Project description:This study is measuring the steady-state levels of mRNA in wild-type Caulobacter crescentus grown in M2 defined medium containing either ammonium or nitrate as the sole nitrogen source. Four independent cultures of Caulobacter crecentus were grown in each of two medium conditions: M2(nitrate)glucose and M2(ammonium)glucose. Cultures in each medium type were grown to OD660=0.3 and RNA was isolated from each.

Project description:The present study used microarray approach to identify the genomewide response to cholera toxin in the presence of nitrate. Considering that fact that the possibility of the existence of multiple GM-NM-1 genes/proteins in plants has not been conclusively ruled out, analysis of the genomewide impact of RGA1 mutation in rice and GPA1 mutation in Arabidopsis reveal only those genes that are under their direct control. On the other hand, assuming that all those different GM-NM-1 subunits in any given plant are regulated by cholera toxin, analysis of the genomwide response to cholera toxin could capture the entire G-protein responsive transcriptome, beyond what can be revealed by the mutant approach. This could reveal even those genes that respond to other, as yet unidentified GM-NM-1 subunits, as well as reveal some genes that are non-specifically regulated by cholera toxin, independent of any G-proteins. Total RNA was isolated from 10 day old excised rice leaves treated with or without cholera toxin in the presence of nitrate.Total RNA was first converted into cDNA and then into cRNA labeled with Cy3 and Cy5 dyes. These were hybridized on the 44K 60-mer whole genome arrays on glass slides. The slides were washed and scanned on an Agilent scanner (G2565B) at 100 % laser power. Data extraction was carried out with Agilent Feature Exiraction software (version 9.1). The experiment was repeated with a biological-cum-technical replicate where total RNA samples were isolated from a fresh batch of rice plants and the cRNAs were labeled with opposite dyes (dye-swap).

Project description:We have done next generation sequencing of optically thin, exponentialy growing Phaeodactylum tricornutum cultures grown with and without nitrogen source to improve our undestanding of the pathways regulation under conditions that promote lipid accumulation (N-starvation). 3 biologically independent exponentially growing culture of Phaeodactylum tricornutum were pelleted and washed several times with N-free media. Each culture was devided to 2 replicates with initial cell concentration of 2X105 cells/mL, one with NaNO3 as nitrogen source and the other without any nitrogen source. The cuture were bubbled foro 48 hours and sampled for transcriptome together with other physiological parameters and lipid analysis.

Project description:Pattern of gene expression of M. mazei in response to 10 uM bismuth nitrate was analyzed relative to gene expression pattern of M. mazei grown in the presence of 30 uM potassium nitrate (control cultures). Therefore, five pre-cultures of M. mazei was grown to mid-exponential growth-phase. Then, the pre-cultures were divided into aliquotes, one half spiked with bismuth nitrate and the other half with potassium nitrate (control) to match nitrate concentration of the bismuth spike. Samples were propagated for two days. Then, total RNA was isolated and transformed into Cy3 or Cy5 labeled cDNA. Labeled cDNA derived from one culture treated with bismuth and from one control culture, both obtained from the same pre-culture, was hybridized with microarray chips. Hybridized chips were scanned, derived data processed and relative expression levels of orfs from M. mazei in response to bismuth calculated.

Project description:Diatoms are responsible for ~40% of marine primary productivity1, fueling the oceanic carbon cycle and contributing to natural carbon sequestration in the deep ocean2. Diatoms rely on energetically expensive carbon concentrating mechanisms (CCMs) to fix carbon efficiently at modern levels of CO23–5. How diatoms may respond over the short and long-term to rising atmospheric CO2 remains an open question. Here we use nitrate-limited chemostats to show that the model diatom Thalassiosira pseudonana rapidly responds to increasing CO2 by differentially expressing gene clusters that regulate transcription and chromosome folding and subsequently reduces transcription of photosynthesis and respiration gene clusters under steady-state elevated CO2. These results suggest that exposure to elevated CO2 first causes a shift in regulation and then a metabolic rearrangement. Genes in one CO2-responsive cluster included CCM and photorespiration genes that share a putative cyclic-AMP responsive cis-regulatory sequence, implying these genes are co-regulated in response to CO2 with cAMP as an intermediate messenger. We verified cAMP-induced down-regulation of CCM gene ?-CA3 in nutrient-replete diatom cultures by inhibiting the hydrolysis of cAMP. These results indicate an important role for cAMP in down-regulating CCM and photorespiration genes under elevated CO2 and provide insights into mechanisms of diatom acclimation in response to climate change. In steady-state experiments: axenic T. pseudonana cells in four biological replicates (duplicate chemostats x 2 experimental runs) were acclimated to nitrate-limitation at 70% (1.5 day-1) of max growth rate for >10 days (>15 generations) under continuous light of 80 µmol photons·m­?2·s?1. Cell biomass was maintained at ~2 x 105 cells·mL?1 by 10 ?M nitrate and carbonate chemistry stabilized to 300, 475 or 800 ?atm CO2, verified by pH and DIC measurements. Transition samples and carbonate chemistry were collected daily from chemostat cultures as CO2 levels were increased from ~300-800 ?atm at a rate ? 0.2 ?atm·min?1 over four consecutive days (6 generations) after pre-acclimation to 300 ?atm CO2 and nitrate-limitation.

Project description:Illumina HiSeq technology was used to generate mRNA profiles from Cenococcum geophilum ectomycorrhizal roots compared to free-living mycelium . Mycorrhizal roots were harvested after 3 months, pooled and used for RNA extraction. Reads of 2X100bp were generated and aligned to Cenococcum geophilum (http://genome.jgi.doe.gov/Cenge3/Cenge3.home.html) reference transcripts using CLC Genomics Workbench 6. mRNA profiles from Cenococcum geophilum ectomycorrhizal roots and free-living mycelium were generated by paired-end (2x100bp) Illumina HiSeq2000 sequencing. Three biological replicates were sequenced for mycorrhizal and mycelium samples.

Project description:Urea can serve as nitrogen source for coral holobionts and plays a cruscial role in coral calcification, although the degradation of urea by coral symbionts is not fully understood. In this study, we investigated the urea utilized pathway and the responses of the Symbiodiniaceae family to urea under high temperature conditions. Genome screening revealed that all Symbiodiniaceae species contain the urease (URE) and DUR2 subunit of urea amidolyase (UAD) system. However, only three speciesCladocopium goreaui, Cladopium c92, and Symbiodinium pilosum possess a complete UAD system, including both DUR1 and DUR2. Phylogentic analyses revealed that the UAD system in Symbiodiniaceae clusters more closely with symbiotic bacteria, indicating that horizontal gene transfer of UAD system has occured in coral symbionts. Physiology analysis showed that the symbiodiniacean species Cladocopium goreaui, which containing both URE and UAD, grew better under urea than ammonium conditions, as indicated by higher maximum specific growth rates. Furthermore, most genes of Symbiodiniaceae involved in urea utilization appeared to be stable under various conditions such as heat stress (HS), low light density, and nitrogen deficiency, wheras in ammonium and nitrate transporters were significantly regulated. These relatively stable molecular regulatory properties support sustained urea absorption by Symbiodiniaceae, as evidenced by an increase in δ15N2-urea absorption and the decreases in δ5N-NO3-, and δ15N-NH4+ from cultural environment to Symbiodiniaceae under HS conditions. Token together, this study reveals two distinct urea utilization systems in coral ecosystem and highlights the importance of the urea cycle in coral symbionts when facing fluctuating nitrogen environment in future warming ocean.

Project description:Using data from microarray experiments, we investigated the effects of excess sodium nitrate on D. vulgaris. Keywords: stress response, time course Comparison of cells treated with 105 mM sodium nitrate to untreated cells at times of 0, 30, 60, 120, and 240 min.

Project description:We have done next generation sequencing of optically thin, exponentialy growing WT Phaeodactylum tricornutum and our ~50% nitrate reductase knock-down cultures. Culture were grown with and without nitrogen source to improve our undestanding of the pathways regulation under conditions that promote lipid accumulation (N-starvation). 3 biologically independent exponentially growing culture of the WT and the NR21 knock-down were pelleted and washed several times with N-free media. Each culture was devided to 2 replicates with initial cell concentration of 2.5X105 cells/mL, one with NaNO3 as nitrogen source and the other without any nitrogen source. The cuture were bubbled for 48 hours and sampled for transcriptome together with other physiological parameters and lipid analysis after reachign exponential growth.

Project description:Using data from microarray experiments, we investigated the effects of excess sodium nitrate on Desulfovibrio vulgaris. Keywords: stress response, time course Comparison of cells treated with 105 mM sodium nitrate to untreated cells at times of 0, 30, 60, 120, and 240 min.