Recolonisation of new habitats by meiobenthic organisms in the deep Arctic Ocean: an experimental approach

Commercial exploitation and abrupt changes of the natural conditions may have severe impacts on the Arctic deep-sea ecosystem. The present recolonisation experiment mimicked a situation after a catastrophic disturbance (e.g. by turbidites caused by destabilised continental slopes after methane hydra...

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Veröffentlicht in:	Polar biology 2012-12, Vol.35 (12), p.1801-1813
Hauptverfasser:	Freese, Daniela, Schewe, Ingo, Kanzog, Corinna, Soltwedel, Thomas, Klages, Michael
Format:	Artikel
Sprache:	eng
Schlagworte:	Algae Animal and plant ecology Animal populations Animal, plant and microbial ecology Biological and medical sciences Biomedical and Life Sciences Continental slope Deep sea Deep water habitats Ecology Environmental conditions Food availability Food chains Fundamental and applied biological sciences. Psychology Life Sciences Marine biology Methane Methane hydrate Microbiology Ocean Oceanography Original Paper Plant Sciences Sea water ecosystems Sediments Sediments (Geology) Synecology Water depth Yeasts Zoology
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container_title	Polar biology
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creator	Freese, Daniela Schewe, Ingo Kanzog, Corinna Soltwedel, Thomas Klages, Michael
description	Commercial exploitation and abrupt changes of the natural conditions may have severe impacts on the Arctic deep-sea ecosystem. The present recolonisation experiment mimicked a situation after a catastrophic disturbance (e.g. by turbidites caused by destabilised continental slopes after methane hydrate decomposition) and investigated whether the recolonisation of a deep-sea habitat by meiobenthic organisms is fostered by variations in nutrition and/or sediment structure. Two “Sediment Tray Free Vehicles” were deployed for 1 year in summer 2003 at 2,500 m water depth in the Arctic deep-sea in the eastern Fram Strait. The recolonisation trays were filled with different artificial and natural sediment types (glass beads, sand, sediment mixture, pure deep-sea sediment) and were enriched with various types of food (algae, yeast, fish). After 1 year, meiobenthos abundances and various sediment-related environmental parameters were investigated. Foraminifera were generally the most successful group: they dominated all treatments and accounted for about 87 % of the total meiobenthos. Colonising meiobenthos specimens were generally smaller compared to those in the surrounding deep-sea sediment, suggesting an active recolonisation by juveniles. Although experimental treatments with fine-grained, algae-enriched sediment showed abundances closest to natural conditions, the results suggest that food availability was the main determining factor for a successful recolonisation by meiobenthos, and the structure of recolonised sediments was shown to have a subordinate influence.
doi_str_mv	10.1007/s00300-012-1223-2
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The present recolonisation experiment mimicked a situation after a catastrophic disturbance (e.g. by turbidites caused by destabilised continental slopes after methane hydrate decomposition) and investigated whether the recolonisation of a deep-sea habitat by meiobenthic organisms is fostered by variations in nutrition and/or sediment structure. Two “Sediment Tray Free Vehicles” were deployed for 1 year in summer 2003 at 2,500 m water depth in the Arctic deep-sea in the eastern Fram Strait. The recolonisation trays were filled with different artificial and natural sediment types (glass beads, sand, sediment mixture, pure deep-sea sediment) and were enriched with various types of food (algae, yeast, fish). After 1 year, meiobenthos abundances and various sediment-related environmental parameters were investigated. Foraminifera were generally the most successful group: they dominated all treatments and accounted for about 87 % of the total meiobenthos. 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subjects	Algae Animal and plant ecology Animal populations Animal, plant and microbial ecology Biological and medical sciences Biomedical and Life Sciences Continental slope Deep sea Deep water habitats Ecology Environmental conditions Food availability Food chains Fundamental and applied biological sciences. Psychology Life Sciences Marine biology Methane Methane hydrate Microbiology Ocean Oceanography Original Paper Plant Sciences Sea water ecosystems Sediments Sediments (Geology) Synecology Water depth Yeasts Zoology
title	Recolonisation of new habitats by meiobenthic organisms in the deep Arctic Ocean: an experimental approach
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