Pelagic microbial heterotrophy in response to a highly productive bloom of <i>Phaeocystis</i>
                  <i>antarctica</i> in the Amundsen Sea Polynya, Antarctica

Williams, C. M.; Dupont, A. M.; Loevenich, J.; Post, Anton F.; Dinasquet, Julie; Yager, Patricia L.

doi:10.12952/journal.elementa.000102

Cited by 29 publications

(83 citation statements)

References 94 publications

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“…Bacterial productivity in the incubation experiments was similar to that reported in the high productivity stations in the central ASP, which was high compared to other Antarctic polynyas (see Williams et al, 2015, for a full description). In contrast to phytoplankton growth and photosynthesis, bacterial productivity did not respond to Fe addition, suggesting that bacteria are not Fe-limited during the early season in the ASP.…”

Section: Phytoplankton Response To Fe Additions: Carrying Capacity Vesupporting

confidence: 79%

“…In addition, despite the increase in bacterial productivity over the four days of incubation, there was no secondary response of bacterial productivity to either the Fe-enhanced phytoplankton growth or photosynthesis rates. Bacterial productivity in surface waters of the ASP showed a positive relationship with phytoplankton biomass (Williams et al, 2015), suggesting bacterial productivity was coupled to phytoplankton biomass and productivity. Likely, the Fe effects on phytoplankton biomass, cellular composition, and photosynthesis rates in our experiments were not sufficient to yield a detectable response in bacterial productivity during the time scale of the incubations.…”

Section: Phytoplankton Response To Fe Additions: Carrying Capacity Vementioning

confidence: 97%

“…Bacterial productivity was estimated in the bioassay experiments from incorporation of 3 H-leucine into protein (Williams et al, 2015). Each of the incubation bottles served as a replicate in the measurements.…”

Section: Bacterial Productivitymentioning

confidence: 99%

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Fe availability drives phytoplankton photosynthesis rates during spring bloom in the Amundsen Sea Polynya, Antarctica

Alderkamp

Dijken

Lowry

et al. 2015

Elementa: Science of the Anthropocene

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To evaluate what drives phytoplankton photosynthesis rates in the Amundsen Sea Polynya (ASP), Antarctica, during the spring bloom, we studied phytoplankton biomass, photosynthesis rates, and water column productivity during a bloom of Phaeocystis antarctica (Haptophyceae) and tested effects of iron (Fe) and light availability on these parameters in bioassay experiments in deck incubators. Phytoplankton biomass and productivity were highest (20 µg chlorophyll a L −1 and 6.5 g C m −2 d −1 ) in the central ASP where sea ice melt water and surface warming enhanced stratification, reducing mixed layer depth and increasing light availability. In contrast, maximum photosynthesis rate (P * max ), initial light-limited slope of the photosynthesis-irradiance curve (a *), and maximum photochemical efficiency of photosystem II (F v / F m ) were highest in the southern ASP near the potential Fe sources of the Dotson and Getz ice shelves. In the central ASP, P * max , a *, and F v / F m were all lower. Fe addition increased phytoplankton growth rates in three of twelve incubations, and at a significant level when all experiments were analyzed together, indicating Fe availability may be rate-limiting for phytoplankton growth in several regions of the ASP early in the season during build-up of the spring bloom. Moreover, Fe addition increased P * max , a*, and F v / F m in almost all experiments when compared to unamended controls. Incubation under high light also increased P * max , but decreased F v / F m and a * when compared to low light incubation. These results indicate that the lower values for P * max , a*, and F v / F m in the central ASP, compared to regions close to the ice shelves, are constrained by lower Fe availability rather than light availability. Our study suggests that higher Fe availability (e.g., from higher melt rates of ice shelves) would increase photosynthesis rates in the central ASP and potentially increase water column productivity 1.7-fold, making the ASP even more productive than it is today.

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Section: Phytoplankton Response To Fe Additions: Carrying Capacity Vesupporting

confidence: 79%

Section: Phytoplankton Response To Fe Additions: Carrying Capacity Vementioning

confidence: 97%

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Fe availability drives phytoplankton photosynthesis rates during spring bloom in the Amundsen Sea Polynya, Antarctica

Alderkamp

Dijken

Lowry

et al. 2015

Elementa: Science of the Anthropocene

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“…The major benefits of using such a tool over more traditional (mostly linear) models are: Regression trees allow for (1) non-linear relationships between input and output variables, (2) non-additive interactions between predictor and response variables and (3) correlations between different input variables (Breiman, 2001;Shi and Horvath, 2006). The relevant variables included were phytoplankton biomass, macronutrients, MLD, temperature, salinity, total irradiance and the relative abundance of the three most important phytoplankton groups, namely diatoms, haptophytes and cryptophytes (Behrenfeld and Falkowski, 1997;Arrigo et al, 1999;Dierssen and Smith, 2000;Vernet et al, 2008Vernet et al, , 2012Montes-Hugo et al, 2009;Piquet et al, 2011;Venables et al, 2013;Williams et al, 2016;Bown et al, 2017;Rozema et al, 2017a,b).…”

Section: Constructing and Evaluate Modelsmentioning

confidence: 99%

Assessing Drivers of Coastal Primary Production in Northern Marguerite Bay, Antarctica

Rozema

Kulk

Veldhuis³

et al. 2017

Front. Mar. Sci.

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The coastal ocean of the climatically-sensitive west Antarctic Peninsula is experiencing changes in the physical and (photo)chemical properties that strongly affect the phytoplankton. Consequently, a shift from diatoms, pivotal in the Antarctic food web, to more mobile and smaller flagellates has been observed. We seek to identify the main drivers behind primary production (PP) without any assumptions beforehand to obtain the best possible model of PP. We employed a combination of field measurements and modeling to discern and quantify the influences of variability in physical, (photo)chemical, and biological parameters on PP in northern Marguerite Bay. Field data of high-temporal resolution (November 2013-March 2014) collected at a long-term monitoring site here were combined with estimates of PP derived from photosynthesis-irradiance incubations and modeled using mechanistic and statistical models. Daily PP varied greatly and averaged 1,764 mg C m −2 d −1 with a maximum of 6,908 mg C m −2 d −1 after the melting of sea ice and the likely release of diatoms concentrated therein. A non-assumptive random forest model (RF) with all possibly relevant parameters (M RFmax ) showed that variability in PP was best explained by light availability and chlorophyll a followed by physical (temperature, mixed layer depth, and salinity) and chemical (phosphate, total nitrogen, and silicate) water column properties. The predictive power from the relative abundances of diatoms, cryptophytes, and haptophytes (as determined by pigment fingerprinting) to PP was minimal. However, the variability in PP due to changes in species composition was most likely underestimated due to the contrasting strategies of these phytoplankton groups as we observed significant negative relations between PP and the relative abundance of flagellates groups. Our reduced model (M RFmin ) showed how light availability, chlorophyll a, and total nitrogen concentrations can be used to obtain the best estimate of PP (R 2 = 0.93). The resulting estimates from our models suggest summer PP to have been between 214.4 and 176.1 g C m −2 . Through the employment of a modeling technique without any assumptions apart from a representative sampling strategy, we showed and estimated how PP in this climatically sensitive and changing region can best be predicted and described.

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“…Net community production and export, were derived from changes in nutrient and carbon inventories . Bacterial production and community respiration rates, measured using 3 H-leucine incorporation and CO 2 production during 24-48 hour dark incubations, were obtained from Williams et al (2015).…”

Section: Other Measurements and Observationsmentioning

confidence: 99%

Particle flux on the continental shelf in the Amundsen Sea Polynya and Western Antarctic Peninsula

Ducklow

Wilson

Post

et al. 2015

Elementa: Science of the Anthropocene

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We report results from a yearlong, moored sediment trap in the Amundsen Sea Polynya (ASP), the first such time series in this remote and productive ecosystem. Results are compared to a long-term time series from the western Antarctic Peninsula (WAP). The ASP trap was deployed from December 2010 to December 2011 at 350 m depth. We observed two brief, but high flux events, peaking at 8 and 5 mmol C m −2 d −1 in January and December 2011, respectively, with a total annual capture of 315 mmol C m −2. Both peak fluxes and annual capture exceeded the comparable WAP observations. Like the overlying phytoplankton bloom observed during the cruise in the ASP (December 2010 to January 2011), particle flux was dominated by Phaeocystis antarctica, which produced phytodetrital aggregates. Particles at the start of the bloom were highly depleted in 13 C, indicating their origin in the cold, CO 2 -rich winter waters exposed by retreating sea ice. As the bloom progressed, microscope visualization and stable isotopic composition provided evidence for an increasing contribution by zooplankton fecal material. Incubation experiments and zooplankton observations suggested that fecal pellet production likely contributed 10-40% of the total flux during the first flux event, and could be very high during episodic krill swarms. Independent estimates of export from the surface (100 m) were about 5-10 times that captured in the trap at 350 m. Estimated bacterial respiration was sufficient to account for much of the decline in the flux between 50 and 350 m, whereas zooplankton respiration was much lower. The ASP system appears to export only a small fraction of its production deeper than 350 m within the polynya region. The export efficiency was comparable to other polar regions where phytoplankton blooms were not dominated by diatoms.

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Pelagic microbial heterotrophy in response to a highly productive bloom of Phaeocystis antarctica in the Amundsen Sea Polynya, Antarctica

Cited by 29 publications

References 94 publications

Fe availability drives phytoplankton photosynthesis rates during spring bloom in the Amundsen Sea Polynya, Antarctica

Fe availability drives phytoplankton photosynthesis rates during spring bloom in the Amundsen Sea Polynya, Antarctica

Assessing Drivers of Coastal Primary Production in Northern Marguerite Bay, Antarctica

Particle flux on the continental shelf in the Amundsen Sea Polynya and Western Antarctic Peninsula

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