Short-term tissue decomposition alters stable isotope values and C:N ratio, but does not change relationships between lipid content, C:N ratio, and Δδ13C in marine animals

Matthew J. Perkins; Yanny K. Y. Mak; Lily S. R. Tao; Archer T. L. Wong; Jason K. C. Yau; David M. Baker; Kenneth M. Y. Leung

doi:10.1371/journal.pone.0199680

Abstract

Measures (e.g. δ¹⁵N, δ¹³C, %C, %N and C:N) derived from animal tissues are commonly used to estimate diets and trophic interactions. Since tissue samples are often exposed to air or kept chilled in ice over a short-term during sample preparation, they may degrade. Herein, we hypothesize that tissue decomposition will cause changes in these measures. In this study, we kept marine fish, crustacean and mollusc tissues in air or ice over 120 h (5 days). We found that tissue decomposition in air enriched δ¹⁵N (range 0.6‰ to 1.3‰) and δ¹³C (0.2‰ to 0.4‰), decreased %N (0.47 to 3.43 percentage points from staring values of ~13%) and %C (4.53 to 8.29 percentage points from starting values of ~43%), and subsequently increased C:N ratio (0.14 to 0.75). In air, while such changes to δ¹³C were relatively minor and therefore likely tolerable, changes in δ¹⁵N, %N, %C and C:N ratio should be interpreted with caution. Ice effectively reduced the extent to which decomposition enriched δ¹⁵N (≤ 0.4‰) and δ¹³C (≤ 0.2‰), and eliminated decomposition in C:N ratio, %N and %C. In our second experiment, for fish tissues in either air or ice over 120 h, we observed no effects of decomposition on relationships between lipid content, C:N ratio, and Δδ¹³C (change in δ¹³C after lipid removal), which are employed to correct δ¹³C for samples containing lipid. We also confirmed that lipid in tissues caused large errors when estimating δ¹³C (mean ± standard error = -1.8‰ ± 0.1‰, range -0.6‰ to -3.8‰), and showed both lipid extraction and mathematical correction performed equally well to correct for lipids when estimating δ¹³C. We, therefore, recommend that specimens of marine animals should be kept in ice during sample preparation for a short-term, as it is an effective means for minimizing changes of the stable isotope measures in their tissue.

Citation: Perkins MJ, Mak YKY, Tao LSR, Wong ATL, Yau JKC, Baker DM, et al. (2018) Short-term tissue decomposition alters stable isotope values and C:N ratio, but does not change relationships between lipid content, C:N ratio, and Δδ¹³C in marine animals. PLoS ONE 13(7): e0199680. https://doi.org/10.1371/journal.pone.0199680

Editor: Daniel E. Naya, Universidad de la Republica Uruguay, URUGUAY

Received: January 21, 2018; Accepted: June 12, 2018; Published: July 18, 2018

Copyright: © 2018 Perkins et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This research was substantially funded by a Research Grants Council of the Government of the Hong Kong Special Administrative Region (HKSAR) via a Collaborative Research Fund (CRF Project No. HKU5/CRF/12G) to KMYL, and partially supported by a Seed Fund for Basic Research (Project Code: 201611159133) by the University of Hong Kong (HKU) to KMYL and MJP. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Stable isotope ratios of nitrogen (¹⁵N/¹⁴N relative to atmospheric nitrogen, termed δ¹⁵N) and carbon (¹³C/¹²C relative to Vienna PeeDee Belemnite, termed δ¹³C) are widely used within aquatic and terrestrial ecological research for dietary reconstruction of consumers [1] and determining trophic structure of communities [2–4]. Derived ecological conclusions are dependent upon the accuracy of δ¹⁵N and δ¹³C estimates. Research has accordingly investigated potential sources of error when estimating δ¹⁵N and δ¹³C, including error associated with methods of sample preservation [5–8] and sample preparation [9,10]. Studies have shown that in some instances, such error is significant. For instance, Tarroux et al. [11] showed that the presence of lipid within tissues affected estimates of δ¹³C and subsequently biased estimates of resource contributions to consumers when using dietary mixing models. Post [12] showed the use of inappropriate δ¹⁵N discrimination values (the change in δ¹⁵N from resource to consumer) introduced error into trophic structure estimates of food chain length, while Perkins et al. [10] proved that selection of different tissue types during sample preparation could lead to such inappropriate δ¹⁵N discrimination values. Therefore, error in estimates of δ¹⁵N and δ¹³C introduced during sample preservation and preparation in many instances must be avoided or accounted for, though this is easily achieved once such error has been documented and is widely understood. As chemical preservation [13,14] and in a limited number of instances even freezing [7,15,16] may confound the fidelity of stable isotope values, many studies opt to keep samples unpreserved or in/on ice until advanced sample preparation is undertaken. Currently, however, we have limited empirical evidence to assess if and how tissue decomposition may affect δ¹⁵N and δ¹³C within unpreserved animal tissues in the short term (e.g. < 1 week).

Decomposition of samples has been better investigated for plants and algae, showing complex and variable effects [17,18]. Conversely, studies on animals have been of restricted scope. Payo-Payo et al. [19] and Burrows et al. [20] opportunistically sampled stranded cetaceans and turtles (n = 1 to 3) of unknown time of death, observing little change in either δ¹⁵N and δ¹³C over 62 or 14 days, respectively. Scarce studies employing greater experimental control have shown mixed results. Observations of a terrestrial invertebrate (Drosophila; [13]) and marine vertebrates (seal, shark, trout; [21]) have shown either no change or limited change (δ¹⁵N enriched by 0.4‰; δ¹³C depleted by 0.4‰ to 0.8‰) over a short-term (≤ 10 days). Variability amongst results and differences in experimental conditions across studies necessitates that further research is needed to determine if there exists consistent and generalisable patterns in how tissue decomposition affects stable isotope measures, or if decomposition effects are largely species- or tissue-specific. Given that tissues undergo both biological breakdown from microorganisms and self-breakdown with cessation of metabolism following death, we expect the chemical composition of tissue samples to change, either through loss of their constituents, change in relative proportion of different constituents, or formation of new constituents through cellular breakdown or deposited microorganism residues [18, 22, 23]. Thus, empirical evidence is required to inform researchers about the extent to which tissue decomposition may alter δ¹⁵N and δ¹³C in the short-term, for a broader range of species using fresh specimens.

In addition to δ¹⁵N and δ¹³C, ratios of percentage carbon (%C) to nitrogen (%N) (termed C:N ratio) of animal tissues provide a proxy of lipid to protein content and so can be informative of both lipid content and diet [24,25]. To date, empirical studies have barely examined potential tissue decomposition effects on C:N ratios of tissues following sampling (but see [18,21]). Decomposition is likely to proceed by physical breakdown and loss of tissues’ structural components, including nitrogen and carbon, so any decomposition would likely infer a change in C:N ratio (unless %C and %N degrade at rates that maintain this ratio). However, it is still unclear how tissue losses of nitrogen and carbon correspond to the heavier or lighter isotopes of each element. Losses in %N and %C may be associated with enriched δ¹⁵N and δ¹³C, respectively, provided that microbial or self-breakdown processes preferentially involve liberation of lighter metabolically more-active ¹⁴N and ¹²C from tissue, respectively [21].

Importantly, C:N ratios are also widely used to provide an a posteriori mathematical correction for δ¹³C values [26]. This is because tissues used for stable isotope analysis (SIA) often contain lipid, which is naturally depleted in δ¹³C [27]. This is a problem as lipid content varies between species, individuals, and tissues within individuals, and thus disproportionately affects estimates of δ¹³C in some samples, so needs to be accounted for [10]. However, lipid extraction prior to SIA can be costly and laborious, and may affect δ¹⁵N values [9,11,26]. Fortunately, the removal of lipids in a subset of samples can allow for the use of a derived equation of the relationship between C:N ratio and Δδ¹³C (the change in δ¹³C following removal of lipids) to provide mathematical correction of remaining samples simply based on their C:N ratios. The relationship between C:N ratio and Δδ¹³C follows two other important relationships between lipid content (%) and Δδ¹³C, and between C:N ratio and lipid content. The mathematical correction is extensively used, with a main paper reporting this procedure [26] currently cited >1000 times. Therefore, it is desirable to understand if and how tissue decomposition may affect the application of this mathematical correction. Decomposition may ultimately affect estimates of δ¹³C in two ways; either through using degraded tissues to derive the correction equation itself, or through using ‘fresh’ tissues to derive the equation but its subsequent application to correct δ¹³C for degraded tissue samples. In either instance, the use of a mathematical correction to estimate δ¹³C maybe robust to tissue decomposition unless decomposition, which includes microbial processes, adds or depletes compounds at a sufficiently high mass to alter relationships between C:N ratio, Δδ¹³C and lipid content of a tissue sample (i.e. tissue C:N ratio not matched by lipid content). In many instances, other approaches are used to estimate δ¹³C, including SIA only (where no attempt is made to correct / control for lipids in tissues), or lipid extraction prior to SIA. It would therefore be insightful to contrast how tissue decomposition may differentially affect estimates of δ¹³C made through either SIA only, lipid extraction prior to SIA, or mathematical correction after SIA.

In this study, we investigated the potential effects of tissue decomposition on multiple tissue measures in selected marine organisms over time. We conducted two separate experiments to answer three questions. Experiment 1 –Q1. How does tissue decomposition affect δ¹⁵N, δ¹³C, %N, %C and C:N ratio? Experiment 2 –Q2. Does tissue decomposition affect tissue lipid content or relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C? and Q3. Are alternative methodologies for estimating δ¹³C (SIA; lipid extraction then SIA; SIA then mathematical correction) differentially affected by tissue decomposition?

Materials and methods

Ethics statement

Freshly killed fishes, crustaceans and molluscs were brought from Aberdeen wholesale fish market, Hong Kong (coordinates: 22.248020, 114.150744). We were able to easily observe animals being killed in the market (i.e. removed from their tanks and left to expire), and so purchased animals for which we knew precise time of death. All individuals were inspected to ensure no visible damage or signs of poor health.

Overview

Here we describe two separate experiments. The first experiment provides a simple test of how decomposition affects common tissue measures. The second experiment tests if decomposition affects a widely applied methodological procedure that is used a posteriori to correct δ¹³C values against error caused by lipid content.

Experiment 1 ― Q1. How does tissue decomposition affect δ¹⁵N, δ¹³C, %N, %C and C:N ratio?

Sample preparation.

Individuals of two fish species (grouper Cephalopholis boenak; rabbitfish Siganus canaliculatus), two crustacean species (mantis shrimp Miyakea nepa; crab Portunus sanguinoletus) and two mollusc species (gastropod Babylonia areolata; bivalve Paphia amabilis) were assigned randomly to air and ice treatments (n = 4 per species per treatment). The air treatment quantified the extent of natural decomposition, while the ice treatment evaluated the effectiveness of using an ice covering to reduce any decomposition effects. Repeated tissue sampling per individual was undertaken at 0, 30, 60, 90 and 120 h. Repeated measures within individuals were used because the results of a pilot experiment suggested that large between-individual variations in derived response variables might mask decomposition effects. Fish and mantis shrimp remained whole, with dorsal muscle and abdominal muscle, respectively, sampled at each time point. Due to difficulties of separating tissues because of decomposition / drying over time, crabs and molluscs were completely dissected fresh (Time = 0 h), with claw and leg muscle (crab), foot muscle (gastropod), or foot and adductor muscle (bivalve) pooled per individual on a petri dish from which subsequent samples were taken over time. Both air and ice treatments provided aerobic conditions. ‘Air’ treatment samples were kept in open trays within the laboratory (mean ± SD across experiment 1 and 2: temperature = 20.91°C ± 0.81°C, n = 10; humidity = 69.82% ± 3.22%, n = 10) while ‘ice’ treatment samples were kept in open freezer bags placed within ice (0.08°C ± 0.86°C, n = 10; humidity = 50.65% ± 2.10%, n = 10). Collected samples were immediately freeze dried for >48 h, homogenized and stored under dry conditions. For each of the freeze dried samples, 1.00mg ± 0.10mg dried tissue was carefully weighed and enclosed in a tin capsule and analysed for δ¹⁵N, δ¹³C, %N, and %C using stable isotope ratio mass spectrometry (EuroVector, model EA3028) at the Stable Isotope Laboratory of the Science Faculty, University of Hong Kong. For each sample, C:N ratio was subsequently calculated by dividing %C by %N. Further details can be found in S1 File.

Lipid correction.

Following Post et al. [26], we applied an a posteriori mathematical correction to all estimates of δ¹³C for fish and crustacean samples to provide lipid free estimates of δ¹³C. Corrections were based on derived equations of relationships between C:N ratio and the difference in δ¹³C with and without lipid (Table A in S1 File). Thus, for fish and crustaceans, we assessed tissue decomposition over time in air and ice upon δ¹³C from tissues with lipid (termed δ¹³C +L) and for values of δ¹³C that were mathematically corrected to account for lipids (termed δ¹³C -L). It was not possible to derive such relationships for mollusc tissues, so for molluscs we only investigated effects of decomposition on uncorrected δ¹³C (δ¹³C +L) and interpreted the results with caution.

Data analysis.

All statistical analyses were performed in the open source software R 3.4.0 [28] using lmer in lme4 [29]. We used a separate analysis per species per response variable. Per species, we used a linear mixed-model (LMM) to test for an interaction between the fixed effects of time (continuous variable) and treatment (2 level factor: air and ice), separately, on δ¹⁵N, δ¹³C +L, δ¹³C -L, %N, %C and C:N ratio. We included the random effect individual in each model to account for non-independence of repeated measures over time per individual. Significance of an interaction effect was determined using analysis of deviance between models with and without the interaction included. Interactions were dropped when they were not significant, and main effects were similarly tested by analysis of deviance between models with and without each term. For LMM, determination of model fit to the data was calculated with pseudo-R squared values [30] using the R package MuMIn [31], with estimates for the variance explained by model fixed effects reported with the prefix R²_GLMM(m) and the combined fixed and random effects as R²_GLMM(c). For all analyses, normality of residuals was checked visually using Q-Q plots, and homogeneity of variances checked visually using plots of residuals against each variable.

Experiment 2

Questions 2 and 3 are both tested using a common dataset derived from the experimental design below.

Sample preparation.

In contrast to experiment 1, experiment 2 used only fish. This was because a pilot experiment suggested individual fish (c.f. mollusc and crustaceans) provided ample tissue for multiple lipid quantifications, while different fish species provided a broad range of lipid contents against which to test the effects of tissue decomposition. Using six species of fishes (seabream Acanthopagrus latus; grouper Epinephelus lanceolatus (hybrid); pomfret Pampus argenteus; scat Scatophagus argus; rabbitfish Siganus canaliculatus and mullet Valamugil cunnesius), one individual per species was assigned to each the air and ice treatment. For all individuals, repeated tissue samples (dorsal muscle) were collected at 0, 60 and 120 h. Thus, each level of treatment and time (Air 0h, A 60h, A 120h, Ice 0h, I 60h, I 120h) had a sample size of six (one sample per the single individual of each of the six fish species). Fish were kept in air or ice as described for Experiment 1 prior to sampling, where upon tissues were immediately freeze dried, homogenised and stored under dry conditions. For each sample we quantified lipid content, C:N ratio and Δδ¹³C. Δδ¹³C was calculated as the difference in δ¹³C between one sub-sample that underwent stable isotope analysis (SIA) and a second sub-sample that underwent lipid extraction and then SIA. Therefore, subsequent relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C were examined at each level of treatment and time. Note, it is appropriate to test these relationships across individuals of different species (c.f. across individuals within species) to maximise range of lipid content [26].

Lipid extraction & quantification.

Samples for each individual per time and treatment underwent lipid extraction and quantification as described by Post et al. [26]. Briefly, 0.5g ± 0.0001g of homogenised dried tissue was placed in a 30ml boiling-tube to which 8ml of chloroform and 8ml of methanol were added, forming a 50:50 methanol-chloroform solution. Boiling tubes were heated in a water bath at 61°C for 40 min, allowed to cool to air temperature, and refilled to 25ml with the addition of chloroform. The mixture was poured through a No. 1 Whatman filter paper into a 250ml separatory funnel. 10ml of 0.9% saline solution was added to the separatory funnel, and the whole mixture shaken vigorously and allowed to settle and separate for 45min. The bottom methanol-chloroform fraction containing the lipid was drained into a pre-weighed aluminium dish and warmed on a hot-plate at 70°C until no liquid remained. The dish was cooled to air temperature, re-weighed to the nearest 0.0001g, and the mass of lipid calculated as the difference between post and pre tray weight, and expressed as a percentage of the original 0.5g sample mass, termed ‘lipid content’. The residual sediment on the filter paper was air dried and collected for use as the lipid extracted sample for SIA.

Stable isotope analysis.

All samples were analysed for δ¹⁵N, δ¹³C, %N, %C and C:N ratio using stable isotope ratio mass spectrometry as described for Experiment 1.

Data Analysis ― Q2.

Does tissue decomposition affect tissue lipid content or relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C? Firstly, we used a LMM to test if time, treatment (2 level factor: air and ice) and their interaction affected lipid content of fish tissues, and included the random effect individual to account for non-independence of repeated measures over time per individual fish. Next, for three known relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C, separately, we investigated how each relationship was affected by tissue decomposition in air or ice. To simplify the analyses, we combined treatment and time to produce a single variable termed combined treatment (6 level factor: Air 0h, A 60h, A 120h, Ice 0h, I 60h, I 120h). Using separate LMMs, we tested if (i) Δδ¹³C was affected by lipid content, combined treatment and their interaction, (ii) lipid content was affected by C:N ratio, combined treatment and their interaction, and (iii) Δδ¹³C was affected by C:N ratio, combined treatment and their interaction. The random effect individual was included in each model to account for non-independence of repeat measures over time per individual fish. Model selection and estimates of model fit were conducted for all analyses as previously described for Experiment 1.

Q3. Are alternative methodologies for estimating δ¹³C differentially affected by tissue decomposition?

Finally, we tested how tissue decomposition may affect δ¹³C values for samples prepared using different methodological procedures. At each sampling event (0, 60 and 120 h) per individual fish, we derived three measures of δ¹³C: from a sample that underwent SIA (termed uncorrected), a sample that underwent SIA and then a posteriori mathematical correction (termed mathematically corrected), and a sample that underwent lipid extraction and then SIA (termed lipid extracted). Mathematical correction was achieved using samples’ C:N ratios and equation 3 in Table A in S1 File. Given potentially larger between-individual than within-individual variation in derived δ¹³C values, to aid direct comparison of δ¹³C values derived across individuals over time and from multiple methodological procedures, we firstly standardised all values of δ¹³C. Within each individual fish, standardisation was achieved by subtracting all sampled values of δ¹³C from a ‘baseline δ¹³C’ which was taken as each fish’s value of lipid extracted δ¹³C at 0 h. Lipid extracted values were deemed to be the most accurate estimates of a lipid-free ‘true’ δ¹³C value, while using 0 h tissues ensured no decomposition had occurred. The difference between sample δ¹³C and baseline δ¹³C is hereafter termed standardised δ¹³C. Lipid extracted values of δ¹³C at 0 h were, therefore, not included in subsequent analysis, given all other values of δ¹³C were standardised against them. As previously, to simplify the analysis, we combined treatment (2 level factor: air or ice) and time to produce a single variable termed combined treatment (6 level factor for uncorrected and mathematically corrected samples: Air 0h, A 60h, A 120h, Ice 0h, I 60h, I 120h; but a 4 level factor for lipid extracted samples: A 60h, A 120h, I 60h, I 120h). Using a separate analysis for each methodological procedure, a LMM tested if standardised δ¹³C was affected by the main effect combined treatment, while the random effect individual was included in each model to account for non-independence of repeat measures over time per individual fish. Model selection and estimates of model fit were conducted as previously described for Experiment 1. Following a significant result, post-hoc analysis was used to determine differences between levels of factors using a P-value adjusted Tukey method (to account for multiple testing) in the R package lsmeans [32]. For all analyses, homogeneity of variances and normality of model residuals were checked as described in Experiment 1. All statistical analyses in questions 2 and 3 were performed in the open source software R 3.4.0 [28] using lme4 [29].

Results

Experiment 1

Q1. How does tissue decomposition affect δ¹⁵N, δ¹³C, %N, %C and C:N ratio? Across all species and response variables, 60% of analyses (18 of 30; Fig 1) showed a significant change over time. Tissue decomposition frequently altered tissue values in air (18 of 30) but infrequently in ice (3 of 30). Decomposition caused δ¹⁵N and δ¹³C to become enriched, caused decreases in both %N and %C, and subsequently increased C:N ratio (inferring decreases in %N were proportionally larger than decreases in %C). Broadly consistent patterns of change were observed for fish and crustacean tissues, which contrasted with the detection of only one significant change in mollusc tissues (1 in 10 analyses). Given the large non-directional variances seen within individual mollusc tissues regardless of the treatment (Fig A in S1 File), this suggested that within individual variability may have masked smaller effects of decomposition. Excluding molluscs, we observed a significant effect of tissue decomposition on the five measured parameters in 85% of cases (17 of 20; Fig 1). Notable results are presented per tissue measure below, with further details in S1 File.

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Fig 1. Change in δ¹⁵N, δ¹³C, %N, %C and C:N ratio over 120 h for fish, crustacean and mollusc tissues kept in air (solid red lines) or ice (dotted blue lines).

Slopes are modelled relationships, and data represent mean values (n = 4). Error bars are not included as they are not appropriate here; between-individual variation was excluded from models using repeated measures within individuals and accounted for in analyses through use of a random effect ‘individual’. For δ¹³C, all species use δ¹³C +L (square symbols with either solid red or dotted blue lines), while we also modelled δ¹³C -L for fish and crustaceans (open triangle symbols with either red or blue dashed lines). δ¹³C -L values were obtained by applying a mathematical correction (Table A in S1 File) to δ¹³C +L data. Significant effects of tissue decomposition over time upon tissue measures are denoted for air (A) and ice (I) treatments where interactions indicated differences between treatments, or (M) when determined by a significant main effect indicating tissue decomposition that did not differ between treatments. + /—indicates the direction of effect. For fish and crustacean δ¹³C, symbol type with letter indicates significant relationships for either δ¹³C -L (open triangles) or δ¹³C +L (squares).

https://doi.org/10.1371/journal.pone.0199680.g001

δ¹⁵N. For fish and crustacean analyses, significant interactions indicated that time affected δ¹⁵N but that this was dependent upon treatment (Grouper: χ²₍₁₎ = 17.91, P < 0.001, R²_GLMM(m) = 0.37; Rabbitfish: χ²₍₁₎ = 20.10, P < 0.001, R²_GLMM(m) = 0.63; Mantis Shrimp: χ²₍₁₎ = 6.88, P < 0.01, R²_GLMM(m) = 0.68; Crab: χ²₍₁₎ = 7.74, P < 0.01, R²_GLMM(m) = 0.66; Fig 1; Table B in S1 File). For these species, tissues kept in air enriched in δ¹⁵N between 0.6‰ to 1.3‰ over 120 h (Fig 1; Table B in S1 File). Conversely, δ¹⁵N of tissues kept in ice did not change over time, except for Mantis Shrimp, which were modestly enriched in δ¹⁵N by 0.4‰ over 120 h (Fig 1; Table B in S1 File).

δ¹³C. Using δ¹³C -L data, we observed that decomposition over time caused δ¹³C to become significantly enriched in air (Rabbitfish, Mantis Shrimp and Crab) and in ice (Rabbitfish only), though this change was small: 0.2‰ to 0.4‰ over 120 h (Fig 1; Table C in S1 File). For Rabbitfish, this was determined as a main effect of time (χ²₍₁₎ = 9.07, P < 0.01, R²_GLMM(m) = 0.02; Table C in S1 File) indicating δ¹³C was enriched in both air and ice, while for Mantis Shrimp and Crab, significant interactions provided evidence of change in δ¹³C over time that was dependent upon treatment (Mantis Shrimp: χ²₍₁₎ = 8.80, P < 0.01, R²_GLMM(m) = 0.13; Crab: χ²₍₁₎ = 9.88, P < 0.01, R²_GLMM(m) = 0.59; Table C in S1 File). Conversely, for molluscs we only had δ¹³C +L data, and we observed decomposition over time caused δ¹³C to become significantly depleted in both air and ice (Bivalve only) by 0.3‰ over 120 h (main effect of time: χ²₍₁₎ = 16.40, P < 0.001, R²_GLMM(m) = 0.13; Fig 1; Table D in S1 File). However, we suspected this result was likely due to lipid affecting Bivalve δ¹³C values. This was supported by the crustacean results, which showed tissue decomposition in air depleted δ¹³C (Mantis Shrimp) or had no effect (Crab) when using δ¹³C +L data (Fig 1; Table D in S1 File) but enriched δ¹³C when using δ¹³C -L data (Fig 1; Table C in S1 File). Thus, these conflicting results clearly demonstrate the need to account for lipids to accurately estimate δ¹³C and thus, that only our δ¹³C results based on δ¹³C -L data are reliable.

%N. For fish and crustacean analyses, significant interactions indicated that time affected %N but that this was dependent upon treatment (Grouper: χ²₍₁₎ = 16.17, P < 0.001, R²_GLMM(m) = 0.59; Rabbitfish: χ²₍₁₎ = 23.38, P < 0.001, R²_GLMM(m) = 0.71; Mantis Shrimp: χ²₍₁₎ = 29.30, P < 0.01, R²_GLMM(m) = 0.78; Crab: χ²₍₁₎ = 7.07, P < 0.01, R²_GLMM(m) = 0.52; Fig 1; Table E is S1 File). For these species, tissues kept in air showed decreases in %N ranging from 0.47 to 3.43 percentage points over 120 h (c.f. starting values at 0 h of ~13%), while %N of tissues kept in ice did not change over time (Fig 1; Table E in S1 File).

%C. For fish and Mantis Shrimp analyses, significant interactions indicated that time affected %C but that this was dependent upon treatment (Grouper: χ²₍₁₎ = 11.20, P < 0.001, R²_GLMM(m) = 0.48; Rabbitfish: χ²₍₁₎ = 42.33, P < 0.001, R²_GLMM(m) = 0.85; Mantis Shrimp: χ²₍₁₎ = 25.92, P < 0.001, R²_GLMM(m) = 0.66; Fig 1; Table F in S1 File). For these species, tissues kept in air showed decreases in %C ranging from 4.53 to 8.29 percentage points over 120 h (c.f. starting values at 0 h of ~43%), while %C of tissues kept in ice did not change over time (Fig 1; Table F in S1 File).

C:N ratio. For Grouper and crustacean analyses, significant interactions indicated that time affected C:N ratios but that this was dependent upon treatment (Grouper: χ²₍₁₎ = 5.64, P < 0.05, R²_GLMM(m) = 0.30; Mantis Shrimp: χ²₍₁₎ = 17.95, P < 0.001, R²_GLMM(m) = 0.71; Crab: χ²₍₁₎ = 11.16, P < 0.001, R²_GLMM(m) = 0.68; Fig 1; Table G in S1 File). For these species, in each instance, tissues kept in air showed increases in C:N ratios ranging from 0.14 to 0.75 over 120 h, while tissues kept in ice did not change (Fig 1; Table G in S1 File). Increases in C:N ratio suggested greater proportional deceases in %N than %C when compared to their respective starting values at 0 h, despite absolute decreases in percentage points (reported above) being greater in %C than %N. The magnitude of changes in C:N ratios should be compared with a mean C:N ratio across all species at 0 h of 3.31 ± 0.22 SD.

Experiment 2 ― Q2. Does tissue decomposition affect tissue lipid content or relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C?

Lipid content.

Across all samples, lipid content ranged between 3.27% and 29.20% (Mean ±SD = 14.55% ± 7.39). Analysis revealed lipid content of fish tissues was not affected by the interaction (χ²₍₁₎ = 3.33, P = 0.07) or main effects of time (χ²₍₁₎ = 1.34, P = 0.25) and treatment (χ²₍₁₎ = 1.93, P = 0.16) (Table H in S1 File). Thus, observed changes in lipid content with time (between 0 and 120 h) were inconsistent between individuals and across species. Variation in lipid content across repeated measures within individuals ranged between 2.97% to 12.14%.

Relationships between C:N ratio, lipid content and Δδ¹³C.

LMMs tested if relationships between (i) lipid content and Δδ¹³C, (ii) C:N ratio and lipid content, and (iii) C:N ratio and Δδ¹³C were significantly different across six levels of the composite variable ‘combined treatment’ (6 level factor: Air 0h, A 60h, A 120h, Ice 0h, I 60h, I 120h). Per each relationship in (i), (ii) and (iii), combined treatment was not significant either as an interaction (χ²₍₅₎ = 7.72, P = 0.17; χ²₍₅₎ = 10.19, P = 0.07; χ²₍₅₎ = 8.40, P = 0.14, respectively) or main effect (χ²₍₅₎ = 10.30, P = 0.07; χ²₍₅₎ = 7.57, P = 0.18; χ²₍₅₎ = 7.44, P = 0.19, respectively). Thus, our analyses did not detect any evidence for tissue decomposition affecting significant relationships between lipid content and Δδ¹³C (χ²₍₁₎ = 55.84, P < 0.001, R²_GLMM(m) = 0.88, intercept ± SE = 0.26 ± 0.13, slope ± SE = 0.10 ± 0.01), C:N ratio and lipid content (χ²₍₁₎ = 63.51, P < 0.001, R²_GLMM(m) = 0.92, intercept = -28.63 ± 2.37, slope = 10.27 ± 0.56), C:N ratio and Δδ¹³C (χ²₍₁₎ = 61.40, P < 0.001, R²_GLMM(m) = 0.84, intercept = -2.79 ± 0.36, slope = 1.09 ± 0.08). Though no significant differences were detected between slopes and intercepts of levels of combined treatment, we report the individual combined treatment levels for relationships (i), (ii) and (iii) in Fig 2.

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Fig 2.

Significant relationships between (a) lipid content and Δδ¹³C (b) C:N ratio and lipid content and, (c) C:N ratio and Δδ¹³C of fish muscle tissues were not affected by exposure to air or ice over 120 h. Per (a), (b) and (c), modelled slopes and raw data for each exposure time (0, 60 and 120 h) in air (red lines) and ice (blue lines) are shown, although they do not significantly differ from one another. Model estimates of slopes, intercepts and model variance explained (R²) are also given.

https://doi.org/10.1371/journal.pone.0199680.g002

Q3. Are alternative methodologies for estimating δ¹³C differentially affected by tissue decomposition? Separate analyses per methodological procedure using LMMs showed that tissue decomposition over time in either air or ice did not affect estimates of standardised δ¹³C (the difference between sample δ¹³C and baseline δ¹³C) derived from samples that were uncorrected (χ²₍₅₎ = 9.41, P = 0.09), mathematically corrected (χ²₍₅₎ = 3.90, P = 0.56) or lipid extracted (χ²₍₃₎ = 2.07, P = 0.56). Subsequently, all data was pooled, and using a LMM we observed that methodological procedure (3 level factor: uncorrected, mathematically corrected, lipid extracted) significantly affected standardised δ¹³C (χ²₍₂₎ = 134.59, P < 0.001, R²_GLMM(m) = 0.69). Post-hoc analysis revealed that standardised δ¹³C of uncorrected samples was significantly lower than mathematically corrected (difference ± SE = 1.7‰ ± 0.1, t.ratio = 16.07, df = 84, P < 0.001) and lipid extracted (difference ± SE = 1.8‰ ± 0.1, t.ratio = 14.92, df = 84, P < 0.001), while mathematically corrected and lipid extracted samples did not differ (difference ± SE = 0.1‰ ± 0.1, t.ratio = 0.55, df = 84, P = 0.85) (Fig 3). Thus, lipid extraction and mathematical correction both produced estimates of δ¹³C that approximated a δ¹³C baseline, while the use of uncorrected samples (where lipid content was not removed or accounted for) resulted in δ¹³C estimates that were between 0.6‰ and 3.8‰ depleted compared to the baseline value of δ¹³C.

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Fig 3. Standardised δ¹³C of fish muscle tissue was not affected by tissue decomposition over 120 h in either air or ice, but was dependent upon methodological procedure.

Standardised δ¹³C of a sample was the difference in the sample’s δ¹³C from a lipid extracted value of δ¹³C at 0 h, termed baseline δ¹³C. Baseline δ¹³C is indicated as a dashed grey line at y = 0. Standardised δ¹³C of lipid extracted (triangles) and a posteriori mathematically corrected (circles) samples did not differ from one another and were typically small (range -0.8‰ to 0.3‰). By contrast, standardised δ¹³C of uncorrected samples (crosses) were significantly depleted (range -0.6‰ to -3.8‰) compared to lipid extracted and mathematically corrected samples.

https://doi.org/10.1371/journal.pone.0199680.g003