
Optimizing Plant Defense against Pathogens
Elucidating the plant’s ability to tweak its defense response to specific pathogens.
Elucidating the plant’s ability to tweak its defense response to specific pathogens.
Adding glucose to a green microalga culture induces accumulation of fatty acids and other valuable bioproducts.
Read more about Feeding Sugars to Algae Makes Them FatIdentified genes involved in plant cell wall polysaccharide production and restructuring could aid in engineering bioenergy crops.
How yeast partition carbon into a metabolite may offer insights into boosting production for biofuels.
Researchers discover how certain bacteria may safeguard plant growth during a drought, making way for strategies to improve crop productivity.
Evidence suggests that biorefineries can accept various feedstocks without negatively impacting the amount of ethanol produced per acre.
Research offers new insights for maximizing sugar production in biofuel crops.
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.
Using genetic engineering, scientists improve biomass growth and conversion in woody and grassy feedstocks.
Chemical genomic-guided engineering of gamma-valerolactone-tolerant yeast.
Genetically engineered switchgrass does not change soil chemistry, microbiology, or carbon storage potential.