Project description:Plants take up nitrate in soils and utilize it both for nitrogen assimilation and as a signaling molecule. Thus, an essential role of nitrate in plants is triggering changes in gene expression patterns, including immediate induction of the expression of genes involved in nitrate transport and assimilation as well as several transcription factor genes and genes related with carbon metabolism and cytokinin biosynthesis and response. Recently we identified NIN-like proteins (NLPs) as transcription factors governing nitrate-inducible gene expression in Arabidopsis. Because of their similar DNA-binding property, nine NLP proteins may play redundant roles in controlling nitrate-regulated gene expression in Arabidopsis. The physiological roles of NLPs were therefore assessed by generating transgenic Arabidopsis plants expressing NLP6 fused to the transcriptional repression domain of SUPERMAN (SUPRD), which has an ability to convert transcriptional activators into transcriptional repressors. Our transcriptome analysis revealed that levels of nitrate-inducible expression of nitrate transporter genes (NRT1.1 and NRT2.1), nitrate reduction enzyme genes (NIA1, NIA2 and NIR1), the genes associated with ammonium assimilation (GLT1 for glutamine-2-oxoglutarate aminotransferase and ASN2 for asparagine synthetase), LBD37-39 transcription factor genes and genes encoding homologs of rice nitrate-inducible NIGT1 transcriptional repressor, were reduced in the NLP6-SUPRD lines. Furthermore, levels of nitrate-inducible expression of the genes associated with the oxidative pentose phosphate pathway (G6PD2 and G6PD3 for glucose-6-phosphate dehydrogenases, and 6-phosphogluconate dehydrogenase genes), cytokinin biosynthesis (IPT3) and signal transduction (A-type ARR genes), a gene encoding a Ser/Thr protein kinase associated with a calcineurin BM-bM-^@M-^Slike calcium sensor (CIPK3) were also found to be largely decreased by reductions in NLP activity. Because induction folds by nitrate and reduction folds by decreases in the NLP activity were well proportional, the NLP activity appeared to be responsible for most of nitrate responsiveness of the genes whose expression occurs immediately after nitrate treatment. Overall design: Gene expression in 3.5-day-old seedlings treated with or without 10 mM potassium nitrate was compared between the transgenic lines expressing a chimeric repressor form of NLP6 (NLP6-SUPRD) and the parental control line.

Project description:Plants modulate gene expression profile in response to nitrate through NIN-LIKE PROTEIN (NLP) transcription factors in order to promote nitrate uptake and utilization. Although there are 9 NLP proteins in Arabidopsis, NLP7 had attracted most of the attention. Here, we focused on NLP2, because the nlp2 and nlp7 knockout mutants displayed different phenotypes. To gain insight into genes whose expression was affected by the nlp2 mutation, we compared gene expression profiles in the wild-type Columiba and the nlp2 mutant that were treated with 10 mM KNO3 for 1 hour. Columbia and nlp2 that were treated with 10 mM KCl for 1 hour were used as controls. We found that nitrate induction of 6 genes was compromised only in the nlp2 mutant.

Project description:NLP1-9 are plant unique transcrition facotrs. To identify NLP1-9 target genes, we transiently expressed NLP1-9 in Arabidopsis mesophyll protoplasts and performed RNA-seq analysis. NLP1-9 individually induced specific gene expression and co-activated nitrate responsive genes expression. To study genome-wide transcriptional landscape modulated by NLP, we performed transcriptome analysis at 20 min after nitrate induction in wild type and nlp2,4,5,6,7,8,9. All nitrate responsive genes were significant reduced in nlp2,4,5,6,7,8,9 indicated that NLP transcription factors are central regulators in PNR.

Project description:Plants aquire nitrogen from the soil, most commonly in the form of either nitrate or ammonium. Unlike ammonium, nitrate must be reduced (with NADH and ferredoxin as electron donors) prior to assimilation. Thus, nitrate nutrition imposes a substantially greater energetic cost than ammonium nutrition. Our goal was to compare the transcriptomes of nitrate-supplied and ammonium-supplied plants, with a particular interest in characterizing the differences in redox metabolism elicited by different forms of inorganic nitrogen. We used microarrays to compare the short-term transcriptional response to either nitrogen supply or ammonium supply in Arabidopsis roots. Genes upregulated or downregulated by nitrate only, ammonium only, or both ammonium and nitrate were identified and analyzed.

Project description:Nitrate is the limiting nitrogen nutrient enabling photosynthetic plants to support the conversion of inorganic elements to organic biomass, which sustains all lives. Plants evolved multifaceted nitrate responses to modulate global gene expression, metabolism and developmental programs. However, primary nitrate signaling mechanisms remained elusive. Using an ultrasensitive Ca2+ biosensor, unique nitrate-induced Ca2+ signaling was illuminated in Arabidopsis cells and plants. Integrative functional genomic screens, chemical genetics, genome-wide transcript sequencing, and analyses of nitrate-associated traits uncovered the surprising roles of Ca2+ sensor protein kinases (CPKs) in orchestrating diverse primary and long-term nitrate responses. Nitrate specifies CPK signaling to reprogram transcriptome and govern N-assimilation, metabolism, transport, hormones, shoot growth, and root system architecture. CPKs may be targeted to enhance nitrogen-use-efficiency, reduce fertilizer demands, and alleviate ecosystem pollution. 

Project description:nitrate induction - nlp mutants-Nitrate induction - nlp mutants

Project description:Freshly harvested Arabidopsis seeds (ecotype Col0 obtained under 10 mM nitrate nutrition, referred to as C10 seeds) are dormant and do not germinate when sown on an agarose-based medium. However, when C10 seeds are sown on 10mM nitrate or when Col0 mother plants are grown on 50 mM nitrate (referred to as C50 seeds), the produced seeds are non dormant and germinate readily on agarose. The G’4-3 arabidopsis mutant which is impaired in nitrate assimilation and accumulates nitrate produces likewise non dormant seeds when grown on 10mM nitrate (referred to as G’4-3 seeds). The goals of these experiments are to better understand the effects of nitrate feeding of mother plants on the produced seed dormancy.

Project description:GATA transcription factors are involved in multiple processes in plant growth and development. Two GATA factors, nitrate-inducible, carbon metabolism-involved (GNC) and CYTOKININ-RESPONSIVE GATA FACTOR 1 (CGA1, also named GNL) are important regulators in greening, flowering, senescence and hormone signaling. However, their direct target genes in regulating these biological processes are poorly characterized. Here, we report a genome-wide identification of the target genes of Arabidopsis GNC and CGA1.

Project description:Transgenic Arabidopsis plants carrying dexamethasone-inducible barley cytokinin oxidase/dehydrogenase (CaMV35S>GR>HvCKX2) and agrobacterial isopentenyl transferase (CaMV35S>GR>ipt) constructs were profiled to elucidate proteome-wide response to cold stress under different light conditions.

Project description:Plants aquire nitrogen from the soil, most commonly in the form of either nitrate or ammonium. Unlike ammonium, nitrate must be reduced (with NADH and ferredoxin as electron donors) prior to assimilation. Thus, nitrate nutrition imposes a substantially greater energetic cost than ammonium nutrition. Our goal was to compare the transcriptomes of nitrate-supplied and ammonium-supplied plants, with a particular interest in characterizing the differences in redox metabolism elicited by different forms of inorganic nitrogen. We used microarrays to compare the short-term transcriptional response to either nitrogen supply or ammonium supply in Arabidopsis roots. Genes upregulated or downregulated by nitrate only, ammonium only, or both ammonium and nitrate were identified and analyzed. Arabidopsis thaliana (Col-0) plants were grown hydroponically until they reached growth stage 5.10. They were then transferred to a nitrogen-free medium for 26 hr and then supplied with 1 mM nitrate or 1 mM ammonium. RNA isolation (and subsequent microarray analysis) was performed on root tissue isolated just before nitrogen supply (time 0) and at 1.5 hr and 8 hr after nitrogen supply (1.5 hr nitrate, 8 hr nitrate, 1.5 hr ammonium, 8 hr ammonium).