THE CONCEPTUAL APPROACH TO THE USE OF POSTBIOTICS BASED ON BACTERIAL MEMBRANE NANOVESICLES FOR PROPHYLAXIS OF ASTRONAUTS’ HEALTH DISORDERS

Pub Date : 2022-12-08 DOI:10.15407/knit2022.06.034
I. Orlovska, O. Podolich, O. Kukharenko, G. Zubova, O. Reva, A. Di Cesare, A. Góes-Neto, V. Azevedo, D. Barh, J. D. de Vera, N. Kozyrovska
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Abstract

The functional fermented foods containing live microorganisms and their components are necessary for the normal functioning of the human body as normal gut microbiota needs fuel from external microbial organisms and their nanostructures — membrane vesicles (MVs), excreting outside. The сoncept that MVs may contribute to astronauts’ health probably to the same extent as their parental microbial cells do and be a temporary substitute for living microbial cells until we know more about the behavior of microbes in the space environment. The advantage of MVs is that they are not alive and cannot be changed under unfavorable conditions as microbial organisms may be. As the model, we selected MVs of a robust to environmental factors kombucha multimicrobial culture (KMC), known for its health-promoting characteristics for humans. We exposed KMC on the International Space Station in a hybrid space/Mars-like environment for an initial proof-of-concept stage. In the exposure study, KMC has survived a long-term period in harsh conditions, and the MVs generated by post-flight kombucha community members did not acquire toxicity, despite the changed membrane composition in the environment imitated conditions on the Mars surface. This observation, together with our KMC metagenomic and comparative genomic analyses of the dominant KMC bacterium Komagataeibacter oboediens, showed that the ground reference sample and spaceexposed ones were similar in topology and maintained their stability. In the next stage, we assessed the fitness, safety, and biodistribution of MVs of post-flight K. oboediens and showed that they were altered, but the modifications in membrane structure did not result in toxicity acquisition. Our proof-of-concept strategy is discussed in this review in line with the literature.
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基于细菌膜纳米囊泡的后生物制剂预防宇航员健康障碍的概念方法
含有活微生物及其成分的功能性发酵食品是人体正常功能所必需的,因为正常的肠道微生物群需要来自外部微生物及其纳米结构——膜囊泡(MV)的燃料,并在外部排泄。假设MV可能对宇航员的健康有贡献,其程度可能与它们的亲代微生物细胞相同,并且是活微生物细胞的临时替代品,直到我们更多地了解微生物在太空环境中的行为。MV的优点是它们不活,不能像微生物一样在不利的条件下改变。作为模型,我们选择了对环境因素具有强大抵抗力的康普茶多微生物培养物(KMC)的MV,该培养物以其促进人类健康的特性而闻名。我们在国际空间站的太空/火星混合环境中展示了KMC,作为概念验证的初始阶段。在暴露研究中,KMC在恶劣的条件下存活了很长一段时间,飞行后康普茶群落成员产生的MV没有获得毒性,尽管环境中的膜组成发生了变化,模拟了火星表面的条件。这一观察结果,加上我们对优势KMC细菌Komagataeibacter oboediens的KMC宏基因组和比较基因组分析,表明地面参考样品和空间暴露样品在拓扑结构上相似,并保持其稳定性。在下一阶段,我们评估了飞行后弓形虫MV的适用性、安全性和生物分布,并表明它们发生了改变,但膜结构的改变并没有导致毒性获得。我们的概念验证策略在这篇综述中根据文献进行了讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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