Are glacier surfaces the last refuge of an evolutionary ancient lineage of unknown fungi?

Project: Externally funded research

Project Details

Layman's description

Glaciers and ice-sheets are increasingly recognized as the homes of surprisingly diverse and active microbial ecosystems. Even the mere prospect of life in Antarctic subglacial lakes, isolated for many millennia, attracts major international attention and investment. However since life certainly flourishes in unusual habitats on glacier surfaces. these should not be overlooked in our attempts to explore microbial biodiversity. Cryoconite holes are one such habitat, formed when rocky dusts are colonized by a diverse and highly active microbial consortium, forming a darkened microbe-mineral aggregate which increases the transfer of the sun's energy to ice and thus accelerates surface melt. My doctoral studies centred on the diversity and functioning of the bacterial community of cryoconite, which is dominated by organisms closely related to taxa in a broad range of habitats world-wide. In stark contrast, of the eukaryotes inhabiting cryoconite on High Arctic glaciers, the most abundant group by biomass, Fungi, appears strongly dominated by two related groups of fungi hitherto unknown to science. These fungi account for 75% of the sequences in collections of fungal DNA extracted from Svalbard cryoconite, and according to microscopy using genetic stains specific to the group, are derived from small ovoid cells attached to debris. Sequenced genes from specific DNA tests for the fungi demonstrate their presence in cryoconite worldwide suggesting a broad geographic range while the absence of affiliated sequences from DNA databases and the failure to detect the group in periglacial habitats imply their restriction to the cryoconite group near the root of the fungal tree of life and provide a crudely estimated divergence during the Neoproterozoic era, which consisted of major world-wide glaciations, including a hypothesized Snowball Earth. Little else is known about these fungi, tentatively named the cryomycetes. Therefore, I seek support to detail their evolutionary history, population structure, ecological functions and interactions. Doing so will permit the testing of the hypotheses that i)cryomycetes assume a significant role in the functioning of the extant cryoconite ecosystem ii)they form a major new branch on the fungal tree of life iii)cryoconite holes have formed a stable refuge for these fungi over glacial cycles. As a consequence, I anticipate insights into the interactions between cryoconite biodiversity and melting glaciers, both in the present day, and potentially in the postulated transition from a Neoproterozoic Snowball to a Mudball Earth.
StatusFinished
Effective start/end date05 Sept 201204 Mar 2015

Funding

  • Natural Environment Research Council (NE/K000942/1): £62,864.66

UN Sustainable Development Goals

In 2015, UN member states agreed to 17 global Sustainable Development Goals (SDGs) to end poverty, protect the planet and ensure prosperity for all. This project contributes towards the following SDG(s):

  • SDG 13 - Climate Action
  • SDG 14 - Life Below Water
  • SDG 15 - Life on Land

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