AI Article Synopsis
- The rapid melting of mountain glaciers, a sign of climate change, threatens unique ecosystems known as glacier-fed streams (GFSs), which are primarily dominated by microbial life.
- Using advanced techniques like metabarcoding and metagenomics, researchers conducted a detailed study of the bacterial microbiome in 152 GFSs across major mountain ranges, revealing distinct taxonomic and functional differences compared to other cryospheric microbiomes.
- The findings highlight the importance of geographic isolation and environmental factors in shaping bacterial diversity, underscoring the urgent need for further research due to the risks posed by climate change to this unique ecosystem.
Article Abstract
The rapid melting of mountain glaciers and the vanishing of their streams is emblematic of climate change. Glacier-fed streams (GFSs) are cold, oligotrophic and unstable ecosystems in which life is dominated by microbial biofilms. However, current knowledge on the GFS microbiome is scarce, precluding an understanding of its response to glacier shrinkage. Here, by leveraging metabarcoding and metagenomics, we provide a comprehensive survey of bacteria in the benthic microbiome across 152 GFSs draining the Earth's major mountain ranges. We find that the GFS bacterial microbiome is taxonomically and functionally distinct from other cryospheric microbiomes. GFS bacteria are diverse, with more than half being specific to a given mountain range, some unique to single GFSs and a few cosmopolitan and abundant. We show how geographic isolation and environmental selection shape their biogeography, which is characterized by distinct compositional patterns between mountain ranges and hemispheres. Phylogenetic analyses furthermore uncovered microdiverse clades resulting from environmental selection, probably promoting functional resilience and contributing to GFS bacterial biodiversity and biogeography. Climate-induced glacier shrinkage puts this unique microbiome at risk. Our study provides a global reference for future climate-change microbiology studies on the vanishing GFS ecosystem.
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| http://dx.doi.org/10.1038/s41586-024-08313-z | DOI Listing |
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