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高纬地区积雪中的微生物及其对寒冷生物圈的影响。

Microbes in high arctic snow and implications for the cold biosphere.

机构信息

Department of Biochemistry and Molecular Biology, Dalhousie University, 1459 Oxford St., Halifax, Nova Scotia B3H4R2, Canada.

出版信息

Appl Environ Microbiol. 2011 May;77(10):3234-43. doi: 10.1128/AEM.02611-10. Epub 2011 Apr 1.

DOI:10.1128/AEM.02611-10
PMID:21460114
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3126466/
Abstract

We applied molecular, microscopic, and culture techniques to characterize the microbial communities in snow and air at remote sites in the Canadian High Arctic (Ward Hunt Island, Ellesmere Island, and Cornwallis Island, latitudes 74 to 83(o)N). Members of the Bacteria and Eukarya were prevalent in the snow, and their small subunit (SSU) rRNA gene signatures indicated strong local aerial transport within the region over the preceding 8 months of winter snowpack accumulation. Many of the operational taxonomic units (OTUs) were similar to previously reported SSU rRNA gene sequences from the Arctic Ocean, suggesting the importance of local aerial transport processes for marine microbiota. More than 47% of the cyanobacterial OTUs in the snow have been previously found in microbial mats in the region, indicating that this group was also substantially derived from local sources. Viable cyanobacteria isolated from the snow indicated free exchange between the snow and adjacent mat communities. Other sequences were most similar to those found outside the Canadian Arctic but were from snow, lake and sea ice, glaciers and permafrost, alpine regions, Antarctica, and other regions of the Arctic, supporting the concept of global distribution of microbial ecotypes throughout the cold biosphere.

摘要

我们应用分子、微观和培养技术来描述加拿大北极地区偏远地点(哈德逊湾群岛、埃尔斯米尔岛和科温斯岛,纬度 74 至 83(o)N)的雪中及空气中的微生物群落。细菌和真核生物在雪中很普遍,它们的小亚基(SSU)rRNA 基因特征表明,在过去 8 个月的冬季积雪积累期间,该地区有强烈的局部空中运输。许多操作分类单元(OTUs)与以前报道的来自北冰洋的 SSU rRNA 基因序列相似,这表明局部空气传输过程对海洋微生物群的重要性。雪中有超过 47%的蓝藻 OTUs 以前在该地区的微生物垫中发现过,这表明该群体也主要来自当地。从雪中分离出的可培养蓝藻表明,雪与相邻垫社区之间存在自由交换。其他序列与在加拿大北极地区以外发现的序列最相似,但来自雪、湖泊和海冰、冰川和永久冻土、高山地区、南极洲以及北极地区的其他地区,这支持了微生物生态型在整个寒冷生物圈中全球分布的概念。

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