Please use this identifier to cite or link to this item: http://hdl.handle.net/10553/51637
Title: Emerging concepts on microbial processes in the bathypelagic ocean - Ecology, biogeochemistry, and genomics
Authors: Nagata, Toshi
Tamburini, Christian
Arístegui, Javier 
Baltar, Federico
Bochdansky, Alexander B.
Fonda-Umani, Serena
Fukuda, Hideki
Gogou, Alexandra
Hansell, Dennis A.
Hansman, Roberta L.
Herndl, Gerhard J.
Panagiotopoulos, Christos
Reinthaler, Thomas
Sohrin, Rumi
Verdugo, Pedro
Yamada, Namiha
Yamashita, Youhei
Yokokawa, Taichi
Bartlett, Douglas H.
UNESCO Clasification: 251001 Oceanografía biológica
Keywords: Bathypelagic zone
Microbial loop
Organic matter
Piezophile
Biogeochemistry, et al
Issue Date: 2010
Publisher: 0967-0645
Project: Intercambio Plataforma-Oceano en El Ecosistema Marino de Las Islas Canarias-Peninsula Iberica (Caibex):Afloramiento de Cabo Guir 
Journal: Deep-Sea Research Part II: Topical Studies in Oceanography 
Abstract: This paper synthesizes recent findings regarding microbial distributions and processes in the bathypelagic ocean (depth >1000 m). Abundance, production and respiration of prokaryotes reflect supplies of particulate and dissolved organic matter to the bathypelagic zone. Better resolution of carbon fluxes mediated by deep microbes requires further testing on the validity of conversion factors. Archaea, especially marine Crenarchaeota Group I, are abundant in deep waters where they can fix dissolved inorganic carbon. Viruses appear to be important in the microbial loop in deep waters, displaying remarkably high virus to prokaryote abundance ratios in some oceanic regions. Sequencing of 18S rRNA genes revealed a tremendous diversity of small-sized protists in bathypelagic waters. Abundances of heterotrophic nanoflagellates (HNF) and ciliates decrease with depth more steeply than prokaryotes; nonetheless, data indicated that HNF consumed half of prokaryote production in the bathypelagic zone. Aggregates are important habitats for deep-water microbes, which produce more extracellular enzymes (on a per-cell basis) than surface communities. The theory of marine gel formation provides a framework to unravel complex interactions between microbes and organic polymers. Recent data on the effects of hydrostatic pressure on microbial activities indicate that bathypelagic microbial activity is generally higher under in situ pressure conditions than at atmospheric pressures. High-throughput sequencing of 16S rRNA genes revealed a remarkable diversity of Bacteria in the bathypelagic ocean. Metagenomics and comparative genomics of piezophiles reveal not only the high diversity of deep sea microbes but also specific functional attributes of these piezophilic microbes, interpreted as an adaptation to the deep water environment. Taken together, the data compiled on bathypelagic microbes indicate that, despite high-pressure and low-temperature conditions, microbes in the bathypelagic ocean dynamically interact with complex mixtures of organic matter, responding to changes in the ocean’s biogeochemical state.
URI: http://hdl.handle.net/10553/51637
ISSN: 0967-0645
DOI: 10.1016/j.dsr2.2010.02.019
Source: Deep-Sea Research Part II: Topical Studies in Oceanography [ISSN 0967-0645], v.. 57, p. 1519-1536
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