Abstract
Aspergillus flavus is a saprophytic fungus that may colonize several important crops, including cotton, maize, peanuts and tree nuts. Concomitant with A. flavus colonization is its potential to secrete mycotoxins, of which the most prominent is aflatoxin. Temperature, water activity (a(w)) and carbon dioxide (CO₂) are three environmental factors shown to influence the fungus-plant interaction, which are predicted to undergo significant changes in the next century. In this study, we used RNA sequencing to better understand the transcriptomic response of the fungus to a(w), temperature, and elevated CO₂ levels. We demonstrate that aflatoxin (AFB₁) production on maize grain was altered by water availability, temperature and CO₂. RNA-Sequencing data indicated that several genes, and in particular those involved in the biosynthesis of secondary metabolites, exhibit different responses to water availability or temperature stress depending on the atmospheric CO₂ content. Other gene categories affected by CO₂ levels alone (350 ppm vs. 1000 ppm at 30 °C/0.99 a(w)), included amino acid metabolism and folate biosynthesis. Finally, we identified two gene networks significantly influenced by changes in CO₂ levels that contain several genes related to cellular replication and transcription. These results demonstrate that changes in atmospheric CO₂ under climate change scenarios greatly influences the response of A. flavus to water and temperature when colonizing maize grain.