Winter‐mixing preconditioning of the spring phytoplankton bloom in the Bay of Biscay

González-Gil, Ricardo; Taboada, Fernando González; Cáceres, Carlos; Largier, John L.; Anadón, Ricardo

doi:10.1002/lno.10769

Cited by 13 publications

(8 citation statements)

References 91 publications

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“…Nevertheless, the location of deep overwintering habitats from which copepods emerge in early spring and to which they return in late summer could determine surface distributions regardless of spring-time hydrographic structures. Winter pre-conditioning is known to affect the spatial distributions of many pelagic species from phytoplankton to seabirds in spring (Schroeder et al, 2009;Black et al, 2010;Batchelder et al, 2013;Gonzalez-Gil et al, 2017). Overwintering habitats of Calanus spp.…”

Section: Introductionmentioning

confidence: 99%

Large scale patches of Calanus finmarchicus and associated hydrographic conditions off the Lofoten archipelago

Weidberg

Hernández

Renner

et al. 2022

Journal of Marine Systems

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Section: Introductionmentioning

confidence: 99%

Large scale patches of Calanus finmarchicus and associated hydrographic conditions off the Lofoten archipelago

Weidberg

Hernández

Renner

et al. 2022

Journal of Marine Systems

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“…S1). Conditions during BIOCANT 1 (March 2012) were typical for the onset of the spring phytoplankton bloom, with high concentrations of Chl a that reflected the high, newly produced phytoplankton biomass (González‐Gil et al ). During that period, the food web in SW was highly size structured, as shown by the high b (2.37‰ g −1 ; Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Seasonal fluctuations in primary production, especially accentuated in temperate seas with a marked annual cycle, are determinant for the dynamics of the deep ocean (Gooday ). In these temperate regions, the transition from mixed to stratified conditions in spring and back to mixing in autumn releases phytoplankton cells from light/nutrient limitation, leading to two major production pulses known as the spring and autumn blooms, respectively (e.g., Fernández and Bode ; González‐Gil et al ). Stratification favors the prevalence of a microbial food loop (Cushing ; Legendre and Rassoulzadegan ), where heterotrophic bacteria recycle the OM while feeding a complex community of heterotrophic or mixotrophic microbes, protozoans, and copepods (Azam et al ).…”

mentioning

confidence: 99%

Seasonal and vertical dynamics in the trophic structure of a temperate zooplankton assemblage

Romero-Romero

González-Gil

Cáceres

et al. 2019

Limnology & Oceanography

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We determined the stable nitrogen isotope composition (δ15N values) and body size of taxonomic groups in a zooplankton community in the Cantabrian Sea (southern Bay of Biscay) to explore seasonal and depth (0–2000 m) variations in the size‐based trophic structure and their coupling to the production cycle. The positive linear relationship between δ15N values and log‐transformed body size reflects the dominance of new vs. regenerated production. The slope of the relationship (b) is high during productive periods and low when herbivory declines and the food web is more dependent on recycled production. This variation can be attributed to high δ15N values of the smallest plankton after repetitive cycles of microbial degradation. Downward transport of organic matter after the spring phytoplankton bloom was captured by a steady variation from low values of b at the surface to high values at the bathypelagic zone, where the imprint of the spring production pulse could be detected. Variation in b reveals that the mesopelagic and bathypelagic zooplankton communities are as dynamic as their epipelagic counterparts. This shows the efficiency of δ15N vs. body size relationships to capture fast, transient ecosystem processes without need for lengthy incubations or complex rate measurements.

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“…Perhaps winter survival of sufficient phytoplankton cells to 'seed' the spring bloom is enhanced by limited photosynthesis when cells in the upper mixed layer are briefly close to the sea surface in their vertical circulation. Whereas the chlorophyll a per volume of seawater in the upper mixed layer can be an order of magnitude lower at the lowest value in winter than at the peak of the spring bloom [55], it is the chlorophyll a per cell and the functionality of photochemistry and downstream metabolism that is important in providing the 'seed' for the spring bloom.…”

Section: Prolonged Dark Survivalmentioning

confidence: 98%

“…Arctic marine phytoplankton must be able to survive months without sunlight [54]. Phytoplankton in high latitude temperate open oceans have very limited productivity in winter with lower temperatures, shorter photoperiods and deeper mixing (see, e.g., [55]). Perhaps winter survival of sufficient phytoplankton cells to 'seed' the spring bloom is enhanced by limited photosynthesis when cells in the upper mixed layer are briefly close to the sea surface in their vertical circulation.…”

Section: Prolonged Dark Survivalmentioning

confidence: 99%

Evolution of Phytoplankton in Relation to Their Physiological Traits

Raven

Beardall

2022

JMSE

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Defining the physiological traits that characterise phytoplankton involves comparison with related organisms in benthic habitats. Comparison of survival time in darkness under natural conditions requires more information. Gas vesicles and flagella as mechanisms of upward movement relative to surrounding water, allowing periodic vertical migration, are not confined to plankton, although buoyancy changes related to compositional changes of a large central vacuole may be restricted to plankton. Benthic microalgae have the same range of photosynthetic pigments as phytoplankton; it is not clear if there are differences in the rate of regulation and acclimation of photosynthetic machinery to variations in irradiance for phytoplankton and for microphytobenthos. There are inadequate data to determine if responses to variations in frequency or magnitude of changes in the supply of inorganic carbon, nitrogen or phosphorus differ between phytoplankton and benthic microalgae. Phagophotomixotrophy and osmophotomixotrophy occur in both phytoplankton and benthic microalgae. Further progress in identifying physiological traits specific to phytoplankton requires more experimentation on benthic microalgae that are closely related to planktonic microalgae, with attention to whether the benthic algae examined have, as far as can be determined, never been planktonic during their evolution or are derived from planktonic ancestors.

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Winter‐mixing preconditioning of the spring phytoplankton bloom in the Bay of Biscay

Cited by 13 publications

References 91 publications

Large scale patches of Calanus finmarchicus and associated hydrographic conditions off the Lofoten archipelago

Large scale patches of Calanus finmarchicus and associated hydrographic conditions off the Lofoten archipelago

Seasonal and vertical dynamics in the trophic structure of a temperate zooplankton assemblage

Evolution of Phytoplankton in Relation to Their Physiological Traits

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