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An Electro-Microbial Process to Uncouple Food Production from Photosynthesis for Application in Space Exploration.

Philip J L BellFerdinand E ParasSophia MandarakasPsyche ArcenalSinead Robinson-CastAnna Sophia GroblerPaul V Attfield
Published in: Life (Basel, Switzerland) (2022)
Here we propose the concept of an electro-microbial route to uncouple food production from photosynthesis, thereby enabling production of nutritious food in space without the need to grow plant-based crops. In the proposed process, carbon dioxide is fixed into ethanol using either chemical catalysis or microbial carbon fixation, and the ethanol created is used as a carbon source for yeast to synthesize food for human or animal consumption. The process depends upon technologies that can utilize electrical energy to fix carbon into ethanol and uses an optimized strain of the yeast Saccharomyces cerevisiae to produce high-quality, food-grade, single-cell protein using ethanol as the sole carbon source in a minimal medium. Crops performing photosynthesis require months to mature and are challenging to grow under the conditions found in space, whereas the electro-microbial process could generate significant quantities of food on demand with potentially high yields and productivities. In this paper we explore the potential to provide yeast-based protein and other nutrients relevant to human dietary needs using only ethanol, urea, phosphate, and inorganic salts as inputs. It should be noted that as well as having potential to provide nutrition in space, this novel approach to food production has many valuable terrestrial applications too. For example, by enabling food production in climatically challenged environments, the electro-microbial process could potentially turn deserts into food bowls. Similarly, surplus electricity generated from large-scale renewable power sources could be used to supplement the human food chain.
Keyphrases
  • human health
  • microbial community
  • carbon dioxide
  • ionic liquid
  • small molecule
  • induced pluripotent stem cells
  • pluripotent stem cells
  • high resolution
  • protein protein
  • drinking water
  • rna seq
  • cell wall