Abstract
Abundance-occupancy relationships (AORs) are an important determinant of biotic community dynamics and habitat suitability. However, little is known about their role in complex bacterial communities, either within a phylogenetic framework or as a function of niche breadth. Based on data obtained in a field study in the St. Lawrence Estuary, we used 16S rRNA gene sequencing to examine the vertical patterns, strength, and character of AORs for particle-attached and free-living bacterial assemblages. Free-living communities were phylogenetically more diverse than particle-attached communities. The dominant taxa were consistent in terms of their presence/absence but population abundances differed in surface water vs. the cold intermediate layer. Significant, positive AORs characterized all of the surveyed communities across all taxonomic ranks of bacteria, thus demonstrating an ecologically conserved trend for both free-living and particle-attached bacteria. The strength of the AORs was low at the species level but higher at and above the genus level. These results demonstrate that an assessment of the distributions and population densities of finely resolved taxa does not necessarily improve determinations of apparent niche differences in marine bacterioplankton communities at regional scales compared with the information inferred from a broad taxonomic classification.
Highlights
Aquatic bacterioplankton can either attach to particles or live freely in the water column (Grossart, 2010; Dang and Lovell, 2016)
The principal component analysis (PCA) revealed a clear separation of the surface and cold intermediate layer (CIL) in terms of their water physio-chemistry and prokaryotic cell abundance (Figure 1B)
DOC released from phytoplankton by direct excretion or through trophic interactions sustains the growth of diverse bacterial assemblages in the surface water (Azam et al, 1983)
Summary
Aquatic bacterioplankton can either attach to particles or live freely in the water column (Grossart, 2010; Dang and Lovell, 2016). The resulting free-living (FL) and particle-associated (PA) assemblages strongly differ in their community composition and diversity, as shown in several aquatic habitats (e.g., Jackson et al, 2014; Salazar et al, 2015; Milici et al, 2017). Empirical studies suggest that FL and PA bacteria differ in their size and lifestyle and respond differently to environmental fluctuations (Dang and Lovell, 2016, and references therein; Adyari et al, 2020). Given the distinct roles of FL and PA assemblages in driving different community features, an in-depth understanding of the diversity and dynamics of these ecological groups and of their environmental relationships is a prerequisite for predicting their response to environmental change
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