Biogeosciences (Nov 2014)

Diversity and seasonal dynamics of airborne archaea

  • J. Fröhlich-Nowoisky,
  • C. Ruzene Nespoli,
  • D. A. Pickersgill,
  • P. E. Galand,
  • I. Müller-Germann,
  • T. Nunes,
  • J. Gomes Cardoso,
  • S. M. Almeida,
  • C. Pio,
  • M. O. Andreae,
  • R. Conrad,
  • U. Pöschl,
  • V. R. Després

DOI
https://doi.org/10.5194/bg-11-6067-2014
Journal volume & issue
Vol. 11, no. 21
pp. 6067 – 6079

Abstract

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Archaea are widespread and abundant in many terrestrial and aquatic environments, and are thus outside extreme environments, accounting for up to ~10% of the prokaryotes. Compared to bacteria and other microorganisms, however, very little is known about the abundance, diversity, and dispersal of archaea in the atmosphere. By means of DNA analysis and Sanger sequencing targeting the 16S rRNA (435 sequences) and amoA genes in samples of air particulate matter collected over 1 year at a continental sampling site in Germany, we obtained first insights into the seasonal dynamics of airborne archaea. The detected archaea were identified as Thaumarchaeota or Euryarchaeota, with soil Thaumarchaeota (group I.1b) being present in all samples. The normalized species richness of Thaumarchaeota correlated positively with relative humidity and negatively with temperature. This together with an increase in bare agricultural soil surfaces may explain the diversity peaks observed in fall and winter. The detected Euryarchaeota were mainly predicted methanogens with a low relative frequency of occurrence. A slight increase in their frequency during spring may be linked to fertilization processes in the surrounding agricultural fields. Comparison with samples from the Cape Verde islands (72 sequences) and from other coastal and continental sites indicates that the proportions of Euryarchaeota are enhanced in coastal air, which is consistent with their suggested abundance in marine surface waters. We conclude that air transport may play an important role in the dispersal of archaea, including assumed ammonia-oxidizing Thaumarchaeota and methanogens.