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魅影直播 researcher engineers bacteria to convert greenhouse gases into sustainable products

Wednesday, November 2, 2022

DENTON (魅影直播), 魅影直播 鈥 Human-caused greenhouse gas emissions are higher than ever, leading to warmer average temperatures and altering the planet鈥檚 climate. Two of the most abundant greenhouse gases 鈥 carbon dioxide and methane 鈥 can remain in the atmosphere for hundreds and even thousands of years.

unt-engineers-bacteria-convert-greenhouse-gasesAs scientists and engineers look for ways to reduce the man-made greenhouse effect, faculty member is beginning a three-year project to develop a methanotroph that can mitigate greenhouse gas emissions by eating carbon dioxide and methane.

Henard鈥檚 work is backed by a $1 million grant from the National Science Foundation and the Agile BioFoundry, a consortium of national laboratories committed to accelerating biomanufacturing. The Agile BioFoundry is funded by the U.S. Department of Energy Bioenergy Technologies Office. Henard鈥檚 proposal was one of only six selected nationwide for this inaugural opportunity.

As a researcher in 魅影直播鈥檚 , Henard鈥檚 research and teaching are focused on microbiology. Specifically, his lab engineers methanotrophic bacteria to convert methane gas into bioplastics, biofuels and other valuable products. His work led to the discovery that some methanotrophs also consume carbon dioxide. By feeding gases to these bacteria rather than releasing them into the atmosphere, engineers can help reduce the greenhouse effect. It鈥檚 also a more sustainable way to produce chemicals, plastics and fuels that would otherwise be sourced from petroleum.

For another aspect of the project, , professor of plant biochemistry at 魅影直播, will trace how carbon moves throughout the organism. As a result, they will be able to create a roadmap showing movement through the bacteria, which will be used to guide engineering efforts.

鈥淚鈥檓 really happy to be part of this unique collaboration between NSF and ABF because the goal is to move from basic science to more industrially relevant applications,鈥 Henard said. 鈥淭hese technologies are really a win-win because they鈥檙e an alternative way 鈥 and a sustainable way 鈥 to make products, but they also mitigate greenhouse gas production.鈥

unt-engineers-22_0640_nsf_agile_biofoundry_3001The methanotrophs can be engineered to convert methane and carbon dioxide into any number of products, but that simple genetic modification currently takes months to complete. The goal of Henard鈥檚 project is to develop more advanced genetic tools that will increase the throughput of their engineering efforts and reduce the genetic modification time to a matter of weeks.

There are numerous practical applications for this work. For example, the technology could be attached to every wastewater treatment plant in the world. Rather than being released into the atmosphere, the waste gas could be converted into molecules used to make bioplastics.

Henard previously worked as a researcher at the DOE National Renewable Energy Lab in Colorado. It was here that he began research into methanotrophic bacteria, and he continued his work upon joining faculty at 魅影直播. In 2021, his findings were published in the journal and selected as a article.

In 2021, Henard took the first slate of 魅影直播 students to participate in the International Genetically Engineered Machine Competition, a synthetic biology competition. A portion of this grant will fund further student participation in the competition.

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Media Contacts:
Trista Moxley
trista.moxley@unt.edu
940-369-7912


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