Microbial activities in the burrow environment of the potamal mayfly Ephoron 
virgo

Stief, P.; Altmann, D.; Beer, D.; Bieg, R.; Kureck, A.

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Microbial activities in the burrow environment of the potamal mayfly Ephoron virgo

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Stief, P.
Permanent Research Group Microsensor, Max Planck Institute for Marine Microbiology, Max Planck Society;

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Altmann, D.
Department of Biogeochemistry, Max Planck Institute for Marine Microbiology, Max Planck Society;

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Beer, D.
Permanent Research Group Microsensor, Max Planck Institute for Marine Microbiology, Max Planck Society;

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Zitation

Stief, P., Altmann, D., Beer, D., Bieg, R., & Kureck, A. (2004). Microbial activities in the burrow environment of the potamal mayfly Ephoron virgo. Freshwater Biology, 49(9), 1152-1163.

Zitierlink: https://hdl.handle.net/21.11116/0000-0001-D100-2

Zusammenfassung

1. The impact of burrowing larvae of Ephoron virgo (Ephemeroptera, Polymitarcidae) on sediment microbiology has not been previously investigated because of difficulties in sampling the sediment of large rivers under in situ conditions. Therefore, we conducted experiments in the on‐ship Ecological Rhine Station of the University of Cologne (Germany), in which ambient conditions of the River Rhine can be closely mimicked.

2. In two consecutive seasons, experimental flow channels were stocked with Ephoron larvae and continuously supplied with water taken directly from the River Rhine. Sediment from the immediate vicinity of Ephoron burrows (i.e. U‐shaped cavities reaching 10–80 mm deep into the sediment) and bulk sediment samples were analysed for (i) particulate organic matter content, (ii) microscale in situ distribution of O2, NOinline image, and NHinline image, and (iii) potential activities of exoenzymes.

3. Sediment surrounding the Ephoron burrows had markedly higher organic matter contents and exoenzyme activities compared with the bulk sediment. Microsensor measurements demonstrated that local O2 and NOinline image penetration into the sediment were greatly enhanced by larval ventilation behaviour. Volumetric O2 and NOinline image turnover rates that were calculated from steady state concentration profiles measured directly in the burrow lining were considerably higher than at the sediment surface.

4. In the sediment of the fast flowing River Rhine Ephoron burrows are preferential sites of organic matter accumulation and dissolved oxidant penetration. Our data suggest that the burrows are surrounded by a highly active microbial community that responds to the inputs from the water column with elevated O2 and NOinline image turnover, and release of exoenzymes into the sediment pore water. Especially during periods of mass occurrence, the larvae of E. virgo may thus significantly contribute (i) to the ecological connection between the water column and the sediment and (ii) to biogeochemical processing of organic matter in the riverbed.