Effects of high CO2 on oxygen consumption rates, aerobic scope and swimming performance

Effects of acute exposure to freshwater acidification on developing Oryzias latipes

Elevated CO2 in aquatic environments causes weak acidification. When exposed to weak acidification, regardless of life stage, most fishes undergo some degree of hypercapnia (elevation of CO2 in the bloodstream). Hypercapnia negatively affects physiological processes and embryo and larval fish are particularly vulnerable to rises in CO2. The aim of our study was to understand if weak acidification induced by elevated CO2 alters the physiology and behaviour of freshwater Japanese medaka (Oryzias latipes) embryos and larvae. To test this, we treated Japanese medaka embryos and larvae for 24 h with varying levels of weak acidification (pH 7.1 [∼482 μatm], 6.4 [∼2,122 μatm], 6.1 [∼3,280 μatm], 5.8 [∼5,306 μatm], and 5.7 [∼10,130 μatm]) at two developmental stages (72 hpf and 9 dpf). Following the treatment, heart rate, burst activity (movement within the egg), and survival of embryos were quantified. Swimming activity of hatched larvae was also measured. We observed a statistically significant 2-fold decline in heart rate of embryonic Japanese medaka as pH decreased (P < 0.01). We also found that survival of embryos significantly declined as acidification increased (P < 0.01). Behaviour of larval fish was significantly altered (P < 0.001) but not in a pH dependent manner. Our study suggests that weak acidification can cause negative effects to early life stage physiology and that behaviour can be altered. Our results suggest that if fish develop in weakly acidified freshwater there may be unfavourable impacts, including mortality at the most extreme levels.

Effects of polystyrene microspheres on the swimming behavior and metabolism of grass carp (Ctenopharyngodon idella)

Microplastics (MPs) are a heterogeneous class of pollutants fouling aquatic environments and they are hazardous to aquatic organisms. This study investigated the size-dependent effects of polystyrene microspheres (PSMPs) on the swimming ability, metabolism, and oxidative stress of juvenile grass carp (Ctenopharyngodon idella). Test fish were exposed to four sizes of PSMPs (0.07, 0.5, 5, and 20-μm), and swimming ability was tested after different exposure times (2, 7, and 15 days). To measure the effect on swimming ability, critical swimming speed (Ucrit) was determined, and to assess metabolic effects, oxygen consumption (MO2), routine metabolic rate (RMR), maximum oxygen consumption (MMR), and excess post-exercise oxygen consumption (EPOC) were determined. To assess the effects on oxidative stress, the activities of two antioxidant enzymes, superoxide dismutase (SOD) and catalase (CAT) were determined in the liver and gills of test fish. After exposure to 20 μm PSMPs, there was a significant drop in Ucrit compared to the control group (P<0.05), with decreases of 22 % on Day 2 and Day 7, and 21 % on Day 15. The RMR and MMR increased significantly (P<0.05), the RMR by 23.9 % on Day 2 and the MMR by 17.2 % on Day 2 and on Day 15, 44.7 % and 20.0 % respectively. The EPOC decreased with exposure time, by 31 % (0.07-μm), 45 %-(0.5-μm), 49 % (5-μm), and 57 % (20-μm) after 15 days. Exposure to the larger PSMPs increased CAT and SOD activity more than the smaller PSMPs and the increases began with SOD activity in the gills. The larger PSMPs were consistently more harmful to juvenile grass carp than the smaller PSMPs. Our results clearly show that PSMPs have detrimental effects on juvenile grass carp and provide additional scientific evidence that environmental monitoring and regulation of microplastic pollution is necessary.

Elevated CO2 levels did not induce species- or tissue-specific damage in young-of-year salmonids

OBJECTIVE

The broad objective of our study was to use a histological approach to examine possible tissue-level effects of exposure to elevated CO₂ in freshwater young-of-year salmonids.

METHODS

To study these effects, young-of-year Arctic Char Salvelinus alpinus, Rainbow Trout Oncorhynchus mykiss, and Brook Trout S. fontinalis were exposed to either control levels of CO₂ (1400 μatm) or elevated levels of CO₂ (5236 μatm) for 15 days. Fish were then sampled for gill, liver, and heart tissues and histologically analyzed.

RESULT

A species effect was observed for the length of secondary lamellae, as Arctic Char had significantly shorter secondary lamellae than the other species. No notable changes within the gills and livers of Arctic Char, Brook Trout, or Rainbow Trout exposed to elevated CO₂ were observed.

CONCLUSION

Generally, our results indicated that elevated CO₂ levels over 15 days do not induce catastrophic tissue damage and it is unlikely that fish health would be seriously impacted. Ongoing research dedicated to examining how elevated CO₂ long-term may affect internal tissues of fish will allow for a more comprehensive understanding of how fish may fair with ongoing climate change and in aquaculture facilities.

Effects of elevated CO2 on metabolic rate and nitrogenous waste handling in the early life stages of yellowfin tuna (Thunnus albacares)

Ocean acidification is predicted to have a wide range of impacts on fish, but there has been little focus on broad-ranging pelagic fish species. Early life stages of fish are thought to be particularly susceptible to CO₂ exposure, since acid-base regulatory faculties may not be fully developed. We obtained yellowfin tuna (Thunnus albacares) from a captive spawning broodstock population and exposed them to control or 1900 μatm CO₂ through the first three days of development as embryos transitioned into yolk sac larvae. Metabolic rate, yolk sac depletion, and oil globule depletion were measured to assess overall energy usage. To determine if CO₂ altered protein catabolism, tissue nitrogen content and nitrogenous waste excretion were quantified. CO₂ exposure did not significantly impact embryonic metabolic rate, yolk sac depletion, or oil globule depletion, however, there was a significant decrease in metabolic rate at the latest measured yolk sac larval stage (36 h post fertilization). CO₂-exposure led to a significant increase in nitrogenous waste excretion in larvae, but there were no differences in nitrogen tissue accumulation. Nitrogenous waste accumulated in embryos as they developed but decreased after hatch, coinciding with a large increase in nitrogenous waste excretion and increased metabolic rate in newly hatched larvae. Our results provide insight into how yellowfin tuna are impacted by increases in CO₂ in early development_, but more research with higher levels of replication is needed to better understand long-term impacts and acid-base regulatory mechanisms in this important pelagic fish.

Rapid evolution fuels transcriptional plasticity to ocean acidification

Ocean acidification (OA) is postulated to affect the physiology, behavior, and life-history of marine species, but potential for acclimation or adaptation to elevated pCO2 in wild populations remains largely untested. We measured brain transcriptomes of six coral reef fish species at a natural volcanic CO2  seep and an adjacent control reef in Papua New Guinea. We show that elevated pCO2 induced common molecular responses related to circadian rhythm and immune system but different magnitudes of molecular response across the six species. Notably, elevated transcriptional plasticity was associated with core circadian genes affecting the regulation of intracellular pH and neural activity in Acanthochromis polyacanthus. Gene expression patterns were reversible in this species as evidenced upon reduction of CO2 following a natural storm-event. Compared with other species, Ac. polyacanthus has a more rapid evolutionary rate and more positively selected genes in key functions under the influence of elevated CO2 , thus fueling increased transcriptional plasticity. Our study reveals the basis to variable gene expression changes across species, with some species possessing evolved molecular toolkits to cope with future OA.

Contrasting effects of constant and fluctuating pCO2 conditions on the exercise physiology of coral reef fishes

Ocean acidification (OA) is predicted to affect the physiology of some fishes. To date, most studies have investigated this issue using stable pCO₂ levels based on open ocean projections. Yet, most shallow, nearshore systems experience temporal and spatial pCO₂ fluctuations. For example, pCO₂ on coral reefs is highest at night and lowest during the day, but as OA progresses, both the average pCO₂ and magnitude of fluctuations are expected to increase. We exposed four coral reef fishes - Lutjanus fulviflamma, Caesio cuning, Abudefduf whitleyi, and Cheilodipterus quinquelineatus - to ambient, stable elevated, or fluctuating elevated pCO₂ conditions for 9-11 days. Then, we measured swimming performance, oxygen uptake rates, and haematological parameters during the day and at night. When compared to ambient pCO₂ conditions, L. fulviflamma, C. cuning, and A. whitleyi exposed to fluctuating elevated pCO₂ increased swimming performance, maximum oxygen uptake rates, and aerobic scope, regardless of time of day; whereas, the only nocturnal species studied, C. quinquelineatus, decreased maximum oxygen uptake rates and aerobic scope. Our findings suggest that exposure to fluctuating or stable elevated pCO₂ can physiologically benefit some coral reef fishes; however, other species, such as the cardinalfish examined here, may be more sensitive to future OA conditions.

Acclimation to prolonged aquatic hypercarbia or air enhances hemoglobin‑oxygen affinity in an amphibious fish

When the amphibious mangrove rivulus (Kryptolebias marmoratus) leaves water for extended periods, hemoglobin-O₂ binding affinity increases. We tested the hypothesis that the change in affinity was a consequence of hemoglobin isoform switching driven by exposure to environments associated with increased internal CO₂ levels. We exposed K. marmoratus to either water (control, pH 8.1), air, aquatic hypercarbia (5.1 kPa CO₂, pH 6.6-6.8), or aquatic acid (isocarbic control, pH 6.6-6.8), for 7 days, and measured hemoglobin-O₂ affinity spectrophotometrically. We found that mangrove rivulus compensated for elevated CO₂ and aquatic acid exposure by shifting hemoglobin-O₂ affinity back to aquatic (control) levels when measured at an ecologically-relevant high CO₂ level that would be experienced in vivo. Using proteomics, we found that the hemoglobin subunits present in the blood did not change between treatments, but air and aquatic acid exposure altered the abundance of cathodic hemoglobin subunits. We therefore conclude that hemoglobin isoform switching is not a primary strategy used by mangrove rivulus to adjust P₅₀ under these conditions. Abundances of other RBC proteins also differed between treatment groups relative to control fish (e.g. Rhesus protein type A, band 3 anion exchanger). Overall, our data indicate that both aquatic hypercarbia and aquatic acidosis create similar changes in hemoglobin-O₂ affinity as air exposure. However, the protein-level consequences differ between these groups, indicating that the red blood cell response of mangrove rivulus can be modulated depending on the environmental cue received.