Abstract

Providing life-support materials to crewed space exploration missions is pivotal for mission success. However, as missions become more distant and extensive, obtaining these materials from <i>in situ</i> resource utilization is paramount. The combination of microorganisms with electrochemical technologies offers a platform for the production of critical chemicals and materials from CO₂ and H₂O, two compounds accessible on a target destination like Mars. One such potential commodity is poly(3-hydroxybutyrate) (PHB), a common biopolyester targeted for additive manufacturing of durable goods. Here, we present an integrated two-module process for the production of PHB from CO₂. An autotrophic <i>Sporomusa ovata (S. ovata)</i> process converts CO₂ to acetate which is then directly used as the primary carbon source for aerobic PHB production by <i>Cupriavidus basilensis (C. basilensis)</i>. The <i>S. ovata</i> uses H₂ as a reducing equivalent to be generated through electrocatalytic solar-driven H₂O reduction. Conserving and recycling media components is critical, therefore we have designed and optimized our process to require no purification or filtering of the cell culture media between microbial production steps which could result in up to 98% weight savings. By inspecting cell population dynamics during culturing we determined that <i>C. basilensis</i> suitably proliferates in the presence of inactive <i>S. ovata</i>. During the bioprocess 10.4 mmol acetate L ^-1 day^-1 were generated from CO₂ by <i>S. ovata</i> in the optimized media. Subsequently, 12.54 mg PHB L^-1 hour^-1 were produced by <i>C. basilensis</i> in the unprocessed media with an overall carbon yield of 11.06% from acetate. In order to illustrate a pathway to increase overall productivity and enable scaling of our bench-top process, we developed a model indicating key process parameters to optimize.