Carbenes are highly reactive carbon-based chemicals that can be used in many different types of reactions. For decades, scientists have wanted to use carbene reactions in the manufacturing of fuels and chemicals, and in drug discovery and synthesis.
But these carbene processes could only be carried out in small batches via test tubes and required expensive chemical substances to drive the reaction.
In the new study, the researchers replaced expensive chemical reactants with natural products that can be produced by an engineered strain of the bacteria Streptomyces. Because the bacteria use sugar to produce chemical products through cellular metabolism, “this work enables us to perform the carbene chemistry without toxic solvents or toxic gases typically used in chemical synthesis,” said first author Jing Huang, a Berkeley Lab postdoctoral researcher in the Keasling Lab. “This biological process is much more environmentally friendly than the way chemicals are synthesized today,” Huang said.
During experiments at JBEI, the researchers observed the engineered bacterium as it metabolized and converted sugars into the carbene precursor and the alkene substrate. The bacterium also expressed an evolved P450 enzyme that used those chemicals to produce cyclopropanes, high-energy molecules that could potentially be used in the sustainable production of novel bioactive compounds and advanced biofuels. “We can now perform these interesting reactions inside the bacterial cell. The cells produce all of the reagents and the cofactors, which means that you can scale this reaction to very large scales” for mass manufacturing, Keasling said.
Huang said that while this fully integrated system can be envisioned for a large number of carbene donor molecules and alkene substrates, it is not yet ready for commercialization.
“For every new advance, someone needs to take the first step. And in science, it can take years before you succeed. But you have to keep trying – we can’t afford to give up. I hope our work will inspire others to continue searching for greener, sustainable biomanufacturing solutions,” Huang said.
Other authors on the paper are Andrew Quest, Pablo Cruz-Morales, Kai Deng, Jose Henrique Pereira, Devon Van Cura, Ramu Kakumanu, Edward E. K. Baidoo, Qingyun Dan, Yan Chen, Christopher J. Petzold, Trent R. Northen, Paul D. Adams, Douglas S. Clark, Emily P. Balskus, John F. Hartwig, and Aindrila Mukhopadhyay.
This work was supported by the DOE Office of Science and DOE Office of Biological and Environmental Research. Additional support was provided by the National Science Foundation.
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