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β-Dicarbonyls Facilitate Engineered Microbial Bromoform Biosynthesis.

Thomas D LoanClaudia E VickersMichael AyliffeMing Luo
Published in: ACS synthetic biology (2024)
Ruminant livestock produce around 24% of global anthropogenic methane emissions. Methanogenesis in the animal rumen is significantly inhibited by bromoform, which is abundant in seaweeds of the genus Asparagopsis . This has prompted the development of livestock feed additives based on Asparagopsis to mitigate methane emissions, although this approach alone is unlikely to satisfy global demand. Here we engineer a non-native biosynthesis pathway to produce bromoform in vivo with yeast as an alternative biological source that may enable sustainable, scalable production of bromoform by fermentation. β-dicarbonyl compounds with low p K a values were identified as essential substrates for bromoform production and enabled bromoform synthesis in engineered Saccharomyces cerevisiae expressing a vanadate-dependent haloperoxidase gene. In addition to providing a potential route to the sustainable biological production of bromoform at scale, this work advances the development of novel microbial biosynthetic pathways for halogenation.
Keyphrases
  • saccharomyces cerevisiae
  • anaerobic digestion
  • microbial community
  • cell wall
  • gene expression
  • ionic liquid
  • municipal solid waste
  • human health