Seto Emily P, Hirsch Aspen L, Schubert Wayne W, Chandramowlishwaran Pavithra, Chernoff Yury O
Honeybee Robotics, Altadena, CA, United States.
Biotechnology and Planetary Protection Group, Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA, United States.
Front Microbiol. 2022 Aug 9;13:911091. doi: 10.3389/fmicb.2022.911091. eCollection 2022.
The National Aeronautics and Space Administration (NASA) and the European Space Agency (ESA) are studying how to improve the safety of future planetary science sample return missions that would bring back materials to Earth. Backward planetary protection requirements have been identified as a critical technology development focus in order to reduce the possibility of harm to Earth's biosphere from such returned materials. In order to meet these challenges, NASA has identified the need for an appropriate suite of biological indicators (BIs) that would be used to develop, test, and ultimately validate sample return mission sterilization systems. Traditionally, BIs are defined as test systems composed of viable microorganisms that are inactivated when necessary conditions are met during sterilization procedures, providing a level of confidence in the process. BIs used traditionally at NASA have been driven by past mission requirements, mainly focused on spore-formers. However, spore-based BIs are insufficient as the only analog for a nominal case in sample return missions. NASA has directed sample return missions from habitable worlds to manage "potential extraterrestrial life and bioactive molecules" which requires investigation of a range of potential BIs. Thus, it is important to develop a mitigation strategy that addresses various known forms of biology, from complex organisms to biomolecular assemblies (including self-perpetuating non-nucleic acid containing structures). The current effort seeks to establish a BI that would address a stable biomolecule capable of replication. Additional engineering areas that may benefit from this information include applications of brazing, sealing, and impact heating, and atmospheric entry heating. Yeast aggregating proteins exhibit aggregation behavior similar to mammalian prion protein and have been successfully employed by researchers to understand fundamental prion properties such as aggregation and self-propagation. Despite also being termed "prions," yeast proteins are not hazardous to humans and can be used as a cost effective and safer alternative to mammalian prions. We have shown that inactivation by dry heat is feasible for the prion formed by the yeast Sup35NM protein, although at higher temperature than for bacterial spores.
美国国家航空航天局(NASA)和欧洲航天局(ESA)正在研究如何提高未来行星科学样本返回任务的安全性,这些任务将把材料带回地球。反向行星保护要求已被确定为关键技术发展重点,以降低此类返回材料对地球生物圈造成危害的可能性。为应对这些挑战,NASA已确定需要一套合适的生物指示剂(BI),用于开发、测试并最终验证样本返回任务的灭菌系统。传统上,BI被定义为由活微生物组成的测试系统,在灭菌程序中满足必要条件时会失活,从而为该过程提供一定程度的可信度。NASA传统上使用的BI一直受过去任务要求驱动,主要侧重于产孢菌。然而,基于孢子的BI不足以作为样本返回任务中正常情况的唯一模拟物。NASA已指示来自宜居世界的样本返回任务要管理“潜在的外星生命和生物活性分子”,这需要研究一系列潜在的BI。因此,制定一种应对各种已知生物形式的缓解策略很重要,这些生物形式从复杂生物体到生物分子组装体(包括自我复制的不含核酸结构)。当前的工作旨在建立一种能针对稳定的可复制生物分子的BI。可能从这些信息中受益的其他工程领域包括钎焊、密封、冲击加热以及大气进入加热的应用。酵母聚集蛋白表现出与哺乳动物朊病毒蛋白相似的聚集行为,研究人员已成功利用其来了解朊病毒的基本特性,如聚集和自我传播。尽管酵母蛋白也被称为“朊病毒”,但它们对人类无害,可作为哺乳动物朊病毒的一种经济高效且更安全的替代品。我们已经表明,通过干热使酵母Sup35NM蛋白形成的朊病毒失活是可行的,尽管所需温度高于细菌孢子。
