Seawater carbonate chemistry and Synechococcus growth from pCO2 experiments

Many microbial photoautotrophs depend on heterotrophic bacteria for accomplishing essential functions. Environmental changes, however, could alter or eliminate such interactions. We investigated the effects of changing pCO2 on gene transcription in co-cultures of 3 strains of picocyanobacteria (Syne...

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Bibliographic Details
Main Authors: Barreto Filho, Marcelo Malisano, Lu, Zhiying, Walker, Melissa, Morris, J Jeffrey
Format: Dataset
Language:English
Published: PANGAEA 2022
Subjects:
Alkalinity
total
Alteromonas sp.
Aragonite saturation state
Bacteria
Bicarbonate ion
Bottles or small containers/Aquaria (<20 L)
Calcite saturation state
Calculated using seacarb after Nisumaa et al. (2010)
Carbon
inorganic
dissolved
Carbonate ion
Carbonate system computation flag
Carbon dioxide
Cell density
Cyanobacteria
Fugacity of carbon dioxide (water) at sea surface temperature (wet air)
Gene expression (incl. proteomics)
Growth/Morphology
Heterotrophic prokaryotes
Identification
Laboratory experiment
Laboratory strains
Not applicable
OA-ICC
Ocean Acidification International Coordination Centre
Partial pressure of carbon dioxide (water) at sea surface temperature (wet air)
Pelagos
pH
standard deviation
Phytoplankton
Prochlorococcus sp.
Proteobacteria
Replicate
Salinity
Species
Species interaction
Strain
Synechococcus sp.
Temperature
water
Time in days
Treatment
Type
Ocean acidification
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.955830
https://doi.org/10.1594/PANGAEA.955830
Description
Summary:Many microbial photoautotrophs depend on heterotrophic bacteria for accomplishing essential functions. Environmental changes, however, could alter or eliminate such interactions. We investigated the effects of changing pCO2 on gene transcription in co-cultures of 3 strains of picocyanobacteria (Synechococcus strains CC9311 and WH8102 and Prochlorococcus strain MIT9312) paired with the 'helper' bacterium Alteromonas macleodii EZ55. Co-culture with cyanobacteria resulted in a much higher number of up- and down-regulated genes in EZ55 than pCO2 by itself. Pathway analysis revealed significantly different transcription of genes involved in carbohydrate metabolism, stress response, and chemotaxis, with different patterns of up- or down-regulation in co-culture with different cyanobacterial strains. Gene transcription patterns of organic and inorganic nutrient transporter and catabolism genes in EZ55 suggested resources available in the culture media were altered under elevated (800 ppm) pCO2 conditions. Altogether, changing transcription patterns were consistent with the possibility that the composition of cyanobacterial excretions changed under the two pCO2 regimes, causing extensive ecophysiological changes in both members of the co-cultures. Additionally, significant downregulation of oxidative stress genes in MIT9312/EZ55 cocultures at 800 ppm pCO2 were consistent with a link between the predicted reduced availability of photorespiratory byproducts (i.e., glycolate/2PG) under this condition and observed reductions in internal oxidative stress loads for EZ55, providing a possible explanation for the previously observed lack of “help” provided by EZ55 to MIT9312 under elevated pCO2. If similar broad alterations in microbial ecophysiology occur in the ocean as atmospheric pCO2 increases, they could lead to substantially altered ecosystem functioning and community composition.

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