Beringian Paleoecology Inferred from Permafrost-preserved Fungal DNA

Overview

Journal Appl Environ Microbiol

Specialties Environmental Health
Microbiology

Date 2005 Feb 5

PMID 15691960

Citations 23

Authors

Magnus C Lydolph

Jonas Jacobsen

Peter Arctander

M Thomas P Gilbert

David A Gilichinsky

Anders J Hansen

Eske Willerslev

Lene Lange

Affiliations

Soon will be listed here.

Abstract

The diversity of fungi in permanently frozen soil from northeastern Siberia was studied by culture-independent PCR amplification of diverse environmental 18S rRNA genes. Elaborate protocols to avoid contamination during drilling, sampling, and amplification were used. A broad diversity of eukaryotic DNA sequences that were 510 bp long, including sequences of various fungi, plants, and invertebrates, could be obtained reproducibly from samples that were up to 300,000 to 400,000 years old. The sequences revealed that ancient fungal communities included a diversity of cold-adapted yeasts, dark-pigmented fungi, plant-parasitic fungi, and lichen mycobionts. DNA traces of tree-associated macrofungi in a modern tundra sample indicated that there was a shift in fungal diversity following the last ice age and supported recent results showing that there was a severe change in the plant composition in northeastern Siberia during this period. Interestingly, DNA sequences with high homology to sequences of coprophilic and keratinophilic fungi indicated that feces, hair, skin, and nails could have been sources of ancient megafauna DNA recently reported to be present in small amounts of Siberian permafrost sediments.

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