Document Type
Article
Publication Date
7-31-2012
Abstract
Background
The Roseobacter clade is a widespread, metabolically versatile, and easily cultured lineage of marine microbes. Furthermore, cultured isolates are generally considered to be representative of the naturally occurring diversity in the environment. Roseobacter is thus considered an ideal clade for exploring and understanding microbial function in a representative model system. Nevertheless, recent studies question whether cultured strains are truly representative of natural populations. Support for one of these studies was based on the potentially biased samples of a Global Ocean Sampling (GOS) expedition [1]. The marine metagenomic studies of the GOS expeditions initially focused on microbes collected from a single filter range (0.1um – 0.8um) and it has been previously suggested that this excludes many Roseobacters, thus biasing the dataset towards smaller cells.
Materials and methods
Here, we take advantage of a GOS metagenomic dataset from a 2006-2008 Antarctic expedition that included community analyses over three different size classes (0.1um-0.8um; 0.8um-3um; and 3um-200um). We examined correlations between bacterial taxonomic diversity (based on 16S rRNA gene analyses) and the three size classes to understand the potential for diversity biases between filter ranges. The 16S rRNA gene sequences from these datasets were extracted using Metaxa and subsequently analyzed using MOTHUR, which provided fine-level resolution taxonomic assignments.
Results
This analysis reveals a potential bias as the ranges of Roseobacter subgroup diversity in this dataset varied between size classes. From this analysis we identified specific Roseobacter subgroups that were predominantly found in specific size classes. For instance, the OCT and Roseovarius subgroups were most prevalent in the 0.8um-3um filter range, while the DC5-80 and NAC11-7 subgroups were well represented in both 0.1um-0.8um and 0.8um-3um filter ranges. These findings reveal the value of analyzing multiple size class fractions when assessing microbial diversity.
Recommended Citation
BMC Bioinformatics 2012, 13(Suppl 12):A5 doi:10.1186/1471-2105-13-S12-A5