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:Drought is an important environmental factor affecting plant growth and biomass production. Despite this importance, little is known on the molecular mechanisms regulating plant growth under water limiting conditions. The main goal of this work was to investigate, using a combination of growth and molecular profiling techniques, how Arabidopsis thaliana leaves adapt their growth to prolonged mild osmotic stress. Fully proliferating, expanding and mature leaves were harvested from plants grown on plates without (control) or with 25mM mannitol (osmotic stress) and compared to seedlings at stage 1.03. Total RNAs were extracted using Trizol method from vegetative part of seedlings at stage 1.03 and leaves that are fully proliferating, expanding or mature. All plants were grown in vitro on medium without (0mM) or with mannitol (25mM) in three independent biological experiments. Each sample was pooled from multiple plants and multiple plates in one experiment. RNA samples were submitted to ATH1 array hybridization.

Project description:Drought is an important environmental factor affecting plant growth and biomass production. Despite this importance, little is known on the molecular mechanisms regulating plant growth under water limiting conditions. The main goal of this work was to investigate, using a combination of growth and molecular profiling techniques, how Arabidopsis thaliana leaves adapt their growth to prolonged mild osmotic stress. Fully proliferating, expanding and mature leaves were harvested from plants grown on plates without (control) or with 25mM mannitol (osmotic stress) and compared to seedlings at stage 1.03.

Project description:Drought is an important environmental factor affecting plant growth and biomass production. Despite this importance little is known on the molecular mechanisms regulating plant growth under water limiting conditions. The main goal of this work was to investigate, using a combination of growth and molecular profiling techniques, how stress arrests CELl proliferation in Arabidopsis thaliana leaves upon osmotic stress imposition. Plants were grown on nylon meshes overlaying control 0.5MS media. At 9 DAS when third leaf is fully proliferating seedlings were transfered to either mannitol (25mM) or control plates, and proliferating leaves were micro-dissected at 1.5h, 3h, 12h and 24h after stress imposition and using RNAlater solution (25mM). Samples were from three independent biological experiments. Each sample was pooled from multiple plants and multiple plates in one experiment. RNA samples were submitted to ATH1 array hybridization.

Project description:We sought to generate a comprehensive proteomic profile for a Populus plant that captures protein abundance behavioral differences in mature leaves under various water deficit conditions. The sudden infliction of severe drought is unlikely to reflect what naturally happens to soil-grown plants. Therefore, rather than exposing plants to severe dehydration via the application of concentrated osmotica (e.g., polyethylene glycol or mannitol), we aimed to monitor plants exposed to prolonged drought as well as plants frequently experiencing cyclic drought. For the progressive drought experiment, herein referred to as acute drought, water will be withheld from the plants for a certain period of time until symptoms of wilting are observed. From this drought treatment, protein abundance changes that occur because of declining water potentials that consequently lead to worsening plant health will provide new insights to biological pathways in response to severe drought conditions. On the other hand, as a consequence of simulating a more natural condition, the cyclic drought treatment will provide novel insights into drought recovery and coping mechanisms. As first noted in a meta-analysis of microarray experiments comparing different water deficit-related treatments3, one consequence of analyzing multiple treatment conditions is that we expect only a few differentially abundant proteins to be common to both treatments. Therefore, we implemented a bioinformatic framework to provide an overall integrative picture of the conserved drought markers but also meaningful divergences in functional behavioral responses between the two experiments.

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:Expression Data from International C.elegans Experiment 1st

Project description:Genome-wide transcriptome analysis of Arabidopsis thaliana was performed to understand the role of auxin in the response of leaf growth to osmotic stress. We studied transcriptional changes in proliferating leaves of the seedlings grown in vitro on control medium, medium supplemented with 25mM mannitol, 0.1μM NAA and 0.1μM NAA + 25mM mannitol.

Project description:Transcriptional profiling of rossette leaves comparing wild type (Col-0) and the mutant (hsi2-5) under no drought or simulated drought stress. Two-condition experiment; wild type (col-0) vs. mutant (hsi2-5). Three stages of drought; no drought (or stage 0), mild drought or soil drying but no visible wiliting (or stage 1), visible wilting (stage 2). At stage 0, four biological replicates of the wild type/mutant co-hybridized, at stage 1 and stage 2, three biological replicates of the wild type/mutant co-hybridized.

Project description:Environmental conditions contributing to abiotic stresses such as drought and salinity result in large annual economic losses around the world. As sessile organisms, plants cannot escape the environmental stresses they encounter, but instead must adapt to survive. Previous studies investigating osmotic and/or salt responses have largely focused on understanding short-term responses (0-1h) at the transcriptomic, proteomic and phosphoproteomic level; however, our understanding of intermediate to longer-term adaptation (24h - days) is relatively limited. In addition to protein abundance and phosphorylation changes, recent evidence suggests reversible protein acetylation may be important for abiotic stress responses. Therefore, to characterize the effects of osmotic and salt stress, we undertook a label-free proteomic and PTMomic analysis of Arabidopsis roots exposed to 300mM Mannitol and 150mM NaCl for 24 h. We quantitatively assessed protein abundance, phosphorylation and acetylation.