Ocean acidification effects on fish hearing

Acidification affects the early development of Colombian endemic fish Prochilodus magdalenae

There is a significant knowledge gap regarding the acidification of freshwater ecosystems and its effects on biological systems. The bocachico (Prochilodus magdalenae), an endemic and migratory species vital to Colombia's inland fisheries, is currently classified as vulnerable. This study evaluated the impact of different pH levels (6.2, 7.2, and 7.6), previously recorded in the species' natural habitat, on its early development. Using an automated IKS Aquastar system, embryo incubation and larval maintenance were monitored from 0 to 5 days post-fertilization, assessing development, hatching, and survival at both organismal and transcriptional levels. Embryos exposed to pH 6.2 showed delayed development within 4 h post-fertilization, the lowest hatching rate (68.33 ± 3.13 %), and survival (23.88 ± 4.53 %), along with the highest incidence of malformations (37.80 ± 4.4 %). The pH 7.6 group also showed adverse effects, but to a lesser extent. Transcriptome analysis revealed a distinct molecular response in the pH 6.2 group, identifying 1214 differentially expressed genes related to early development, ossification, organ formation, sensory systems, and cellular processes. The findings indicate that pH fluctuations previously observed in the species' natural environment significantly affect P. magdalenae during early life stages, which raises serious concerns about the long-term viability of this endemic species and the sustainability of the artisanal fisheries that depend on it.

Effect of pH on Development of the Zebrafish Inner Ear and Lateral Line: Comparisons between High School and University Settings

Increasing carbon dioxide levels associated with climate change will likely have a devastating effect on aquatic ecosystems. Aquatic environments sequester carbon dioxide, resulting in acidic conditions that can negatively affect fish development. Increasing climate change impacts in the coming decades will have an outsized effect on younger generations. Therefore, our research had two interconnected goals: 1) understand how aquatic acidification affects the development of zebrafish, and 2) support a high school scientist's ability to address environmental questions of increasing importance to her generation. Working with teachers and other mentors, the first author designed and conducted the research, first in her high school, then in a university research laboratory. Zebrafish embryos were reared in varying pH conditions (6.7-8.2) for up to 7 days. We assessed fish length and development of the inner ear, including the otoliths; structures that depend on calcium carbonate for proper development. Although pH did not affect fish length, fish reared in pH 7.75 had smaller anterior otoliths, showing that pH can impact zebrafish ear development. Furthermore, we demonstrate how zebrafish may be used for high school students to pursue open-ended questions using different levels of available resources.

Brain transcriptome of gobies inhabiting natural CO2 seeps reveal acclimation strategies to long-term acidification

Ocean acidification (OA) is known to affect the physiology, survival, behaviour and fitness of various fish species with repercussions at the population, community and ecosystem levels. Some fish species, however, seem to acclimate rapidly to OA conditions and even thrive in acidified environments. The molecular mechanisms that enable species to successfully inhabit high CO2 environments have not been fully elucidated especially in wild fish populations. Here, we used the natural CO2 seep in Vulcano Island, Italy to study the effects of elevated CO2 exposure on the brain transcriptome of the anemone goby, a species with high population density in the CO2 seep and investigate their potential for acclimation. Compared to fish from environments with ambient CO2, gobies living in the CO2 seep showed differences in the expression of transcripts involved in ion transport and pH homeostasis, cellular stress, immune response, circadian rhythm and metabolism. We also found evidence of potential adaptive mechanisms to restore the functioning of GABAergic pathways, whose activity can be affected by exposure to elevated CO2 levels. Our findings indicate that gobies living in the CO2 seep may be capable of mitigating CO2-induced oxidative stress and maintaining physiological pH while meeting the consequent increased energetic costs. The conspicuous difference in the expression of core circadian rhythm transcripts could provide an adaptive advantage by increasing the flexibility of physiological processes in elevated CO2 conditions thereby facilitating acclimation. Our results show potential molecular processes of acclimation to elevated CO2 in gobies enabling them to thrive in the acidified waters of Vulcano Island.

Pilot study to investigate the effect of long-term exposure to high pCO2 on adult cod (Gadus morhua) otolith morphology and calcium carbonate deposition

To date the study of ocean acidification on fish otolith formation has been mainly focused on larval and juvenile stages. In the present pilot study, wild-captured adult Atlantic cod (Gadus morhua) were exposed to two different levels of pCO_2, 422µatm (ambient, low pCO₂) or 1091µatm (high pCO₂), for a period of 30 weeks (from mid-October to early April 2014-2015) in order to study the effects on otolith size, shape and CaCO₃ crystallization amongst other biological parameters. We found that otoliths from cod exposed to high pCO₂ were slightly smaller (- 3.4% in length; - 3.3% in perimeter), rounder (- 2.9% circularity and + 4% roundness) but heavier (+ 5%) than the low pCO₂ group. Interestingly, there were different effects in males and females; for instance, male cods exposed to high pCO₂ exhibited significant changes in circularity (- 3%) and roundness (+ 4%) compared to the low pCO₂ males, but without significant changes on otolith dimensions, while females exposed to high pCO₂ had smaller otoliths as shown for length (- 5.6%), width (- 2%), perimeter (- 3.5%) and area (- 4.8%). Furthermore, while the majority of the otoliths analysed showed normal aragonite deposition, 10% of fish exposed to 1091µatm of pCO₂ had an abnormal accretion of calcite, suggesting a shift on calcium carbonate polymorph crystallization in some individuals under high pCO₂ conditions. Our preliminary results indicate that high levels of pCO₂ in adult Atlantic cod might affect otolith growth in a gender-specific way. Our findings reveal that otoliths from adult cod are affected by ocean acidification, and we believe that the present study will prompt further research into this currently under-explored area.