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美国犹他州冬季仙境冰洞的细菌多样性和地质微生物学。

Bacterial diversity and geomicrobiology of Winter Wonderland ice cave, Utah, USA.

机构信息

Department of Earth and Climate Sciences, Middlebury College, Middlebury, Vermont, USA.

Biology Department, Middlebury College, Middlebury, Vermont, USA.

出版信息

Microbiologyopen. 2024 Aug;13(4):e1426. doi: 10.1002/mbo3.1426.

DOI:10.1002/mbo3.1426
PMID:38995161
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11241547/
Abstract

The Winter Wonderland ice cave, located at an elevation of 3140 m above sea level in the Uinta Mountains of northern Utah, USA, maintains a constant sub-zero temperature. Seasonal snowmelt and rain enter the cave, freeze on the surface of the existing ice, and contribute to a 3-m-thick layered ice mass. This ice mass contains organic matter and cryogenic cave carbonates (CCCs) that date back centuries. In this study, samples of ice, liquid water, and exposed CCCs were collected to examine the bacterial communities within the cave and to determine if these communities vary spatially and between sample types. Flow cytometry showed that cell counts are an order of magnitude higher in liquid water samples than in ice. Epifluorescence microscopy and scanning electron microscopy imaging revealed potential coccoid and bacillus microbial morphologies in water samples and putative cells or calcite spherules in the CCCs. The diversity of bacteria associated with soil, identified through sequence-based analysis, supports the hypothesis that water enters the cave by filtering through soil and bedrock. A differential abundance of bacterial taxa was observed between sample types, with the greatest diversity found in CCCs. This supports a geomicrobiological framework where microbes aggregate in the water, sink into a concentrated layer, and precipitate out of the ice with the CCCs, thereby reducing the cell counts in the ice. These CCCs may provide essential nutrients for the bacteria or could themselves be products of biomineralization.

摘要

美国犹他州北部温特沃思仙境冰洞位于海拔 3140 米的尤因塔山脉,洞内温度保持在零下。季节性融雪和雨水进入洞穴,在现有的冰面上冻结,并形成了 3 米厚的分层冰体。这些冰层含有有机物质和低温洞穴碳酸盐(CCCs),可以追溯到几个世纪以前。在这项研究中,采集了冰、液态水和暴露的 CCC 样本,以研究洞穴内的细菌群落,并确定这些群落是否在空间上和样本类型上存在差异。流式细胞术显示,水样中的细胞计数比冰样高一个数量级。荧光显微镜和扫描电子显微镜成像显示,水样中存在潜在的球菌和杆菌微生物形态,以及 CCC 中的假定细胞或方解石球。通过基于序列的分析确定与土壤相关的细菌多样性,支持了水通过过滤土壤和基岩进入洞穴的假说。在不同的样本类型之间观察到细菌分类群的丰度差异,其中 CCC 中的多样性最大。这支持了一个地质微生物学框架,即微生物在水中聚集,下沉到浓缩层,然后与 CCC 一起沉淀出冰,从而降低了冰中的细胞计数。这些 CCC 可能为细菌提供了必需的营养物质,或者本身就是生物矿化的产物。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8660/11241547/8eb1c17b7cc4/MBO3-13-e1426-g003.jpg
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