Project description:Mesembryanthemum crystallinum, a facultative CAM plant, shifts from C3 to CAM photosynthesis under salt stress, enhancing water use efficiency due to inverse stomatal patterns. Exploring the mechanisms of this transition could improve salt tolerance in C3 crops. We used transcriptomics, proteomics, and targeted metabolomics every 8 hours to track molecular shifts during this transition. Results confirmed changes in CAM photosynthesis, starch biosynthesis, degradation, and glycolysis/gluconeogenesis. Transcripts displayed greater circadian regulation than proteins. Oxidative phosphorylation was crucial, with the inositol pathway, involving methylation and phosphorylation, potentially initiating the transition. V-type ATPases showed consistent transcription regulation, aiding in vacuolar osmotic pressure maintenance. ABI1, a major component in the ABA signaling pathway, could be the trigger for the salt-induced transition, as it inhibits ABA-dependent stomatal closure. Our work highlights the pivotal role of ABA pathways in the C3 to CAM shift.

Project description:Coordinated regulation of protection mechanisms against environmental abiotic stress and pathogen attack is essential for plant adaptation and survival. Initial abiotic stress can interfere with disease resistance signaling. Conversely, initial plant immune signaling may interrupt subsequent ABA signal transduction. However, the processes involved in cross talk between these signaling networks have not been determined. By screening a 9,600 compound chemical library, we identified a small molecule [5-(3,4-Dichlorophenyl)Furan-2-yl]-Piperidin-1-ylMethanethione that rapidly down-regulates ABA-dependent gene expression and also inhibits ABA-induced stomatal closure. Transcriptome analyses show that DFPM also stimulates expression of plant defense-related genes. Plate grown 12-day-old seedlings were transferred into 6 well plates with 1:5000 (V/V) DMSO in water as a control, 30uM DFPM, and 10uM ABA in water as a treatment for 6 hours. DFPM was added 30 min prior to ABA treatment. RNA was extracted using Trizol (Invitrogen, Carlsbad, CA, USA) and further purified using RNeasy Plant RNA purification kit (QIAgen, Valencia, CA, USA). Three biological replicates of ATH1 oligonucleotide arrays were hybridized with labeled samples from 1) wild-type Columbia (WT) untreated, 2) WT with 30uM DFPM treatment, 3) WT with 10uM ABA treatment, 4) WT with 30uM DFPM and 10uM ABA treatment. Each biological replicate was prepared by combining 7 independently-treated samples. Seedling treatments, 4 agent, 1 genotype/variation sets.

Project description:We previously showed that increased levels of the tomato DELLA protein PROCERA (PRO) promoted ABA responses in guard cells, including ABA-induced stomatal closure and gene expression. Thus we aimed to identifiy DELLA-regulated genes in guard cells in order to study the molecular mechanism by which DELLA promotes stomatal closure.

Project description:Coordinated regulation of protection mechanisms against environmental abiotic stress and pathogen attack is essential for plant adaptation and survival. Initial abiotic stress can interfere with disease resistance signaling. Conversely, initial plant immune signaling may interrupt subsequent ABA signal transduction. However, the processes involved in cross talk between these signaling networks have not been determined. By screening a 9,600 compound chemical library, we identified a small molecule [5-(3,4-Dichlorophenyl)Furan-2-yl]-Piperidin-1-ylMethanethione that rapidly down-regulates ABA-dependent gene expression and also inhibits ABA-induced stomatal closure. Transcriptome analyses show that DFPM also stimulates expression of plant defense-related genes. Plate grown 12-day-old seedlings were transferred into 6 well plates with 1:5000 (V/V) DMSO in water as a control, 30uM DFPM, and 10uM ABA in water as a treatment for 6 hours. DFPM was added 30 min prior to ABA treatment. RNA was extracted using Trizol (Invitrogen, Carlsbad, CA, USA) and further purified using RNeasy Plant RNA purification kit (QIAgen, Valencia, CA, USA). Three biological replicates of ATH1 oligonucleotide arrays were hybridized with labeled samples from 1) wild-type Columbia (WT) untreated, 2) WT with 30uM DFPM treatment, 3) WT with 10uM ABA treatment, 4) WT with 30uM DFPM and 10uM ABA treatment. Each biological replicate was prepared by combining 7 independently-treated samples.

Project description:Gene expression profiling of retrograde PAP-signaling and ABA-signaling mutants in response to ABA treatment

Project description:Mutations in the heterotrimeric G-protein a-subunit of Arabidopsis, GPA1, leads to deficiency in ABA-induced stomatal closure (Wang et al., 2001). To further investigate whether GPA1 is involved in the regulation of gene expression in response to ABA, we examined the induction of known ABA-inducible genes in the gpa1 mutant and compared it to wild-type. We found significant differences in levels of ABA-induced expression between wild-type and gpa1 mutant. In order to systematically investigate GPA1 involvement in ABA signalling leading to gene expression, we are requesting the transcriptome analysis of the gpa1 mutant in response to ABA.In detail, 2 week old wild-type and gpa1 plants grown in the 16/8 hrs light and dark cycle will be treated with either ABA or with a control solution for 3 hours. 10 plants will be used per sample to produce RNA, to give 4 samples, one for each chip: gpa1-1 mutant in the presence (chip1) or absence of ABA (chip2) and wild-type (WS2) in the presence (chip3) or absence of ABA (chip4).

Project description:Mutations in the heterotrimeric G-protein a-subunit of Arabidopsis, GPA1, leads to deficiency in ABA-induced stomatal closure (Wang et al., 2001). To further investigate whether GPA1 is involved in the regulation of gene expression in response to ABA, we examined the induction of known ABA-inducible genes in the gpa1 mutant and compared it to wild-type. We found significant differences in levels of ABA-induced expression between wild-type and gpa1 mutant. In order to systematically investigate GPA1 involvement in ABA signalling leading to gene expression, we are requesting the transcriptome analysis of the gpa1 mutant in response to ABA.In detail, 2 week old wild-type and gpa1 plants grown in the 16/8 hrs light and dark cycle will be treated with either ABA or with a control solution for 3 hours. 10 plants will be used per sample to produce RNA, to give 4 samples, one for each chip: gpa1-1 mutant in the presence (chip1) or absence of ABA (chip2) and wild-type (WS2) in the presence (chip3) or absence of ABA (chip4). Keywords: strain_or_line_design

Project description:Mutations in the heterotrimeric G-protein a-subunit of Arabidopsis, GPA1, leads to deficiency in ABA-induced stomatal closure (Wang et al., 2001). To further investigate whether GPA1 is involved in the regulation of gene expression in response to ABA, we examined the induction of known ABA-inducible genes in the gpa1 mutant and compared it to wild-type. We found significant differences in levels of ABA-induced expression between wild-type and gpa1 mutant. In order to systematically investigate GPA1 involvement in ABA signalling leading to gene expression, we are requesting the transcriptome analysis of the gpa1 mutant in response to ABA.In detail, 2 week old wild-type and gpa1 plants grown in the 16/8 hrs light and dark cycle will be treated with either ABA or with a control solution for 3 hours. 10 plants will be used per sample to produce RNA, to give 4 samples, one for each chip: gpa1-1 mutant in the presence (chip1) or absence of ABA (chip2) and wild-type (WS2) in the presence (chip3) or absence of ABA (chip4). Experiment Overall Design: Number of plants pooled:10 plants

Project description:Abscisic acid (ABA) plays a key role in plant development and responses to abiotic stress. A wide number of regulatory mechanisms on ABA perception and signaling are known, including transcriptional regulation and post-translational regulations; however, less to know about the post-transcriptional regulations. In this work, we have found that SKIP, a splicing factor in spliceosome, positively regulates ABA signal transduction. Mutation of SKIP, skip-1, confers ABA insensitive phenotype in seed germination, root growth, and ABA-responsive gene expression. Transformation of SKIP genomic DNA to skip-1 is able to recover its defects. SKIP binds to the pre-mRNA of genes in ABA signaling, such as PYL8, to regulate their splicing. The alternative splicing of PYL7, PYL8, ABF2, and ABI5 in ABA pathway is disrupted by skip-1, reducing the mRNA levels of them. The abnormal splicing of PP2Cs activates their transcription by skip-1, suggesting there is a feedback regulation for PP2Cs caused by skip-1. The down-regulation of PYL ABA receptors, ABF2 and ABI5 ABA response transcription factors, and the up-regulation of PP2Cs through alternative splicing reduce the plant responses to ABA in skip-1. SKIP is required for ABA-mediated genome-wide alternative splicing. ABA treatment enhances the novel splicing events in WT genome-widely. The novel alternative splicing events are increased by skip-1 in the absence and present of ABA. Our results first reveal a principle on how a splicing factor affects the ABA signaling.

Project description:Water availability is a key determinant of terrestrial plant productivity. Many climate models predict that water stress will increasingly challenge agricultural yields and exacerbate projected food deficits. To ensure food security and increase agricultural efficiency, crop water productivity must be increased. Research over past decades has established that the phytohormone abscisic acid (ABA) is a central regulator of water use and directly regulates stomatal opening and transpiration. In this study, we investigated whether the water productivity of wheat could be improved by increasing its ABA sensitivity. We show that overexpression of a wheat ABA receptor increases wheat ABA sensitivity, which significantly lowers a plant’s lifetime water consumption. Physiological analyses demonstrated that this water-saving trait is a consequence of reduced transpiration and a concomitant increase in photosynthetic activity, which together boost grain production per liter of water and protect productivity during water deficit. Our findings provide a general strategy for increasing water productivity that should be applicable to other crops because of the high conservation of the ABA signaling pathway.