Project description:Preceding hypoxia by an ethylene treatment improves root tip survival. To identify key players and processes mediating ethylene enhanced tolerance, the transcriptomic response of root tips was investigated directly after ethylene or control pretreatment, 2 and 4 hours of subsequent hypoxia, and 1 hour of reoxygenation. Seedlings were 4 days or 7 days old and grown on MS plates without added sugar. Only the root tips were harvested

Project description:A complex interplay between ethylene, ETP1/ETP2 F-box proteins, and degradation of EIN2 is essential for triggering ethylene responses in plants. The gaseous plant hormone ethylene can trigger myriad physiological and morphological responses in plants. While many ethylene signaling pathway components have been identified and characterized, little is known about the function of the integral membrane protein EIN2, a central regulator of all ethylene responses. Here, we demonstrate that Arabidopsis thaliana EIN2 is a protein with a short half-life that undergoes rapid proteasome-mediated protein turnover. Moreover, EIN2 protein accumulation is positively regulated by ethylene. We identified two F-box proteins, EIN2 TARGETING PROTEIN and 2 (ETP1 and ETP2), that interact with the EIN2 carboxyl-terminal domain (CEND), which is highly conserved and sufficient to activate most ethylene responses. Overexpression of ETP1 or ETP2 disrupts EIN2 protein accumulation, and these plants manifest a strong ethylene insensitive phenotype. Furthermore, knocking down the levels of both ETP1 and ETP2 mRNAs using an artificial microRNA (amiRNA) leads to accumulation of EIN2 protein, resulting in plants that display constitutive ethylene response phenotypes. Finally, ethylene down-regulates ETP1 and ETP2 proteins, impairing their ability to interact with EIN2. Thus, these studies reveal that a complex interplay between ethylene, the regulation of ETP1/ETP2 F-box proteins, and subsequent targeting and degradation of EIN2 is essential for triggering ethylene responses in plants. Experiment Overall Design: Six samples were analyzed. There were three treatments with two biological replicates each. The treatments are as follows: 8 week old Col-0 plants (air control), 8 week old Col-0 plants treated for 24 hours with ethylene gas (10 ppm), and artificial microRNA knockdown mutants, amiR-ETP1/2.

Project description:Ethylene response in Arabidopsis with wild-type or kinase-inactive ETR1

Project description:This study analyzes transcriptome profiles in pre-germinated seeds and hypoxia-treated seedlings of Arabidopsis thaliana wild type (Col-0) and homozygous mutants (prt6-1 and ate1 ate2). This dataset includes CEL files, RMA signal values and MAS5 P/M/A calls. For pre-germinated seeds, seeds imbibed for 24 h were used for total RNA extraction. For hypoxia treatment, 7-d-old seedlings were incubated in a hypoxia chamber for 2 h and the entire seedling was subjected to RNA extraction. Quantitative profiling of cellular mRNAs was accomplished with the Affymetrix ATH1 platform. Changes in the transcriptome during early seed germination stage and in response to hypoxia in seedlings were evaluated. The data led to identification of mRNAs with abundance regulated by PRT6 and ATE1 / ATE2, which are essential components for the N-end rule pathway of targeted proteolysis (NERP). A combination of genetic, biochemical and molecular analyses reveal that NERP coordinates the stability of key ethylene responsive factor (ERF) family transcription factors, which regulate expression of core hypoxia response genes and tolerance to low oxygen stress. This indicates that the NERP functions as a homeostatic sensor of low oxygen in plants. Pre-germinated seeds; 2 genotypes (Col-0 and prt6-1) x 3 independent biological replicate experiments: Hypoxia treated seedlings; 3 genotypes (Col-0, prt6-1, and ate1 ate2) x 2 treatments (2h aerobic and 2h hypoxia) x 2 independent biological replicate experiments.

Project description:Aerenchyma is a specialized tissue consisting of longitudinal gas spaces, which enables internal movement of gases (e.g., O2, CO2, ethylene and methane), in plant roots, petioles and stems. Especially, internal transport of oxygen via aerenchyma from shoots to roots is very important for adaptation or survival of plants under waterlogged condition. To identify aerenchyma formation-associated genes expressed in maize root, we used LM combined with a microarray for monitoring genes expressed in root cortical cells under three conditions: under aerobic condition and under waterlogged condition with and without pretreatment with 1-MCP, an inhibitor of ethylene perception. For the waterlogging treatments, the primary root (but not the shoots) was waterlogged. Two and half day-old-seedlings were pre-treated with an inhibitor of ethylene perception 1-methylcyclopropene (1-MCP; 1 ppm) for 12 hours before the waterlogging treatment. Three-day-old seedlings were growing under aerated condition at the same time with other treatments as a control. Total RNA was extracted from root cortex cells from the segment of the primary root, 0.5 cm long: from 1.5 to 2 cm from the junction shoot-root derived from 3-days-old maize seedlings, and subjected to 44k oligo-DNA microarray (1. Aerated vs Hypoxia, 2. Hypoxia+MCP vs Hypoxia) with 3 biological replicates and color swaps.

Project description:We analyzed global transcriptional changes in both shoots and roots of root-flooded Arabidopsis seedlings by microarrays. We also interpreted the significance of the systemic communication between roots and shoots by functional classification of affected genes. We performed genetic analysis with an ethylene signaling mutant, ein2-5, to correlate systemic flooding responses with ethylene signaling. We identified a class of genes that were up- or downregulated in shoots, but not affected in roots, under hypoxic conditions. A comprehensive managing program of carbohydrate metabolism was observed, providing an example of how systemic communications might facilitate the survival of plants under flooding. A proportion of long-distance hypoxic regulation was altered in ein2-5. Time course experiments (0.5, 1, 3, 6, and 12h for Columbia; 0.5, 3, and 6h for ein2-5). Tissues from root-flooded seedlings vs. Tissues from un-flooded seedlings. Biological replicates: 4 replicates for each time point, independently grown, treated, and harvested. One replicate per array. 2 of 4 replicates are dye-swapped.

Project description:Ethylene plays major roles in adaptive growth of rice plants in water-saturated soil; however, ethylene signaling in rice is largely unclear. Here, we report identification and characterization of ethylene-response mutants based on distinct ethylene-response phenotypes of dark-grown rice seedlings. The seeds were soaked in tap-water and germinated at 37°C in the dark for two days (change the water daily). For ethylene treatment, we reduced the amount of water to 1.5-1.7cm below the seeds.Three-day old seedlings were treated with ethylene (10 ppm) for 8 hours at 28°C in the dark. Seedling grown in the air was used as control. We isolated RNA from roots and shoots of wild-type and mutant.

Project description:Ethylene plays major roles in adaptive growth of rice plants in water-saturated soil; however, ethylene signaling in rice is largely unclear. Here, we report identification and characterization of ethylene-response mutants based on distinct ethylene-response phenotypes of dark-grown rice seedlings. The seeds were soaked in tap-water and germinated at 37°C in the dark for two days (change the water daily). For ethylene treatment, we reduced the amount of water to 1.5-1.7cm below the seeds.Three-day old seedlings were treated with ethylene (10 ppm) for 8 hours at 28°C in the dark. Seedling grown in the air was used as control. We isolated RNA from roots and shoots of wild-type and mutant.

Project description:Ethylene plays major roles in adaptive growth of rice plants in water-saturated soil; however, ethylene signaling in rice is largely unclear. Here, we report identification and characterization of ethylene-response mutants based on distinct ethylene-response phenotypes of dark-grown rice seedlings. The seeds were soaked in tap-water and germinated at 37M-BM-0C in the dark for two days (change the water daily). For ethylene treatment, we reduced the amount of water to 1.5-1.7cm below the seeds.Three-day old seedlings were treated with ethylene (10 ppm) for 8 hours at 28M-BM-0C in the dark. Seedling grown in the air was used as control. We isolated RNA from roots and shoots of wild-type and mutant.

Project description:To adapt to waterlogging in soil, some gramineous plants, such as maize (Zea mays), form lysigenous aerenchyma in the root cortex. Ethylene, which is accumulated during waterlogging, promotes aerenchyma formation. Aerencyma is formedonly in cortex in maise root. Therevore, aerenchyma is one of the model of programmed cell death. However, the molecular mechanism of aerenchyma formation is not understood. Therefore we isolated only cortex cells in maize primary root using laser microdissection. And microarray analysis was perforemed to identify the arechyma formation related genes. For microarray analysis, we designed 4 different experiments. Basal part and apical part of root were used for 1st experiment because arenchyma was formed in basal part of root, but not in apex. In second experiment, basal part of root with 6 hours waterlogged treatment and without treatment were used. And, as aerenchyma was induced by ethylene, ethylene and 1-MCP (inhibitor of ethylen perception) were used for experiment3 and 4. Gene expression analysis in 4 kinds of samples (cortex in basal reagion of maize primary root which were treated with waterlogged condition, aerobic condition, ethylene and 1-MCP and cortex in apical reagion of maize primary root which were treated with waterlogged conditio)