A new modeling framework helps understand the consequences of future sea-ice loss in the Arctic.
Researchers discover how certain bacteria may safeguard plant growth during a drought, making way for strategies to improve crop productivity.
The bacteria from cows and other ruminants’ digestive systems could provide insights for converting corn stover and other biomass into fuels.
A new platform melding microfluidics and robotics allows more in-depth bioanalysis with fewer cells than ever before.
How microbial communities adjust to nutrient-poor soils at the genomic and proteomic level gives scientists insights into land use.
Analyses reveal how a microbe breaks down lignin, providing a better understanding useful to making biofuels.
A combined experimental and modeling approach contributes to understanding small proteins with potential use in industrial, therapeutic applications.
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.
Experimental warming treatments show how peatland forests may respond to future environmental change.
Collaborative, open-source software and data platform accelerates systems biology research.
