http://orcid.org/0000-0002-4192-6956
Figures
Abstract
Anthropogenic pressures, such as contaminant exposure, may affect stable isotope ratios in biota. These changes are driven by alterations in the nutrient allocation and metabolic pathways induced by specific stressors. In a controlled microcosm study with the amphipod Gammarus spp., we studied effects of the β-blocker propranolol on stable isotope signatures (δ15N and δ13C), elemental composition (%C and %N), and growth (protein content and body size) as well as biomarkers of oxidative status (antioxidant capacity, ORAC; lipid peroxidation, TBARS) and neurological activity (acetylcholinesterase, AChE). Based on the known effects of propranolol exposure on cellular functions, i.e., its mode of action (MOA), we expected to observe a lower scope for growth, accompanied by a decrease in protein deposition, oxidative processes and AChE inhibition, with a resulting increase in the isotopic signatures. The observed responses in growth, biochemical and elemental variables supported most of these predictions. In particular, an increase in %N was observed in the propranolol exposures, whereas both protein allocation and body size declined. Moreover, both ORAC and TBARS levels decreased with increasing propranolol concentration, with the decrease being more pronounced for TBARS, which indicates the prevalence of the antioxidative processes. These changes resulted in a significant increase of the δ15N and δ13C values in the propranolol-exposed animals compared to the control. These findings suggest that MOA of β-blockers may be used to predict sublethal effects in non-target species, including inhibited AChE activity, improved oxidative balance, and elevated stable isotope ratios. The latter also indicates that metabolism-driven responses to environmental contaminants can alter stable isotope signatures, which should be taken into account when interpreting trophic interactions in the food webs.
Citation: Ek C, Garbaras A, Yu Z, Oskarsson H, Wiklund A-KE, Kumblad L, et al. (2019) Increase in stable isotope ratios driven by metabolic alterations in amphipods exposed to the beta-blocker propranolol. PLoS ONE 14(5): e0211304. https://doi.org/10.1371/journal.pone.0211304
Editor: Samantha E. M. Munroe, University of Adelaide, AUSTRALIA
Received: January 10, 2019; Accepted: May 5, 2019; Published: May 16, 2019
Copyright: © 2019 Ek 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 manuscript and Supporting Information.
Funding: The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. The work was supported by the Swedish Institute, Sweden (www.si.se) via Isotope ecology network in the Baltic Sea region (grant number 12906/2013 to EG), State Key Laboratory of Pollution Control and Resource Reuse Foundation (Tongji University, China) (grant number PCRRIC16003; ZY), and by the Swedish Research Council (www.vr.se) as a part of CHEMSTRRES project (grant number 639-2013-6913; EG).
Competing interests: The authors have declared that no competing interests exist.
Introduction
In human physiology, the natural variations of the isotopic ratios of carbon, nitrogen and other major elements comprising biomass (δ15N, δ13C, δ18O, δ2H, δ44/40Ca, etc.) are attracting increasing attention since they offer a new means to study the imbalances linked to pathological conditions [1,2]. In non-human biology, however, the physiology of a consumer is rarely coupled to δ15N and δ13C values that are assumed to be a bare reflection of the diets’ isotope composition plus a discrimination factor (Δ15N and Δ13C, respectively). There is ample evidence that consumer Δ-values and the isotopic signatures may vary depending on various endogenous and environmental factors via their effects on metabolism and growth. These factors include variations in moulting status [3], food quantity [4,5] and quality [6], temperature [7,8], and contaminant exposure [9]. Therefore, to improve interpretation of stable isotope analysis (SIA) data in stress ecology and ecotoxicology, it is crucial to consider the physiological state in addition to the potential dietary sources of the consumer.
In line with this, isotope signatures have been reported to respond to changes in oxidative status [10], suggesting that both δ15N and δ13C values can reflect not only the diet but also shifts in the balance between antioxidative and pro-oxidative processes. Such shifts are not particularly unexpected because heavier isotopes have been found to accumulate in molecules in which they are present in the highest oxidation state [11]. Oxidative stress is commonly used to assess toxic exposure [12] and various metabolic activities related to oxidative balance, such as feeding [13] and reproduction [14]. Therefore, by combining biomarkers and SIA data, the assessment of trophic structure based on SIA can be facilitated by including responses to confounding factors, such as toxic exposure, migratory activity, and food levels. It has also been proposed that major biomolecules (i.e., proteins, nucleic acids, and lipids) enriched in heavy isotopes might be less prone to the oxidative damage due to kinetic effects and higher stability [15,16]. Hence, organisms and tissues with higher isotope signatures would display lower oxidative damage. On the other hand, under toxic exposure variations in δ-values may be explained by changes in the relative abundance of heavy and light isotopes due to the elevated oxidation.
Studies exploring the effects of contaminants on δ15N and δ13C values have mostly focused on persistent organic pollutants (POPs) [8,9,17,18]. POPs are known to cause deleterious effects in wildlife via oxidative stress, increased physiological costs, and neurotoxicity [12]. A group of very different environmental contaminants is pharmaceuticals. First, they are designed to be biologically active in living organisms by having a specific drug target, which is a molecular structure that undergoes a specific interaction, i.e., the mechanism of action (MOA), with the drug administered to treat or diagnose a disease. MOA connects specific molecular and metabolic interactions to the response, but for most drugs, several (if not many) targets are known [19]. Second, the potency of a pharmaceutical for a non-target organism is dependent on whether drug targets are evolutionary conserved [20], and unknown targets and MOAs for such drugs cannot be excluded in phylogenetically distant species. Whereas the effects of toxic exposure on stable isotope ratios are often associated with increased physiological costs due to detoxification [21], such effects of pharmaceuticals may result from the intended therapeutic effects or side effects. Hence, to understand changes in the isotopic composition of non-target species exposed to pharmaceuticals in the environment, the specific MOAs need to be considered.
Propranolol is a non-selective β-blocker used to treat hypertension in humans by acting as an antagonist to the adrenergic β-receptors. In mammals, in addition to lowering blood pressure and heart rate, propranolol has been reported to lower protein turnover via modulation of both protein synthesis and catabolism [22,23]. Furthermore, it also possesses antioxidant properties by stabilizing lysosomes [24] and, thus, reducing oxidative stress [25]. For crustaceans, it appears as there exist no adrenergic receptors in the cardiovascular system [26], which would indicate low potency for a propranolol effect. However, propranolol is also a serotonin receptor (5-HT) antagonist [27] for which there are evolutionarily conserved receptors in crustaceans and other invertebrates [28,29]. In bivalves, for example, propranolol exposure has been linked to altered cyclic adenosine monophosphate (cAMP) signaling via the 5-HT1 receptor [30], suggesting that effects on cAMP signaling in invertebrates, including crustaceans, can occur and cause downstream alterations in catabolic, anabolic and transport processes. Moreover, because of the overlapping adrenergic and cholinergic innervation in many systems, drugs acting on one system are known to modify the activity of the other. That is also the case with propranolol, which inhibits cholinesterase (ChE) enzyme activity [31]. In line with these MOAs, propranolol has been found to reduce heart rate in Daphnia magna [32] and motility in Gammarus spp. [33]. Therefore, propranolol presents a suitable model substance to predict effects of pharmaceuticals on isotope ratios in crustaceans and to test the relationships between oxidative stress and isotope ratios, as a consequence of contaminant-induced changes in the physiology.
In oxidative status assessment, total oxygen radical absorbance capacity (ORAC) and lipid peroxidation (TBARS) are common biomarkers of antioxidative and pro-oxidative processes, respectively [13]. The antioxidant capacity (ORAC) reflects concentrations of water-soluble antioxidants, the substances that delay or prevent the oxidation of biomolecules by reactive oxygen species, ROS [34]. When pro-oxidative processes dominate, the reaction between ROS and lipids gives rise to lipid peroxidation that causes functional loss of membrane-stability. Such shifts in the oxidative status have been linked to several diseases and aging [35]. Also, the ORAC:TBARS ratio can serve as a proxy for the balance between the antioxidative and pro-oxidative processes with lower values indicating the prevalence of oxidation [36]. The activity of acetylcholinesterase (AChE) is central for maintaining the function of acetylcholine receptors by degrading the neurotransmitter acetylcholine; various neuropathologies, including decreased cardiac output and motility, occur in animals with AChE inhibition [37].
This study aimed to evaluate whether the MOAs of propranolol can be used to predict its effects on stable isotope ratios and oxidative stress biomarkers in crustaceans (Table 1; Fig 1). We assayed elemental composition (percentages of carbon and nitrogen, %C and %N, respectively), stable isotope ratios (δ15N and δ13C) and biomarkers of oxidative stress (ORAC, TBARS, and ORAC:TBARS ratio) and neurological damage (AChE activity) in amphipods (Gammarus spp.) exposed to propranolol (100 and 1000 μg L-1) in microcosms. These test concentrations are high compared to the ecologically relevant concentrations, which have been reported to be in the upper range of 0.29–1.9 and 0.59 μg L-1 for sewage treatment plant effluent and surface waters, respectively [38,39]. However, using high concentrations was considered appropriate, because we were not focused on assessing the effects of environmentally relevant concentrations of propranolol in non-target species but investigated the overall predictably of these effects.
The negative effects are shown as arrows pointing down and positive effects as arrows pointing up. The orange arrows depict measured effects, whereas grey arrows indicate effects that were not accessed but appear plausible considering propranolol MOA and literature. See Table 1 for the rationale for specific effects.
Propranolol (μg L-1); %N, nitrogen content; %C, carbon content, WW, wet weight; ORAC, oxygen radical absorbance capacity as proxy for antioxidative capacity; AChE, acetylcholinesterase activity; ORAC:TBARS ratio, a proxy for the balance between antioxidative and pro-oxidative activities. Significant predictors are in bold face.
Material and methods
Microcosms
The model communities consisting of amphipods (Gammarus spp.), blue mussels (Mytilus edulis trossulus), red filamentous macroalgae (Ceramium tenuicorne), were exposed to 0, 100 and 1000 μg L-1 propranolol in 8-L aquaria for six weeks, five aquaria per treatment. Animals and sediment used in the microcosms were collected in June 2011 nearby Askö laboratory, in the northern Baltic proper, Sweden. Details on sampling, sediment collection and quality are presented elsewhere [40]. In each of the 15 aquaria, 30 amphipods, 31 mussels, and 8.3 g WW C. tenuicorne were placed. Before the experiment, microcosms were acclimated for seven days in a climate chamber with a water temperature of 12.5 ± 0.5°C and a 16:8 h light:dark regime; the same conditions were used during the experiment. The microcosms were connected to a flow-through system with seawater (salinity 6.5 PSU) entering each aquarium via a PVC tubing allowing for the daily exchange of the total water volume. Propranolol was dissolved in dilute phosphoric acid (0.1 mM; pH adjusted to 7.1 using sodium carbonate). All solutions were prepared and diluted with buffer so that the final concentrations of sodium, phosphate and carbonate ions were identical [33,41]. The propranolol solution was continuously added at the test concentrations via siphons of PTFE Teflon tubing connected to fused silica capillaries from glass reservoirs above the aquaria into each experimental unit. The microalgae (Isochrysis galbana, Reed Mariculture) were added daily ad libitum (7.8 × 107 cells L-1) to ensure a sufficient food supply for the animals. The mortality was recorded daily, and dead animals were removed. Samples for quantification of propranolol in water were taken at day 2 and day 15, and samples for quantification of propranolol in organisms and sediment were taken at the end of the experiment (day 42). Upon termination of the experiment, the wet weight (WW) of the surviving amphipods was determined, and they were frozen individually in Eppendorf tubes at -80°C pending biomarker and stable isotope analysis. The general responses to the exposure (i.e., mortality, respiration, feeding rate, excretion and community-specific gross production and respiration) as well as the concentrations of propranolol quantified for the different compartments are reported elsewhere [40]; mortality and propranolol quantifications for water and amphipods from this study are summarized in Supporting Information, Table A in S1 File. Here, we focus on the propranolol effects on the stable isotope signatures, elemental composition and biomarkers in the amphipods collected within the same experiment as well as the relationships between these endpoints; see Table 1 for the details on expected effects and causal relationships between the endpoints and biomarkers.
Sample preparation
For biomarker and stable isotope analyses, 45 amphipods (15 ind. treatment-1) were used. Using a stereomicroscope and a scalpel, each individual was dissected separating abdominal and thoracic parts; during the dissection, the animals were held on dry ice. The thoracic part was used for biomarker analysis, while the abdominal part was used for δ15N and δ13C analysis. The SIA samples were placed in pre-weighed tin capsules, dried at 60°C for 24 h, weighed and stored in a desiccator before being shipped to the SIA facilities.
Biochemical assays
Sample preparation.
Assessment of oxidative status was conducted using ORAC and TBARS assays, whereas AChE activity was used to evaluate neurological effects of propranolol. Using FastPrep (MP Biomedicals), the samples were homogenized in 500 μL of PPB (0.1 M, pH 7.2) for 30 sec × 2 times with an ice bath (30 sec) in between. After centrifugation (10 000 rpm × 5 min at 4°C), the supernatants from the two tubes were aliquoted to 40, 50 and 150 μL for protein, ORAC, TBARS, and AChE, respectively; the aliquots were frozen at -80°C pending the analyses. All samples were analyzed in duplicate for each biomarker using a FluoStar Optima plate reader (BMG Lab Technologies, Germany) with absorbance (protein and AChE) or fluorescence (ORAC and TBARS) configuration.
Protein quantification.
Protein content (μg ind.−1) was determined by the bicinchoninic acid (BCA) method [42] using a Pierce BCA Protein Assay kit (Thermo Scientific, Product No. 23225) and the microplate protocol with some modifications. In transparent 96-well microplate, 20 μL sample and 130 μL working solution were mixed in each well. Absorbance was measured at 540 nm, and protein concentrations were calculated using a standard curve (18.5–1500 μg mL−1).
ORAC.
We used the microplate-based assay [34] with fluorescein as a fluorescent probe (106 nM), 2,2-azobis(2-amidinopropane), dihydrochloride (AAPH; 152.66 mM) as a source of peroxyl radicals, and Trolox (218 μM) as the standard. The samples were diluted with PPB (0.1 M, pH 7.2) to 0.08–0.12 mg protein mL-1 and 25 μL were mixed with 30 μL AAPH and 150 μL fluorescein in each well. After 5 min incubation at 37°C, a kinetic fluorescence read (excitation 485 nm, emission 538 nm, 2 min/cycle × 65 cycles) was carried out. The values of the area under the curve (AUC) of standards were used to calculate the ORAC levels per individual. These ORAC values were normalized to protein content to account for variability in wet mass.
Lipid peroxidation.
The TBARS was measured as aldehydic lipid peroxidation fluorescent products after reacting with thiobarbituric acid (TBA) [43]. The samples were first diluted with PPB (0.1 M, pH 7.2) to 0.50 mg protein mL-1. Then, homogenate (150 μL) was diluted 1:1 with 10% trichloroacetic acid and rested on ice for 5 min. After centrifugation (10 000 rpm × 5 min at 4°C), the supernatant (250 μL) was mixed with 150 μL of reaction solution (200 mg TBA in 5 mL 1.5 M NaOH and 5 mL acetic acid), and incubated at 100°C for 1 h. After cooling to room temperature and the addition of butanol/pyridine mixture (250 μL; volume ratio 15:1), the samples were vortexed (2 × 10 s) and centrifuged for 5 min at 4000 g at 20°C. The organic phase (upper layer, 80 μL well-1) was used for fluorometric determination (excitation 540 nm, emission 590 nm) of malondialdehyde (MDA) concentration (μM MDA equivalents ind.−1). The MDA concentrations were expressed as TBARS normalized to protein content of the sample.
AChE activity.
Ellman assay [44] modified for a microplate format was used. The reaction solution was freshly prepared by mixing 169 μL acetylthiocholine solution (75 mM), 845 μl DTNB solution (10 mM), and 25.4 mL PPB. In each well, sample (25 μL) was mixed with 250 μL reaction solution. The plate was then incubated for 2 min with a gentle shake in the plate reader, followed by reading absorbance at 405 nm every 2 min with ten cycles. The AChE activity was calculated as:
where slope is calculated through a linear fit between the absorbance change (sample minus blank) and time, F refers to the dilution factor (total volume/sample volume, 275 μL/25 μL), ε is extinction coefficient of DTNB (13600 M-1 cm-1), l is the length of light path length (0.75 cm in the present instrument) and c is the protein concentration (mg mL-1).
Stable isotope ratio analysis
Stable isotope analysis was conducted at the Center for Physical Science and Technology, Vilnius, Lithuania, using a Flash EA 1112 Series Elemental Analyzer connected via a Conflo III to a DeltaV Advantage isotope ratio mass spectrometer (all Thermo Finnigan, Bremen, Germany). The stable isotope ratios 15N:14N and 13C:12C are expressed relative to the international standards atmospheric air (N) and Vienna Pee Dee Belemnite (C). Caffeine (IAEA-600) was used as secondary reference material for the reference gas calibration. Elemental composition of nitrogen and carbon (%N and %C, respectively) are expressed as the percentage content of the sample dry weight. Calibration curves for %N and %C quantification were created using EMA P2 reference material (Elemental Microanalysis). To estimate the analytical precision of δ15N and δ13C, an internal reference (Esox lucius, n = 6) was analyzed together with the test samples. For analytical precision of elemental composition (%N and %C), a series of samples (n = 9) each containing a single individual of the crustacean D. magna collected from a culture (size 340–520 μg) were used. The overall analytical precision was 0.1 ‰ and 0.04 ‰ for δ15N and δ13C, respectively, and 0.02% and 0.09% for %N and %C, respectively.
Data analysis and statistics
To explore the overall variability in the data set, a between-group principal component analysis (bgPCA) was conducted using PAleontological STatistics (PAST) version 3.13 [45]. In the bgPCA, we used a correlation matrix of %N, %C, C:N, protein content, WW, ORAC, TBARS, ORAC:TBARS, AChE, δ15N and δ13C. When necessary, some variables (%C, WW, TBARS, ORAC:TBARS, AChE, δ15N and δ13C) were Box-Cox transformed using Statistica 8.0 (StatSoft, USA).
As the next step, all predictors were evaluated for aquarium effects, because the experimental design did not allow for complete independence between the amphipods sampled from the same experimental unit. Linear mixed models (LMM) with restricted maximum likelihood (REML) was used to test for random effect, i.e., whether the fixed effect of treatment was different between the aquaria. Linear models using generalized least square (GLS) with REML (without random effects) were used as null models to test the hypotheses of a significant aquarium effect for different variables; the resulting models were compared using analysis of variance (ANOVA). When no significant aquarium effect was detected (%N, WW, protein, δ5N, δ13C, and all biomarkers), generalized linear models (GLMs) were used to analyze the data. When this effect was significant (%C and the C:N ratio), the data were analyzed using GLS-REML. Thus, to answer the hypotheses linking specific responses to propranolol effects, we used either GLM (H1 to H6) or GLS-REML (H7; Table 1 and Table B in S1 File). All linear mixed models and linear models using GLS were made using the package Linear and Nonlinear Mixed Effects Models (nlme) version 3.1–118, and for GLMs The R Stats Package (stats) was used in the statistical software R version 3.1.2 (R core team 2015). The significance level was set to α ≤ 0.05. If not specified otherwise, the data are reported as mean and standard deviation.
Results
Principal component analysis
The bgPCA suggested a lower similarity between the animals exposed to the high propranolol concentration (PH) and the control compared to that for the low propranolol (PL) and control groups (Fig 2). The first principal component (PC1) described 85.8% of the variance and was best explained (>0.3) by the negative loadings of %N, ORAC:TBARS ratio, δ15N and δ13C. The PC1 also contributed most to the between-group differences, with positive loadings of C:N ratio, protein content, WW, TBARS, and ORAC. The projection of PH treatment on PC1 suggested that high propranolol exposure coincided with increased %N yet decreased protein content and lowered oxidative damage, i.e., low levels of TBARS and high levels of ORAC:TBARS ratio (Table 2).
The animals exposed to the high propranolol concentration (PH, grey) showed the least overlap with those in Control (open) and low propranolol concentration (PL, beige) groups. PC1 and PC2 explained 85.8% and 14.2% of the variation, respectively. The vectors represent loadings for specific variables (see Table 2).
The PC1 loadings also indicate higher values for both δ15N and δ13C; moreover, this increase was uncoupled from the oxidative status. The PC2 explaining the rest of the variance was mostly (>0.5) associated with positive loadings of %C and AChE. The projection of %C and AChE on the biplot indicated elevated %C in PH treatment and higher AChE activity in controls (Table 2).
Mortality in relation to exposure concentrations
Amphipod mortality was high in all treatments (51–77%; Table A in S1 File, Supporting Information). It decreased with increasing propranolol concentration (GLM: p < 0.03) with significantly lower values in the PH treatment compared to the control amphipods (Tukey test: p < 0.02). The propranolol concentrations in the system were below the quantification limit in the control treatment, whereas the levels in the water were close to the nominal concentrations for both the PL and PH treatment: 108 ± 5.8 μg L-1 and 1058 ± 37 μg L-1, respectively (mean ± SE). Moreover, the concentrations measured in amphipods were twice as high in the PH treatment compared to PL, 6.3 and 3.2 μg g WW-1, respectively (Table A in S1 File).
Hypothesis testing
H1: As hypothesized, the nitrogen content was significantly positively affected by propranolol concentration, with %N varying from 8.2% in PL and control to 8.6% in the PH treatment (Table 3; Fig 3A).
The elemental composition (%C and %N) and the C:N ratio in amphipods (A), body size and protein content (B), biomarkers of oxidative stress (antioxidant capacity assayed as ORAC; lipid peroxidation assayed as TBARS; and the balance between antioxidative and pro-oxidative activities assayed as the ORAC:TBARS ratio) (C), and stable isotope composition (δ15N and δ13C) (D) in the amphipods exposed to propranolol. Control (0 μg L-1 propranolol), PL (Propranolol Low; 100 μg L-1 propranolol), PH (Propranolol High; 1000 μg L-1 propranolol). Data are shown as group means and error bars represent min and max values; n = 15 in all cases. See Table C in S1 File (Supplementary Information) for the mean and SE values for each variable and treatment and Table 3 and Table B in S1 File for the GLM output testing treatment effects.
Propranolol, concentration of propranolol (μg L-1); %N, nitrogen content; %C, carbon content; WW, wet weight; TBARS, thiobarbituric acid reactive substances as proxy for reactive oxygen species; ORAC, oxygen radical absorbance capacity as proxy for antioxidative capacity; AChE, acetylcholinesterase activity. When used as response variables, the values for WW, AChE, TBARSp, δ15N and δ13C were Box-Cox transformed.
H2: The protein content variability was significantly positively related to %N, with a significant negative propranolol × %N interaction effect, indicating that at higher propranolol concentration less nitrogen was allocated to proteins (Table 3).
H3: The amphipods from the PH treatment had the lowest WW; they were by 4% and 17% smaller compared to the PL and control groups, respectively (Fig 3B). The protein content was the best positive predictor of WW (Table 3).
H4-6: As hypothesized, the TBARS levels were negatively related to the propranolol concentration, with the lowest values observed in the PH treatment where were lower by 17% and 35% compared to those measured in the PL and control amphipods, respectively (Fig 3C). Also, a significant inhibition of AChE activity was observed in propranolol-exposed animals. The ORAC values were significantly positively related to WW; moreover, a significant positive relationship between AChE and the ORAC:TBARS ratio was found (Table 3).
H7-8: The δ15N values were significantly positively related to propranolol concentration and the ORAC:TBARS ratio (Table 3). Thus, the δ15N values were elevated in the animals exposed to propranolol and with the prevalence of the antioxidants. In PH treatment, the δ15N values were higher by 0.7 ‰, with mean values of 4.8 ‰ compared to 4.1–4.2 ‰ in PL and control groups (Fig 3D). As hypothesised, the δ13C values were best explained by propranolol concentration and %C as significant positive and negative predictors, respectively. The amphipod δ13C values in the PH treatment (-22.7 ‰) were elevated by ~1 ‰, compared to the PL (-23.3 ‰) and control (-23.7 ‰) animals (Fig 3D).
Discussion
In animals, the majority of drugs either (i) mimic or inhibit normal physiological/biochemical processes; (ii) inhibit pathological processes; or (iii) inhibit vital processes of endo- or ectoparasites/microorganisms. Our study aimed to evaluate whether exposure to propranolol that belongs to the first group would cause predictable effects in crustaceans with regard to their stable isotope ratios and oxidative status. Based on the known targets and MOAs of propranolol, we expected to observe a lower scope for growth, improved oxidative balance, and AChE inhibition. As isotopic fractionation is a function of growth and metabolism [5], we expected to observe higher δ-values in the exposed animals. Most of the hypothesized effects (Table 1; Fig 1) were indeed observed, albeit only because of the magnitude of responses in the highest propranolol concentration (1058 μg L-1). The two exposure concentrations resulted in internal propranolol concentrations (3–6 μg g-1) that were within the range of the therapeutic concentrations reported in rabbit (~5 μg g-1) and human (0.47–11.67 μg g-1) brain, respectively [46]; thus, the exposure levels were consistent with the therapeutic doses for this drug.
As hypothesized (H1), the nitrogen content was positively related to propranolol concentration and in agreement with the increased nitrogen retention observed in propranolol-exposed rats [23]. The positive effect of %N on the protein content (H2) was not particularly surprising as nitrogen constitute about 15–17% of cell protein [47,48]. However, the significant propranolol × %N interaction effect on protein content indicates that with increasing dose, less nitrogen was allocated to proteins. The decrease in protein-bound nitrogen (and a concomitant increase in non-protein nitrogen, presumably as ammonia) is in line with the elevated nitrogen excretion induced by propranolol in humans [49]. Also, a part of the non-protein nitrogen could have been associated with free amino acids or shorter peptides, indicating either an elevated breakdown or slow synthesis of proteins [22]. It is also possible, however, that in the slow-growing animals, the relative contribution of the exoskeleton to body mass was higher compared to that in the amphipods growing faster, which would result in the overall decrease of the protein-bound nitrogen in the former.
The consequence of the propranolol-induced inhibition of protein synthesis is growth inhibition that was both biologically (up to 17%) and statistically significant (Table 3). The reduced growth could be a consequence of a reduced food intake related to behavioral change and slow feeding in the propranolol treatments as described for rabbits [50] and bivalves [51]. In these studies, the reduced growth rate was associated with reduced food intake as a result of the propranolol exposure and not related to the β-adrenoreceptor-blocking activity of the drug. Moreover, the inhibited AChE activity observed in the propranolol-exposed amphipods (this study) and mussels [51,52] is also a manifestation of the behavioural response contributing to the possible decline in motility and food acquisition [53,54]. Interestingly, the observed growth inhibition was not translated into higher mortality in the exposed animals. On the contrary, the mortality was significantly lower in the highest propranolol concentration compared to the controls, suggesting that changes in energy budget exerted by the exposure were promoting lower biomass accumulation yet increased survivorship. Such trade-offs between individual growth and mortality are well-known in ecology and occur both inter-and intra-specifically as a part of general adaptation and fitness optimization processes [55].
The oxidative balance assayed as lipid peroxidation (TBARS) and ORAC:TBARS ratio was predicted to improve in the propranolol exposure (H4; Fig 3C). Indeed, the levels of TBARS were ~17% and 35% lower in PH compared to PL and the control, respectively, which is in line with reports showing an ameliorating effect of propranolol on lipid peroxidation [24,25]. However, no direct effects of propranolol on the antioxidant levels and no relationship between ORAC and TBARS (H5) were found. The amphipod body size was the single best predictor for ORAC, with smaller amphipods having lower ORAC levels. The opposite, i.e., a decrease in antioxidant capacity with increasing body size/age, has been reported for animals across multiple ontogenetic stages and broad size span [56,57]. In our experiment, however, the amphipods were within a relatively narrow size range (1.1 to 1.5 cm) and, thus, the ontogenetic component was not likely to be detectable. Instead, the smaller body size in the propranolol treatments may reflect a decrease in food consumption and concomitant intake of dietary antioxidants resulting in lower ORAC levels. Finally, accelerated growth itself is a pro-oxidative process that drives elevated antioxidant production [58], which implies that slower-growing individuals would have lower ORAC values.
Both propranolol exposure and the oxidative balance were significant predictors of the AChE inhibition. However, contrary to Hypothesis 6, the relationship between AChE and ORAC:TBARS ratio was positive (Table 3). In humans, the positive effect of moderate oxidative stress on AChE activity has been linked to hydrogen peroxide-mediated inactivation of the enzyme [59], with concomitant positive feedback on AChE expression. Similar feedback between AChE activity and oxidative status has previously been suggested for the amphipod Monoporeia affinis exposed to contaminated sediments and hypoxia [60]. The latter study also reported a significant positive relationship between AChE and the RNA:DNA ratio, which is in line with the observed decrease in physical activity and feeding rate in Gammarus in concert with AChE inhibition [54] and the observed propranolol effects on growth and AChE (this study). Therefore, propranolol-induced inhibition of AChE may, at least in part, explain effects attributed to the antagonistic effects of propranolol on the serotonin receptor [61]. For instance, the reduced motility and feeding rate due to neurological impairments could reduce both antioxidant intake and oxidative damage, thus corroborating the observed ORAC and TBARS responses. Taken together, these findings indicate that propranolol-induced AChE inhibition may play an important role in both sub-organismal and organism-level effects of propranolol exposure in crustaceans (Figure A in S1 File).
As expected (H7-H8), we found significant positive effects of propranolol on both δ15N and δ13C values, whereas body size was not a significant predictor of the isotopic signatures. In crustaceans exposed to organochlorine and PCBs, the effects on δ15N and δ13C values were related to growth and metabolic rates [8,62]. Consequently, the metabolic detoxification costs were implicated in altering energy budget, increasing turnover, and isotope fractionation. However, the exposure to propranolol does not have to increase energy expenditure and, therefore, the mechanisms for the shifts in isotopic fractionation may differ from those acting solely via growth and metabolic turnover. For example, these pathways could involve alterations in cAMP signaling induced by the antagonistic effect of propranolol on the 5-HT1 receptor, previously observed in bivalves [30] or stem from the indirect effects of propranolol on the muscarinic acetylcholine receptors [63]. Changes in metabolic pathways can alter bulk δ15N [64] in response to alterations in 15N fractionation pattern of specific amino acids and their relative abundances [65]. The observed increase in δ15N is, therefore, in line with the significant changes in amino acid concentrations observed in Gammarus exposed to propranolol [66]. This correlative evidence suggests that greater isotope fractionation was related to changes in protein metabolism induced by propranolol.
Also, a shift towards antioxidative processes was associated with higher δ15N values as suggested by the positive effect of the ORAC:TBARS ratio on the δ15N values. This is in line with the hypothsis that isotope-reinforced biomolecules may better resist oxidative damage as was observed in yeasts [16]. In another study with yeasts, heavy hydrogen isotope has been found to confer resistance to oxidative phosphorylation, the major source of cellular ROS [67]. Hence, the 15N-enriched tissues would then emerge as a consequence of selective reactions between ROS and isotopically light biomolecules or as an adaptation to consistently elevated ROS production.
The relationships between isotopic composition and oxidative status are complex, because many dietary and non-dietary factors may affect both isotope markers and biomarkers of oxidative status. In field studies, effects of diet and physiological status on the isotopic signatures are particularly difficult to disentangle, because dietary sources with great differences in their isotopic signatures would mask the isotope effect on the oxidative status and vice versa. For example, a positive relationship between δ15N and oxidative damage in Gentoo penguins [10] was related to a combination of varying intake of antioxidants and foraging efforts associated with oxidative costs. Therefore, laboratory studies are particularly important for understanding the underlying causes of the observed isotope signatures in field studies. Since the amphipods in our study were all presented with the same food options and kept in the confined, controlled environment, no effects of variation in antioxidants for different food sources or differences in specific foraging costs as well as environmental factors may have confounded the isotopic signatures.
In summary, we have shown that the effects of the pharmaceutical propranolol on both stable isotope values and oxidative stress were indeed predictable in Gammarus. More studies are needed to investigate how MOA might be used to predict biomarker, nutrient allocation, and isotopic changes in non-target organisms possessing evolutionarily conserved targets for this drug, and, most probably, other pharmaceuticals with similar effect pathways. Moreover, a positive link between δ15N values and the oxidative balance was predicted and confirmed to exist in the exposed animals, which can be used for interpretation of biomarkers of oxidative stress and stable isotope data in ecotoxicological and ecological surveys. The fact that isotopic signal can be confounded by non-dietary parameters, including environmental stress, is also of high relevance for food web reconstructions based on stable isotope signatures, particularly, in environments chronically exposed to environmental contaminants, including pharmaceuticals.
Supporting information
S1 File. Background experimental data and analysis results.
Additional information on the observed mortality and propranolol levels in amphipod and water samples (Table A), statistical evaluation of the aquarium effects on the measured endpoints (Table B), a summary of the measured endpoints (Table C) and a diagram illustrating pathways leading to isotopic fractionation and affected by propranolol (Figure A).
https://doi.org/10.1371/journal.pone.0211304.s001
(PDF)
Acknowledgments
We acknowledge Gunnar Thorsén and Gabriella Danielsson for their assistance in designing and conducting the mesocosm experiment, and Birgitta Liewenborg for the help with the biochemical analyses.
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