Effects of high pCO2 on early life development of pelagic spawning marine fish

Faria, Ana M.; Filipe, Soraia; Lopes, Ana F.; Oliveira, A. P.; Gonçalves, Emanuel João; Ribeiro, Laura

doi:10.1071/mf16385

Cited by 14 publications

(7 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Hatching often presents a critical bottleneck in the life history of marine fish (Köster et al 2003;Houde 2008;Dahlke et al 2020a). Reduced hatching in response to high ρCO 2 has been observed in some marine fish, including Senegalese Sole Solea senegalensis (Pigmental et al 2014;Faria et al 2017), White Seabream Diplodus sargus, and Meagre Argyrosomus regius, as well as crustaceans, including Florida stone crab Menippe mercenaria (Gravinese 2018), Antarctic krill Euphausia superba (Kawaguchi et al 2013), and the copepod Calanus finmarchicus (Mayor et al 2007).…”

Section: Discussionmentioning

confidence: 99%

Resilience of Black Sea Bass Embryos to Increased Levels of Carbon Dioxide

et al. 2022

View full text Add to dashboard Cite

After a decade of research on how embryonic fish will respond to the increased dissolved carbon dioxide (ρCO2) levels predicted for the next century, no uniform response to near future acidification has been observed among marine species. We exposed Black Sea Bass Centropristis striata (BSB) embryos to varied levels of ρCO2 (microatmospheres [μatm]) for 48 h during seasonal experiments conducted in 2013–2015 to compare embryonic response among multiple broodstocks. The relationship between ρCO2 concentration and hatching success was inconsistent among years, with a nonlinear, inverse relationship noted in 2014 only, explaining 13% of observed variance. Conversely, ρCO2 was a good predictor of unhatched BSB embryos after 48 h for all years combined (39%) and for 2013 (38%). The ρCO2 concentration was a good predictor of the frequency of vertebral column anomalies for individual years (2013: 40%; 2014: 12%; 2015: 38%) but not when data were pooled for all years. In 2013 and 2015, vertebral column anomalies were relatively consistent below 1,000 μatm and were elevated above that threshold. Preliminary results suggest that BSB embryos may demonstrate resilience to future ρCO2 levels, but the results also highlight the challenges associated with drawing broad conclusions given observed variability in results obtained from different broodstocks and study years.

show abstract

Section: Discussionmentioning

confidence: 99%

Resilience of Black Sea Bass Embryos to Increased Levels of Carbon Dioxide

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Otoliths are composed of aragonite [33,34] and it was initially thought that otolith calcification might be impaired in acidified conditions due to reduced carbonate saturation in low pH seawater [35]. However, a consistent finding in fish ocean acidification research is that otoliths are often larger in larval fishes exposed to elevated CO 2 conditions [33,[36][37][38][39][40]. For example, Bignami et al [36] showed that the sagittal otoliths of larval cobia (Rachycentron canadum) had 49% greater volume and 58% greater mass in fish reared under increased CO 2 saturation (2100) µatm compared to control fish.…”

Section: Introductionmentioning

confidence: 99%

Ocean acidification effects on fish hearing

et al. 2021

View full text Add to dashboard Cite

Humans are rapidly changing the marine environment through a multitude of effects, including increased greenhouse gas emissions resulting in warmer and acidified oceans. Elevated CO 2 conditions can cause sensory deficits and altered behaviours in marine organisms, either directly by affecting end organ sensitivity or due to likely alterations in brain chemistry. Previous studies show that auditory-associated behaviours of larval and juvenile fishes can be affected by elevated CO 2 (1000 µatm). Here, using auditory evoked potentials (AEP) and micro-computer tomography (microCT) we show that raising juvenile snapper, Chrysophyrs auratus , under predicted future CO 2 conditions resulted in significant changes to their hearing ability. Specifically, snapper raised under elevated CO 2 conditions had a significant decrease in low frequency (less than 200 Hz) hearing sensitivity. MicroCT demonstrated that these elevated CO 2 snapper had sacculus otolith's that were significantly larger and had fluctuating asymmetry, which likely explains the difference in hearing sensitivity. We suggest that elevated CO 2 conditions have a dual effect on hearing, directly effecting the sensitivity of the hearing end organs and altering previously described hearing induced behaviours. This is the first time that predicted future CO 2 conditions have been empirically linked through modification of auditory anatomy to changes in fish hearing ability. Given the widespread and well-documented impact of elevated CO 2 on fish auditory anatomy, predictions of how fish life-history functions dependent on hearing may respond to climate change may need to be reassessed.

show abstract

“…Originally, it was predicted that CO2-induced ocean acidification (OA) would impair otolith biomineralization because the associated decreases in seawater pH and [CO3 2-] hamper CaCO3 precipitation [9]. However, subsequent studies reported that fish exposed to OA developed enlarged otoliths [10][11][12][13][14][15][16]. These findings led to a broader awareness otolith biomineralization is strongly linked to endolymph and blood chemistries, and to the hypothesis that biological regulation of endolymph pH could lead to increased [CO3 2-] resulting in otolith overgrowth [10].…”

Section: Introductionmentioning

confidence: 99%

“…In the current study, splitnose rockfish ( Sebastes diploproa) were exposed to ~1,600 μatm CO 2 (pH ~7.5), a condition readily experienced in their natural habitat [31,32] and predicted for the surface ocean by the year 2300 [33]. The OA exposure spanned three days, a duration previously documented to result in otolith overgrowth [16]. Blood acid-base chemistry was measured after taken samples using a benzocaine-based anesthetic protocol that yields measurements comparable to those achieved using cannulation [20].…”

Section: Introductionmentioning

confidence: 99%

Elucidating the acid-base mechanisms underlying otolith overgrowth in fish exposed to ocean acidification

Kwan

Tresguerres

2021

Preprint

View full text Add to dashboard Cite

Over a decade ago, ocean acidification (OA) exposure was reported to induce otolith overgrowth in teleost fish. This phenomenon was subsequently confirmed in multiple species; however, the underlying physiological causes remain unknown. Here, we report that splitnose rockfish (Sebastes diploproa) exposed to ~1,600 μatm pCO2 (pH ~7.5) were able to fully regulated the pH of both blood and endolymph (the fluid that surrounds the otolith within the inner ear). However, while blood was regulated around pH 7.80, the endolymph was regulated around pH ~8.30. These different pH setpoints result in increased pCO2 diffusion into the endolymph, which in turn leads to proportional increases in endolymph [HCO3−] and [CO32−]. Endolymph pH regulation despite the increased pCO2 suggests enhanced H+ removal. However, a lack of differences in inner ear bulk and cell-specific Na+/K+-ATPase and vacuolar type H+-ATPase protein abundance localization pointed out to activation of preexisting ATPases, non-bicarbonate pH buffering, or both, as the mechanism for endolymph pH-regulation. These results provide the first direct evidence showcasing the acid-base chemistry of the endolymph of OA-exposed fish favors otolith overgrowth, and suggests that this phenomenon will be more pronounced in species that count with more robust blood and endolymph pH regulatory mechanisms.

show abstract

Effects of high pCO2 on early life development of pelagic spawning marine fish

Cited by 14 publications

References 51 publications

Resilience of Black Sea Bass Embryos to Increased Levels of Carbon Dioxide

Resilience of Black Sea Bass Embryos to Increased Levels of Carbon Dioxide

Ocean acidification effects on fish hearing

Elucidating the acid-base mechanisms underlying otolith overgrowth in fish exposed to ocean acidification

Contact Info

Product

Resources

About