Drivers of plankton community structure in intermittent and continuous coastal upwelling systems–from microbes and microscale in-situ imaging to large scale patterns

Schmid, Moritz S.; Sponaugle, Su; Thompson, Anne W.; Sutherland, Kelly R.; Cowen, Robert K.

doi:10.3389/fmars.2023.1166629

Cited by 5 publications

(1 citation statement)

References 144 publications

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“…Disentangling the interacting roles of physics and biology in driving plankton patchiness has been a central question in ecology for many decades (Levin and Segel, 1976;Gower et al, 1980;Abraham, 1998;Martin, 2003;McGillicuddy and Franks, 2019). The processes driving plankton diversity and community structure have similarly been examined, with many studies showing the influence of bottom-up and top-down trophic interactions (Allen et al, 2005;Mangolte et al, 2022;Dugenne et al, 2020), transport (Wilkins et al, 2013), or a combination of all of these processes (Clayton et al, 2013;Lévy et al, 2014;Schmid et al, 2023). Lagrangian studies have also explored how water parcels are connected between remote regions (i.e., their "connectivity") across differing spatial scales-from a single basin to the global ocean-and how this connectivity influences various biological processes, such as genetic similarity or larval dispersal (Rossi et al, 2014;Wilkins et al, 2013;Jönsson and Watson, 2016).…”

Section: Introductionmentioning

confidence: 99%

Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

Gangrade,

Mangolte

2024

Preprint

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The transport of plankton by highly dynamic (sub)mesoscale currents–-often associated with fronts and eddies–-shapes the structure of plankton communities on the same time scales as biotic processes, such as growth and predation. The resulting bio-physical couplings generate heterogeneities in their finescale distributions (1-10 km), or "patchiness." Here, we test the hypothesis that cross-frontal plankton patchiness at a front found 200-250 km offshore in the California Current System was influenced by wind-driven upwelling conditions upstream of the front. We show that in situ Eulerian measurements (cross-frontal transects) can be interpreted in a Lagrangian framework by using satellite-derived current velocities to trace water parcels backward in time to their coastal origins. We find that the majority of the water parcels sampled at this front originated along the central California coast during different episodic wind-driven upwelling pulses and followed various trajectories before converging temporarily at the front. In response to nutrient injections at the coast, plankton communities transformed during their journeys from the coast to the sampling zone, with a succession of phytoplankton and zooplankton blooms. The cross-frontal sampling captured the convergence of these distinct water parcels at different points in their biological histories, which resulted in the observed spatial patchiness. Our results suggest that identifying the processes controlling frontal plankton communities requires understanding them in the context of their spatial and temporal histories, rather than as two-dimensional responses to local frontal processes. In particular, Lagrangian approaches should be more widely applied to understand critical ecological patterns in highly dynamic systems.

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Section: Introductionmentioning

confidence: 99%

Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

Gangrade,

Mangolte

2024

Preprint

View full text Add to dashboard Cite

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Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

Gangrade,

Mangolte

2024

Limnology & Oceanography

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The transport of plankton by highly dynamic (sub)mesoscale currents—often associated with fronts and eddies—shapes the structure of plankton communities on the same time scales as biotic processes, such as growth and predation (days–weeks). The resulting biophysical couplings generate heterogeneities in their finescale distributions (1–10 km), or “patchiness.” Here, we test the hypothesis that cross‐frontal plankton patchiness at a front found 200–250 km offshore in the California Current System was influenced by wind‐driven upwelling conditions upstream of the front. We show that in situ Eulerian measurements (cross‐frontal transects) can be interpreted in a Lagrangian framework by using satellite‐derived current velocities to trace water parcels backward in time to their coastal origins. We find that the majority of the water parcels sampled at this front originated along the central California coast during different episodic wind‐driven upwelling pulses and followed various trajectories before converging temporarily at the front. In response to nutrient injections at the coast, plankton communities transformed during their journeys from the coast to the sampling zone, with a succession of phytoplankton and zooplankton blooms. The cross‐frontal sampling captured the convergence of these distinct water parcels at different points in their biological histories, which resulted in the observed spatial patchiness. Our results suggest that identifying the processes controlling frontal plankton communities requires understanding them in the context of their spatial and temporal histories. In particular, Lagrangian approaches should be more widely applied to understand critical ecological patterns in highly dynamic systems.

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The microorganisms associated with doliolids in a productive coastal upwelling system

Steinman,

Schmid,

Cowen

et al. 2024

Limnology & Oceanography

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Doliolids have a unique ability to impact the marine microbial community through bloom events and filter feeding. Their predation on large eukaryotic microorganisms is established and evidence of predation on smaller prokaryotic microorganisms is beginning to emerge. We studied the association between microorganisms and wild‐caught doliolids in the Northern California Current system. Doliolids were collected during bloom events identified at three different shelf locations with variable upwelling intensity. We discovered doliolids were associated with a range of prokaryotic microbial functional groups, which included free‐living pelagic Archaea, SAR11, and picocyanobacteria. The results suggest the possibility that doliolids could feed on the smallest members of the microbial community, expanding our understanding of doliolid feeding and microbial mortality. Given the ability of doliolids to clear large portions of seawater by filtration and their high abundance in this system, we suggest that doliolids could be an important player in shaping the microbial community structure of the Northern California Current system.

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Drivers of plankton community structure in intermittent and continuous coastal upwelling systems–from microbes and microscale in-situ imaging to large scale patterns

Cited by 5 publications

References 144 publications

Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

Patchiness of plankton communities at fronts explained by Lagrangian history of upwelled water parcels

The microorganisms associated with doliolids in a productive coastal upwelling system

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