It’s elemental, my dear Watson: validating seasonal patterns in otolith chemical chronologies

Hüssy, Karin; Krüger‐Johnsen, Maria; Thomsen, Tonny B.; Heredia, Benjamin Dominguez; Næraa, Tomas; Limburg, Karin E.; Heimbrand, Yvette; McQueen, Kate; Haase, Stefanie; Krumme, Uwe; Casini, Michèle; Mion, Monica; Radtke, Krzysztof

doi:10.1139/cjfas-2020-0388

Cited by 17 publications

(46 citation statements)

References 71 publications

(70 reference statements)

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“…Also food (Walther et al 2010) and other physiological factors (Sturrock et al 2015) have been suggested to regulate otolith Sr concentrations. However, similar to other studies on Atlantic cod from the North Sea to the Baltic Sea (Hüssy et al 2016;Hüssy et al 2021), the samples used in the present study showed no apparent seasonality in otolith Sr patterns, suggesting that changes in otolith Sr are associated with a change in habitat occupation rather than seasonally varying temperature or growth.…”

Section: Discussionsupporting

confidence: 89%

“…Significant differences in particularly Mg, P, Cu and Zn were also detected between a few year classes within the two populations. These elements are under strong physiological control (Campana 1999;Sturrock et al 2015;Limburg et al 2018;Hüssy et al 2020) and have been shown to reflect fish growth (Heimbrand et al 2020;Hüssy et al 2021). Otolith element concentrations of these elements were consistently higher in the North Sea populations.…”

Section: Discussionmentioning

confidence: 99%

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Where do you come from, where do you go: early life stage drift and migrations of cod inferred from otolith microchemistry and genetic population assignment

Hüssy

Albertsen

Hemmer‐Hansen

et al. 2022

Can. J. Fish. Aquat. Sci.

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This study investigates stock mixing of genetically distinct Atlantic cod (Gadus morhua) stocks in the Kattegat, an area geographically located between the North Sea and the Baltic Sea, by combining genetic population identification with habitat assignments from hatch to capture from otolith microchemistry. Cod captured in Kattegat were genetically assigned to either the North Sea or the endemic Kattegat population. Otolith chemical fingerprints differed significantly between populations during the larval and pelagic juvenile stage with higher strontium and lower barium and manganese concentrations in the North Sea population than the Kattegat population, indicating that North Sea cod are spawned in the North Sea or Skagerrak and drift into the Kattegat during the early life stages. Individual cod of both populations undertook frequent migrations to other areas, with < 25 % of individuals remaining resident within the Kattegat throughout their life. Across seasons and age classes, the two populations were most frequently distributed in the Kattegat (67 %), with approximately 25 % distributed in the western Baltic Sea and < 10 % in the Skagerrak/North Sea.

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Section: Discussionsupporting

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Where do you come from, where do you go: early life stage drift and migrations of cod inferred from otolith microchemistry and genetic population assignment

Hüssy

Albertsen

Hemmer‐Hansen

et al. 2022

Can. J. Fish. Aquat. Sci.

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“…High-resolution micromilling followed by IRMS has sufficient resolution to detect temperature related cycles in δ 18 O values in cod up to 6 years of age (Høie et al 2004b;Kastelle et al 2017), but long-lived species require higher resolution probe-based secondary ion mass spectrometry (SIMS) (Matta et al 2010). With LA-ICPMS, continuous line scans can capture oscillations in trace elements at high spatial and temporal resolution allowing for the reconstruction of entire life history profiles (Heimbrand et al 2020;Hüssy et al 2016bHüssy et al , 2021a. Alternatively, high-resolution 2D elemental maps, produced using LA-ICPMS (Artetxe-Arrate et al 2021;Heimbrand et al 2020;McGowan et al 2014), particle induced x-ray emission (PIXE) (Halden et al 2000;Walther & Limburg 2012) or scanning X-ray fluorescence microscopy (Hermann et al 2016;Tzeng et al 1999) can reveal spatial heterogeneity in elemental composition, which is useful for observing banding patterns and identifying the optimal transect for analysis of seasonal trends (Heimbrand et al 2020).…”

Section: Methodological Challengesmentioning

confidence: 99%

“…Recently, variations in chemical concentrations have been explored as tracers of physiological processes to underpin age estimation. Elements P, Mg and Zn are associated with the organic matrix of the otolith (Izzo et al 2016b;Miller et al 2006;Thomas et al 2017) and reflect seasonal variations in growth (Heimbrand et al 2020;Hüssy et al 2021a;) (Fig. 1).…”

Section: Seasonal Patterns In Element Concentrationmentioning

confidence: 99%

“…1). Minima often correlate with visually identified translucent winter growth zones (Friedrich & Halden 2010;Halden et al 2000;Halden & Friedrich 2008;Hüssy et al 2016b;Limburg & Elfman 2010) or occur during the coldest months of the year (Hüssy et al 2021a). Seasonal differences have also been described in Sr (Brophy et al 2021;Siskey et al 2016;Tzeng et al 1999), though this element is often considered a proxy for environmental salinity.…”

Section: Seasonal Patterns In Element Concentrationmentioning

confidence: 99%

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Reading the biomineralized book of life: expanding otolith biogeochemical research and applications for fisheries and ecosystem-based management

Patrick

Gillanders

Sturrock

et al. 2022

Rev Fish Biol Fisheries

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Chemical analysis of calcified structures continues to flourish, as analytical and technological advances enable researchers to tap into trace elements and isotopes taken up in otoliths and other archival tissues at ever greater resolution. Increasingly, these tracers are applied to refine age estimation and interpretation, and to chronicle responses to environmental stressors, linking these to ecological, physiological, and life-history processes. Here, we review emerging approaches and innovative research directions in otolith chemistry, as well as in the chemistry of other archival tissues, outlining their value for fisheries and ecosystem-based management, turning the spotlight on areas where such biomarkers can support decision making. We summarise recent milestones and the challenges that lie ahead to using otoliths and archival tissues as biomarkers, grouped into seven, rapidly expanding and application-oriented research areas that apply chemical analysis in a variety of contexts, namely: (1) supporting fish age estimation; (2) evaluating environmental stress, ecophysiology and individual performance; (3) confirming seafood provenance; (4) resolving connectivity and movement pathways; (5) characterising food webs and trophic interactions; (6) reconstructing reproductive life histories; and (7) tracing stock enhancement efforts. Emerging research directions that apply hard part chemistry to combat seafood fraud, quantify past food webs, as well as to reconcile growth, movement, thermal, metabolic, stress and reproductive life-histories provide opportunities to examine how harvesting and global change impact fish health and fisheries productivity. Ultimately, improved appreciation of the many practical benefits of archival tissue chemistry to fisheries and ecosystem-based management will support their increased implementation into routine monitoring. Graphical abstract

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Using seasonal oscillations in fin ray microchemistry to chemically age Lake Sturgeon

Taylor,

Loeppky,

Stadig

et al. 2024

Trans Am Fish Soc

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ObjectiveNonlethally sampled pectoral fin rays are commonly used as aging structures for Lake Sturgeon Acipenser fulvescens, but they tend to underestimate the true age in older, slow‐growing individuals (age > 14 years). Current aging practices involve counting bands along the structure, which are construed as annuli. Oscillations of certain trace elements corresponding with annuli have been seen across various fish species, with patterns continuing to the marginal edge of hard structures. This study explored the aging of fin rays by using microchemistry patterns in Lake Sturgeon of known age (n = 94; ages 5–21) to determine the potential use of this method as an alternative or supplementary aging technique.MethodsElements were chosen for age determination analysis by examining the relationship between profile minima/maxima and visually interpreted annuli. Fish were assigned ages using three different methods: (1) traditional interpretation (counting annuli along the structure), (2) chemical interpretation (examination of seasonal variations in elemental profiles with visually identified annuli), and (3) a statistical model (multivariate multiple changepoint analysis with finite differencing using raw elemental profiles).ResultMean absolute differences between age estimates and known age were significantly higher for the traditional interpretation method than for the chemical interpretation method. The mean coefficient of variation in estimated age was 11.14% for the traditional interpretation method and 4.04% for the chemical interpretation method. The changepoint model was able to correctly classify age for 100% of the samples within ±1 year in one population (ages 5–8) but could not classify samples from the second population (ages 12–21).ConclusionOur results suggest that chemical aging techniques could provide more reliable age estimates for juvenile and subadult Lake Sturgeon when fin rays are the only aging option. Further work is required to determine the applicability of the model for assigning ages to older fish and for use with different populations and structures.

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It’s elemental, my dear Watson: validating seasonal patterns in otolith chemical chronologies

Cited by 17 publications

References 71 publications

Where do you come from, where do you go: early life stage drift and migrations of cod inferred from otolith microchemistry and genetic population assignment

Where do you come from, where do you go: early life stage drift and migrations of cod inferred from otolith microchemistry and genetic population assignment

Reading the biomineralized book of life: expanding otolith biogeochemical research and applications for fisheries and ecosystem-based management

Using seasonal oscillations in fin ray microchemistry to chemically age Lake Sturgeon

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