarrays. There were two biological replicates for each genotype and salt treatment combination.

Project description:Mannitol induced drought stress, metabolic labeling experiment 14N control vs 15N mannitol induced drought stress, 0mM mannitol control experiment, LCMSMS of gel slice10 of 20, 1st of 2 replicas, 14 N peptide searching

Project description:Plants often face combinatorial stresses in their natural environment. Here arsenic (As) toxicity was combined with hypoxia (Hpx) in the roots of Arabidopsis thaliana as it often occurs in nature. The present work aimed to explore the effects of single and combined hypoxia and As stress applied at realistic stress levels to hydroponically grown A. thaliana. Arsenic as well as hypoxic growth conditions generate a characteristic signaling pattern, a significant part of which is mediated by ROS. The current study utilized the microarray to determine the overlapping signalling pattern and changes in gene expression for the defined stress combinaton compared to individual stresses.