太空生物膜 - 国际空间站硅胶和纤维素膜上生长的铜绿假单胞菌生物膜形态概览

IF 5.9 Q1 MICROBIOLOGY
Pamela Flores , Jiaqi Luo , Daniel Wyn Mueller , Frank Muecklich , Luis Zea
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引用次数: 0

摘要

微生物作为有组织的多细胞群落(也称为生物膜)生存的天然能力为它们提供了独特的生存优势。例如,细菌生物膜借助其细胞外基质抵御环境压力,这可能会导致抗生素治疗后的持续感染。细菌生物膜还能强力附着在表面上,其代谢副产物可导致表面材料降解。此外,微重力会以意想不到的方式改变生物膜的行为,因此太空中生物膜的存在对宇航员和航天硬件都是一种风险。尽管人们努力消除航天器表面的微生物污染,但仍不可能防止与人类相关的细菌最终在表面形成生物膜。不过,通过了解细菌生物膜在微重力环境下发生的变化,可以找出关键的差异和途径,从而有针对性地大幅减少生物膜的形成。2020 年初在国际空间站上进行的太空生物膜项目的细菌部分,通过描述在微重力环境下形成的细菌生物膜与地面对照的形态和基因表达,有助于加深这种理解。由于铜绿假单胞菌在生物膜研究中的相关性及其作为机会性病原体引起尿路感染的能力,因此被用作模式生物。在六种不同材料上培养一、二、三天(37 °C)后,对生物膜的形成进行了鉴定。本手稿中报告的材料包括导管级硅胶(因其在医院感染中的医学相关性而被选中)、导管级硅胶与超短脉冲直接激光干涉图案(用于测试作为一种潜在生物膜控制策略的微图案)以及纤维素膜(用于复制之前在微重力研究中报告的柱状和冠状结构)。我们在此概述了生物膜的形态,包括生物膜的三维图像,以展示在每种测试材料中观察到的独特形态,以及生物膜厚度、质量和表面覆盖面积的一些关键差异。我们还介绍了不同材料、培养时间和重力条件下表面微观形貌对生物膜形成的影响。太空生物膜项目(细菌方面)得到了美国国家航空航天局(National Aeronautics and Space Administration)80NSSC17K0036 和 80NSSC21K1950 号拨款的支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Space biofilms – An overview of the morphology of Pseudomonas aeruginosa biofilms grown on silicone and cellulose membranes on board the international space station

Microorganisms’ natural ability to live as organized multicellular communities – also known as biofilms – provides them with unique survival advantages. For instance, bacterial biofilms are protected against environmental stresses thanks to their extracellular matrix, which could contribute to persistent infections after treatment with antibiotics. Bacterial biofilms are also capable of strongly attaching to surfaces, where their metabolic by-products could lead to surface material degradation. Furthermore, microgravity can alter biofilm behavior in unexpected ways, making the presence of biofilms in space a risk for both astronauts and spaceflight hardware. Despite the efforts to eliminate microorganism contamination from spacecraft surfaces, it is impossible to prevent human-associated bacteria from eventually establishing biofilm surface colonization. Nevertheless, by understanding the changes that bacterial biofilms undergo in microgravity, it is possible to identify key differences and pathways that could be targeted to significantly reduce biofilm formation. The bacterial component of Space Biofilms project, performed on the International Space Station in early 2020, contributes to such understanding by characterizing the morphology and gene expression of bacterial biofilms formed in microgravity with respect to ground controls. Pseudomonas aeruginosa was used as model organism due to its relevance in biofilm studies and its ability to cause urinary tract infections as an opportunistic pathogen. Biofilm formation was characterized at one, two, and three days of incubation (37 °C) over six different materials. Materials reported in this manuscript include catheter grade silicone, selected due to its medical relevance in hospital acquired infections, catheter grade silicone with ultrashort pulsed direct laser interference patterning, included to test microtopographies as a potential biofilm control strategy, and cellulose membrane to replicate the column and canopy structure previously reported from a microgravity study. We here present an overview of the biofilm morphology, including 3D images of the biofilms to represent the distinctive morphology observed in each material tested, and some of the key differences in biofilm thickness, mass, and surface area coverage. We also present the impact of the surface microtopography in biofilm formation across materials, incubation time, and gravitational conditions.

The Space Biofilms project (bacterial side) is supported by the National Aeronautics and Space Administration under Grant No. 80NSSC17K0036 and 80NSSC21K1950.

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来源期刊
Biofilm
Biofilm MICROBIOLOGY-
CiteScore
7.50
自引率
1.50%
发文量
30
审稿时长
57 days
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