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Food dependent activation of one carbon metabolism during heat shock in Mytilus californianus
 

Food dependent activation of one carbon metabolism during heat shock in Mytilus californianus

R F Fabela, M A May L Tomanek
Journal of experimental biology
07-14-2026
: 42444508
One carbon metabolism Oxidative stress Mytilus Proteomics Carbohydrate metabolism Histone modifications Cellular stress response
Of the ecological factors affecting the cellular stress response (CSR), food ration has received little attention despite a likely role in stress tolerance limits. To test the interactive effects of food and temperature on the proteomic response to heat shock, the intertidal mussel Mytilus californianus was acclimated to four combinations of nearshore (low) and aquaculture (high) phytoplankton levels, combined with low (20 °C) and high (30 °C) aerial temperatures during daytime low tides. Whole mussels were then exposed to an acute (6 h), aerial heat stress (33 °C) and allowed to recover for 1 h and 25 h in pre-exposure conditions. Proteomic changes in the gill before and after heat shock were measured using liquid-chromatography-mass spectrometry and label-free quantification. Mussels acclimated to low-temperature-low-food elicited a greater heat shock response compared to other acclimation groups, increasing protein levels of core carbohydrate and sulfide metabolism. These glycolytic metabolites proposedly feed into one-carbon metabolism (e.g., folate and methionine cycles) and connecting pathways, which also increased abundance and likely contribute to purine synthesis, methylation, and transsulfuration. These mussels additionally increased levels of proteins scavenging hydrogen peroxide, chelating ferrous iron, and maintaining reduced glutathione levels. Proteins modifying chromatin (histone) structure and regulating transcription likely link the metabolic changes to chromatin modifications, specifically through SAM-dependent methyltransferases, which may contribute to repairing DNA-damage caused by oxidative stress. Overall, our results suggest a food-dependent link between metabolism and epigenetic modifications that we hypothesize may function as an autoregulatory feedback mechanism during the CSR under tidally fluctuating conditions.

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url
https://doi.org/10.1242/jeb.252105
Published (Version of record)

1
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