Utilizing the KSC Fixation Tube to Conduct Human-Tended Plant Biology Experiments on a Suborbital Spaceflight

Overview

Journal Life (Basel)

Specialty Biology

Date 2022 Nov 26

PMID 36431005

Authors

Natasha J Haveman

Mingqi Zhou

Jordan Callaham

Hunter F Strickland

Donald Houze

Susan Manning-Roach

Gerard Newsham

Anna-Lisa Paul

Robert J Ferl

Affiliations

Soon will be listed here.

Abstract

Suborbital spaceflights now enable human-tended research investigating short-term gravitational effects in biological systems, eliminating the need for complex automation. Here, we discuss a method utilizing KSC Fixation Tubes (KFTs) to both carry biology to suborbital space as well as fix that biology at certain stages of flight. Plants on support media were inserted into the sample side of KFTs preloaded with RNAlater in the fixation chamber. The KFTs were activated at various stages of a simulated flight to fix the plants. RNA-seq analysis conducted on tissue samples housed in KFTs, showed that plants behaved consistently in KFTs when compared to petri-plates. Over the time course, roots adjusted to hypoxia and leaves adjusted to changes in photosynthesis. These responses were due in part to the environment imposed by the encased triple containment of the KFTs, which is a requirement for flight in human spacecraft. While plants exhibited expected reproducible transcriptomic alteration over time in the KFTs, responses to clinorotation during the simulated flight suggest that transcriptomic responses to suborbital spaceflight can be examined using this approach.

Citing Articles

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Zhou M, Ferl R, Paul A NPJ Microgravity. 2024; 10(1):82.

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