Genetics of Wood Formation
Researchers identify genetic regulatory networks that influence poplar wood formation, a key bioenergy plant.
Researchers identify genetic regulatory networks that influence poplar wood formation, a key bioenergy plant.
Study shows that “stop” code can be assigned other meanings.
Genetic engineering allows biomass-degrading bacterium to make fuel in a single process.
Genetic insights into nutrient movement will enhance bioenergy feedstock’s sustainability.
Study reveals insights into plant structural changes during bioenergy pretreatments.
Duckweed sequencing reveals insights into genes for lignin, cellulose, and starch production.
The species and its relatives appear to be prevalent in areas of high methane flux worldwide.
DOE Joint Genome Institute expands data and analytical tools.
New, rapid, and low-cost approach can be applied to many species.
Opportunities emerge for using microbes to convert the gas to biofuels and other products.
Altered stop codon allows E. coli strain to incorporate nonstandard amino acids.
Genome variability helps explain why Emiliania huxleyi canflourish in diverse ocean habitats.