Abstract
Sustainable agriculture in microgravity is integral to future long-term human space exploration. To ensure the efficient and sustainable cultivation of plants in space, a contingency plan to monitor plant health and mitigate plant diseases is necessary. Yet, neither methods nor tools currently exist to evaluate the plant microbial interactions or to diagnose potential plant diseases in space-based bioregenerative life support systems. In this study, we show how the MinION sequencing platform can be used to diagnose the opportunistic pathogen Fusarium oxysporum sensu lato, a fungal infection on Zinnia hybrida (zinnia) plants that were grown on the International Space Station (ISS) in 2015–2016. Genomic DNA from the infected plant material (root and leaf tissues) retrieved from the ISS were extracted and sequenced. In addition, pure cultures of Burkholderia contaminans, F. oxysporum sensu lato, and Fusarium sporotrichioides were used as controls to test the specificity of the bioinformatics pipeline developed. The results show that the MinION platform can be used to accurately differentiate between fusaria species and strengthens the case for using the platform as a rapid plant disease diagnostic tool in space.
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