Environmental drivers of spring primary production in Hudson Bay

Matthes, Lisa; Ehn, Jens K.; Dalman, Laura A.; Babb, David G.; Peeken, Ilka; Harasyn, Madison L.; Kirillov, Sergei; Lee, J.; Bélanger, Simon; Tremblay, Jean‐Éric; Barber, David G.; Mundy, C. J.

doi:10.1525/elementa.2020.00160

Cited by 16 publications

(21 citation statements)

References 103 publications

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“…Exponential fitting indicated a Chl a-based specific growth rate constant of 0.46 d À1 (R 2 = 0.98), corresponding to a doubling of Chl a roughly every 36 h. As measured POC:Chl a ratios showed no clear trend (Table 1) Chl a may be used as a proxy for phytoplankton biomass for the short time span of this study. Such high POC:Chl a ratios, indicative a high nonphototrophic component of the particulate organic carbon pool, are commonly observed in high Arctic environments outside of bloom situations (Riedel et al 2008;Campbell et al 2016;Leu et al 2020;Matthes et al 2021). In combination with the observed increase in volume-based NPP, in situ as well as under reference conditions (Fig.…”

Section: Resultsmentioning

confidence: 62%

Always ready? Primary production of Arctic phytoplankton at the end of the polar night

Hoppe

2021

Limnol Oceanogr Letters

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The end of the polar night with the concurrent onset of photosynthetic biomass production ultimately leads to the spring bloom, which represents the most important event of primary production for the Arctic marine ecosystem. This dataset shows, for the first time, significant in situ biomass accumulation during the dark–light transition in the high Arctic, as well as the earliest recorded positive net primary production rates together with constant chlorophyll a‐normalized potential for primary production through winter and spring. The results indicate a high physiological capacity to perform photosynthesis upon re‐illumination, which is in the same range as that observed during the spring bloom. Put in context with other data, the results of this study indicate that also active cells originating from the low winter standing stock in the water column, rather than solely resting stages from the sediment, can seed early spring bloom assemblages.

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Section: Resultsmentioning

confidence: 62%

Always ready? Primary production of Arctic phytoplankton at the end of the polar night

Hoppe

2021

Limnol Oceanogr Letters

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“…Annual productivity rates measured for S. latissima and L. solidungula at sites around Southampton Island in 2019 ranged from 23.1 to 67.8 g C m −2 y −1 (Filbee-Dexter, unpublished data) and for L. solidungula from Igloolik (Foxe Basin) in 1977 were 19.6 (±12.1 SD) g C m −2 y −1 (Chapman and Lindley, 1980). These measures of NPP are comparable to NPP for phytoplankton in Hudson Bay, Baffin Bay, and Labrador Sea (44-58 g C m −2 y −1 ) (Frey et al, 2020), 3.5× lower than estimates of combined ice algae and phytoplankton productivity for Hudson Bay (72 C m −2 y −1 ) (Matthes et al, 2021) and an order of magnitude lower than the productivity of most kelp forests (global average 516 ± 30 SE g C m −2 y −1 ; Pessarrodona et al, 2021b), yet the extensive area of kelp in the Eastern Canadian Arctic suggests these habitats are still cycling large quantities of carbon in the coastal zone, ranging from 2.2 to 6.4 Tg C y −1 and 10.4 to 30.6 Tg C y −1 , based on a lower depth limit of 10 and 40 m, respectively (Supplementary Table 4).…”

Section: Arctic Kelp and Ecosystem Functionmentioning

confidence: 75%

Sea Ice and Substratum Shape Extensive Kelp Forests in the Canadian Arctic

et al. 2022

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The coastal zone of the Canadian Arctic represents 10% of the world’s coastline and is one of the most rapidly changing marine regions on the planet. To predict the consequences of these environmental changes, a better understanding of how environmental gradients shape coastal habitat structure in this area is required. We quantified the abundance and diversity of canopy forming seaweeds throughout the nearshore zone (5–15 m) of the Eastern Canadian Arctic using diving surveys and benthic collections at 55 sites distributed over 3,000 km of coastline. Kelp forests were found throughout, covering on average 40.4% (±29.9 SD) of the seafloor across all sites and depths, despite thick sea ice and scarce hard substrata in some areas. Total standing macroalgal biomass ranged from 0 to 32 kg m–2 wet weight and averaged 3.7 kg m–2 (±0.6 SD) across all sites and depths. Kelps were less abundant at depths of 5 m compared to 10 or 15 m and distinct regional assemblages were related to sea ice cover, substratum type, and nutrient availability. The most common community configuration was a mixed assemblage of four species: Agarum clathratum (14.9% benthic cover ± 12.0 SD), Saccharina latissima (13% ± 14.7 SD), Alaria esculenta (5.4% ± 1.2 SD), and Laminaria solidungula (3.7% ± 4.9 SD). A. clathratum dominated northernmost regions and S. latissima and L. solidungula occurred at high abundance in regions with more open water days. In southeastern areas along the coast of northern Labrador, the coastal zone was mainly sea urchin barrens, with little vegetation. We found positive relationships between open water days (days without sea ice) and kelp biomass and seaweed diversity, suggesting kelp biomass could increase, and the species composition of kelp forests could shift, as sea ice diminishes in some areas of the Eastern Canadian Arctic. Our findings demonstrate the high potential productivity of this extensive coastal zone and highlight the need to better understand the ecology of this system and the services it provides.

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“…The post-bloom scenario observed in NWHB was characterized by strong nutrient depletion throughout the water column, suggesting that the bloom-deepening scenario had already occurred. A further sign of stressful growth conditions at surface was the highest PPC: PSC ratio observed (Figure 6; Matthes et al, 2021). The postbloom scenario showed low carotenoid and LC-PUFA water contents that were explained in our RDA model by high seawater dissolved silicate and a strong contribution of choanoflagellates to the protist community (Figure 7).…”

Section: Spring Phytoplankton Bloom Scenarios In the Hbc And Associat...mentioning

confidence: 85%

“…Due to the dominant northwesterly wind direction, sea ice breakup generally starts in the northwestern and eastern parts of Hudson Bay between May and June, and progresses toward the southern region where the last ice typically remains until late July (Andrews et al, 2018;Kirillov et al, 2020). Variability in spring ice conditions generates largely different spatial patterns in primary production between the different HBC sub-regions (Matthes et al, 2021).…”

Section: Study Areamentioning

confidence: 99%

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Content in fatty acids and carotenoids in phytoplankton blooms during the seasonal sea ice retreat in Hudson Bay complex, Canada

Amiraux

Lavaud

Cameron-Bergeron

et al. 2022

Elementa: Science of the Anthropocene

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The Hudson Bay complex (HBC) is home to numerous indigenous communities that traditionally have relied heavily on its marine resources. The nutritional quality and stocks of the entire HBC food web depend in large part on the phytoplankton production of bioactive molecules (long chain polyunsaturated fatty acids and carotenoids) and their transfer through trophic levels. The purpose of this study was thus to determine which molecules were produced during spring phytoplankton blooms, as well as the environmental factors driving this production. We investigated 21 stations in 5 sub-regions of the HBC. At the time of sampling, the sub-regions studied had different environmental settings (e.g., ice cover, nutrients, seawater salinity and temperature) conditioning their bloom stages. Pre- and post-bloom stages were associated with relatively low concentrations of bioactive molecules (either fatty acids or carotenoids). In contrast, the highest concentrations of bioactive molecules (dominated by eicosapentaenoic acid and fucoxanthin) were associated with the diatom bloom that typically occurs at the ice edge when silicates remain available. Interestingly, the large riverine inputs in eastern Hudson Bay led to a change in protist composition (larger contribution of Dinophyceae), resulting in lower while more diverse content of bioactive molecules, whether fatty acids (e.g., α-linolenic acid) or carotenoids (e.g., peridinin). As greater stratification of the HBC is expected in the future, we suggest that a mixotrophic/heterotrophic flagellate-based food web would become more prevalent, resulting in a smaller supply of bioactive molecules for the food web.

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Environmental drivers of spring primary production in Hudson Bay

Cited by 16 publications

References 103 publications

Always ready? Primary production of Arctic phytoplankton at the end of the polar night

Always ready? Primary production of Arctic phytoplankton at the end of the polar night

Sea Ice and Substratum Shape Extensive Kelp Forests in the Canadian Arctic

Content in fatty acids and carotenoids in phytoplankton blooms during the seasonal sea ice retreat in Hudson Bay complex, Canada

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