Fungal colonies in open fractures of subseafloor basalt

Ivarsson, Magnus; Bengtson, Stefan; Skogby, Henrik; Belivanova, Veneta; Marone, Federica

doi:10.1007/s00367-013-0321-7

Cited by 30 publications

(67 citation statements)

References 38 publications

(54 reference statements)

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“…Regarding the first mechanism, the extensive weathering of zeolites seen in the granite fracture in the present study, as well as similar observations in sub-seafloor basalts elsewhere 33, 34 , calls for consideration when planning to use this group of minerals as geochemical barriers in subsurface storages. Zeolites have been planned to function as an ion-exchange retention barrier for the storage of high-level nuclear waste in the US 68, 69 .…”

Section: Discussionsupporting

confidence: 60%

Anaerobic consortia of fungi and sulfate reducing bacteria in deep granite fractures

et al. 2017

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The deep biosphere is one of the least understood ecosystems on Earth. Although most microbiological studies in this system have focused on prokaryotes and neglected microeukaryotes, recent discoveries have revealed existence of fossil and active fungi in marine sediments and sub-seafloor basalts, with proposed importance for the subsurface energy cycle. However, studies of fungi in deep continental crystalline rocks are surprisingly few. Consequently, the characteristics and processes of fungi and fungus-prokaryote interactions in this vast environment remain enigmatic. Here we report the first findings of partly organically preserved and partly mineralized fungi at great depth in fractured crystalline rock (−740 m). Based on environmental parameters and mineralogy the fungi are interpreted as anaerobic. Synchrotron-based techniques and stable isotope microanalysis confirm a coupling between the fungi and sulfate reducing bacteria. The cryptoendolithic fungi have significantly weathered neighboring zeolite crystals and thus have implications for storage of toxic wastes using zeolite barriers.

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Section: Discussionsupporting

confidence: 60%

Anaerobic consortia of fungi and sulfate reducing bacteria in deep granite fractures

et al. 2017

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“…The investigated filaments are characterized by microbial-like morphologies and correspond to other filamentous microfossils from subsurface and subseafloor settings293334. The dimensions and morphologies, including septa, anastomoses between branches, and mycelium-like networks, are further characteristic of fungi rather than filamentous prokaryotes3536.…”

Section: Discussionmentioning

confidence: 94%

Fungal colonization of an Ordovician impact-induced hydrothermal system

Ivarsson

Broman

Sturkell

et al. 2013

Sci Rep

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Impacts are common geologic features on the terrestrial planets throughout the solar system, and on at least Earth and Mars impacts have induced hydrothermal convection. Impact-generated hydrothermal systems have been suggested to possess the same life supporting capability as hydrothermal systems associated with volcanic activity. However, evidence of fossil microbial colonization in impact-generated hydrothermal systems is scarce in the literature. Here we report of fossilized microorganisms in association with cavity-grown hydrothermal minerals from the 458 Ma Lockne impact structure, Sweden. Based on morphological characteristics the fossilized microorganisms are interpreted as fungi. We further infer the kerogenization of the microfossils, and thus the life span of the fungi, to be contemporaneous with the hydrothermal activity and migration of hydrocarbons in the system. Our results from the Lockne impact structure show that hydrothermal systems associated with impact structures can support colonization by microbial life.

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“…Previous work has established thin mycelial structures from these rocks as fungal hyphae based on characteristic fungal morphologies like repetitive septa, anastomoses between branches, a central strand, and the presence of chitin, which together suggest affinity to the Dikarya (Ivarsson et al ., , ). Because the hyphae seem to emanate from the basal film and become wider with increasing distance from the film, we tentatively interpret the film and its coarser protrusions to belong to the same organism as the hyphae.…”

Section: Discussionmentioning

confidence: 99%

“…Fossilized mycelial micro‐organisms in subseafloor basalts have been interpreted as remnants of fungi (Schumann et al ., ; Reitner et al ., ; Peckmann et al ., ; Eickmann et al ., ; Ivarsson, ; Ivarsson et al ., , ). The ability of fungi to live in such extreme environments is corroborated by discoveries of viable yeast cells deep in continental crust (Ekendahl et al ., ) and of active fungal genes in deep‐sea sediments at various depths below the seafloor (Orsi et al ., ,b).…”

Section: Introductionmentioning

confidence: 99%

Deep‐biosphere consortium of fungi and prokaryotes in Eocene subseafloor basalts

et al. 2014

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The deep biosphere of the subseafloor crust is believed to contain a significant part of Earth's biomass, but because of the difficulties of directly observing the living organisms, its composition and ecology are poorly known. We report here a consortium of fossilized prokaryotic and eukaryotic micro-organisms, occupying cavities in deep-drilled vesicular basalt from the Emperor Seamounts, Pacific Ocean, 67.5 m below seafloor (mbsf). Fungal hyphae provide the framework on which prokaryote-like organisms are suspended like cobwebs and iron-oxidizing bacteria form microstromatolites (Frutexites). The spatial inter-relationships show that the organisms were living at the same time in an integrated fashion, suggesting symbiotic interdependence. The community is contemporaneous with secondary mineralizations of calcite partly filling the cavities. The fungal hyphae frequently extend into the calcite, indicating that they were able to bore into the substrate through mineral dissolution. A symbiotic relationship with chemoautotrophs, as inferred for the observed consortium, may be a pre-requisite for the eukaryotic colonization of crustal rocks. Fossils thus open a window to the extant as well as the ancient deep biosphere.

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Fungal colonies in open fractures of subseafloor basalt

Cited by 30 publications

References 38 publications

Anaerobic consortia of fungi and sulfate reducing bacteria in deep granite fractures

Anaerobic consortia of fungi and sulfate reducing bacteria in deep granite fractures

Fungal colonization of an Ordovician impact-induced hydrothermal system

Deep‐biosphere consortium of fungi and prokaryotes in Eocene subseafloor basalts

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