Author
Listed:
- Hakyung Lee
(Washington University in St. Louis)
- Jinjin Diao
(Washington University in St. Louis)
- Yuxin Tian
(Washington University in St. Louis
J. Craig Venter Institute)
- Richa Guleria
(University of Delaware)
- Eunseo Lee
(Washington University in St. Louis)
- Alexandra Smith
(University of South Florida)
- Millie Savage
(Lincoln University of Missouri)
- Daniel Yeh
(University of South Florida)
- Luke Roberson
(John F. Kennedy Space Center)
- Mark Blenner
(University of Delaware)
- Yinjie J. Tang
(Washington University in St. Louis)
- Tae Seok Moon
(Washington University in St. Louis
J. Craig Venter Institute)
Abstract
In-space biomanufacturing provides a sustainable solution to facilitate long-term, self-sufficient human habitation in extraterrestrial environments. However, its dependence on Earth-supplied feedstocks renders in-space biomanufacturing economically nonviable. Here, we develop a process termed alternative feedstock-driven in-situ biomanufacturing (AF-ISM) to alleviate dependence on Earth-based resupply of feedstocks. Specifically, we investigate three alternative feedstocks (AF)—Martian and Lunar regolith, post-consumer polyethylene terephthalate, and fecal waste—to develop an alternative medium for lycopene production using Rhodococcus jostii PET strain S6 (RPET S6). Our results show that RPET S6 could directly utilize regolith simulant particles as mineral replacements, while the addition of anaerobically pretreated fecal waste synergistically supported its cell growth. Additionally, lycopene production using AF under microgravity conditions achieved levels comparable to those on Earth. Furthermore, an economic analysis shows significant lycopene production cost reductions using AF-ISM versus conventional methods. Overall, this work highlights the viability of AF-ISM for in-space biomanufacturing.
Suggested Citation
Hakyung Lee & Jinjin Diao & Yuxin Tian & Richa Guleria & Eunseo Lee & Alexandra Smith & Millie Savage & Daniel Yeh & Luke Roberson & Mark Blenner & Yinjie J. Tang & Tae Seok Moon, 2025.
"Developing an alternative medium for in-space biomanufacturing,"
Nature Communications, Nature, vol. 16(1), pages 1-16, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-56088-2
DOI: 10.1038/s41467-025-56088-2
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