Project description:affy_agro-bi_medicago - Identification of genes from the model legume Medicago truncatula whose expression is affected by the plant nitrogen status, with or without inoculation with the symbiotic bacteria Sinorhizobium meliloti. - Comparison of the supernodulant, nitrogen-insensitive, sunn-2 mutant with the A17 wild type genotype.-The plant root systems of plants were split into two parts, each one being installed in a separate compartment. For the â??Sâ?? treatment, one part was supplied with 10 mM NH4NO3 while the other part was supplied with a nitrogen-free nutrient solution. For the â??Lâ?? treatment, one part was supplied 0.5mM NO3- and the other part was supplied with the nitrogen free solution. Eight biological materials (designated AL, AS, SL, SS, IL, IS, NIL, NIS), with three biological repeats for each, were collected and analyzed. The effects of the S and L conditions were investigated on wild-type A17 (AL vs. AS) and sunn-2 mutant plants (SL vs. SS); one set of A17 plants was inoculated with Sinorhizobium meliloti (IL vs. IS), harvested at four days post inoculation and compared to non-inoculated plants (NIL vs. NIS). Keywords: growth in nitrogen-sufficient (s) vs. nitrogen-limited (l) conditions 18 arrays - Medicago

Project description:The experiment aims to analyze the effect of systemic signaling of plant N demand on the transcriptome of Medicago truncatula roots inoculated with Sinorhizobium medicae MD4 at 2, 4, and 7 days post-inoculation (dpi). We divided the roots systems into two parts; one of them was supplied with nutrient solution with mineral N (10 mM NH4NO3 for N-satisfied plants, 0.5 mM for N-limited plants) whereas the non-N treated part was kept in nutrient solution without mineral N. All roots were inoculated 48h after initiation of the N treatments. To characterize specifically the impact of systemic signaling of N demand, we collected the roots the non-N treated sides of the split roots systems and we isolated total RNA for RNAseq analysis. Root transcriptomes of N-limited and N-satisfied plants were compared at 2, 4 and 7 dpi.

Project description:The experiment aims to analyze the effect of inoculation with Sinorhizobium medicae MD4 of on the transcriptome of the Medicago truncatula roots of N-limited plants. We divided the roots systems into two parts; one of them was supplied with nutrient solution with mineral N (0.5 mM for N-limited plants) whereas the non-N treated part was kept in nutrient solution without mineral N. All roots were inoculated 48h after initiation of the N treatments. We collected the roots the non-N treated side of the split roots system and we isolated total RNA for RNAseq analysis. Root transcriptomes were analyze before inoculation, at 1 and 2 days post-inoculation.

Project description:The experiment aims to investigate the effect of the sunn mutation on systemic signaling of the plant N demand in Medicago truncatula roots inoculated with Sinorhizobium medicae MD4 at 2 and 7 days post-inoculation (dpi). We compared the TR122/sunn-2 mutant to the wild type Jemalong A17. For each plant genotype, we divided the roots systems into two parts; one of them was supplied with a nutrient solution with mineral N (10 mM NH4NO3 for N-satisfied plants, 0.5 mM for N-limited plants) whereas the non-N treated part was kept in a nutrient solution without mineral N. All roots were inoculated 48h after initiation of the N treatments. To characterize specifically the impact of systemic signaling of N demand, we collected for both genotypes the roots of the non-N treated sides of the split roots systems, and we isolated total RNA for RNAseq analysis. Root transcriptomes of N-limited and N-satisfied plants were compared in both genotypes at 2 or 7 dpi.

Project description:Arabidopsis plants were grown in sand and supplied with full nutrient during 6 to 7 weeks in a growth chamber in controlled conditions (21/18°C day/night temperature, 60 % humidity, 8 h photoperiod). Then for the split-root experiments, the root system was washed in water to discard the sand and separated in two parts dipped in 2 containers (300 mL each) containing either the same medium (MS/10 supplied with 500 ?M Pi (cP500) or without Pi (cP0) or different media (500 ?M Pi and no Pi, respectively spP500 and spP0) for two days. Three plants were pooled for each condition and the experiment was triplicated.

Project description:The experiment aim is the identification of the transcriptional response of mature nodules of Medicago truncatula inoculated with the strain MD4 of Sinorhizobium medicae in response to different nitrogen (N) supply (N-satiety and N-deficient conditions). We performed a time-course (1 and 3 days treatment) split-root experiment to identify plant systemic responses: the root systems of nodulated symbiotic plants were divided into two compartments, one of them treated and the other kept on control conditions. Nodules were isolated from the non-treated side of the split root and total RNA isolated for RNAseq analysis.

Project description:The experiment aim is the identification of the transcriptional response of mature nodules of Medicago truncatula inoculated with the strain MD4 of Sinorhizobium medicae in response to different nitrogen (N) supply (N-satiety and N-deficient conditions). We performed a time-course (1 and 3 days treatment) split-root experiment to identify plant systemic responses: the root systems of nodulated symbiotic plants were divided into two compartments, one of them treated and the other kept on control conditions. Nodules were isolated from the non-treated side of the split root and total RNA isolated for RNAseq analysis. To analyse Sinorhizobium medicae MD4 expression, a ribosomal RNA depletion protocol was performed before library preparation.

Project description:The experiment aims to identify the response of mature nodules and denodulated roots of Medicago truncatula /Sinorhizobium medicae md4 to the systemic signaling of plant N deficit. The root systems of nodulated symbiotic plants were divided into two compartments. The N source of N2 fixing plants was exclusively the air. To reduce the plant nitrogen (N) supply (N-deficient conditions), we flushed one half root system with Ar/O2 (80/20 v/v) while the other half root system was kept on control conditions (Air). To characterize the systemic responses of the transcriptome to plant N deficit , nodules and roots of the non-treated half root system were harvested and total RNA isolated for RNAseq analysis. We performed a time-course (6 hours, 1-, 3- and 5-days treatment).

Project description:The experiment aims to identify the response of the mature nodules and denodulated roots of Medicago truncatula /Sinorhizobium medicae md4 to the systemic signaling of plant water deficit. The root systems of nodulated symbiotic plants were divided into two compartments. The N source of N2 fixing plants was exclusively the air. To apply the water stress, we treated half root system with PEG while the other was kept on control conditions. To characterize the systemic responses of the transcriptome to the PEG treatment , nodules and roots of the non-treated half root system were harvested and total RNA isolated for RNAseq analysis. We performed a time-course (6 hours, 1-, 3- and 5-days treatment) .

Project description:Internal aeration is crucial for root growth in waterlogged soil. A barrier to radial oxygen loss (ROL) can enhance long- distance oxygen transport via the aerenchyma to the root tip; a higher oxygen concentration at the apex enables root growth into anoxic soil. The ROL barrier is formed within the outer part of roots (OPR). Suberin and/or lignin depos- ited in cell walls are thought to contribute to the barrier, but it is unclear which compound is the main constituent. This study describes gene expression profiles during ROL barrier formation in rice roots to determine the relative responses of suberin and/or lignin biosyntheses for the barrier. OPR tissues were isolated by laser microdissection and their transcripts were analysed by microarray. A total of 128 genes were significantly up- or downregulated in the OPR during the barrier formation. Genes associated with suberin biosynthesis were strongly upregulated, whereas genes associated with lignin biosynthesis were not. By an ab initio analysis of the promoters of the upregulated genes, the putative cis-elements that could be associated with transcription factors, WRKY, AP2/ERF, NAC, bZIP, MYB, CBT/DREB, and MADS, were elucidated. They were particularly associated with the expression of transcrip- tion factor genes containing WRKY, AP2, and MYB domains. A semiquantitative reverse-transcription PCR analysis of genes associated with suberin biosynthesis (WRKY, CYP, and GPAT) confirmed that they were highly expressed during ROL barrier formation. Overall, these results suggest that suberin is a major constituent of the ROL barrier in roots of rice. 23-d-old plants were either continued in aerated solution or transplanted into N2-flushed or stagnant deoxygenated solution for 9 h. After treating the roots of plants in aerated, stagnant, or N2-flushed conditions for 9h, the basal parts (12.5 -22.5mm below the root - shoot junction) of the adventitious roots were collected. Cells in OPR (including exodermis and sclerenchyma) were isolated using laser microdissection. RNA extracted from the isolated OPR was analysed with a 44k rice oligo-DNA microarray. Total RNAs were labeled with a Quick Amp Labeling Kit (Agilent Technologies) according to the manufacturerM-bM-^@M-^Ys instructions. Aliquots of Cy5-labeled and Cy3-labeled cRNA (10 ng each) were used for hybridization in a rice 44K oligo-DNA microarray.