Fossilized anaerobic and possibly methanogenesis-fueling fungi identified deep within the Siljan impact structure, Sweden

Recent discoveries of extant and fossilized communities indicate that eukaryotes, including fungi, inhabit energy-poor and anoxic environments deep within the fractured igneous crust. This subterranean biosphere may constitute the largest fungal habitat on our planet, but knowledge of abyssal fungi...

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Bibliographic Details
Published in:Communications earth & environment 2021-02, Vol.2 (1), p.1, Article 34
Main Authors: Drake, Henrik, Ivarsson, Magnus, Heim, Christine, Snoeyenbos-West, Oona, Bengtson, Stefan, Belivanova, Veneta, Whitehouse, Martin
Format: Article
Language:English
Subjects:
Abyssal zone
Autotrophs
Bedrock
Biosphere
Calcite
Chitin
Chronology
Decomposition
deep biosphere
Den föränderliga jorden
Depth indicators
Environmental Science
Eocene
Eukaryotes
Fossils
Fungi
impact
Methanogenesis
Miljövetenskap
Organic matter
Prokaryotes
Sweden
The changing Earth
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Summary:Recent discoveries of extant and fossilized communities indicate that eukaryotes, including fungi, inhabit energy-poor and anoxic environments deep within the fractured igneous crust. This subterranean biosphere may constitute the largest fungal habitat on our planet, but knowledge of abyssal fungi and their syntrophic interactions with prokaryotes and their concomitant metabolisms is scarce. Here we report findings of fossilized, chitin-bearing fungal hyphae at ~540 m depth in fractured bedrock of the Siljan impact structure, the largest crater in Europe. Strong 13 C-enrichment of calcite precipitated with and on the fungi suggests formation following methanogenesis, and that the anaerobic fungi decomposed dispersed organic matter producing for example H 2 that may have fueled autotrophic methanogens. An Eocene age determined for the calcite infers the first timing constraint of fossilized fungi in the continental igneous crust. Fungi may be widespread decomposers of organic matter and overlooked providers of H 2 to autotrophs in the vast rock-hosted deep biosphere.
ISSN:2662-4435
2662-4435
DOI:10.1038/s43247-021-00107-9