Ontogenic variations in fatty acid and alcohol composition of the pelagic amphipod Themisto libellula in Kongsfjorden (Svalbard)

Noyon, Margaux; Narcy, Fanny; Gasparini, Stéphane; Mayzaud, Patrick

doi:10.1007/s00227-011-1856-7

Cited by 8 publications

(5 citation statements)

References 69 publications

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“…Significantly higher levels of the diatom-associated FA 16:1(n-7), an important contributor to the FA pool of Calanus spp., in T. libellula during winter further highlights the significance of these copepods for the successful overwintering of T. libellula. The significantly higher relative proportions of the polyunsaturated FAs (PUFAs) 20:5(n-3) and 22:6(n-3) in T. libellula in summer compared to winter (Figures 4A,B) could again point to ontogenetic differences in feeding habits, as the rather omnivorous younger stages (length group 5-20 mm) collected during summer probably fed more intensely on PUFArich phytoplankton/ice algae than the mostly carnivorous adult stages of T. libellula (length group 10-40 mm) (Noyon et al, 2009(Noyon et al, , 2012. However, these PUFAs are mainly incorporated into polar lipids (Stübing et al, 2003), and lower PUFA concentrations in T. libellula in winter might be explained by the larger proportion of storage lipids during the polar night (Supplementary Table 1).…”

Section: Themisto Amphipodsmentioning

confidence: 96%

“…In both amphipod species, heterotrophic prey had a greater contribution to their food composition in winter versus summer based on the higher carnivory ratios of 18:1(n-9)/18:1(n-7) and zoosterols to phytosterol ratios (Tables 3, 4). To some extent, the observed seasonal differences likely reflect ontogenetic changes in carbon and prey composition (Noyon et al, 2012), e.g., in T. libellula from early life stages during summer (average dry weight 3.5 mg ind. −1 ) to larger predatory T. libellula individuals during winter (average dry weight 43.4 mg/ind −1 ).…”

Section: Themisto Amphipodsmentioning

confidence: 99%

“…The presence versus absence of sea ice-derived HBIs in amphipods and copepods, respectively, likely reflects differences in their feeding location (under ice versus water column) and/or feeding behavior. Furthermore, it is possible that the juvenile amphipods during summer were feeding on sinking ice algal aggregates in the midwater column (marine snow), as suggested for pteropods and appendicularians (Kohlbach et al, 2021), as young Arctic and Antarctic Themisto have been observed to feed partly on phytoplankton (Noyon et al, 2012;Watts and Tarling, 2012). Sea ice algae-associated HBIs were somewhat more concentrated in the winter compared to the summer Themisto spp., but concentrations varied strongly among the individuals (Figure 5A).…”

Section: Themisto Amphipodsmentioning

confidence: 99%

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Winter Carnivory and Diapause Counteract the Reliance on Ice Algae by Barents Sea Zooplankton

et al. 2021

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The Barents Sea is a hotspot for environmental change due to its rapid warming, and information on dietary preferences of zooplankton is crucial to better understand the impacts of these changes on food-web dynamics. We combined lipid-based trophic marker approaches, namely analysis of fatty acids (FAs), highly branched isoprenoids (HBIs) and sterols, to compare late summer (August) and early winter (November/December) feeding of key Barents Sea zooplankters; the copepods Calanus glacialis, C. hyperboreus and C. finmarchicus and the amphipods Themisto libellula and T. abyssorum. Based on FAs, copepods showed a stronger reliance on a diatom-based diet. Phytosterols, produced mainly by diatoms, declined from summer to winter in C. glacialis and C. hyperboreus, indicating the strong direct linkage of their feeding to primary production. By contrast, C. finmarchicus showed evidence of year-round feeding, indicated by the higher winter carnivory FA ratios of 18:1(n-9)/18:1(n-7) than its larger congeners. This, plus differences in seasonal lipid dynamics, suggests varied overwintering strategies among the copepods; namely diapause in C. glacialis and C. hyperboreus and continued feeding activity in C. finmarchicus. Based on the absence of sea ice algae-associated HBIs (IP25 and IPSO25) in the three copepod species during both seasons, their carbon sources were likely primarily of pelagic origin. In both amphipods, increased FA carnivory ratios during winter indicated that they relied strongly on heterotrophic prey during the polar night. Both amphipod species contained sea ice algae-derived HBIs, present in broadly similar concentrations between species and seasons. Our results indicate that sea ice-derived carbon forms a supplementary food rather than a crucial dietary component for these two amphipod species in summer and winter, with carnivory potentially providing them with a degree of resilience to the rapid decline in Barents Sea (winter) sea-ice extent and thickness. The weak trophic link of both zooplankton taxa to sea ice-derived carbon in our study likely reflects the low abundance and quality of ice-associated carbon during late summer and the inaccessibility of algae trapped inside the ice during winter.

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Section: Themisto Amphipodsmentioning

confidence: 96%

Section: Themisto Amphipodsmentioning

confidence: 99%

Section: Themisto Amphipodsmentioning

confidence: 99%

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Winter Carnivory and Diapause Counteract the Reliance on Ice Algae by Barents Sea Zooplankton

et al. 2021

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“…Falk-Petersen et al (2000) demonstrated that the omnivorous T. inermis and T. raschii feed mostly on phytoplankton and small copepods, and that T. longicaudata feeds more heavily on copepods. T. abyssorum, meanwhile, is a pelagic amphipod known to feed on both diatoms and dinoflagellates as well as copepods (Noyon et al 2012, Kraft et al 2013). The phytoplankton biomarkers in fish species sampled here, therefore, likely come from these important omnivorous primary and secondary consumers.…”

Section: Fatty Acids: Benthic Vs Pelagic Carbon Poolsmentioning

confidence: 99%

Hyperbenthic food-web structure in an Arctic fjord

McGovern¹,

Berge²,

Szymczycha³

et al. 2018

Mar. Ecol. Prog. Ser.

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Current knowledge of the Arctic marine ecosystem is based primarily on studies performed during the polar day on the pelagic and benthic realms. Both the polar night and the hyperbenthic layer remain as substantial knowledge gaps in our understanding of the marine system at high latitudes. This study investigated the hyperbenthic food web in Kongsfjord, a highlatitude, ice-free fjord, in September 2014 and January 2015. The hyperbenthic food web was analyzed using a multi-biomarker approach including stable isotopes of carbon and nitrogen as well as fatty acid profiles of a variety of hyperbenthic taxa. While results suggested no difference in biomarker composition between September and January, they indicated a division in the sampled hyperbenthic species assemblage between pelagic and benthic feeders in both sampling periods. The presence of these 2 food-web pathways may have implications for maintaining higher trophic levels through the polar night, thereby enhancing stability in the Kongsfjord system.

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“…Three hyperiid amphipod species comprise the genus Themisto in northern latitudes: T. libellula, a large Arctic species associated with cold, polar water masses, its subarctic congener T. abyssorum, which is transported to the Arctic by inflowing North Atlantic water masses and T. compressa, a North Atlantic species with its major distribution area in the southern Norwegian Sea (Kraft et al, 2011). Themisto libelulla and T. abyssorum have been studied over the past decade with regard to their food sources, variations in distribution, reproductive strategies, abundances and summer lipid compositions, while little is known about the deepwater species Cyclocaris guilelmi (Bousfield, 1951;Percy, 1993;Koszteyn et al, 1995;Auel et al, 2002;Dalpadado et al, 2008;Marion et al, 2008;Noyon et al, 2009Noyon et al, , 2011Noyon et al, , 2012Kraft et al, 2011Kraft et al, , 2012Kraft et al, , 2013b.…”

mentioning

confidence: 99%

Arctic pelagic amphipods: lipid dynamics and life strategy

et al. 2015

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Polar regions are characterized by a strong seasonality in primary production and distinct fluctuations in food supply. The storage of energy in the form of lipids is expected to follow a seasonal pattern; however, year-round observations are lacking. The seasonal variations of lipid classes and fatty acid compositions of four pelagic amphipods have been investigated. Individuals were collected at various depths during summer and winter expeditions to the Fram Strait and Svalbard archipelago (788-818N). Our results show a year-round dominance of wax esters and triacylglycerols over phospholipids for Themisto abyssorum, Themisto libellula, Themisto compressa and Cyclocaris guilelmi. High levels of the Calanus-marker fatty acids 20:1 and 22:1 (both isomers) during summer and winter indicated that all four species are part of the Calanus-based food web. Specific fatty acid trophic markers for diatoms and flagellates indicated that the lipid-based energy transfer could be traced back to the respective algal sources. We found a distinct difference between animals collected from very deep and shallow waters, which indicates that the lipid reservoir of these amphipods and their biochemical modifications seem to buffer seasonal variations in available prey and to allow an active, predatory lifestyle year-round in Arctic waters.

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Ontogenic variations in fatty acid and alcohol composition of the pelagic amphipod Themisto libellula in Kongsfjorden (Svalbard)

Cited by 8 publications

References 69 publications

Winter Carnivory and Diapause Counteract the Reliance on Ice Algae by Barents Sea Zooplankton

Winter Carnivory and Diapause Counteract the Reliance on Ice Algae by Barents Sea Zooplankton

Hyperbenthic food-web structure in an Arctic fjord

Arctic pelagic amphipods: lipid dynamics and life strategy

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