Project description:Response to salt stress of Raptor mutants

Project description:We performed an expression analysis of the response of seedling root tips to 1 hour of treatment with 140mM NaCl using mutants defective in root hair patterning. Cells are amazingly adept at integrating both external and internal cues to regulate transcriptional states. While internal processes such as differentiation and cell-type specification are generally understood to have an important impact on gene expression, very little is known about how cells utilize these developmental cues to regulate responses to external stimuli. Here we use the response to a well characterized environmental stress, high salinity, to obtain a global view of the role that cell identity plays in guiding transcriptional responses in the root of Arabidopsis. Our analysis is based on three microarray data sets we have generated that explore transcriptional changes spatially among 6 cell layers and 4 longitudinal regions or temporally along 5 time points after salt treatment. We show that the majority of the response to salt stress is cell-type specific resulting in the differential regulation of unique biological functions in subsets of cell layers. To understand the regulatory mechanisms controlling these responses we have analyzed cis-element enrichment in the promoters of salt responsive genes and demonstrate that known stress regulatory elements likely control responses to salt occurring in multiple cell types. Despite the extensive shift in transcriptional state that salt stress elicits, we are able to identify several biological processes that consistently define each cell layer and find that transcriptional regulators of cell-identity tend to exhibit robust cell-type specific expression. Finally, using mutants that disrupt cell-type specification in the epidermis, we reveal cell autonomous and non-autonomous effects when cell identity is altered. Together, these data elucidate a novel intersection between physiology and development and expand our understanding of how transcriptional states are regulated in a multi-cellular context. Keywords: Response analysis of mutants

Project description:Transcriptomic and phenotypic variation for salt stress response in Arabidopsis

Project description:this study discovered unique glycoprotein resources responsible for plant salt stress tolerance and suggested crucial roles of Nthis study discovered unique glycoprotein resources responsible for plant salt stress tolerance and suggested crucial roles of N-glycans in regulating salt responsive protein expression in Arabidopsis.-glycans in regulating salt responsive protein expression in Arabidopsis.

Project description:Role of the SPIRRIG protein in Arabidopsis thaliana salt stress response

Project description:Time course expression analysis of the salt stress response in Arabidopsis roots

Project description:We performed an expression analysis of the response of seedling root tips to 1 hour of treatment with 140mM NaCl using mutants defective in root hair patterning. Cells are amazingly adept at integrating both external and internal cues to regulate transcriptional states. While internal processes such as differentiation and cell-type specification are generally understood to have an important impact on gene expression, very little is known about how cells utilize these developmental cues to regulate responses to external stimuli. Here we use the response to a well characterized environmental stress, high salinity, to obtain a global view of the role that cell identity plays in guiding transcriptional responses in the root of Arabidopsis. Our analysis is based on three microarray data sets we have generated that explore transcriptional changes spatially among 6 cell layers and 4 longitudinal regions or temporally along 5 time points after salt treatment. We show that the majority of the response to salt stress is cell-type specific resulting in the differential regulation of unique biological functions in subsets of cell layers. To understand the regulatory mechanisms controlling these responses we have analyzed cis-element enrichment in the promoters of salt responsive genes and demonstrate that known stress regulatory elements likely control responses to salt occurring in multiple cell types. Despite the extensive shift in transcriptional state that salt stress elicits, we are able to identify several biological processes that consistently define each cell layer and find that transcriptional regulators of cell-identity tend to exhibit robust cell-type specific expression. Finally, using mutants that disrupt cell-type specification in the epidermis, we reveal cell autonomous and non-autonomous effects when cell identity is altered. Together, these data elucidate a novel intersection between physiology and development and expand our understanding of how transcriptional states are regulated in a multi-cellular context. Experiment Overall Design: Seedlings were grown for 5 days before being transferred to standard media or media supplemented with 140mM NaCl. One hour after transfer, a razor blade was used to cut the root ~5 mm above the root tip. Approximately 30 roots were pooled per replicate. Two biological replicates were performed per genotype, per condition.

Project description:Transcriptomic profiling of Arabidopsis thaliana mutants in response to combined abiotic stress

Project description:Salt stress is one of the abiotic stresses that adversely affect plant growth and agricultural productivity all over the word. Root is the organ that immediately suffers salt stress in soil, and thus the ability of roots to adapt to high salinity is critical for salt stress tolerance in plants. During a long-term evolution, plants have developed a variety of strategies to respond to salt stress. The mechanisms of salt stress response are complicated and are stilly largely unknown. In this study, through the screening of Arabidopsis mutants that are sensitive to salt stress, we identified a mutant itpk4, that displayed reduced root growth, reduced seeds germination, and increased root hairs under salt stress compared with wild type plants. in future, the molecular mechanism underlying the role of ITPK4 in root elongation under high.

Project description:Identification of differentially expressed genes in Arabidopsis thaliana mutants in response to combined abiotic stress treatment through Microarray experiment.