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Sediment microbial taxonomic and functional diversity in a natural salinity gradient challenge Remane’s “species minimum” concept
Pavloudi, C; Kristoffersen, J.B.; Oulas, A.; De Troch, M.; Arvanitidis, C. (2017). Sediment microbial taxonomic and functional diversity in a natural salinity gradient challenge Remane’s “species minimum” concept. PeerJ 5: e3687. https://dx.doi.org/10.7717/peerj.3687
In: PeerJ. PeerJ: Corte Madera & London. e-ISSN 2167-8359
Peer reviewed article  

Available in  Authors 
    Vlaams Instituut voor de Zee: Open access 307806 [ download pdf ]

Keywords
    Biodiversity
    Biology > Microbiology
    Marine biology
Author keywords
    Amvrakikos Gulf, Salinity gradient; Illumina sequencing; Prokaryotes; Sediment; 16S rRNA

Authors  Top 
  • Pavloudi, C
  • Kristoffersen, J.B.
  • Oulas, A.
  • De Troch, M.
  • Arvanitidis, C.

Abstract
    Several models have been developed for the description of diversity in estuaries and other brackish habitats, with the most recognized being Remane's Artenminimum (``species minimum'') concept. It was developed for the Baltic Sea, one of the world's largest semi-enclosed brackish water body with a unique permanent salinity gradient, and it argues that taxonomic diversity of macrobenthic organisms is lowest within the horohalinicum (5 to 8 psu). The aim of the present study was to investigate the relationship between salinity and sediment microbial diversity at a freshwater-marine transect in Amvrakikos Gulf (Ionian Sea, Western Greece) and assess whether species composition and community function follow a generalized concept such as Remane's. DNA was extracted from sediment samples from six stations along the aforementioned transect and sequenced for the 16S rRNA gene using high-throughput sequencing. The metabolic functions of the OTUs were predicted and the most abundant metabolic pathways were extracted. Key abiotic variables, i.e., salinity, temperature, chlorophyll-a and oxygen concentration etc., were measured and their relation with diversity and functional patterns was explored. Microbial communities were found to differ in the three habitats examined (river, lagoon and sea) with certain taxonomic groups being more abundant in the freshwater and less in the marine environment, and vice versa. Salinity was the environmental factor with the highest correlation to the microbial community pattern, while oxygen concentration was highly correlated to the metabolic functional pattern. The total number of OTUs showed a negative relationship with increasing salinity, thus the sediment microbial OTUs in this study area do not follow Remane's concept.

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