Scientists explore how drought-tolerant plants communicate to nearby microorganisms, suggesting ways to engineer more resilient bioenergy crops.
Researchers discover how certain bacteria may safeguard plant growth during a drought, making way for strategies to improve crop productivity.
How microbial communities adjust to nutrient-poor soils at the genomic and proteomic level gives scientists insights into land use.
Analyses of natural communities forming soil crusts agree with laboratory studies of isolated microbe-metabolite relationships.
Evidence suggests that biorefineries can accept various feedstocks without negatively impacting the amount of ethanol produced per acre.
A large-scale soil project uncovered genetic information from bacteria with the capacity to make specialized molecules that could lead to new pharmaceuticals.
Collaborative, open-source software and data platform accelerates systems biology research.
Systems biology leads the way to exascale computing on Summit supercomputer.
New class of solvents breaks down plant biomass into sugars for biofuels and bioproducts in a closed-loop biorefinery concept.
Catalog of candidate genes involved in plant-microbe relationships.
Using genetic engineering, scientists improve biomass growth and conversion in woody and grassy feedstocks.
Chemical genomic-guided engineering of gamma-valerolactone-tolerant yeast.
