Abstract
Diazotrophs are important contributors to nitrogen availability in the ocean. Oceanographic cruise data accumulated over the past three decades has revealed a heterogeneous distribution of diazotroph species at regional to global scales. However, dynamic fine-scale physical structures likely affect the distribution of diazotrophs at smaller spatiotemporal scales. The interaction between fine-scale ocean dynamics and diazotrophs remains poorly understood due to typically insufficient spatiotemporal sampling resolution and the lack of parallel detailed physical studies. Here we show the distribution of five groups of diazotrophs in the South Pacific at an unprecedented resolution of 7–16 km. We find a patchy distribution of diazotrophs, with each group being differentially affected by parameters describing fine-scale physical structures. The observed variability in species abundance and distribution would be masked by a coarser sampling resolution, highlighting the need to consider fine-scale physics to resolve the distribution of diazotrophs in the ocean.
The surface ocean is constantly stirred by currents that swirl and mix different seawater masses creating a dynamic mosaic of biogeochemical properties.1 Numerical modeling and satellite data show that “fine-scale” structures such as filaments and eddies (with typical spatiotemporal scales of 1–100 km and days-weeks) impact the distribution of phytoplankton and carbon export in the ocean.2,3,4 While these remote approaches provide synoptic views at large spatial scales, at-sea sampling remains imperative to resolve the diversity, metabolism and trophic interactions of microbes at finer scales. Yet, the typical spatiotemporal sampling resolution is too coarse to resolve fine-scale processes.5
Understanding the effect of fine-scales on biogeochemically relevant microbes is of particular importance. Dinitrogen (N2) fixers or “diazotrophs” provide a significant source of bioavailable nitrogen to the ocean.6 Diazotrophs may accumulate in anticyclonic eddies,7,8 where eddy pumping deepens isopycnals impoverishing surface waters in inorganic nitrogen presumably favoring diazotroph growth.9 However, diazotrophs also accumulate in cyclonic eddies where low nutrient concentrations are attributed to wind-driven Ekman pumping.10 Such complex interactions between fine-scale physics and diazotrophs cannot be understood from satellite data alone.
Diazotrophs have a variable tolerance to biogeochemical conditions. For example, photosynthetic cyanobacteria such as Trichodesmium and UCYN-B abound in oligotrophic (sub)tropical waters, while UCYN-A’s distribution spans the tropics to polar seas.6 Non-cyanobacterial diazotrophs cannot photosynthesize, and thus are regulated by different drivers to obtain carbon and energy.11 With such divergent physiologies, it is unlikely that different diazotrophs respond to fine-scale forcing similarly. Resolving these ambiguities requires coupling fine-scale physical measurements and diazotroph activity/abundance data at high spatiotemporal resolution. The vast majority of published diazotroph data were obtained at locations ~160 km apart (median distance between stations in the diazotroph database12). Robidart et al.13 quantified diazotrophs with an ecogenomic sensor drifting over a single eddy at a resolution of ~30 km. More recently, Tang et al.14 showed underway diazotroph activity/abundance data with ~18 km resolution, but the effect of fine-scale physics was not taken into account.
Here we demonstrate the fine-scale distribution of diazotrophs in three zones of intense fine-scale activity in the South Pacific (TONGA cruise doi: 10.17600/18000884; Fig. 1). Each zone was selected for high-resolution sampling according to satellite and Lagrangian product maps received onboard on a daily basis.15 Maps included absolute dynamic topography (ADT), used to compute geostrophic velocities; finite-size Lyapunov exponents (FSLE), which depict transport barriers created by currents that can represent ecological boundaries; and the Okubo-Weiss parameter (OW), which distinguishes vorticity-dominated from strain-dominated zones (e.g., eddies vs. non-eddies) (Supplementary Information; Table S1; Fig. S1). These parameters are thus useful to quantify fine-scale structures and to study their covariability with plankton distribution [e.g., 4]. Planktonic biomass was collected with an automated filtration system at an unprecedented resolution of 7–16 km. DNA extracted from the filters was used to quantify five diazotroph groups (Trichodesmium, UCYN-A1, UCYN-B, UCYN-C, and Gamma A) by quantitative PCR targeting the nifH gene, and, only in zone 3 nutrient concentrations and N2 fixation rates were also measured (Supplementary Information).
Our results reveal a patchy distribution of diazotrophs, driven by a heterogeneous effect of fine-scale physical parameters on each group (Fig. 1; Fig. S2; Table S2). Trichodesmium correlated positively with ADT (Fig. 1; Fig. S2; Table S2) and accumulated at positive-negative OW transition and high FSLE regions located at ~170 °E, 176 °E, and 171 °W in zones 1, 2 and 3, respectively; Fig. 2). A particularly striking accumulation of Trichodesmium was observed at the convergence of two counter-rotating eddies in zone 2 (maximum 3 × 107 gene copies l−1; Fig. 1), coinciding with high FSLE values (Fig. 2) and a steep change in temperature (Fig. S3). The concentration of Trichodesmium at fronts depicted by high FSLE is likely linked to intracellular gas-vesicles providing them positive buoyancy.16 Previous concentrations of Trichodesmium along FSLE ridges uncoupled from significant N2 fixation rates have been interpreted as “passive” accumulations, i.e. fine-scale dynamics affecting their distribution but not their activity.17
UCYN-A1 were negatively related to FSLE (Table S2) and to Trichodesmium (Figs. S2 and S4), in agreement with the antagonistic biogeographic trends of these two diazotrophs witnessed at larger spatial scales.12 In comparison to other groups, the distribution of UCYN-A1 and UCYN-B was more spatially homogeneous and independent of fine-scales (Fig. S2). They were instead positively correlated to phosphate concentrations (Fig. S5), suggesting an “active” response to nutrient inputs induced by fine-scale dynamics9). These unicellular groups have a large surface area:volume ratio allowing for efficient nutrient utilization and higher growth rates than Trichodesmium,6 which could explain their faster response to limiting nutrient inputs induced by fine-scale dynamics. UCYN-C were significantly related to both ADT and FSLE (Table S2), but were the least abundant group (Fig. 1), likely due to their presumed coastal origin.6 Finally, Gamma A were significantly related to ADT (Table S2) and accumulated in frontal zones with high FSLE (Fig. 1), which agrees with their apparent particle-attached lifestyle.18
Although relatively high concentrations of phosphate were measured east of ~175°W (Fig. S6), they sustained only moderate N2 fixation rates (1–5 nmol N l−1 d−1; Fig. S6) likely due to a scarcity of iron east of the Tonga volcanic arc.19 N2 fixation rates correlated positively with Trichodesmium and negatively with UCYN-B (Fig. S5). Temperature and nutrients are typically invoked to define diazotroph biogeography on regional/global scales.12 These factors were remarkably homogeneously distributed in zone 3 (Figs. S6–7), and did not vary significantly according to fine-scale parameters (Fig. S7). Yet, diazotroph abundance revealed high spatial variability at the fine-scale in zone 3 (Fig. 1). Such variability would have gone unseen at a coarser resolution, stressing the role of fine-scale dynamics in diazotroph distribution.
The patchiness observed likely responds to a combination of bottom-up and top-down interactions between diazotrophs’ competitors, predators and their biogeochemical environment. Understanding the controls imposed by fine-scales on other biotic and abiotic drivers will enhance our understanding of current and future diazotroph distribution and role in supplying new nitrogen to the ocean.
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Acknowledgements
This study was funded by the projects TONGA (ANR-18-CE01-0016, LEFE-CyBER, Fondation A-Midex and Flotte Océanographique Française) to S.B. and C. Guieu, DEFINE (LEFE-CyBER) to M.B., and OASIS (Thomas Jefferson Fund) to S. T. Wilson and M.B. The development of SPASSO is supported by TOSCA/CNES, the EU program Copernicus Academy and the SIP OSU PYTHEAS. L.C. was funded by a Master degree internship from TONGA A-Midex. The authors would like to thank the crew and technical staff of R/V L’Atalante as well as the scientists that participated in sample acquisition and equipment installation onboard (C. Lory, K. Sellegri, and F. Gazeau), and sample analyses in the lab (S. Nunige, O. Grosso, A. Torremocha). The MODIS chlorophyll image used in Fig. 1 is a courtesy of J. Uitz. The authors greatly acknowledge the OMICS platform at the Mediterranean Institute of Oceanography (Marseille, France) for access to their facilities.
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Benavides, M., Conradt, L., Bonnet, S. et al. Fine-scale sampling unveils diazotroph patchiness in the South Pacific Ocean. ISME COMMUN. 1, 3 (2021). https://doi.org/10.1038/s43705-021-00006-2
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DOI: https://doi.org/10.1038/s43705-021-00006-2
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