Urban endoliths: incidental microbial communities occurring inside concrete.

IF 2.7 Q3 MICROBIOLOGY AIMS Microbiology Pub Date : 2023-01-01 DOI:10.3934/microbiol.2023016
Jordan Brown, Corona Chen, Melania Fernández, Deborah Carr
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引用次数: 2

Abstract

Concrete is now a prevalent type of synthetic rock, and its production and usage have major environmental implications. Yet, assessments of ordinary concrete have rarely considered that concrete itself is potential habitat for a globally important microbial guild, the endolithic microbes, which live inside rocks and other mineralized substrates. We sought evidence that many common concrete structures harbor endolithic microbial communities and that these communities vary widely depending on the conditions imposed by the concrete. In Summer 2022, we obtained samples from various concrete structures found throughout Lubbock, Texas, USA and subjected the internal (non-surface) portions of each sample to controlled microbial life detection tests including culture tests, DNA quantifications, DNA amplification tests, and ATP assays. The great preponderance of positive life detection results from our concrete samples suggests that most modern concrete hosts cryptic endolith communities composed of bacteria, sometimes co-occurring with fungi and/or archaea. Moreover, many of these microbes are viable, culturable, and identifiable via genetic analysis. Endolith signatures varied widely across concrete samples; some samples only yielded trace evidence of possibly dormant microbes while other samples contained much more microbial biomass and diversity, on par with some low-biomass soils. Pre-cast masonry units and fragments of poured concrete found underwater generally had the most endolith signatures, suggesting that concrete forms and environmental positioning affect endolithy. Endolith biosignatures were generally greater in less dense and less alkaline concrete samples. So, concrete endolith communities may be as ubiquitous and diverse as the concrete structures they inhabit. We propose further research of concrete endoliths to help clarify the role of modern concrete in our rapidly urbanizing biosphere.

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城市内石:混凝土内部偶然发生的微生物群落。
混凝土现在是一种普遍的合成岩石类型,它的生产和使用具有重大的环境影响。然而,对普通混凝土的评估很少考虑到混凝土本身是一个全球重要的微生物协会的潜在栖息地,即生活在岩石和其他矿化基质中的内生微生物。我们寻找的证据表明,许多常见的混凝土结构中含有内生微生物群落,这些群落根据混凝土施加的条件而变化很大。在2022年夏季,我们从美国德克萨斯州Lubbock的各种混凝土结构中获得了样品,并对每个样品的内部(非表面)部分进行了受控的微生物生命检测测试,包括培养测试、DNA定量、DNA扩增测试和ATP分析。从我们的混凝土样品中获得的积极的生命检测结果表明,大多数现代混凝土都含有由细菌组成的隐性内岩群落,有时与真菌和/或古细菌共存。此外,这些微生物中的许多是可存活的,可培养的,并通过基因分析可识别。岩石特征在混凝土样品中差异很大;一些样品只产生了可能休眠微生物的微量证据,而其他样品含有更多的微生物生物量和多样性,与一些低生物量土壤相当。水下发现的预制砌体和浇筑混凝土碎片普遍具有最多的内岩特征,表明混凝土形式和环境定位影响内岩性。在密度较低和碱性较低的混凝土样品中,腔石生物特征通常较大。因此,混凝土内石群落可能和它们居住的混凝土结构一样无处不在,种类繁多。我们建议进一步研究混凝土内石,以帮助阐明现代混凝土在我们快速城市化的生物圈中的作用。
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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来源期刊
AIMS Microbiology
AIMS Microbiology MICROBIOLOGY-
CiteScore
7.00
自引率
2.10%
发文量
22
审稿时长
8 weeks
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