Your search keyword '"Clark, Timothy"' showing total 25 results

1. Estimating maximum oxygen uptake of fishes during swimming and following exhaustive chase - different results, biological bases and applications.

Author

Rees BB, Reemeyer JE, Binning SA, Brieske SD, Clark TD, De Bonville J, Eisenberg RM, Raby GD, Roche D, Rummer JL, and Zhang Y

Subjects

Animals, Oxygen metabolism, Swimming physiology, Fishes physiology, Fishes metabolism, Oxygen Consumption physiology

Abstract

The maximum rate at which animals take up oxygen from their environment (ṀO2,max) is a crucial aspect of their physiology and ecology. In fishes, ṀO2,max is commonly quantified by measuring oxygen uptake either during incremental swimming tests or during recovery from an exhaustive chase. In this Commentary, we compile recent studies that apply both techniques to the same fish and show that the two methods typically yield different mean estimates of ṀO2,max for a group of individuals. Furthermore, within a group of fish, estimates of ṀO2,max determined during swimming are poorly correlated with estimates determined during recovery from chasing (i.e. an individual's ṀO2,max is not repeatable across methods). One explanation for the lack of agreement is that these methods measure different physiological states, each with their own behavioural, anatomical and biochemical determinants. We propose that these methods are not directly interchangeable but, rather, each is suited to address different questions in fish biology. We suggest that researchers select the method that reflects the biological contexts of their study, and we advocate for the use of accurate terminology that acknowledges the technique used to elevate ṀO2 (e.g. peak ṀO2,swim or peak ṀO2,recovery). If the study's objective is to estimate the 'true' ṀO2,max of an individual or species, we recommend that pilot studies compare methods, preferably using repeated-measures designs. We hope that these recommendations contribute new insights into the causes and consequences of variation in ṀO2,max within and among fish species., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

2. Daily thermal variability does not modify long-term gene expression relative to stable thermal environments: A case study of a tropical fish.

Author

Scheuffele H, Todd EV, Donald JA, and Clark TD

Subjects

Animals, Temperature, Acclimatization physiology, Climate, Gene Expression, Fishes genetics, Perciformes genetics

Abstract

Global warming is leading to an increase in the frequency and intensity of extreme weather events, magnifying the breadth of temperatures faced by ectotherms across days and seasons. Despite the importance and ecological relevance of diurnal thermal variability, the vast majority of knowledge on gene expression patterns and physiology stems from animals acclimated to constant temperatures or in the early stages of exposure to a new temperature regime. If heterothermal environments modulate responses differently from constant thermal environments, our existing capacity to forecast impacts of climate warming may be compromised. To address this knowledge gap, we acclimated barramundi (Lates calcarifer) to 23 °C, 29 °C (optimal), 35 °C and to thermal cycling conditions (23-35 °C daily with a mean of 29 °C) and sampled liver and white muscle tissue before acclimation and after 2 and 17 weeks of acclimation. NanoString nCounter technologies were used to measure expression of 20 genes related to metabolism, growth and maintenance of cellular homeostasis. Acclimation to cool and warm conditions caused predictable changes in whole-animal performance (metabolism and growth) and the underlying gene expression patterns. Acclimation to a cycling temperature regime did not change the molecular regulation of metabolism or growth compared with barramundi acclimated to constant 29 °C, nor did it cause any discernible effects on whole-animal performance. However, the heat shock response was higher in the former group, suggesting that barramundi under a daily temperature cycle have an increased need for cellular chaperoning to minimise detrimental effects of temperature on proteins. We conclude that the genetic regulation of metabolism and growth may be more dependent on the mean daily temperature than on the daily temperature range., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

3. The Role of Metabolic Phenotype in the Capacity to Balance Competing Energetic Demands.

Author

Lawrence MJ, Scheuffele H, Beever SB, Holder PE, Garroway CJ, Cooke SJ, and Clark TD

Subjects

Animals, Basal Metabolism, Food, Phenotype, Fishes metabolism, Energy Metabolism

Abstract

AbstractGiven the critical role of metabolism in the life history of all organisms, there is particular interest in understanding the relationship between individual metabolic phenotypes and the capacity to partition energy into competing life history traits. Such relationships could be predictive of individual phenotypic performances throughout life. Here, we were specifically interested in whether an individual fish's metabolic phenotype can shape its propensity to feed following a significant stressor (2-min exhaustive exercise challenge). Such a relationship would provide insight into previous intraspecific observations linking high metabolism with faster growth. Using a teleost fish, the barramundi ( Lates calcarifer ), we predicted that individuals with high standard metabolic rates (SMRs) and maximal metabolic rates (MMRs) would be faster to recover and resume feeding after exercise. Contrary to our prediction, neither SMR nor MMR was correlated with latency to feed after exercise (food was offered at 0.5, 1.5, 3, and 18 h after exercise). Only time after exercise and individual fish ID were significant predictors of latency to feed. Measurements of MMR from the same individuals (three measurements spaced 8-12 d apart) revealed a moderate degree of repeatability ( R = 0.319 ). We propose that interindividual differences in biochemical and endocrine processes may be more influential than whole-organism metabolic phenotype in mediating feeding latency after exercise.

Published

2023

4. Meta-analysis reveals an extreme "decline effect" in the impacts of ocean acidification on fish behavior.

Author

Clements JC, Sundin J, Clark TD, and Jutfelt F

Subjects

Animals, Bias, Coral Reefs, Oceans and Seas, Behavior, Animal drug effects, Fishes physiology, Hydrogen-Ion Concentration, Seawater chemistry

Abstract

Ocean acidification-decreasing oceanic pH resulting from the uptake of excess atmospheric CO2-has the potential to affect marine life in the future. Among the possible consequences, a series of studies on coral reef fish suggested that the direct effects of acidification on fish behavior may be extreme and have broad ecological ramifications. Recent studies documenting a lack of effect of experimental ocean acidification on fish behavior, however, call this prediction into question. Indeed, the phenomenon of decreasing effect sizes over time is not uncommon and is typically referred to as the "decline effect." Here, we explore the consistency and robustness of scientific evidence over the past decade regarding direct effects of ocean acidification on fish behavior. Using a systematic review and meta-analysis of 91 studies empirically testing effects of ocean acidification on fish behavior, we provide quantitative evidence that the research to date on this topic is characterized by a decline effect, where large effects in initial studies have all but disappeared in subsequent studies over a decade. The decline effect in this field cannot be explained by 3 likely biological explanations, including increasing proportions of studies examining (1) cold-water species; (2) nonolfactory-associated behaviors; and (3) nonlarval life stages. Furthermore, the vast majority of studies with large effect sizes in this field tend to be characterized by low sample sizes, yet are published in high-impact journals and have a disproportionate influence on the field in terms of citations. We contend that ocean acidification has a negligible direct impact on fish behavior, and we advocate for improved approaches to minimize the potential for a decline effect in future avenues of research., Competing Interests: Three of the authors (J. Sundin, T. Clark, and F. Jutfelt) have previously raised concerns about, and have requested formal investigations into, the scientific integrity of some studies published by Drs. Philip Munday and Danielle Dixson.

Published

2022

5. Best practices for non-lethal blood sampling of fish via the caudal vasculature.

Author

Lawrence MJ, Raby GD, Teffer AK, Jeffries KM, Danylchuk AJ, Eliason EJ, Hasler CT, Clark TD, and Cooke SJ

Subjects

Animal Welfare, Animals, Blood Specimen Collection methods, Phlebotomy methods, Blood Specimen Collection veterinary, Fishes, Phlebotomy veterinary

Abstract

Blood sampling through the caudal vasculature is a widely used technique in fish biology for investigating organismal health and physiology. In live fishes, it can provide a quick, easy and relatively non-invasive method for obtaining a blood sample (cf. cannulation and cardiac puncture). Here, a general set of recommendations are provided for optimizing the blood sampling protocol that reflects best practices in animal welfare and sample integrity. This includes selecting appropriate use of anaesthetics for blood sampling as well as restraint techniques for situations where sedation is not used. In addition, ideal sampling environments where the fish can freely ventilate and strategies for minimizing handling time are discussed. This study summarizes the techniques used for extracting blood from the caudal vasculature in live fishes, highlighting the phlebotomy itself, the timing of sampling events and acceptable blood sample volumes. This study further discuss considerations for selecting appropriate physiological metrics when sampling in the caudal region and the potential benefits that this technique provides with respect to long-term biological assessments. Although general guidelines for blood sampling are provided here, it should be recognized that contextual considerations (e.g., taxonomic diversity, legal matters, environmental constraints) may influence the approach to blood sampling. Overall, it can be concluded that when done properly, blood sampling live fishes through the caudal vasculature is quick, efficient and minimally invasive, thus promoting conditions where live release of focal animals is possible., (© 2020 The Fisheries Society of the British Isles.)

Published

2020

6. Ocean acidification does not impair the behaviour of coral reef fishes.

Author

Clark TD, Raby GD, Roche DG, Binning SA, Speers-Roesch B, Jutfelt F, and Sundin J

Subjects

Animals, Behavior, Animal, Carbon Dioxide analysis, Hydrogen-Ion Concentration, Oceans and Seas, Coral Reefs, Fishes physiology

Abstract

The partial pressure of CO 2 in the oceans has increased rapidly over the past century, driving ocean acidification and raising concern for the stability of marine ecosystems 1-3 . Coral reef fishes are predicted to be especially susceptible to end-of-century ocean acidification on the basis of several high-profile papers 4,5 that have reported profound behavioural and sensory impairments-for example, complete attraction to the chemical cues of predators under conditions of ocean acidification. Here, we comprehensively and transparently show that-in contrast to previous studies-end-of-century ocean acidification levels have negligible effects on important behaviours of coral reef fishes, such as the avoidance of chemical cues from predators, fish activity levels and behavioural lateralization (left-right turning preference). Using data simulations, we additionally show that the large effect sizes and small within-group variances that have been reported in several previous studies are highly improbable. Together, our findings indicate that the reported effects of ocean acidification on the behaviour of coral reef fishes are not reproducible, suggesting that behavioural perturbations will not be a major consequence for coral reef fishes in high CO 2 oceans.

Published

2020

7. Rising temperatures may drive fishing-induced selection of low-performance phenotypes.

Author

Clark TD, Messmer V, Tobin AJ, Hoey AS, and Pratchett MS

Subjects

Animals, Climate Change, Coral Reefs, Energy Metabolism, Global Warming, Oxygen Consumption, Fisheries, Fishes, Phenotype, Temperature

Abstract

Climate warming is likely to interact with other stressors to challenge the physiological capacities and survival of phenotypes within populations. This may be especially true for the billions of fishes per year that undergo vigorous exercise prior to escaping or being intentionally released from fishing gear. Using adult coral grouper (Plectropomus leopardus), an important fisheries species throughout the Indo-Pacific, we show that population-level survival following vigorous exercise is increasingly compromised as temperatures increase from current-day levels (100-67% survival at 24-30 °C) to those projected for the end of the century (42% survival at 33 °C). Intriguingly, we demonstrate that high-performance individuals take longer to recover to a resting metabolic state and subsequently have lower survival in warm water compared with conspecifics that exercise less vigorously. Moreover, we show that post-exercise mortality of high-performance phenotypes manifests after 3-13 d at the current summer maximum (30 °C), while mortality at 33 °C occurs within 1.8-14.9 h. We propose that wild populations in a warming climate may become skewed towards low-performance phenotypes with ramifications for predator-prey interactions and community dynamics. Our findings highlight the susceptibility of phenotypic diversity to fishing activities and demonstrate a mechanism that may contribute to fishing-induced evolution in the face of ongoing climate change.

Published

2017

8. Remote bioenergetics measurements in wild fish: Opportunities and challenges.

Author

Cooke SJ, Brownscombe JW, Raby GD, Broell F, Hinch SG, Clark TD, and Semmens JM

Subjects

Accelerometry veterinary, Animals, Animals, Wild metabolism, Ecosystem, Electromyography veterinary, Fishes physiology, Heart Rate, Models, Biological, Swimming physiology, Energy Metabolism, Fishes metabolism, Telemetry veterinary

Abstract

The generalized energy budget for fish (i.e., Energy Consumed=Metabolism+Waste+Growth) is as relevant today as when it was first proposed decades ago and serves as a foundational concept in fish biology. Yet, generating accurate measurements of components of the bioenergetics equation in wild fish is a major challenge. How often does a fish eat and what does it consume? How much energy is expended on locomotion? How do human-induced stressors influence energy acquisition and expenditure? Generating answers to these questions is important to fisheries management and to our understanding of adaptation and evolutionary processes. The advent of electronic tags (transmitters and data loggers) has provided biologists with improved opportunities to understand bioenergetics in wild fish. Here, we review the growing diversity of electronic tags with a focus on sensor-equipped devices that are commercially available (e.g., heart rate/electrocardiogram, electromyogram, acceleration, image capture). Next, we discuss each component of the bioenergetics model, recognizing that most research to date has focused on quantifying the activity component of metabolism, and identify ways in which the other, less studied components (e.g., consumption, specific dynamic action component of metabolism, somatic growth, reproductive investment, waste) could be estimated remotely. We conclude with a critical but forward-looking appraisal of the opportunities and challenges in using existing and emerging electronic sensor-tags for the study of fish energetics in the wild. Electronic tagging has become a central and widespread tool in fish ecology and fisheries management; the growing and increasingly affordable toolbox of sensor tags will ensure this trend continues, which will lead to major advances in our understanding of fish biology over the coming decades., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

9. Limited Capacity for Faster Digestion in Larval Coral Reef Fish at an Elevated Temperature.

Author

McLeod IM and Clark TD

Subjects

Animals, Climate Change, Energy Metabolism, Fishes growth & development, Intestines physiology, Larva physiology, Coral Reefs, Digestion, Fishes physiology, Hot Temperature

Abstract

The prevalence of extreme, short-term temperature spikes in coastal regions during summer months is predicted to increase with ongoing climate change. In tropical systems, these changes are predicted to increase the metabolic demand of coral reef fish larvae while also altering the plankton communities upon which the larvae feed during their pelagic phase. The consequences of these predictions remain speculative in the absence of empirical data on the interactive effects of warm temperatures on the metabolism, postprandial processes and growth responses of coral reef fish larvae. Here, we tested the effect of increased temperature on the metabolism, postprandial performance and fine-scale growth patterns of a coral reef fish (Amphiprion percula) in the latter half of its ~11-d larval phase. First, we measured the length and weight of fed versus fasted larvae (N = 340; mean body mass 4.1±0.05 mg) across fine temporal scales at a typical current summer temperature (28.5°C) and a temperature that is likely be encountered during warm summer periods later this century (31.5°C). Second, we measured routine metabolic rate (Mo2 routine) and the energetics of the postprandial processes (i.e., digestion, absorption and assimilation of a meal; termed specific dynamic action (SDA)) at both temperatures. Larvae fed voraciously when provided with food for a 12-hour period and displayed a temperature-independent increase in mass of 40.1% (28.5°C) and 42.6% (31.5°C), which was largely associated with the mass of prey in the gut. A subsequent 12-h fasting period revealed that the larvae had grown 21.2±4.8% (28.5°C) and 22.8±8.8% (31.5°C) in mass and 10.3±2.0% (28.5°C) and 7.8±2.6% (31.5°C) in length compared with pre-feeding values (no significant temperature effect). Mo2 routine was 55±16% higher at 31.5°C and peak Mo2 during the postprandial period was 28±11% higher at 31.5°C, yet elevated temperature had no significant effect on SDA (0.51±0.06 J at 28.5°C vs. 0.53±0.07 J at 31.5°C), SDA duration (6.0±0.6 h vs. 6.5±0.5 h), or the percent of total meal energy used for SDA (SDA coefficient: 10.1±1.3% vs. 13.0±1.7%). Our findings of higher Mo2 routine but similar SDA coefficient at high temperature provide the first empirical evidence that coral reef fish larvae may have to secure more food to attain similar growth rates during warm summer periods, and perhaps with chronically warmer conditions associated with climate change.

Published

2016

10. Ecological Influences and Morphological Correlates of Resting and Maximal Metabolic Rates across Teleost Fish Species.

Author

Killen SS, Glazier DS, Rezende EL, Clark TD, Atkinson D, Willener AS, and Halsey LG

Subjects

Animal Fins anatomy & histology, Animals, Basal Metabolism, Ecosystem, Fishes anatomy & histology, Fishes classification, Gills anatomy & histology, Muscle Proteins, Phylogeny, Swimming physiology, Energy Metabolism physiology, Fishes metabolism

Abstract

Rates of aerobic metabolism vary considerably across evolutionary lineages, but little is known about the proximate and ultimate factors that generate and maintain this variability. Using data for 131 teleost fish species, we performed a large-scale phylogenetic comparative analysis of how interspecific variation in resting metabolic rates (RMRs) and maximum metabolic rates (MMRs) is related to several ecological and morphological variables. Mass- and temperature-adjusted RMR and MMR are highly correlated along a continuum spanning a 30- to 40-fold range. Phylogenetic generalized least squares models suggest that RMR and MMR are higher in pelagic species and that species with higher trophic levels exhibit elevated MMR. This variation is mirrored at various levels of structural organization: gill surface area, muscle protein content, and caudal fin aspect ratio (a proxy for activity) are positively related with aerobic capacity. Muscle protein content and caudal fin aspect ratio are also positively correlated with RMR. Hypoxia-tolerant lineages fall at the lower end of the metabolic continuum. Different ecological lifestyles are associated with contrasting levels of aerobic capacity, possibly reflecting the interplay between selection for increased locomotor performance on one hand and tolerance to low resource availability, particularly oxygen, on the other. These results support the aerobic capacity model of the evolution of endothermy, suggesting elevated body temperatures evolved as correlated responses to selection for high activity levels.

Published

2016

11. Response to Farrell and to Portner and Giomi.

Author

Clark TD, Sandblom E, and Jutfelt F

Subjects

Animals, Climate Change, Fishes physiology, Physiology methods, Respiration

Published

2013

12. Aerobic scope measurements of fishes in an era of climate change: respirometry, relevance and recommendations.

Author

Clark TD, Sandblom E, and Jutfelt F

Subjects

Aerobiosis, Animals, Climate Change, Fishes physiology, Physiology methods, Respiration

Abstract

Measurements of aerobic scope [the difference between minimum and maximum oxygen consumption rate ( and , respectively)] are increasing in prevalence as a tool to address questions relating to fish ecology and the effects of climate change. However, there are underlying issues regarding the array of methods used to measure aerobic scope across studies and species. In an attempt to enhance quality control before the diversity of issues becomes too great to remedy, this paper outlines common techniques and pitfalls associated with measurements of , and aerobic scope across species and under different experimental conditions. Additionally, we provide a brief critique of the oxygen- and capacity-limited thermal tolerance (OCLTT) hypothesis, a concept that is intricately dependent on aerobic scope measurements and is spreading wildly throughout the literature despite little evidence for its general applicability. It is the intention of this paper to encourage transparency and accuracy in future studies that measure the aerobic metabolism of fishes, and to highlight the fundamental issues with assuming broad relevance of the OCLTT hypothesis.

Published

2013

13. Characterization of the hemoglobins of the Australian lungfish Neoceratodus forsteri (Krefft).

Author

Rasmussen JR, Wells RM, Henty K, Clark TD, and Brittain T

Subjects

2,3-Diphosphoglycerate blood, Adaptation, Physiological, Adenosine Triphosphate blood, Animals, Fishes physiology, Guanosine Triphosphate blood, Hydrogen-Ion Concentration, Isoelectric Point, Molecular Weight, Oxyhemoglobins chemistry, Partial Pressure, Phytic Acid blood, Protein Conformation, Protein Isoforms, Sodium Chloride blood, Structure-Activity Relationship, Fishes blood, Hemoglobins metabolism, Oxygen blood, Oxyhemoglobins metabolism

Abstract

We examined for the first time the hemoglobin components of the blood of the Australian lungfish, Neoceratodus forsteri and their functional responses to pH and the allosteric modulators adenosine triphosphate (ATP), guanosine triphosphate (GTP), 2,3-bisphosphoglyceric acid (BPG) and inositol hexaphosphate (IHP) at 25 degrees C. Lysates prepared from stripped, unfractionated hemolysate produced sigmoidal oxygen equilibrium curves with high oxygen affinity (oxygen partial pressure required for 50% hemoglobin saturation, p(50)=5.3 mmHg) and a Hill coefficient of 1.9 at pH 7.5. p(50) was 8.3 and 4.5 mmHg at pH 6 and 8, respectively, which corresponded to a modest Bohr coefficient (Delta log p(50)/Delta pH) of -0.13. GTP increased the pH sensitivity of oxygen binding more than ATP, such that the Bohr coefficient was -0.77 in the presence of 2 mmol L(-1) GTP. GTP was the most potent regulator of hemoglobin affinity, with concentrations of 5 mmol L(-1) causing an increase in p(50) from 5 to 19 mm Hg at pH 7.5, while the order of potency of the other phosphates was IHP>ATP>BPG. Three hemoglobin isoforms were present and each contained both alpha and beta chains with distinct molecular weights. Oxygen affinity and pH-dependence of isoforms I and II were essentially identical, while isoform III had a lower affinity and increased pH-dependence. The functional properties of the hemoglobin system of Neoceratodus appeared consistent with an active aquatic breather adapted for periodic hypoxic episodes.

Published

2009

14. Continuous measurement of oxygen tensions in the air-breathing organ of Pacific tarpon (Megalops cyprinoides) in relation to aquatic hypoxia and exercise.

Author

Seymour RS, Farrell AP, Christian K, Clark TD, Bennett MB, Wells RM, and Baldwin J

Subjects

Animals, Fiber Optic Technology, Optical Fibers, Partial Pressure, Respiratory Mechanics, Time Factors, Air, Fishes physiology, Hypoxia physiopathology, Oxygen pharmacokinetics, Respiration, Respiratory System metabolism, Swimming

Abstract

The Pacific tarpon is an elopomorph teleost fish with an air-breathing organ (ABO) derived from a physostomous gas bladder. Oxygen partial pressure (PO(2)) in the ABO was measured on juveniles (238 g) with fiber-optic sensors during exposure to selected aquatic PO(2) and swimming speeds. At slow speed (0.65 BL s(-1)), progressive aquatic hypoxia triggered the first breath at a mean PO(2) of 8.3 kPa. Below this, opercular movements declined sharply and visibly ceased in most fish below 6 kPa. At aquatic PO(2) of 6.1 kPa and swimming slowly, mean air-breathing frequency was 0.73 min(-1), ABO PO(2) was 10.9 kPa, breath volume was 23.8 ml kg(-1), rate of oxygen uptake from the ABO was 1.19 ml kg(-1) min(-1), and oxygen uptake per breath was 2.32 ml kg(-1). At the fastest experimental speed (2.4 BL s(-1)) at 6.1 kPa, ABO oxygen uptake increased to about 1.90 ml kg(-1) min(-1), through a variable combination of breathing frequency and oxygen uptake per breath. In normoxic water, tarpon rarely breathed air and apparently closed down ABO perfusion, indicated by a drop in ABO oxygen uptake rate to about 1% of that in hypoxic water. This occurred at a wide range of ABO PO(2) (1.7-26.4 kPa), suggesting that oxygen level in the ABO was not regulated by intrinsic receptors.

Published

2007

15. Effects of an unprecedented summer heatwave on the growth performance, flesh colour and plasma biochemistry of marine cage-farmed Atlantic salmon (Salmo salar).

Author

Wade, Nicholas M., Clark, Timothy D., Maynard, Ben T., Atherton, Stuart, Wilkinson, Ryan J., Smullen, Richard P., and Taylor, Richard S.

Subjects

*ATLANTIC salmon, *OCEAN temperature, *FOOD production, *THERMAL resistance, *OSMOREGULATION, *FISHES

Abstract

Abstract Global seawater temperatures are increasing and becoming more variable, with consequences for all marine animals including those in food production systems. In several countries around the world,arming of Atlantic salmon (Salmo salar) occurs towards the upper end of the thermal tolerance window for this species, and marked effects on salmon production during summers have been experienced but never empirically investigated. This project tracked the effects of an extreme summer heatwave on two different cohorts of fish stocked into farm cages either during early winter (EW) or late winter (LW). The farm site experienced an unprecedented high water temperature event, with a peak water temperature of 22.9 °C and 117 days above 18 °C. Fish in both EW and LW cohorts experienced a temperature-induced cessation of voluntary feed intake as well as inefficient osmoregulatory, liver and renal function during high temperature periods. Flesh colour declined primarily in the dorsal and ventral regions of the fillet and secondarily along the midline, with over 20% of fish demonstrated a complete loss of flesh colour during the months of March and April. A return to feeding in autumn occurred faster in some fish and caused a marked bimodal size distribution to appear within both the EW and LW cohorts as autumn progressed. However, the LW cohort returned to feeding at seawater temperatures of 20.2 °C, compared with 18.6 °C for the EW cohort. There was a strong positive relationship between fillet colour recovery and residual condition index (RCI). These findings identified alkaline phosphatase as a potential marker to non-destructively track individual fish for signs of recovery after a thermal stress event, and shed light on the physiological consequences of marine heatwaves on fishes. This study also identified that supporting feed intake or promoting a return to feeding may help mitigate the negative impacts of climate warming on cultured Atlantic salmon. Highlights • The farm recorded a peak water temperature of 22.9 °C (5 m) and 117 days > 18 °C. • Temperature caused a cessation of voluntary feeding for approximately 2 months. • Flesh colour declined during March and April, with complete loss in over 20% of fish. • High temperature compromised fish osmoregulatory, liver and renal functions. • RCI and plasma AP levels may be useful as a non-destructive indicator of recovery. [ABSTRACT FROM AUTHOR]

Published

2019

16. Exploring key issues of aerobic scope interpretation in ectotherms: absolute versus factorial.

Author

Halsey, Lewis G., Killen, Shaun S., Clark, Timothy D., and Norin, Tommy

Subjects

COLD-blooded animals, METABOLISM, FISHES, LOCOMOTOR control, ROBUST control

Abstract

Aerobic scope represents an animal’s capacity to increase its aerobic metabolic rate above maintenance levels (i.e. the difference between standard (SMR) and maximum (MMR) metabolic rates). Aerobic scope data can be presented in absolute or factorial terms (AAS or FAS, respectively). However, the robustness of these calculations to noise or variability in measures of metabolic rate can influence subsequent interpretations of patterns in the data. We explored this issue using simple models and we compared the predictions from these models to experimental data from the literature. First, we investigated the robustness of aerobic scope calculations as a function of varying SMR when MMR is fixed, and vice versa. While FAS is unexpectedly robust to variability in SMR, even in species with low aerobic scopes, AAS is less sensitive to variation in SMR than is FAS. However, where variation in MMR is the main concern, FAS is more robust than AAS. Our findings highlight the equal importance of minimising variability in MMR, rather than just the variability in SMR, to obtain robust aerobic scope estimates. Second, we analysed metabolic rate accounting for locomotor speed and body mass for swimming fish. The interactions among these factors in relation to AAS and FAS are complex and the appropriate metric is dependent on the specific eco-physiological context of the research question. We conclude with qualified recommendations for using and interpreting AAS and FAS. [ABSTRACT FROM AUTHOR]

Published

2018

17. Comment: Practices for Drawing Blood Samples from Teleost Fish.

Author

Cooke, Steven J., Lawrence, Michael J., Raby, Graham D., Teffer, Amy K., Jeffries, Ken M., Danylchuk, Andy J., and Clark, Timothy D.

Subjects

BLOOD sampling, FISHES, FUNCTIONAL genomics, FISH farming, ECOPHYSIOLOGY, FISH anatomy, FISH physiology

Published

2019

18. Fishing for Effective Conservation: Context and Biotic Variation are Keys to Understanding the Survival of Pacific Salmon after Catch-and-Release.

Author

Raby, Graham D., Donaldson, Michael R., Hinch, Scott G., Clark, Timothy D., Eliason, Erika J., Jeffries, Kenneth M., Cook, Katrina V., Teffer, Amy, Bass, Arthur L., Miller, Kristina M., Patterson, David A., Farrell, Anthony P., and Cooke, Steven J.

Subjects

FISHERIES, CONSERVATION biology, MORTALITY prevention, FISH physiology, FISHES, BIOTELEMETRY, PATHOGENIC microorganisms, ANIMAL health

Abstract

Acute stressors are commonly experienced by wild animals but their effects on fitness rarely are studied in the natural environment. Billions of fish are captured and released annually around the globe across all fishing sectors (e.g., recreational, commercial, subsistence). Whatever the motivation, release often occurs under the assumption of postrelease survival. Yet, capture by fisheries (hereafter "fisheries-capture") is likely the most severe acute stressor experienced in the animal's lifetime, which makes the problem of physiological recovery and survival of relevance to biology and conservation. Indeed, fisheries managers require accurate estimates of mortality to better account for total mortality from fishing, while fishers desire guidance on strategies for reducing mortality and maintaining the welfare of released fish, to maximize current and future opportunities for fishing. In partnership with stakeholders, our team has extensively studied the effects of catch-and-release on Pacific salmon in both marine and freshwater environments, using biotelemetry and physiological assessments in a combined laboratory-based and field-based approach. The emergent theme is that post-release rates of mortality are consistently context-specific and can be affected by a suite of interacting biotic and abiotic factors. The fishing gear used, location of a fishery, water temperature, and handling techniques employed by fishers each can dramatically affect survival of the salmon they release. Variation among individuals, co-migrating populations, and between sexes all seem to play a role in the response of fish to capture and in their subsequent survival, potentially driven by pre-capture pathogen-load, maturation states, and inter-individual variation in responsiveness to stress. Although some of these findings are fascinating from a biological perspective, they all create unresolved challenges for managers. We summarize our findings by highlighting the patterns that have emerged most consistently, and point to areas of uncertainty that require further research. [ABSTRACT FROM AUTHOR]

Published

2015

19. Facing the River Gauntlet: Understanding the Effects of Fisheries Capture and Water Temperature on the Physiology of Coho Salmon.

Author

Raby, Graham D., Clark, Timothy D., Farrell, Anthony P., Patterson, David A., Bett, Nolan N., Wilson, Samantha M., Willmore, William G., Suski, Cory D., Hinch, Scott G., and Cooke, Steven J.

Subjects

*WATER temperature, *COHO salmon, *MORTALITY, *HEART rate monitoring, *ELECTROCARDIOGRAPHY, *OSMOREGULATION, *PHYSIOLOGY, *FISHES

Abstract

An improved understanding of bycatch mortality can be achieved by complementing field studies with laboratory experiments that use physiological assessments. This study examined the effects of water temperature and the duration of net entanglement on physiological disturbance and recovery in coho salmon (Oncorhynchus kisutch) after release from a simulated beach seine capture. Heart rate was monitored using implanted electrocardiogram biologgers that allowed fish to swim freely before and after release. A subset of fish was recovered in respirometers to monitor metabolic recovery, and separate groups of fish were sacrificed at different times to assess blood and white muscle biochemistry. One hour after release, fish had elevated lactate in muscle and blood plasma, depleted tissue energy stores, and altered osmoregulatory status, particularly in warmer (15 vs. 10°C) and longer (15 vs. 2 min) capture treatments. A significant effect of entanglement duration on blood and muscle metabolites remained after 4 h. Oxygen consumption rate recovered to baseline within 7–10 h. However, recovery of heart rate to routine levels was longer and more variable, with most fish taking over 10 h, and 33% of fish failing to recover within 24 h. There were no significant treatment effects on either oxygen consumption or heart rate recovery. Our results indicate that fishers should minimize handling time for bycatch and maximize oxygen supply during crowding, especially when temperatures are elevated. Physiological data, such as those presented here, can be used to understand mechanisms that underlie bycatch impairment and mortality, and thus inform best practices that ensure the welfare and conservation of affected species. [ABSTRACT FROM AUTHOR]

Published

2015

20. Aerobic scope does not predict the performance of a tropical eurythermal fish at elevated temperatures.

Author

Norin, Tommy, Malte, Hans, and Clark, Timothy D.

Subjects

EFFECT of temperature on fishes, FISH populations, OXYGEN consumption, THERMAL tolerance (Physiology), GIANT perch, FISH metabolism, FISHES

Abstract

Climate warming is predicted to negatively impact fish populations through impairment of oxygen transport systems when temperatures exceed those which are optimal for aerobic scope (AS). This concept of oxygen- and capacity-limited thermal tolerance (OCLTT) is rapidly gaining popularity within climate change research and has been applied to several fish species. Here, we evaluated the relevance of aerobic performance of juvenile barramundi (Lates calcarifer) in the context of thermal preference and tolerance by (1) measuring standard and maximum metabolic rates (SMR and MMR, respectively) and AS of fish acclimated to 29°C and acutely exposed to temperatures from 23 to 38°C, (2) allowing the fish to behaviourally select a preferred temperature between 29 and 38°C, and (3) quantifying alterations to AS after 5 weeks of acclimation to 29 and 38°C. SMR and MMR both increased continuously with temperature in acutely exposed fish, but the increase was greater for MMR such that AS was highest at 38°C, a temperature approaching the upper lethal limit (40-41°C). Despite 38°C eliciting maximum AS, when given the opportunity the fish selected a median temperature of 31.7±0.5°C and spent only 10±3% of their time at temperatures >36°C. Following acclimation to 38°C, AS measured at 38°C was decreased to the same level as 29°C-acclimated fish measured at 29°C, suggesting that AS may be dynamically modulated independent of temperature to accommodate the requirements of daily life. Together, these results reveal limited power of the OCLTT hypothesis in predicting optimal temperatures and effects of climate warming on juvenile barramundi. [ABSTRACT FROM AUTHOR]

Published

2014

21. Refuge-Seeking Impairments Mirror Metabolic Recovery Following Fisheries-Related Stressors in the Spanish Flag Snapper (Lutjanus carponotatus) on the Great Barrier Reef.

Author

Cooke, Steven J., Messmer, Vanessa, Tobin, Andrew J., Pratchett, Morgan S., and Clark, Timothy D.

Subjects

FISHERIES, REEF fishes, PREDATORY animals, FISHING, FISHES

Abstract

Fisheries and marine park management strategies for large predatory reef fish can mean that a large proportion of captured fish are released. Despite being released, these fish may experience high mortality while they traverse the water column to locate suitable refuge to avoid predators, all the while recovering from the stress of capture. The predatory reef fish Spanish flag snapper (Lutjanus carponotatus) is frequently released because of a minimum-size or bag limit or by fishers targeting more desirable species. Using L. carponotatus as a model, we tested whether simulated fishing stress (exercise and air exposure) resulted in impairments in reflexes (e.g., response to stimuli) and the ability to identify and use refuge in a laboratory arena and whether any impairments were associated with blood physiology or metabolic recovery. Control fish were consistently responsive to reflex tests and rapidly located and entered refugia in the arena within seconds. Conversely, treatment fish (exhausted and air exposed) were unresponsive to stimuli, took longer to search for refugia, and were more apprehensive to enter the refuge once it was located. Consequently, treatment fish took more than 70 times longer than control fish to enter the coral refuge (26.12 vs. 0.36 min, respectively). The finding that fish exposed to stress were hesitant to use refugia suggests that there was likely cognitive, visual, and/or physiological impairment. Blood lactate, glucose, and hematocrit measures were perturbed at 15 and 30 min after the stressor, relative to controls. However, measurements of oxygen consumption rate revealed that about 50% of metabolic recovery occurred within 30 min after the stressor, coinciding with apparent cognitive/ visual/physiological recovery. Recovering the treatment fish in aerated, flow-through chambers for 30 min before introduction to the behavioral arena restored reflexes, and "recovered" fish behaved more similarly to controls. Therefore, we suggest that temporarily holding coral reef fish that have undergone an exhaustive fishing interaction and an air exposure episode should enable significant recovery of cognitive and metabolic attributes that would enable fish to more rapidly locate and utilize refugia to avoid postrelease predation. However, after nonexhaustive fishing interactions (i.e., minimal reflex impairment), it is likely that immediate release would be most beneficial. [ABSTRACT FROM AUTHOR]

Published

2014

22. Simultaneous biologging of heart rate and acceleration, and their relationships with energy expenditure in free-swimming sockeye salmon ( Oncorhynchus nerka).

Author

Clark, Timothy Darren, Sandblom, E., Hinch, S. G., Patterson, D. A., Frappell, P. B., and Farrell, A. P.

Subjects

*HEART beat, *RESPIRATORY measurements, *SOCKEYE salmon, *FISHES, *SALMON

Abstract

Monitoring the physiological status and behaviour of free-swimming fishes remains a challenging task, although great promise stems from techniques such as biologging and biotelemetry. Here, implanted data loggers were used to simultaneously measure heart rate ( fH), visceral temperature, and a derivation of acceleration in two groups of wild adult sockeye salmon ( Oncorhynchus nerka) held at two different water speeds (slow and fast). Calibration experiments performed with individual fish in a swim tunnel respirometer generated strong relationships between acceleration, fH, tail beat frequency and energy expenditure over a wide range of swimming velocities. The regression equations were then used to estimate the overall energy expenditure of the groups of fish held at different water speeds. As expected, fish held at faster water speeds exhibited greater fH and acceleration, and correspondingly a higher estimated energy expenditure than fish held at slower water speeds. These estimates were consistent with gross somatic energy density of fish at death, as determined using proximate analyses of a dorsal tissue sample. Heart rate alone and in combination with acceleration, rather than acceleration alone, provided the most accurate proxies for energy expenditure in these studies. Even so, acceleration provided useful information on the behaviour of fish and may itself prove to be a valuable proxy for energy expenditure under different environmental conditions, using a different derivation of the acceleration data, and/or with further calibration experiments. These results strengthen the possibility that biologging or biotelemetry of fH and acceleration may be usefully applied to migrating sockeye salmon to monitor physiology and behaviour, and to estimate energy use in the natural environment. [ABSTRACT FROM AUTHOR]

Published

2010

23. Reduced and reversed temperature dependence of blood oxygenation in an ectothermic scombrid fish: implications for the evolution of regional heterothermy?

Author

Clark, Timothy Darren, Rummer, J. L., Sepulveda, C. A., Farrell, A. P., and Brauner, C. J.

Subjects

*SCOMBRIDAE, *TISSUES, *BLOOD vessels, *PERCIFORMES, *FISHES

Abstract

Tunas (family Scombridae) are exceptional among most teleost fishes in that they possess vascular heat exchangers which allow heat retention in specific regions of the body (termed ‘regional heterothermy’). Seemingly exclusive to heterothermic fishes is a markedly reduced temperature dependence of blood–oxygen (blood–O2) binding, or even a reversed temperature dependence where increasing temperature increases blood–O2 affinity. These unusual binding properties have been documented in whole blood and in haemoglobin (Hb) solutions, and they are hypothesised to prevent oxygen loss from arteries to veins within the vascular heat exchangers and/or to prevent excessive oxygen unloading to the warm tissues and ensure an adequate supply of oxygen to tissues positioned efferent to the heat exchangers. The temperature sensitivity of blood–O2 binding has not been characterised in an ectothermic scombrid (mackerels and bonitos), but the existence of the unusual binding properties in these fishes would have clear implications for their proposed association with regional heterothermy. Accordingly, the present study examined oxygenation of whole blood of the chub mackerel ( Scomber japonicus) at 10, 20 and 30°C and at 0.5, 1 and 2% CO2. Oxygen affinity was generally highest at 20°C for all levels of CO2. Temperature-independent binding was observed at low (0.5%) CO2, where the PO2 at 50% blood–O2 saturation ( P50) was not statistically different at 10 and 30°C (2.58 vs. 2.78 kPa, respectively) with an apparent heat of oxygenation (∆ H°) close to zero (−6 kJ mol−1). The most significant temperature-mediated difference occurred at high (2%) CO2, where the P50 at 10°C was twofold higher than that at 20°C with a corresponding ∆ H° of +43 kJ mol−1. These results provide clear evidence of independent and reversed open-system temperature effects on blood oxygenation in S. japonicus, and it is therefore speculated that these unusual blood–O2 binding characteristics may have preceded the evolution of vascular heat exchangers and regional heterothermy in fishes. [ABSTRACT FROM AUTHOR]

Published

2010

24. Sex differences in circulatory oxygen transport parameters of sockeye salmon ( Oncorhynchus nerka) on the spawning ground.

Author

Clark, Timothy Darren, Hinch, S. G., Taylor, B. D., Frappell, P. B., and Farrell, A. P.

Subjects

*PHYSIOLOGICAL transport of oxygen, *SOCKEYE salmon, *ONCORHYNCHUS, *SPAWNING, *HEART beat, *HEMOGLOBINS, *FISHES, *SALMON, SEX differences (Biology)

Abstract

Upon reaching sexual maturity, several species of male salmonids possess a relative ventricular mass (rMV) that may be up to 90% larger than females. This can increase maximum cardiac stroke volume and power output, which may be beneficial to increasing the oxygen transport capacity of male salmonids during the spawning period. It may be further hypothesized, therefore, that other variables within the circulatory oxygen transport cascade, such as blood oxygen-carrying capacity and heart rate, are similarly enhanced in reproductively mature male salmonids. To test this idea, the present study measured a range of circulatory oxygen transport variables in wild male and female sockeye salmon ( Oncorhynchus nerka) during their spawning period, following a 150 km migration from the ocean. The rMV of male fish was 13% greater than females. Conversely, the haemoglobin concentration ([Hb]) of female fish was 19% higher than males, indicative of a greater blood oxygen-carrying capacity (138 vs. 116 ml O2 l−1, respectively). Surgically implanted physiological data loggers revealed a similar range in heart rate for both sexes on the spawning ground (20–80 beats min−1 at 10°C), with a tendency for male fish to spend a greater percentage of time (64%) than females (49%) at heart rates above 50 beats min−1. Male fish on average consumed significantly more oxygen than females during a 13-h respirometry period. However, routine oxygen consumption rates $$ (\dot{M}{\text{O}}_{2} ) $$ ranged between 1.5 and 8.5 mg min−1 kg−1 for both sexes, which implies that males did not inherently possess markedly higher routine aerobic energy demands, and suggests that the higher [Hb] of female fish may compensate for the smaller rMV. These findings reject the hypothesis that all aspects of the circulatory oxygen transport cascade are inherently superior in male sockeye salmon. Instead, it is suggested that any differences in $$ \dot{M}{\text{O}}_{2} $$ between sexually mature male and female sockeye salmon can likely be attributed to activity levels. [ABSTRACT FROM AUTHOR]

Published

2009

25. Behavioural lateralization in a detour test is not repeatable in fishes.

Author

Roche, Dominique G., Amcoff, Mirjam, Morgan, Rachael, Sundin, Josefin, Andreassen, Anna H., Finnøen, Mette H., Lawrence, Michael J., Henderson, Eleanor, Norin, Tommy, Speers-Roesch, Ben, Brown, Culum, Clark, Timothy D., Bshary, Redouan, Leung, Brian, Jutfelt, Fredrik, and Binning, Sandra A.

Subjects

*OCEAN acidification, *FISHES, *HYPOXIA (Water), *STATISTICS, *STATISTICAL reliability

Abstract

Behavioural lateralization, the asymmetric expression of cognitive functions, is reported to enhance key fitness-relevant traits such as group coordination, multitasking and predator escape. Therefore, studies reporting negative effects on lateralization in fish due to environmental stressors such as ocean acidification, hypoxia and pollutants are worrisome. However, such studies tend to use a detour test and focus on population level measures, without validating whether lateralization is consistent within individuals across time. We conducted a multispecies, international assessment of the repeatability (R) of lateralization in four previously studied fish species using a detour test (T-maze), a common method for testing lateralization. We also reanalysed a published data set on a fifth species using new statistical methods. We expected the three shoaling species to exhibit greater within-individual consistency in lateralization than their nonshoaling counterparts given previous reports of stronger lateralization in group-living fishes. Absolute and relative lateralization scores were highly nonrepeatable in all five species (0.01< R <0.08), irrespective of their shoaling status. We carefully reviewed 31 published studies in which the detour test was employed to examine lateralization in fish and identified statistical issues in all of them. We develop and propose new statistical analyses to test for population and individual level lateralization. The commonly used detour test does not appear to be appropriate for quantifying behavioural lateralization in fishes, calling into question functional inferences drawn by many published studies, including our own. Potential fitness benefits of lateralization and anthropogenic effects on lateralization as a proxy for adaptive brain functioning need to be assessed with alternative paradigms. • Behavioural lateralization reportedly enhances many fitness-relevant traits. • Thus, negative effects of environmental stressors on lateralization are worrisome. • We develop and propose new statistical analyses to test for lateralization. • Lateralization in five fish species using a detour test was highly nonrepeatable. • Potential fitness benefits of lateralization must be tested using validated methods. [ABSTRACT FROM AUTHOR]

Published

2020