Project description:Carbon (C), nitrogen (N) and phosphorus (Pi) are crucial macronutrients for plants. While substantial knowledge exists on C/N balance signaling physiological and molecular perspectives, the core regulatory mechanism governing C/N and Pi balance remains largely unexplored. This study reveals that C/N assimilatory metabolisms matching the Pi-deficiency stress is integrated by a DEEP GREEN PANICLE1 (DGP1)-mediated regulatory network in rice (Oryza sativa). We found that low-Pi stress triggers DGP1 expression in a dose-responsive manner, facilitated by the PHOSPHATE STARVATION RESPONSE REGULATOR (PHR2). Intriguingly, DGP1 interacts with transcription factors (GLK1 and GLK2) and mitochondrial factors (GDCH and QCR9), modulating their roles in photosynthetic gene expression, the glycine cleavage system and the mitochondrial electron transport chain (mETC), respectively. Additionally, DGP1 influences aminoacyl-tRNA synthetases and ribosomal subunits, impacting protein biosynthesis, and intervenes in various metabolic pathways, including glycolysis and the citrate cycle. Phenotypically, we observed that under short-term Pi-deficiency, wild-type plants exhibit compromised photosynthesis, photorespiration and mETC-driven ATP synthesis, whereas dgp1 and phr2 mutants display reduced sensitivity to these conditions. Conversely, DGP1 overexpressors show decreased yield under normal conditions due to altered cell metabolomes and protein biosynthesis inadequacy, despite unaffected 15NO3– uptake and transport. In conclusion, the PHR2-DGP1 module orchestrates a comprehensive signaling network, harmonizing C and N metabolic fluxes under Pi limitation through coordinated interactions among cytoplast, chloroplast and mitochondria.

Project description:The goal of this study is to identify transcriptome changes by the RPGE overexpression or glk1/glk2 double mutant under white light. We compared the transcriptome of RPGE2-OX (35Spro::GFP-RPGE2) with wild type (Col-0) and glk12 (glk1/glk2 double mutant) with wild type in continuous white light to investigate the expression changes of genes which are related with chloroplast development and the relationship between RPGE and GLK in the chloroplast development process.

Project description:We sequenced mRNA of WT (Col-0) and glk1 glk2 double mutants under LD conditions. RNA was extracted from seedlings of 1.02 developmental stage at ZT4 and proceeded for library preparation

Project description:Aim: To discover the target genes of Golden2-like transcription factors in Arabidopsis. Background: The Golden2-like (GLK) family of transcription factors is essential for proper chloroplast development in several plant species. In Arabidopsis, there are two largely redundant GLK genes, GLK1 and GLK2. Double mutant plants are pale green and reduced in stature. Their most notable chloroplast-related phenotype is impaired thylakoid membrane appression and reduction in steady-state levels of Photosystem II components. GLK proteins group within the GARP family of myb transcription factors; however, the genes they regulate remain unknown. Experimental Design: We have employed a two-component dexamethasone-inducible expression system [1]. An overexpressed fusion protein comprising the glucocorticoid receptor (GR), the lac repressor and the Gal4 activation domain resides in the plant cytoplasm. This protein, termed LHGR-N, enters the nucleus once dexamethasone binds to the GR domain. It then activates transcription from the lac operator promoter sequences present on separate transgenes which carry the cDNA to be induced. Since overexpression of either GLK1 or GLK2 is sufficient to complement the mutant phenotype, we reasoned that induction of expression of GLK1 and GLK2 cDNAs in the glk1;glk2 double mutant background should allow determination of their downstream genetic targets. In the first case, we decided to focus on GLK1 only. Genetic lines: Plants carrying a single copy of the LHGR-N transgene, conferring kanamycin resistance, were crossed with glk1;glk2 double mutant plants. A single homozygous F3 line was selected on the basis of pale green mutant phenotype and kanamycin resistance. This line was transformed with a construct carrying the GLK1 cDNA downstream of six repeats of the lac operator (pOp6) and a single CaMV minimal promoter. This construct confers hygromycin resistance. Transformants were confirmed by PCR and Southern blot, before being selected on the basis of transcript accumulation following induction by dexamethasone. The line with the strongest induction response was chosen for microarray experiments. Tissues: Approx. 100 10-day-old seedlings were grown on MS plates and transferred to 100 ml liquid MS for two further days prior to induction. Whole seedlings were harvested. Treatment: Either a) 10 uM dexamethasone dissolved in DMSO (INDUCED samples) or b) 0.1% v/v DMSO (CONTROL samples). Samples were harvested 4 and 24 hours post-treatment. Separate vessels were used for each time point and treatment. Two complete replicates were performed. Reference1. Craft, J. et al. (2005) Plant J. 41 899-918. 10 samples were used in this experiment.

Project description:Regulation of stomatal movement is one of the effective strategies for developing resistant crops to air pollutant because stomata allows absorption of various air pollutants, such as ozone and sulfur dioxide. Transcription factor (TF) is a fascinating target of genetic manipulation for this end because TF regulates many genes simultaneously and methods of genetic manipulation are universally established. Here, we have screened transgenic Arabidopsis lines expressing chimeric repressor of TFs in high-concentration of ozone and found that the chimeric repressors of GOLDEN-LIKE1 (GLK1) and GLK2 (GLK1-SRDX and GLK2-SRDX) conferred strong tolerance to ozone. These 35S:GLK1/2-SRDX plants also showed sulfur dioxide tolerance. Their leaves showed lower rate of transpiration than wild type and a remarkable closed-stomata phenotype. The expression of the genes encoding K+ and water channels, including KAT1 and AKT1, which are involved in stomatal opening, was downregulated in 35S:GLK1-SRDX plants. Consistently, expression of GLK1-SRDX driven by the GC1 promoter, which has an activity only in guard cell, also induced closed-stomata and an ozone tolerant phenotype. On the contrary, 35S:GLK1/2 plants showed hypersensitivity to ozone and an opened-stomata phenotype. These data suggested that GLK1 and GLK2 have an ability to induce transcriptional change in guard cell and regulate stomatal movement. Our findings provide an effective tool to confer resistance to air pollutant by regulating stomatal aperture and improve crop productivity in future.

Project description:Aim: To discover the target genes of Golden2-like transcription factors in Arabidopsis. Background: The Golden2-like (GLK) family of transcription factors is essential for proper chloroplast development in several plant species. In Arabidopsis, there are two largely redundant GLK genes, GLK1 and GLK2. Double mutant plants are pale green and reduced in stature. Their most notable chloroplast-related phenotype is impaired thylakoid membrane appression and reduction in steady-state levels of Photosystem II components. GLK proteins group within the GARP family of myb transcription factors; however, the genes they regulate remain unknown. Experimental Design: We have employed a two-component dexamethasone-inducible expression system [1]. An overexpressed fusion protein comprising the glucocorticoid receptor (GR), the lac repressor and the Gal4 activation domain resides in the plant cytoplasm. This protein, termed LHGR-N, enters the nucleus once dexamethasone binds to the GR domain. It then activates transcription from the lac operator promoter sequences present on separate transgenes which carry the cDNA to be induced. Since overexpression of either GLK1 or GLK2 is sufficient to complement the mutant phenotype, we reasoned that induction of expression of GLK1 and GLK2 cDNAs in the glk1;glk2 double mutant background should allow determination of their downstream genetic targets. In the first case, we decided to focus on GLK1 only. Genetic lines: Plants carrying a single copy of the LHGR-N transgene, conferring kanamycin resistance, were crossed with glk1;glk2 double mutant plants. A single homozygous F3 line was selected on the basis of pale green mutant phenotype and kanamycin resistance. This line was transformed with a construct carrying the GLK1 cDNA downstream of six repeats of the lac operator (pOp6) and a single CaMV minimal promoter. This construct confers hygromycin resistance. Transformants were confirmed by PCR and Southern blot, before being selected on the basis of transcript accumulation following induction by dexamethasone. The line with the strongest induction response was chosen for microarray experiments. Tissues: Approx. 100 10-day-old seedlings were grown on MS plates and transferred to 100 ml liquid MS for two further days prior to induction. Whole seedlings were harvested. Treatment: Either a) 10 uM dexamethasone dissolved in DMSO (INDUCED samples) or b) 0.1% v/v DMSO (CONTROL samples). Samples were harvested 4 and 24 hours post-treatment. Separate vessels were used for each time point and treatment. Two complete replicates were performed. Reference1. Craft, J. et al. (2005) Plant J. 41 899-918.

Project description:RNA sequencing of glk1 glk2 double mutants under LD conditions at ZT4

Project description:Defining the transcriptome response to the brief induction of Golden2-like (GLK) gene expression in a glk mutant background. Expression of either GLK1 or GLK2 from an inducible promoter by the application of dexamethasone. Changes to transcriptome four hours after induction are compared with uninduced controls.

Project description:Phosphorus (Pi) starvation prevents a good match between light energy absorption and photosynthetic carbon metabolism. Photosynthetic electron-transport chain switches to use molecular oxygen as an electron carrier, generating photo-reactive oxygen species (photo-ROS) in chloroplast. In rice (Oryza sativa), DEEP GREEN PANICLE1 (DGP1) is robustly up-regulated in response to Pi-deficiency stress. DGP1 decreases the DNA-binding activities of the photosynthetic activators GLK1/2 on the genes involved in chlorophyll biosynthesis, light harvesting and electron transport. This Pi-starvation-induced mechanism dampens electron transport rates (ETRI and ETRII) and alleviates the electron-excessive stress in mesophyll cells. Meanwhile, DGP1 hijacks glycolytic enzymes GAPC1/2/3, redirecting glucose metabolism toward pentose phosphate pathway with superfluous NADPH production. Phenotypically, light irradiation induces O2– accumulation in Pi-starved WT leaves, but was observably accelerated in dgp1 mutant and impaired in GAPCsRNAi line and glk1glk2 double mutant. Interestingly, overexpression of DGP1 in rice caused hyposensitivity to the ROS-inducers (catechin and methyl viologen) and dgp1 mutant shows a similar inhibitory growth with the WT plants. We conclude that DGP1 gene serves as a specific antagonizer against Pi-starvation-induced photo-ROS, which integrates light-absorbing and anti-oxidative systems by orchestrating transcriptional and metabolic regulations, respectively.

Project description:Phosphorus (Pi) starvation prevents a good match between light energy absorption and photosynthetic carbon metabolism. Photosynthetic electron-transport chain switches to use molecular oxygen as an electron carrier, generating photo-reactive oxygen species (photo-ROS) in chloroplast. In rice (Oryza sativa), DEEP GREEN PANICLE1 (DGP1) is robustly up-regulated in response to Pi-deficiency stress. DGP1 decreases the DNA-binding activities of the photosynthetic activators GLK1/2 on the genes involved in chlorophyll biosynthesis, light harvesting and electron transport. This Pi-starvation-induced mechanism dampens electron transport rates (ETRI and ETRII) and alleviates the electron-excessive stress in mesophyll cells. Meanwhile, DGP1 hijacks glycolytic enzymes GAPC1/2/3, redirecting glucose metabolism toward pentose phosphate pathway with superfluous NADPH production. Phenotypically, light irradiation induces O2– accumulation in Pi-starved WT leaves, but was observably accelerated in dgp1 mutant and impaired in GAPCsRNAi line and glk1glk2 double mutant. Interestingly, overexpression of DGP1 in rice caused hyposensitivity to the ROS-inducers (catechin and methyl viologen) and dgp1 mutant shows a similar inhibitory growth with the WT plants. We conclude that DGP1 gene serves as a specific antagonizer against Pi-starvation-induced photo-ROS, which integrates light-absorbing and anti-oxidative systems by orchestrating transcriptional and metabolic regulations, respectively.