The exception was an intense algal bloom (.25 mg Chl a L 21) during La Niña-intensified upwelling conditions in April 2008, during which biomass and production estimates of picophytoplankton were at their lowest levels, suggesting that the smallest primary producers were being replaced by larger cells. Thus, for most of the environmental circumstances encountered during our study, our results supported the recent "rising tide" hypothesis that improved growth (nutrient) conditions benefit all size classes, including picophytoplankton. Under extreme conditions of upwelling, however, the picophytoplankton declined abruptly, despite seemingly strong (average) growth rates. Future studies need to provide a better mechanistic understanding of the physical (advection), physiological (nutrient uptake and temperature) and ecological (food web) factors that result in this dramatic nonlinearity in picophytoplankton response to system forcing and richness.
Assessments of picoplankton carbon biomass in the pelagic ecosystem over the deep region of the southern Gulf of Mexico were conducted during three consecutive summer cruises. Notably, the relationship between carbon distribution of Prochlorococcus (PRO) and Loop Current (LC) dynamics was evaluated. Seawater samples were collected from the euphotic zone (~150 m) for estimating the abundance of the picoplankton populations using flow cytometry analyses. Carbon biomass estimates were based on cell abundance and variable conversion factors computed across stations and depths. On average, about half of the total depth-integrated carbon biomass of picoplankton was attributed to heterotrophic bacteria (HB, 54%) and three autotrophic populations (Prochlorococcus, Synechococcus, and pico-eukaryotes, 46%). In agreement with previous winter assessments, PRO was the dominant component of abundance (~90%) and pico-phytoplankton community biomass (>70%). Based on molecular analyses, distinct ecotypes of high-light PRO and low-light (LL) PRO were found within the euphotic zone, vertically distributed along light and nutrient gradients. Also, PRO distributions were related to hydrographic conditions strongly modulated by mesoscale dynamics. LL-PRO subgroups, located close to the nutricline under LL conditions, were associated with the westward propagation of anticyclonic eddies that episodically detach from the LC. This study highlights the role of the LC and its eddies in the transport and distribution of carbon biomass into the Gulf of Mexico, as represented by the deep subgroups of the dominant, tiniest autotroph within this oligotrophic ecosystem.
Abstract. Surface chlorophyll concentrations inferred from satellite images suggest a
strong influence of the mesoscale activity on biogeochemical variability
within the oligotrophic regions of the Gulf of Mexico (GoM). More
specifically, long-living anticyclonic Loop Current eddies (LCEs) are shed
episodically from the Loop Current and propagate westward. This study
addresses the biogeochemical response of the LCEs to seasonal forcing and
show their role in driving phytoplankton biomass distribution in the GoM.
Using an eddy resolving (1/12∘) interannual regional simulation,
it is shown that the LCEs foster a large biomass increase in winter in the
upper ocean. It is based on the coupled physical–biogeochemical model
NEMO-PISCES (Nucleus for European Modeling of the Ocean and Pelagic Interaction Scheme for Carbon and
Ecosystem Studies) that yields a realistic representation of the surface
chlorophyll distribution. The primary production in the LCEs is larger than
the average rate in the surrounding open waters of the GoM. This behavior
cannot be directly identified from surface chlorophyll distribution alone
since LCEs are associated with a negative surface chlorophyll anomaly all
year long. This anomalous biomass increase in the LCEs is explained by the
mixed-layer response to winter convective mixing that reaches deeper and
nutrient-richer waters.
Microzooplankton grazing impact on the phytoplankton community at a coastal upwelling station off northern Baja California, MexicoImpacto del pastoreo del microzooplancton sobre la comunidad fitoplanctónica en una estación de surgencia costera localizada en la región norte de Baja California, México ABSTRACT. Experiments were carried out at a coastal upwelling site (ENSENADA station) off northern Baja California (México) during autumn 2015 (OCT-15) and spring 2016 (APR-16) to estimate phytoplankton daily growth (µ o ) and mortality (m) rates and to assess microzooplankton grazing impact (m:µ o ) on the phytoplankton community and specific autotrophic groups. In accordance with regional seasonality and under an environmental warming scenario due to the El Niño 2015-2016 event, significant differences in both hydrographic conditions and the growth-mortality dynamics of the phytoplankton community were observed between the 2 study periods. The µ o and m estimates were, respectively, 0.120 ± 0.012 d -1 and 1.145 ± 0.049 d -1 for OCT-15 and 1.186 ± 0.002 d -1 and 0.409 ± 0.086 d -1 for APR-16. The results of this study suggest that the effects of the anomalous warming on the phytoplankton community were more evident in OCT-15. During that period, growth of the larger autotrophic components (diatoms) was severely controlled by the environmental limitation of nutrients caused by the sinking of the thermocline that resulted from the entrance of warm water to the region. Furthermore, microzooplankton exerted active grazing pressure on phytoplankton biomass (72% of chlorophyll a [Chla]) and primary production (PP = 0.20 µg Chla·L -1 ·d -1 ), with grazing impact >100% of PP. In APR-16, when the ecosystem apparently started returning to the spring conditions, a high value for PP (3.73 µg Chla·L -1 ·d -1 ) was estimated, with only one third of it being consumed by microzooplankton (34% of PP). The results of this research evidence the high dynamism of multivorous food webs coupled to the seasonal and interannual variability of coastal upwelling systems.RESUMEN. En un sitio de surgencia costera (estación ENSENADA) frente a la región norte de Baja California (México) se realizaron experimentos durante el otoño de 2015 (OCT-15) y la primavera de 2016 (ABR-16) para estimar las tasas diarias de crecimiento (µ o ) y mortalidad (m) del fitoplancton, que permitieron evaluar el impacto (m:µ o ) que genera el pastoreo diario del microzooplancton sobre la comunidad de fitoplancton y grupos autótrofos específicos. Acorde con la estacionalidad de la región y bajo el escenario de un calentamiento ambiental debido al evento El Niño 2015-2016, se observaron notables diferencias en las condiciones hidrográficas y en la dinámica de crecimiento y mortalidad de la comunidad de fitoplancton entre los 2 periodos de estudio. Las estimaciones de µ o y m fueron, respectivamente, 0.120 ± 0.012 d -1 y 1.145 ± 0.049 d -1 para OCT-15 y 1.186 ± 0.002 d -1 y 0.409 ± 0.086 d -1 para ABR-16. Los resultados de este estudio sugieren que los efectos del calenta...
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