A newly discovered pathway in a plant process could help farmers grow more successful crops, particularly in places where harsh, high light stresses ...

MIT gave photosynthesis a boost by evolving rubisco to work faster, raising hopes for higher crop yields and more efficient ...

Study can help design efficient artificial leaves, fuel cells, and other systems that mimic photosynthesis. Findings published in Proceedings of the National Academy of Sciences.

Researchers at the Indian Institute of Science (IISc) and the California Institute of Technology (Caltech) have solved a long ...

Scientists at MIT discover how lanthanides, a class of rare earth metals, help crops resist UV stress by enhancing ...

Plant cells have chloroplasts while animal cells don’t. Plant cells need chloroplasts so that they can convert energy from ...

Scientists at MIT have turbocharged one of nature’s most sluggish but essential enzymes—rubisco—by applying a cutting-edge evolution technique in living cells. Normally prone to wasteful reactions ...

In the next phase of photosynthesis, cells use that energy to transform a molecule known as ribulose bisphosphate into ...

For the first of these tasks Dr Baker and his colleagues use RF diffusion, an AI model they have developed to predict a ...

The advance was published in Proceedings of the National Academy of Sciences by researchers at the UC San Diego Materials Research Science and Engineering Center (MRSEC). The team was led by Jinhye ...

Science X Science News Wire : Revisiting energy flow in photosynthetic plant cells -- a press release is provided to you ìas isî with little or no review from Science X staff.

Nanotube bridge networks grow between the most abundant photosynthetic bacteria in the oceans, suggesting that the world is far more interconnected than anyone realized.