Abstract
Deciphering the ecological traits of abundant marine bacteria is a major challenge in marine microbial ecology. In the current study, we linked compositional and functional predictions to elucidate such traits for abundant bacterioplankton lineages in the North Sea. For this purpose, we investigated entire and active bacterioplankton composition along a transect ranging from the German Bight to the northern North Sea by pyrotag sequencing of bacterial 16S rRNA genes and transcripts. Functional profiles were inferred from 16S rRNA data using Tax4Fun. Bacterioplankton communities were dominated by well-known marine lineages including clusters/genera that are affiliated with the Roseobacter group and the Flavobacteria. Variations in community composition and function were significantly explained by measured environmental and microbial properties. Turnover of dissolved free amino acids (DFAA) showed the strongest correlation to community composition and function. We applied multinomial models, which enabled us to identify bacterial lineages involved in DFAA turnover. For instance, the genus Planktomarina was more abundant at higher DFAA turnover rates, suggesting its vital role in amino acid degradation. Functional predictions further indicated that Planktomarina is involved in leucine and isoleucine degradation. Overall, our results provide novel insights into the biogeochemical significance of abundant bacterioplankton lineages in the North Sea.
Highlights
Bacteria are an integral component of marine ecosystems as key drivers of important nutrient cycles [1,2]
As we found a strong significant correlation between dissolved free amino acids (DFAA) turnover rates and microbial community composition, we calculated multinomial models based on log-linear regression using measured DFAA turnover rates to identify bacterial groups related to the DFAA turnover
We investigated the ecological traits of abundant bacterioplankton lineages in the North Sea by linking compositional and functional predictions to environmental and microbial properties
Summary
Bacteria are an integral component of marine ecosystems as key drivers of important nutrient cycles [1,2]. The application of novel sequencing techniques and meta-omics approaches has greatly advanced our understanding of bacterial communities and their ecological determinants in these ecosystems [3,4,5,6]. Information on biogeochemical and functional traits of prominent marine bacterial lineages is often missing and is mostly based on genomic information that is retrieved from single isolates [10,11], which do not necessarily represent abundant marine lineages. This is exemplified by the unexpected discovery of respiratory nitrate reductases in members of the SAR11 clade [12], which can contribute to an anoxic lifestyle. Deciphering functional traits of prominent marine lineages is a major challenge in marine microbiology
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