New insights on the dominance of cryptophytes in Antarctic coastal waters: A case study in Gerlache Strait

Mendes, Carlos; Tavano, Virgínia Maria; Dotto, Tiago S.; Kerr, Rodrigo; Souza, Márcio Silva de; Garcia, Carlos Alberto Eiras; Secchi, Eduardo R.

doi:10.1016/j.dsr2.2017.02.010

Cited by 70 publications

(85 citation statements)

References 54 publications

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“…Diatoms are known to form plentiful blooms early in the season (Goldman et al, 2015;Schofield et al, 2017) and in offshore regions (Whitehouse, Priddle, & Woodward, 1995). We observed considerable drawdown of nitrate + nitrite relative to silicate in the highest January chlorophyll concentrations associated with SU 5 however, suggesting that these nearshore blooms ( Figure S3) likely reflect mixed or flagellate-dominated blooms, consistent with previous studies (Borges Mendes et al, 2017;Goldman et al, 2015;Schofield et al, 2017). It is important to recognize that these January accumulations of biomass do not necessarily represent the peak in the annual cycle of primary production (Goldman et al, 2015).…”

Section: Discussionsupporting

confidence: 90%

Recurrent seascape units identify key ecological processes along the western Antarctic Peninsula

Bowman

Kavanaugh

Doney

et al. 2018

Global Change Biology

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The western Antarctic Peninsula (WAP) is a bellwether of global climate change and natural laboratory for identifying interactions between climate and ecosystems. The Palmer Long-Term Ecological Research (LTER) project has collected data on key ecological and environmental processes along the WAP since 1993. To better understand how key ecological parameters are changing across space and time, we developed a novel seascape classification approach based on in situ temperature, salinity, chlorophyll a, nitrate + nitrite, phosphate, and silicate. We anticipate that this approach will be broadly applicable to other geographical areas. Through the application of self-organizing maps (SOMs), we identified eight recurrent seascape units (SUs) in these data. These SUs have strong fidelity to known regional water masses but with an additional layer of biogeochemical detail, allowing us to identify multiple distinct nutrient profiles in several water masses. To identify the temporal and spatial distribution of these SUs, we mapped them across the Palmer LTER sampling grid via objective mapping of the original parameters. Analysis of the abundance and distribution of SUs since 1993 suggests two year types characterized by the partitioning of chlorophyll a into SUs with different spatial characteristics. By developing generalized linear models for correlated, time-lagged external drivers, we conclude that early spring sea ice conditions exert a strong influence on the distribution of chlorophyll a and nutrients along the WAP, but not necessarily the total chlorophyll a inventory. Because the distribution and density of phytoplankton biomass can have an impact on biomass transfer to the upper trophic levels, these results highlight anticipated links between the WAP marine ecosystem and climate.

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Section: Discussionsupporting

confidence: 90%

Recurrent seascape units identify key ecological processes along the western Antarctic Peninsula

Bowman

Kavanaugh

Doney

et al. 2018

Global Change Biology

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“…The production of fucoxanthin is an important mechanism for diatom assemblages to increase light harvesting in the tip of Antarctic Peninsula as addressed by Mendes et al . [] and similarly observed in surface Argentinean waters [ Lutz et al ., ]. In fact, the production of photosynthetic pigments is feasible in nonlimiting nutrient conditions.…”

Section: Resultssupporting

confidence: 60%

“…Note that the samples were taken during middle/late summer, thus, they do not represent average growth conditions, which can only be described when similar analyses and comparisons are performed in other periods for the studied area. Similar proportions of photoprotective pigments to those for lower latitudes suggest that algal communities around the Antarctic Peninsula are not light limited in summer [see also Mendes et al ., ]. In fact, during our surveys, the ratios of Z eu to Z MLD were generally higher than 1, which implies that phytoplankton cells within Z MLD probably did not experience light limitation while they mixed vertically through the mixed layer.…”

Section: Resultsmentioning

confidence: 67%

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Phytoplankton light absorption and the package effect in relation to photosynthetic and photoprotective pigments in the northern tip of Antarctic Peninsula

et al. 2017

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This study investigates the variability in the spectral absorption of phytoplankton in Antarctic waters. A large in situ data set comprising phytoplankton pigments and hyperspectral absorption was measured in the northern tip of Antarctic Peninsula during 2013 and 2014 summers at several depths. A proxy of package effect was estimated from the phytoplankton absorption spectra, independently of chlorophyll a. Variations in the concentration of photosynthetic and photoprotective pigments were discernible by changes in this metric but not in the chlorophyll a specific absorption coefficient of phytoplankton. The fucoxanthin to chlorophyll a ratio correlated positively to package effect due to an increase in cell size of phytoplankton (diatoms) and increasing fucoxanthin content per cell to maximize light harvesting in depth. The package effect was found to covary inversely with photoprotective pigments relative to chlorophyll a, partially due to their contribution to enhance absorption in the blue part of the spectrum. Using a cluster analysis (k‐means algorithm) on the phytoplankton absorption spectra, we illustrate the capacity to identify a regular increase in the degree of package effect. This approach can be useful to classify the phytoplankton assemblages in Antarctic waters according to different degrees of pigment packaging, each one related to a specific pigment composition. Our results demonstrate the potential for this classification at different temporal and spatial scales from ocean color satellite data. This should improve our understanding of deviations in global bio‐optical algorithms when applied to the Southern Ocean.

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“…Decreased ice cover has been associated with a reduction in photosynthetic efficiency (Schofield et al 2018) and several studies have described a reduction in overall phytoplankton biomass and a shift from large phytoplankton (diatoms) to smaller flagellated species. These shifts have been associated with reduced salinities, higher temperatures and stronger vertical stratification (Moline and Prezelin 1996;Moline et al 2004;Montes-Hugo et al 2009;Venables et al 2013;Mendes et al 2017;Rozema et al 2017c). However, the physicochemical drivers behind community shifts towards flagellated phytoplankton remain unclear, likely due to the diversity among flagellated phytoplankton spanning different taxonomic groups and cell sizes, and each may interact differently with the physicochemical environment.…”

Section: Introductionmentioning

confidence: 99%

Antarctic phytoplankton community composition and size structure: importance of ice type and temperature as regulatory factors

et al. 2019

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Climate change at the Western Antarctic Peninsula (WAP) is predicted to cause major changes in phytoplankton community composition, however, detailed seasonal field data remain limited and it is largely unknown how (changes in) environmental factors influence cell size and ecosystem function. Physicochemical drivers of phytoplankton community abundance, taxonomic composition and size class were studied over two productive austral seasons in the coastal waters of the climatically sensitive WAP. Ice type (fast, grease, pack or brash ice) was important in structuring the pre-bloom phytoplankton community as well as cell size of the summer phytoplankton bloom. Maximum biomass accumulation was regulated by light and nutrient availability, which in turn were regulated by wind-driven mixing events. The proportion of larger-sized (> 20 µm) diatoms increased under prolonged summer stratification in combination with frequent and moderate-strength wind-induced mixing. Canonical correspondence analysis showed that relatively high temperature was correlated with nano-sized cryptophytes, whereas prymnesiophytes (Phaeocystis antarctica) increased in association with high irradiance and low salinities. During autumn of Season 1, a large bloom of 4.5-µm-sized diatoms occurred under conditions of seawater temperature > 0 °C and relatively high light and phosphate concentrations. This bloom was followed by a succession of larger nano-sized diatoms (11.4 µm) related to reductions in phosphate and light availability. Our results demonstrate that flow cytometry in combination with chemotaxonomy and size fractionation provides a powerful approach to monitor phytoplankton community dynamics in the rapidly warming Antarctic coastal waters.

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New insights on the dominance of cryptophytes in Antarctic coastal waters: A case study in Gerlache Strait

Cited by 70 publications

References 54 publications

Recurrent seascape units identify key ecological processes along the western Antarctic Peninsula

Recurrent seascape units identify key ecological processes along the western Antarctic Peninsula

Phytoplankton light absorption and the package effect in relation to photosynthetic and photoprotective pigments in the northern tip of Antarctic Peninsula

Antarctic phytoplankton community composition and size structure: importance of ice type and temperature as regulatory factors

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