Project description:This data set was downloaded from MetaboLights (http://www.ebi.ac.uk/metabolights/) accession number MTBLS309 Abstract:"Anthropogenic CO2 presently at 400 ppm is expected to reach 550 ppm in 2050, an increment expected to affect plant growth and productivity. Paired stomatal guard cells (GCs) are the gate-way for water, CO2, and pathogen, while mesophyll cells (MCs) represent the bulk cell-type of green leaves mainly for photosynthesis. We used the two different cell types, i.e., GCs and MCs from canola (Brassica napus) to profile metabolomic changes upon increased CO2 through supplementation with bicarbonate (HCO3-). Two metabolomics platforms enabled quantification of 268 metabolites in a time-course study to reveal short-term responses. The HCO3- responsive metabolomes of the cell types differed in their responsiveness. The MCs demonstrated increased amino acids, phenylpropanoids, redox metabolites, auxins and cytokinins, all of which were decreased in GCs in response to HCO3-. In addition, the GCs showed differential increases of primary C-metabolites, N-metabolites (e.g., purines and amino acids), and defense-responsive pathways (e.g., alkaloids, phenolics, and flavonoids) as compared to the MCs, indicating differential C/N homeostasis in the cell-types. The metabolomics results provide insights into plant responses and crop productivity under future climatic changes where elevated CO2 conditions are to take center-stage."

Project description:Global CO2 level presently recorded at 400 ppm is expected to reach 550 ppm in 2050, an increment likely to impact plant growth and productivity. Using targeted LC-MS and GC-MS platforms we quantified 229 and 29 metabolites, respectively in a time-course study to reveal short-term responses to different concentrations (1, 3, and 10 mM) of bicarbonate (HCO3-) under light and dark conditions. Results indicate that HCO3- treatment responsive metabolomic changes depend on the HCO3- concentration, time of treatment, and light/dark. Interestingly, 3 mM HCO3- concentration treatment induced more significantly changed metabolites than either lower or higher concentrations used. Flavonoid biosynthesis and glutathione metabolism were common to both light and dark-mediated responses in addition to showing concentration-dependent changes. Our metabolomics results provide insights into short-term plant cellular responses to elevated HCO3- concentrations as a result of ambient increases in CO2 under light and dark.

Project description:This data set was downloaded from MetaboLights (http://www.ebi.ac.uk/metabolights/) accession number MTBLS311 Abstract:Global CO2 level presently recorded at 400 ppm is expected to reach 550 ppm in 2050, an increment likely to impact plant growth and productivity. Using targeted LC-MS and GC-MS platforms we quantified 229 and 29 metabolites, respectively in a time-course study to reveal short-term responses to different concentrations (1, 3, and 10 mM) of bicarbonate (HCO3-) under light and dark conditions. Results indicate that HCO3- treatment responsive metabolomic changes depend on the HCO3- concentration, time of treatment, and light/dark. Interestingly, 3 mM HCO3- concentration treatment induced more significantly changed metabolites than either lower or higher concentrations used. Flavonoid biosynthesis and glutathione metabolism were common to both light and dark-mediated responses in addition to showing concentration-dependent changes. Our metabolomics results provide insights into short-term plant cellular responses to elevated HCO3- concentrations as a result of ambient increases in CO2 under light and dark.

Project description:• Reference to published study making use of this data: • Cseke LJ, Tsai C-J, Rogers A, Nelsen MP, White HL, Karnosky DF, Podila GK. (2009) Transcriptomic comparison in the leaves of two aspen genotypes having similar carbon assimilation rates but different allocation patterns under elevated CO2. New Phytologist. submitted. • This study compared the leaf transcription profiles, physiological characteristics, and primary metabolites of two Populus tremuloides genotypes (clones 216 and 271) known to differ in their responses to long-term elevated [CO2] (e[CO2]) at the Aspen FACE site near Rhinelander, WI. • Physiological responses of these clones are similar in photosynthesis, stomatal conductance, and leaf area index under e[CO2] yet very different in growth enhancement (0-10% in clone 216; 40-50% in clone 271). While few genes responded to long-term exposure to e[CO2], the transcriptional activity of leaf e[CO2]-responsive genes was distinctly different between the clones, differentially impacting multiple pathways during both early and late growing seasons. • Analysis of transcript abundance and carbon/nitrogen biochemistry suggests that the CO2-responsive clone (271) partitions C into pathways associated with active defense/response to stress, carbohydrate/starch biosynthesis and subsequent growth. The CO2-unresponsive clone (216) partitions C into pathways associated with passive defense (e.g. lignin, phenylpropanoid) and cell wall thickening. • This study indicates that there is significant variation in expression patterns between different tree genotypes in response to long-term exposure to e[CO2]. Consequently, future efforts to improve productivity or other advantageous traits for carbon sequestration should include an examination of genetic variability in CO2 responsiveness. Keywords: Tree genotype comparison under elevated [CO2]

Project description:We experimentally manipulate CO2 levels and investigate the effects of high-CO2/low pH on seagrass metabolism and underlying molecular mechanisms. Cymodocea nodosa plants were collected in Cadiz Bay at the end of January 2014 and transported to the mesocosm facility. After a one week acclimation period, C. nodosa were either kept under normal (400 ppm) or elevated (1200 ppm) CO2 concentration for 12 days. RNA extraction and sequencing was performed in all phases to test differential expression of genes in different conditions.

Project description:To study long-term elevated CO2 and enriched N deposition interactive effects on microbial community and soil ecoprocess, here we investigated soil microbial community in a grassland ecosystem subjected to ambient CO2 (aCO2, 368 ppm), elevated CO2 (eCO2, 560 ppm), ambient nitrogen deposition (aN) or elevated nitrogen deposition (eN) treatments for a decade. There exist antagonistic CO2×N interactions on microbial functional genes associated with C, N, P S cycling processes. More strong antagonistic CO2×N interactions are observed on C degradation genes than other genes. Remarkably antagonistic CO2×N interactions on soil microbial communities could enhance soil C accumulation.

Project description:Several reports have investigated the effects of future climate conditions on photosynthesis and biomass production in woody plants but none combining temperature and atmospheric CO2 concentration. We used grow chambers to expose Eucalyptus grandis and E. globulus seedlings to three temperature regimes (10-12°C - low temperature, 20-22°C - control temperature and 33-35°C - high temperature) combined with two CO2 concentration (390 ppm – normal and 700 ppm - high). After 35 days the stems were used for transcriptome (RNAseq) analysis aiming to understand  changes in the expression of genes related with biosynthesis and remodeling of the cell wall, as well as genes related with carbon partitioning and hormonal regulation. E. globulus, a species adapted to low temperature, was more responsive to the treatments compared to E. grandis. The most relevant biological processes affected by the treatments were related to stress, secondary metabolism, hormonal response, and signaling. We also analyzed in depth all cell wall biopolymer synthetic genes and their regulation by innumerous transcriptional factors. There was an upregulation of ethylene and auxin biosynthetic genes in both species, but it was stronger under high and low temperature in E.globulus. Temperature was more effective to change cell wall biosynthetic genes than CO2 and CO2 stimulated lignin biosynthetic pathway. We also analyzed lignin composition and structure. There was an increase in F5H and COMT expression and the S/G ratio also increased under high CO2 in E.globulus. Thus, the species responded differently to treatments and stem composition and development was highly affected by temperature and CO2 concentration.

Project description:• Reference to published study making use of this data: • Cseke LJ, Tsai C-J, Rogers A, Nelsen MP, White HL, Karnosky DF, Podila GK. (2009) Transcriptomic comparison in the leaves of two aspen genotypes having similar carbon assimilation rates but different allocation patterns under elevated CO2. New Phytologist. submitted. • This study compared the leaf transcription profiles, physiological characteristics, and primary metabolites of two Populus tremuloides genotypes (clones 216 and 271) known to differ in their responses to long-term elevated [CO2] (e[CO2]) at the Aspen FACE site near Rhinelander, WI. • Physiological responses of these clones are similar in photosynthesis, stomatal conductance, and leaf area index under e[CO2] yet very different in growth enhancement (0-10% in clone 216; 40-50% in clone 271). While few genes responded to long-term exposure to e[CO2], the transcriptional activity of leaf e[CO2]-responsive genes was distinctly different between the clones, differentially impacting multiple pathways during both early and late growing seasons. • Analysis of transcript abundance and carbon/nitrogen biochemistry suggests that the CO2-responsive clone (271) partitions C into pathways associated with active defense/response to stress, carbohydrate/starch biosynthesis and subsequent growth. The CO2-unresponsive clone (216) partitions C into pathways associated with passive defense (e.g. lignin, phenylpropanoid) and cell wall thickening. • This study indicates that there is significant variation in expression patterns between different tree genotypes in response to long-term exposure to e[CO2]. Consequently, future efforts to improve productivity or other advantageous traits for carbon sequestration should include an examination of genetic variability in CO2 responsiveness. Keywords: Tree genotype comparison under elevated [CO2] 24 two-channel arrays, directly comparing RNA from trees grown in the ambient (control) [CO2] to RNA derived from the same genotype grown under e[CO2]. For each of 4 experimental conditions (clone 216 early season; clone 271 early season; clone 216 late season; clone 271 late season), three independent biological replicates derived from trees grown in three independent replicate FACE rings were used. In addition, each clone and time point included dye swap reciprocal two-color experiments for each biological replicate. Thus, six data points per cDNA are included (three biological replicates with two technical replicates each).

Project description:Six weeks old Arabidopsis plants were transferred to a low CO2 (100 ppm) environment during 24 hours and compared to control plants kept under ambient CO2 conditions. Limited CO2 availability will cause higher rates of photorespiration and affect the plant redox homeostasis. We studied the transcriptomic impact of exposing plants to a lower CO2 environment to further eliculidate the signaling pathways during photorespiratory stress. After 6 weeks plants were transferred to low CO2 conditions (100 ppm) during 24 h or kept at 400 ppm CO2 (control condition). Design: 3 replicates x 2 conditions (low CO2 - ambient CO2)

Project description:Ocean acidification, resulting from the dissolution of excess CO2 produced by humans into the ocean, is predicted to impact a broad variety of marine taxa, particularly calcifying animals such as the thecosome (shelled) pteropods. To achieve a better understanding of the mechanisms of pteropod calcification and physiological compensation for high CO2 exposure, we investigated the transcriptomic responses of Clio pyramidata, a cosmopolitan diel migratory thecosome. Individuals were sampled from the Northwest Atlantic in the fall of 2011 and were exposed to ambient (~380 ppm) and end of the century predicted CO2 levels (~800 ppm) and their oxygen consumption was measured. We then used RNA-seq technology to assess transcriptome-wide effects of exposure to elevated CO2. We conducted a de novo assembly of the transcriptome of C. pyramidata, annotated the genes associated with biomineralization, and assessed the differential gene expression patterns. This assembly reveals a number of similarities with other molluscan transcriptomes, and some similar biomineralization genes such as perlucin, calmodulin, regucalcin and SPARC. The results of the differential expression indicate that there is a great deal of natural variability in gene expression and suggest that a few genes putatively associated with biomineralization, particularly perlucin, were up-regulated in the high CO2 treatment. This is the first experiment employing gene expression analysis to investigate the effects of CO2 on a planktonic open-ocean species, providing the first insights into the effects of acidification on these important planktonic calcifiers and suggesting interesting gene families which may prove useful in further ecophysiological, biomaterials and phylogenetic studies.