Visual predation risk and spatial distributions of large Arctic copepods along gradients of sea ice and bottom depth

Langbehn, Tom J.; Aarflot, Johanna M.; Freer, Jennifer; Varpe, Øystein

doi:10.1002/lno.12354

Cited by 6 publications

(4 citation statements)

References 89 publications

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“…Large copepods, such as Calanus spp., experience a reduced visual predation risk and subsequent increased survival rate where sea ice shades the water. The increased predation risk in open waters can therefore shift the community to a dominance of smaller species (Aarflot et al, 2019;Langbehn et al, 2023), which is also in accordance with our observations.…”

Section: Calanus Glacialis Reproductionsupporting

confidence: 92%

“…While our data indicates that differences in bloom phenology and food availability between the two years may explain the observed changes in community composition from larger to smaller species, the presence of sea ice itself and its effect on visual predation risk may have played an important role. A recent study from the Barents Sea suggests that the prevalence of large copepods in deeper troughs and under sea ice is best explained by top-down control (Langbehn et al, 2023). Large copepods, such as Calanus spp., experience a reduced visual predation risk and subsequent increased survival rate where sea ice shades the water.…”

Section: Calanus Glacialis Reproductionmentioning

confidence: 99%

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Response of the copepod community to interannual differences in sea-ice cover and water masses in the northern Barents Sea

Gawinski,

Daase,

Primicerio

et al. 2024

Front. Mar. Sci.

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The reduction of Arctic summer sea ice due to climate change can lead to increased primary production in parts of the Barents Sea if sufficient nutrients are available. Changes in the timing and magnitude of primary production may have cascading consequences for the zooplankton community and ultimately for higher trophic levels. In Arctic food webs, both small and large copepods are commonly present, but may have different life history strategies and hence different responses to environmental change. We investigated how contrasting summer sea-ice cover and water masses in the northern Barents Sea influenced the copepod community composition and secondary production of small and large copepods along a transect from 76°N to 83°N in August 2018 and August 2019. Bulk abundance, biomass, and secondary production of the total copepod community did not differ significantly between the two years. There were however significant spatial differences in the copepod community composition and production, with declining copepod abundance from Atlantic to Arctic waters and the highest copepod biomass and production on the Barents Sea shelf. The boreal Calanus finmarchicus showed higher abundance, biomass, and secondary production in the year with less sea-ice cover and at locations with a clear Atlantic water signal. Significant differences in the copepod community between areas in the two years could be attributed to interannual differences in sea-ice cover and Atlantic water inflow. Small copepods contributed more to secondary production in areas with no or little sea ice and their production was positively correlated to water temperature and ciliate abundance. Large copepods contributed more to secondary production in areas with extensive sea ice and their production was positively correlated with chlorophyll a concentration. Our results show how pelagic communities might function in a future ice-free Barents Sea, in which the main component of the communities are smaller copepods, and the secondary production they generate is available in energetically less resource-rich portions.

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Section: Calanus Glacialis Reproductionsupporting

confidence: 92%

Section: Calanus Glacialis Reproductionmentioning

confidence: 99%

Response of the copepod community to interannual differences in sea-ice cover and water masses in the northern Barents Sea

Gawinski,

Daase,

Primicerio

et al. 2024

Front. Mar. Sci.

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“…The biomass of C. hyperboreus is generally low in the Barents Sea, which probably reflects its vulnerability to predation from visual predators such as capelin ( Aarflot et al. , 2022 ; Langbehn et al. , 2023 ).…”

Section: Discussionmentioning

confidence: 99%

“…A reason for their low importance in the Barents Sea could be vulnerability to predation by visual fish predators due to their large size. This makes them easy targets for visual predators in shallow shelf waters ( Langbehn et al. , 2023 ) and could explain their tendency to be mesopelagic ( Mauchline, 1995 ).…”

Section: Discussionmentioning

confidence: 99%

Abundance and biomass of copepods and cladocerans in Atlantic and Arctic domains of the Barents Sea ecosystem

Skjoldal,

Aarflot

2023

Journal of Plankton Research

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Zooplankton in the Barents Sea have been monitored annually with a standard procedure with determination of size-fractioned biomass since the mid-1980s. Biomass of copepods and cladocerans was estimated based on measured abundance and individual weights taken from literature. Calanus species were dominant, making up ~85% of the estimated biomass of copepods. The second most important taxon was Oithona spp. (~0.5 g dry weight (dw) m−2, ~10%), followed by Metridia spp. (~0.15 g dw m−2, 2–3%) and Pseudocalanus spp. (0.10–0.15 g dw m−2, 1–5%). Estimated biomass of cladoceran taxa (Evadne and Podon) was low (0.01 g dw m−2). Calanus spp. contributed most of the biomass of the medium size fraction (1–2 mm), whereas small copepod species (Oithona, Pseudocalanus and others) contributed to the small size fraction (<1 mm). Estimated biomass of Calanus spp. and of the sum of small copepod species were both positively correlated with measured total zooplankton biomass (R2 = 0.72 and 0.34, respectively). The biomass ratio of small copepod species to Calanus was similar in Atlantic and Arctic water masses (~0.15–0.2) but tended to increase with decreasing total biomass. This suggests a shift to relatively larger roles of small copepods as Calanus and total biomass decrease.

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Diets of gadoid fish in Arctic waters of Svalbard fjords during the polar night

Larsen,

Cusa,

Eglund-Newby

et al. 2023

Polar Biol

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As the climate warms, boreal fish species are expected to expand into the Arctic domain. Though water temperature is an important factor driving expansion of aquatic species, other variables may play a critical role in restricting those movements. Continuous darkness during the Arctic polar night has been suggested to impair foraging in visually searching boreal fish and may thus limit their northward expansion. We discuss feeding and diet composition of co-existing polar cod (Boreogadus saida), Atlantic cod (Gadus morhua), and haddock (Melanogrammus aeglefinus) during the polar night. The data presented cover January sampling during five consecutive years (2012–2016) in Svalbard fjords (78–80°N). Across species, more than 70% of individuals were feeding. Few stomachs were well filled, suggesting an overall moderate foraging activity or success. The endemic polar cod had the highest frequency of empty stomachs (40%), while Atlantic cod (25% empty) and haddock (21% empty) had fed most extensively. Diet composition indicated opportunistic feeding, with extensive diet overlap of the most abundant prey species (krill, Thysanoessa spp.) during years of highly abundant krill (2014–2015) but reverting to more distinct diets in a year (2016) with lower krill abundance. For all three species, presence of prey items in advanced degrees of digestion indicated feeding activity prior to each annual trawl sampling. The stomach fullness and diet overlap suggest that coexisting and similar sized gadoids feed on the same available prey resources during polar night.

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Visual predation risk and spatial distributions of large Arctic copepods along gradients of sea ice and bottom depth

Cited by 6 publications

References 89 publications

Response of the copepod community to interannual differences in sea-ice cover and water masses in the northern Barents Sea

Response of the copepod community to interannual differences in sea-ice cover and water masses in the northern Barents Sea

Abundance and biomass of copepods and cladocerans in Atlantic and Arctic domains of the Barents Sea ecosystem

Diets of gadoid fish in Arctic waters of Svalbard fjords during the polar night

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