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Cellular engineers seek to boost bromoform in seaweed

Fed to livestock, the molecule could block methane production

by Laurel Oldach
August 21, 2024

Ruminants are a major source of greenhouse gases, but tweaks to their feed may help control those emissions. Several start-ups are developing feed supplements based on seaweed to control microbial methanogenesis in cow rumens. Researchers at the National Science Foundation’s Center for Cellular Construction at the University of California, San Francisco, are hoping to engineer seaweeds to bring bovine methane production down more efficiently.

Structure of the molecule bromoform, a tetrahedral carbon with three bromine atoms and one hydrogen atom.
Bromoform is a small, volatile molecule that protects seaweed from predation.

Red and brown algae, or seaweeds, produce bromoform, CHBr3, which can act as an inhibitor and block some of the series of metabolic enzymes that reduce CO2 to form methane. But bromoform is a small, volatile molecule that algae release as a defense against predation, and it is it hard to tell how much makes it through processing and into a cow’s stomach. Researchers would like to find a method to stably sequester more bromoform in seaweed. But first they must determine how this relatively unstudied molecule escapes from cells in the first place. In a talk delivered Tuesday to the American Chemical Society Division of Biological Chemistry at ACS Fall 2024, IBM postdoctoral researcher Jie Shi of the CCC described computational research probing bromoform’s interactions with cell membranes.

By simulating how bromoform interacts with a simple lipid bilayer, the researchers found that at low concentrations, bromoform diffuses across cell membranes. At higher concentrations, more of it tends to aggregate and phase separate from its aqueous environment. Shi and colleagues told C&EN in an email that although the work will need to be repeated in a bilayer that resembles true seaweed cell membranes, so far it supports their goal to engineer California kelp with specialized bromoform-storing organelles. Someday, tiny intracellular storage containers might ensure that more bromoform reaches feedlots.

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