鲜为人知的微生物类群主导着永久冻土融化池塘的微生物群落。
Poorly known microbial taxa dominate the microbiome of permafrost thaw ponds.
作者信息
Wurzbacher Christian, Nilsson R Henrik, Rautio Milla, Peura Sari
机构信息
Department of Biological and Environmental Sciences, University of Gothenburg, Göteborg, Sweden.
Gothenburg Global Biodiversity Centre, Göteborg, Sweden.
出版信息
ISME J. 2017 Aug;11(8):1938-1941. doi: 10.1038/ismej.2017.54. Epub 2017 Apr 21.
Abstract
In the transition zone of the shifting permafrost border, thaw ponds emerge as hotspots of microbial activity, processing the ancient carbon freed from the permafrost. We analyzed the microbial succession across a gradient of recently emerged to older ponds using three molecular markers: one universal, one bacterial and one fungal. Age was a major modulator of the microbial community of the thaw ponds. Surprisingly, typical freshwater taxa comprised only a small fraction of the community. Instead, thaw ponds of all age classes were dominated by enigmatic bacterial and fungal phyla. Our results on permafrost thaw ponds lead to a revised perception of the thaw pond ecosystem and their microbes, with potential implications for carbon and nutrient cycling in this increasingly important class of freshwaters.
摘要
在不断移动的永久冻土边界的过渡地带,融化池塘成为微生物活动的热点区域,处理着从永久冻土中释放出来的古老碳。我们使用三种分子标记物,分析了从新出现到较老池塘的梯度范围内的微生物演替:一种通用标记物、一种细菌标记物和一种真菌标记物。年龄是融化池塘微生物群落的主要调节因素。令人惊讶的是,典型的淡水分类群在群落中只占一小部分。相反,所有年龄类别的融化池塘都以神秘的细菌和真菌门为主。我们关于永久冻土融化池塘的研究结果导致了对融化池塘生态系统及其微生物的重新认识,这可能对这类日益重要的淡水的碳和养分循环产生影响。
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