Project description:The hydrothermal vent gammaproteobacterium Thiomicrospira crunogena inhabits an unstable environment and must endure dramatic sweeps in habitat chemistry. This sulfur chemolithoautotroph responds to changes in dissolved inorganic carbon (DIC; = CO2 + HCO3- + CO3-2) availability with a carbon concentrating mechanism (CCM), in which whole-cell affinity for DIC, as well as the intracellular DIC concentration, increase substantially under DIC-limitation. To determine whether this CCM is regulated at the level of transcription, cells cultivated under high-DIC conditions in chemostats were resuspended in growth medium with low concentrations of DIC, and CCM development was tracked in the presence and absence of RNA polymerase inhibitor rifampicin. The induction of the CCM, as measured by silicone oil centrifugation, was hindered in the presence of rifampicin. Similar results were observed for carboxysome gene transcription and assembly, as assayed by qRT-PCR and transmission electron microscopy, respectively. Genome-wide transcription patterns, assayed via microarrays, were compared for cells grown under DIC-limitation versus ammonia limitation. In addition to carboxysome genes, two novel genes (Tcr_1019 and Tcr_1315), present in other organisms including chemolithoautotrophs, but whose function(s) have not been elucidated in any organism, were found to be upregulated under low-DIC conditions. Likewise, under ammonia limitation, in addition to the expected enhancement of ammonia transporter and PII-gene transcription, the transcription of two novel genes was measurably enhanced (Tcr_0466 and Tcr_2018). Upregulation of all four genes was verified via qRT-PCR (Tcr_1019: 4-fold; Tcr_1315: ~7-fold; Tcr_0466: >200-fold; Tcr_2018: 7-fold), suggesting novel components are part of the response to nutrient limitation by this organism.

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:Transcription Response by sulfur chemolithoautotroph Thiomicrospira crunogenato dissolved inorganic carbon and ammonia limitation

Project description:Carbon fixation plays a central role in determining cellular redox poise, increasingly understood to be a key parameter in cyanobacterial physiology. In the cyanobacterium Prochlorococcus--—the most abundant phototroph in the oligotrophic oceans--—the carbon-concentrating mechanism (CCM) is reduced to the bare essentials. Given the ability of Prochlorococcus populations to grow under a wide range of oxygen concentrations in the ocean, we wondered how carbon and oxygen physiology intersect in this minimal phototroph. We monitored genome-wide transcription in cells shocked with acute limitation of CO2, O2, or both. O2 limitation produced much smaller transcriptional changes than the broad suppression seen under CO2 limitation and CO2/O2 co-limitation. Strikingly, the transcriptional responses evoked by both CO2 limitation conditions were initially similar to that previously seen in high light stress, but at later timepoints we observed O2-dependent recovery of photosynthesis-related transcripts. These results suggest that oxygen plays a protective role in Prochlorococcus when carbon fixation is not a sufficient sink for light energy.

Project description:Carbon fixation plays a central role in determining cellular redox poise, increasingly understood to be a key parameter in cyanobacterial physiology. In the cyanobacterium Prochlorococcus--—the most abundant phototroph in the oligotrophic oceans--—the carbon-concentrating mechanism (CCM) is reduced to the bare essentials. Given the ability of Prochlorococcus populations to grow under a wide range of oxygen concentrations in the ocean, we wondered how carbon and oxygen physiology intersect in this minimal phototroph. We monitored genome-wide transcription in cells shocked with acute limitation of CO2, O2, or both. O2 limitation produced much smaller transcriptional changes than the broad suppression seen under CO2 limitation and CO2/O2 co-limitation. Strikingly, the transcriptional responses evoked by both CO2 limitation conditions were initially similar to that previously seen in high light stress, but at later timepoints we observed O2-dependent recovery of photosynthesis-related transcripts. These results suggest that oxygen plays a protective role in Prochlorococcus when carbon fixation is not a sufficient sink for light energy. Two biological replicates of timecourses under four conditions: medium bubbled with air (control) or three experimental gases (low CO2; low O2; or low CO2 and low O2)

Project description:Nitrosomonas europaeais a chemolithoautotrophic bacterium that oxidizes ammonia (NH3) to obtain energy for growth on carbon dioxide (CO2), and can also produce nitrous oxide (N2O), a greenhouse gas. We interrogated the growth, physiological, and transcriptome responses ofN. europaeato replete (> 5.2 mM) and limited inorganic carbon (IC) provided by either 1.0 mM or 0.2 mM sodium carbonate (Na2CO3) supplemented with atmospheric CO2 IC-limited cultures oxidized 25 to 58% of available NH3to nitrite, depending on dilution rate and Na2CO3concentration. IC limitation resulted in a 2.3-fold increase in cellular maintenance energy requirements compared to NH3-limited cultures. Rates of N2O production increased 2.5- and 6.3-fold under the two IC-limited conditions increasing the percentage of oxidized NH3-N being transformed to N2O-N from 0.5% (replete) up to 4.4% (0.2 mM Na2CO3). Transcriptome analysis showed differential expression (p≤ 0.05) of 488 genes (20% of inventory) between replete and IC-limited conditions, but few differences were detected between the two IC-limiting treatments. IC-limited conditions resulted in decreased expression of ammonium/ammonia transporter and ammonia monooxygenase subunits, and increased expression of genes involved in C1 metabolism including RuBisCO (cbbgene cluster), carbonic anhydrase, folate-linked metabolism of C1 moieties, and putative C salvage due to oxygenase activity of RuBisCO. Increased expression of nitrite reductase (gene cluster NE0924-0927) correlated with increased production of N2O. Together, these data suggest thatN. europaeaadapts physiologically during IC-limited steady state growth, which leads to uncoupling of NH3oxidation from growth and increased N2O production. Transcriptome responses of N. europaea in 60 mM NH4+ to suboptimum levels of carbonate (1.0 mM and 0.2 mM) in continuous steady-state culture in a bioreactor.

Project description:Nitrosomonas europaea is a chemolithoautotrophic bacterium that oxidizes ammonia (NH3) to obtain energy for growth on carbon dioxide (CO2), and can also produce nitrous oxide (N2O), a greenhouse gas. We interrogated the growth, physiological, and transcriptome responses of N. europaea to replete (> 5.2 mM) and limited inorganic carbon (IC) provided by either 1.0 mM or 0.2 mM sodium carbonate (Na2CO3) supplemented with atmospheric CO2. IC-limited cultures oxidized 25 to 58% of available NH3 to nitrite, depending on dilution rate and Na2CO3 concentration. IC limitation resulted in a 1.5-fold increase in cellular maintenance energy requirements compared to NH3-limited cultures. Rates of N2O production increased 2- and 6.3 fold under the two IC-limited conditions increasing the percentage of oxidized NH3-N being transformed to N2O-N from 0.5% (replete) to 4.4% (0.25 mM Na2CO3). Transcriptome analysis showed differential expression (p ≤ 0.05) of 488 genes (20% of inventory) between replete and IC-limited conditions, but few differences were detected between the two IC-limiting treatments. IC-limited conditions resulted in decreased expression of ammonium/ammonia transporter and ammonia monooxygenase subunits, and increased expression of genes involved in C1 metabolism including RuBisCO (cbb gene cluster), carbonic anhydrase, folate-linked metabolism of C1 moieties, and putative C salvage due to oxygenase activity of RuBisCO. Increased expression of nitrite reductase (gene cluster NE0924-0927) correlated with increased production of N2O. Together, these data suggest that N. europaea adapts physiologically during IC-limited steady state growth, which leads to uncoupling of NH3 oxidation from growth and increased N2O production.

Project description:The general acclimation of cyanobacteria to low carbon (LC) conditions includes coordinated alterations of gene expression and metabolism. To analyze possible signals for LC sensing and compensating reactions, we compared wild-type (WT) cells with two mutants of Synechocystis, the carboxysome-less mutant ccmM and the photorespiratory mutant ΔglcD1/D2. Metabolic phenotyping revealed that the mutant ΔccmM accumulated high 2-phosphoglycolate (2PG) levels while the ΔglcD1/D2 mutant accumulated glycolate, indicating oxygenase activity of RubisCO at high carbon (HC). The changes in the metabolite spectrum were compared to alterations in the global gene expression pattern. Cells of HC-grown mutants ΔccmM and ΔglcD1/D2 showed altered mRNA levels for many genes involved in photosynthesis, high light stress, and N-assimilation, while LC-specific genes such as those for inorganic carbon (Ci) transporters were not increased. After a shift to LC, mutant ΔglcD1/D2 revealed gene expression changes similar to WT cells, while mutant ΔccmM showed no differential expression of most LC-induced genes under identical conditions. In fact, none of the genes for Ci transporters or other components of the carbon concentrating mechanism (CCM) displayed higher transcript levels in the ΔccmM mutant. This finding renders a direct role for 2PG as a metabolic signal component for the induction of CCM during LC acclimation less likely. Because, the transcription pattern of ΔglcD1/D2 under LC showed specific differences compared to WT, a potential role for glycolate as a signal molecule that may trigger expression of parts of the CCM is proposed. Transcriptional profiling of carboxysomal and photorespiratory mutants of Synechocystis sp. PCC 6803 under high carbon (HC) and low carbon (LC) conditions relative to the wildtype response.

Project description:The available energy and carbon sources for prokaryotes in the deep ocean remain still largely enigmatic. Reduced sulfur compounds, such as thiosulfate, are a potential energy source for both auto- and heterotrophic marine prokaryotes. Shipboard experiments performed in the North Atlantic using Labrador Sea Water (~2000 m depth) amended with thiosulfate led to an enhanced prokaryotic dissolved inorganic carbon (DIC) fixation.

Project description:The general acclimation of cyanobacteria to low carbon (LC) conditions includes coordinated alterations of gene expression and metabolism. To analyze possible signals for LC sensing and compensating reactions, we compared wild-type (WT) cells with two mutants of Synechocystis, the carboxysome-less mutant ccmM and the photorespiratory mutant ΔglcD1/D2. Metabolic phenotyping revealed that the mutant ΔccmM accumulated high 2-phosphoglycolate (2PG) levels while the ΔglcD1/D2 mutant accumulated glycolate, indicating oxygenase activity of RubisCO at high carbon (HC). The changes in the metabolite spectrum were compared to alterations in the global gene expression pattern. Cells of HC-grown mutants ΔccmM and ΔglcD1/D2 showed altered mRNA levels for many genes involved in photosynthesis, high light stress, and N-assimilation, while LC-specific genes such as those for inorganic carbon (Ci) transporters were not increased. After a shift to LC, mutant ΔglcD1/D2 revealed gene expression changes similar to WT cells, while mutant ΔccmM showed no differential expression of most LC-induced genes under identical conditions. In fact, none of the genes for Ci transporters or other components of the carbon concentrating mechanism (CCM) displayed higher transcript levels in the ΔccmM mutant. This finding renders a direct role for 2PG as a metabolic signal component for the induction of CCM during LC acclimation less likely. Because, the transcription pattern of ΔglcD1/D2 under LC showed specific differences compared to WT, a potential role for glycolate as a signal molecule that may trigger expression of parts of the CCM is proposed.