Abstract
Abstract. Biogeochemical cycling of carbon (C) and nitrogen (N) in the ocean depends on both the composition and activity of underlying biological communities and on abiotic factors. The Southern Ocean is encircled by a series of strong currents and fronts, providing a barrier to microbial dispersion into adjacent oligotrophic gyres. Our study region straddles the boundary between the nutrient-rich Southern Ocean and the adjacent oligotrophic gyre of the southern Indian Ocean, providing an ideal region to study changes in microbial productivity. Here, we measured the impact of C and N uptake on microbial community diversity, contextualized by hydrographic factors and local physico-chemical conditions across the Southern Ocean and southern Indian Ocean. We observed that contrasting physico-chemical characteristics led to unique microbial diversity patterns, with significant correlations between microbial alpha diversity and primary productivity (PP). However, we detected no link between specific PP (PP normalized by chlorophyll-a concentration) and microbial alpha and beta diversity. Prokaryotic alpha and beta diversity were correlated with biological N2 fixation, which is itself a prokaryotic process, and we detected measurable N2 fixation to 60∘ S. While regional water masses have distinct microbial genetic fingerprints in both the eukaryotic and prokaryotic fractions, PP and N2 fixation vary more gradually and regionally. This suggests that microbial phylogenetic diversity is more strongly bounded by physical oceanographic features, while microbial activity responds more to chemical factors. We conclude that concomitant assessments of microbial diversity and activity are central to understanding the dynamics and complex responses of microorganisms to a changing ocean environment.
Highlights
The Southern Ocean (SO), in particular its sub-Antarctic zone, is a major sink for atmospheric CO2 (Constable et al, 2014)
Through our analysis of temperature, salinity, oxygen, and dissolved inorganic nutrient (N, P, Si) concentrations, we identified five distinct water masses, fronts, and frontal zones: the Indian South Subtropical Gyre (ISSG), Subtropical Front (STF), Subantarctic Front (SAF), Polar Front Zone (PFZ), and Antarctic Zone (AZ), which broadly aligned with three oceanographic provinces (ISSG, South Subtropical Convergence province (SSTC), and SO; Fig. 1a)
Within the Southern Ocean (SO), we identified four water masses in our transect including the Antarctic Zone (AZ) and three distinct frontal systems: (1) the Polar Front (PF), (2) the Subantarctic Front (SAF), and (3) the Subtropical Front (STF; Fig. 1)
Summary
The Southern Ocean (SO), in particular its sub-Antarctic zone, is a major sink for atmospheric CO2 (Constable et al, 2014). The SSTC is a zone of deep mixing and elevated nutrient concentrations (Longhurst, 2007). The SSTC has been shown to act as a transition zone both numerically and taxonomically for dominant populations of marine bacterioplankton (Baltar et al, 2016). In this dynamic context, a key driver of microbial productivity is nutrient availability, especially through tightly coupled carbon (C) and nitrogen (N) cycles. The constant availability of nutrients through vertical mixing in frontal zones, such as the STF, enhances primary productivity
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