Northern cod species risk loss of spawning habitat if global warming exceeds 1.5 ° C

Abstract

Rapid climate change in the northeastern Atlantic and the Arctic is threatening some of the world's largest fish populations. The impacts of warming and acidification could become accessible through mechanism-based risk badessments and future quality projections of habitat. We show that ocean acidification results in shrinking of embryonic thermal ranges, thereby determining whether spawning habitats are appropriate as a vital life-cycle bottleneck for two abundant cod species. The embryonic tolerance ranges badociated with climate simulations reveal that CO₂ shows [Representative Concentration Pathway (RCP) 8.5] deteriorate the suitability of the current spawning habitat for Atlantic cod (Gadus morhua) and polar cod (Boreogadus saida) by 2100. Moderate warming (RCP4.5) can avoid dangerous climate impacts on Atlantic cod, but leaves few spawning areas for more vulnerable Atlantic cod, which also loses benefits an ocean covered with ice. Emissions following RCP2.6, however, confirm that habitat suitability for both species is virtually unchanged, suggesting that risks are minimized if warming is maintained "below 2 ° C". C, or 1.5 ° C, as promised by the Paris Agreement.

INTRODUCTION

Ocean Warming and Acidification (OWA), driven by undiluted CO₂ emissions, should limit the survival and reproduction of many marine organisms (1). Existing knowledge implies that the physiological limits of the early stages of life history define the species' vulnerability to OWA (2). Studies on the most adverse impact scenarios are important to raise public awareness of risks and to gain acceptance by society of the risk reduction policy (3). However, it is even more important to identify the emission pathways required to minimize the risk of impact and to locate potential refuge habitats for endangered species that should be given priority for conservation (1–3). However, risk badessments based on mechanisms that integrate vulnerable life stages and their specific habitat needs into a scenario scenario are barely available, especially for marine species living in arctic regions (4, 5).

The subarctic and arctic seas surrounding northern Europe (Iceland Sea, Norwegian Sea, East Greenland Sea and Barents Sea) are expected to experience higher rates of global warming, acidification and sea ice loss. than most other marine areas of the Earth (6). These oceanic regions, previously known as the Norden Seas (7) – are populated by highly productive fish populations, most of which undertake annual migrations to specific spawning grounds (4). The biophysical characteristics of suitable spawning habitat favor early life survival and dispersal to appropriate growth areas (p.24).8). Since fish embryos are often more sensitive to environmental changes than later stages of life (2), embryo tolerance may be a fundamental constraint to the quality of spawning habitat. For example, thermal tolerance ranges that are narrower in fish embryos than in other stages of development may be a biogeographic constraint (8) and is probably explained by the incomplete development of cardiovascular systems and other homeostatic systems (9). Ocean acidification caused by high concentration of CO in the aquatic environment₂ levels can exacerbate the disturbance of homeostasis (ten), thus reducing the thermal range (2, 11) and possibly reduce the ability of the spawning habitat by harming the survival of the eggs.

Atlantic cod and Arctic cod are key members of the high northern latitudes fish fauna, but their thermal affinity and spawning preferences differ (4, 5). Atlantic cod is a "thermal generalist" that occupies temperate to arctic waters between -1.5 and 20 ° C (12). Polar cod, on the other hand, is a "heat specialist" endemic to the High Arctic and is rarely found at temperatures above 3 ° C (13). Due to overlapping temperature ranges between the juvenile and adult life stages, both species coexist during their summer migrations of food (14). In winter and spring, however, spawning occurs in separate locations with different water temperatures and sea ice conditions (Fig. 1). Since Atlantic cod prefer warmer waters (3 to 7 ° C) than polar cod (-1 to 2 ° C), the latter species is considered particularly vulnerable to climate change (5, 14). In addition, another indirect threat to polar cod breeding is the predicted loss of sea ice, which serves as a nursery habitat for larvae and juveniles in spring and summer (5).

Concentrations of Atlantic and polar cod spawners – often including several million individuals – are important resources for humans and other marine predators. For example, the Norwegian Atlantic cod fishery alone generates an annual income of 800 million US dollars (15), while polar cod is an essential food for many marine birds and mammals (5). The estimation of the evolution of the quality of the spawning habitat for these focal species is therefore of great socio-ecological importance (4). Functional responses of embryos to OWAs incorporated into habitat models can help identify risks and spatial benefits under different emission scenarios, including the goal of limiting global warming to 1.5 ° C above pre-industrial levels (16).

Here, we evaluate the embryonic heat tolerance ranges under osteoarthritis in Atlantic cod and polar cod. Oxygen consumption rate (MO₂) eye stage embryos and larval morphometry at hatch provide a better understanding of the energy constraints imposed by OWA. The suitability of spawning habitat has been mapped in the Norden Seas under various representative pathways of concentration (RCP) by linking egg survival data to climate simulations of Phase 5 of the model intercrop comparison project. coupled (CMIP5). PCRs badume either "no greenhouse gas mitigation" (RCP8.5), "intermediate mitigation" (RCP4.5), or "strong attenuation" (RCP2.6). The latter scenario was developed with the aim of limiting the increase in global mean surface temperature (average soil and sea surface) to less than 2 ° C compared to the 1850 reference period. -1900 and provides a first estimate of the consequences of maintaining global warming at "well below 2 ° C, or even 1.5 ° C", as indicated in the Paris Agreement (16).

RESULTS

Embryo oxygen consumption (MO₂) increased with increasing temperature but stabilized or decreased at warmer temperatures (cod ≥ 9 ° C, polar cod ≥ 4.5 ° C, Fig. 2 A and B), which combined with increased mortality under these conditions (Fig. 3), indicating severe heat stress. Embryos acclimated to lower temperatures (<9 ° / 4.5 ° C) and higher Pco₂ (partial pressure of CO₂) consumed about 10% more oxygen compared to those raised under control Pco₂. This trend reversed during warming, indicating that the additional oxygen and energy requirements badociated with osteoarthritis conditions can not be met at extremely high temperatures, resulting in a decrease in the upper thermal limit of maintenance. metabolic. Higher energy requirements under elevation Pco₂ may result from the cumulative costs of increased regulation of acid-base, protein turnover and damage repair (9, ten). Energy allocation to life support functions should be prioritized over growth (17), as evidenced by the CO₂– and reductions in hatch size at hatching induced by warming (Fig 2, C to F and Fig S2). The relative decrease in body surface area free from larval yellow due to Pco₂ average of 10% for Atlantic cod (P < 0.001) and 13% for polar cod (P < 0.001), the smaller larvae hatching at the hottest temperature (Fig 2, C and D, and Table S1). Reductions in larval body size and dry weight (Fig 2, E and F, and Table S1) are in line with CO₂induced by the reallocation of energy away from growth, also observed in other species of fish (18).

Egg survival decreased outside the preferred spawning temperatures of Atlantic cod (≤ 0 ° C and ≥ 9 ° C) and polar cod (≥ 3 ° C), particularly under the influence of Pco₂ (Fig. 3 and Table S1). As a result, our results confirm that embryonic tolerance ranges represent a significant constraint on the thermal spawning niche of Atlantic cod and polar cod. CO₂The mortalities induced at their optimal spawning temperature were less pronounced for Atlantic cod (6 ° C, Fig. 3A) than for polar cod (0 ° to 1.5 ° C, Fig. 3B). This observation corresponds to the variation of CO₂ sensitivity reported by earlier studies of early life fish and having tested the effects of OWA only under optimal temperature conditions (18). However, both species experienced a level of CO₂decline due to egg survival at their respective warming threshold (-48% at 9 ° C for Atlantic cod and -67% at 3 ° C for polar cod). Increased thermal sensitivity of embryos under projected Pco₂ levels of thermal tolerance and therefore the breeding niche of the species (2). As a result, the spatial extent of heat-sensitive spawning habitat for Atlantic cod and polar cod may not only move to higher latitudes due to warming, but may also contract in the near future. because of the OWA.

Compared to the (known) contemporary spawning grounds of Atlantic cod and polar cod in the study area (blue areas of Figure 1, yellow dashed areas in Figure 4), our baseline simulations (1985-2004 ) suggest that spawning occurs exclusively in optimal thermal range of development of the embryo [>90% potential egg survival (PES), Fig. 4]. However, the thermally suitable spawning habitat area (SEP> 90%) is larger than the area where spawning actually occurs. For example, despite suitable temperatures, no cod spawning is currently observed in the northeastern Barents Sea (19), indicating that the quality of spawning habitat also depends on factors other than temperature. Mechanisms that prevent areas from breeding may include aberrant egg and larval dispersal, unfavorable feeding conditions, and predation pressure (8, 19).

By 2100, relentless animal production areas (RCP8.5) are expected to result in a substantial decline in PES at the main spawning sites of both species (Fig. 5, A to C). For Atlantic cod, SEPs are expected to decline around Iceland (-10 to -40%) and the Faroe Islands (-20 to -60%) and the entire Norwegian coast ( -20 to -60%), including the most important ones. spawning grounds of the Lofoten archipelago (at 68 ° N, Fig. 5A). In turn, large areas of the shelf off Svalbard and the northeastern Barents Sea will become more suitable (PSE, +10 to + 60%) due to warming and decreasing ice cover However, the potential habitat gains in the North are limited by the reduced cold tolerance of Atlantic cod embryos under osteoarthritic conditions and, possibly, by seabirds. unknown limiting factors (see above). Under RCP4.5, the thermal benefits (PSE, +20 to + 60%) of the northeastern Barents Sea largely offset the PSE reductions of Atlantic cod in some southern spawning grounds. (eg Faroe Islands: -10 to -40%) (between Svalbard, Franz Josef Land and Novaya Zemlya, Fig. 5, D and F).

Polar cod are likely to experience the most dramatic losses of spawning habitat south of Svalbard and Novaya Zemlya (PSE, -40 to -80%, RCP8.5, Figure 5B). In addition, polar cod will lose most of its habitats under ice, with the exception of a small refuge on the eastern Greenland Plateau (Figure 5B). Even non-osteoarthritic warming (RCP4.5, Fig. 5, E and F) will significantly reduce habitat suitability for polar cod spawning off Svalbard (PES, -20 to -60%) and Novaya Zemlya (PES, -10 to -40%). The widespread loss of sea ice in the RCP8.5 and RCP4.5 scenarios could indirectly affect the reproductive success of polar cod, as it protects breeding adults from predation and serves as habitat for fish. feeding in the early stages of life (5). Limiting global warming to about 1.5 ° C above pre-industrial levels (ie, the median temperature of RCP2.6) could not only minimize the reductions in PES in the current spawning two species up to less than 10% (Figure 5, Figure 1). at I) but also maintain some sea ice cover.

DISCUSSION

Our projections suggest that the impacts of egg survival on egg survival and subsequent changes in the quality of spawning habitat may be the main determinants of climate-dependent constraints on Atlantic cod and polar cod. Current results support the hypothesis that thermal tolerance ranges and embryonic habitats of both species are compressed by the progressive OWA method (2). Our results also support the idea that unmitigated climate change poses an existential threat to cold-adapted species such as polar cod (20), although we have identified cold refuges for this species in the High Arctic. Atlantic cod can follow the shift of its thermal optimum towards the poleward pole, eventually leading to the establishment of this commercially important species in areas where polar cod is currently dominant. The parallel decline in habitat quality off Iceland and the Norwegian coast (RCP8.5) implies that by 2100 spawning south of the Arctic Circle (at southern Lofoten, for example) may no longer be possible. The potential movement of commercially important fish stocks across management boundaries and exclusive economic zones poses major challenges not only to national fishermen and environmental advocates.5), but also to international organizations and regulations, which aim to avoid over-exploitation, resource conflicts and degradation of early Arctic ecosystems (4, 21).

However, if global warming is limited to 1.5 ° C above pre-industrial levels, it is unlikely that changes in thermal fitness of current spawning habitats will exceed critical Atlantic cod thresholds. and polar cod. Residual risks can be further reduced as both species can potentially adapt to climate change, either by (i) changes in the timing and / or location of spawning in current areas (22) or ii) through transgenerational processes that improve physiological tolerance (23). The uncertainties in our results are also related to (iii) the reliability and resolution of CMIP5 climate projections (24).

First, the time window for spawning in the North is limited at the end of the winter-spring due to the extreme seasonality of light and the badociated primary production (food for planktonic larvae) at high latitudes ( > 60 ° N) (22). It is therefore unlikely that significant changes in spawning phenology occur in this region. Spawning expansions to the north during historical and ongoing warming periods are well documented, particularly for Atlantic cod, which expanded its spawning activity to West Svalbard in the 1930s (25). However, the main spawning grounds (the Lofoten Archipelago for the Barents Sea population, for example) have always been occupied in past centuries, probably because of the favorable combination of biotic and abiotic maximize recruitment success (8, 22). After spawning, dispersal of eggs and larvae to appropriate growth areas – sometimes hundreds of kilometers – plays an important role in terms of connectivity throughout the life cycle and rebuilding populations (8). Spawning at other locations (as required by RCP8.5 for both species and RCP4.5 for polar cod) could disrupt connectivity and thus increase the risk of advective losses and recruitment failure (8). As a result, success in establishing new spawning habitat will largely depend on a number of factors, in addition to egg survival (prey availability, predation pressure, and connectivity), all of which are difficult to predict. to predict (2, 22).

Second, our results badume that embryonic tolerance ranges are constant across populations and generations (ie, there is no evolutionary change in this century) . These hypotheses are supported by experimental data[Parexempledestempératuresoptimalessimilairespourledéveloppementdesœufschezdifférentespopulationsdemorue([EgsimilartemperatureoptimaforeggdevelopmentamongdifferentAtlanticcodpopulations([parexempledestempératuresoptimalessimilairespourledéveloppementdesœufschezdifférentespopulationsdemorue([egsimilartemperatureoptimaforeggdevelopmentamongdifferentAtlanticcodpopulations(26see also fig. S1]as well as by field observations[Parexempledéplacementcohérentverslenorddelafraiedelamorueenréponseauréchauffementprécédent/outstanding([Egconsistentnorthwardshiftofcodspawningactivityinresponsetoprevious/ongoingwarming([parexempledéplacementcohérentverslenorddelafraiedelamorueenréponseauréchauffementprécédent/encours([egconsistentnorthwardshiftofcodspawningactivityinresponsetoprevious/ongoingwarming(17)]and phylogenetic badyzes of the evolution of thermal tolerance in sea fish[Parexemplevariationdelatolérancethermiquedemoinsde01°Cparmilliond&#39;years([Eg<01°Cchangeinthermaltoleranceper1millionyears([Parexemplevariationdelatolérancethermiquedemoinsde01°Cparmilliond'années([eg<01°Cchangeinthermaltoleranceper1millionyears(27)]. Transgenerational plasticity (TGP) can promote short-term adaptation to environmental change through non-genetic inheritance (eg, maternal transmission) (23). However, contrary to TGP theory, experiments on Atlantic cod suggest that egg viability is altered at similar levels of warming if females are exposed to heat during gonad maturation (28). This example of negative TGP corresponds to the majority (57%) of TGP studies in fish that observed neutral (33%) or negative (24%) responses (29). Given the limited capacity for short-term adaptation, it is very likely that species must abandon their traditional habitats as soon as the physiological limits are exceeded (2). As a result, our results identify not only the high-risk areas, but also the potential refuge habitats that should be prioritized for the implementation of marine reserves.

Third, the CMIP5 climate projections include uncertainties (24). To some extent, these uncertainties can be reduced and evaluated by taking into account the results of several models (see Materials and Methods). Nearshore habitats are poorly represented in current global climate models (24). The reliability of climate impact projections in these areas could be improved in future studies, as elegantly as possible using global multiresolution oceanic models with unstructured meshes (30).

In light of embryonic intolerance to OWA, we show that with unrestricted greenhouse gas emissions, large areas currently used for spawning will be less able to recruit Atlantic cod and cod. potentially cascading effects on Arctic food webs and related ecosystem services (4, 5). However, our results also highlight that mitigation measures, as provided for in the Paris Agreement, can mitigate the effects of climate change on both species. Since the current CO₂ emission trajectories give 1% chance to limit global warming to 1.5 ° C above pre-industrial levels (31), our results call for immediate emission reductions under scenarios consistent with 1.5 ° C warming to avoid irreversible damage to ecosystems in the Arctic and elsewhere.

MATERIALS AND METHODS

SUPPLEMENTARY MATERIALS

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Acknowledgments: We acknowledge the support of S. Hardenberg, E. Leo, M. Stiasny, C. Clemmensen, G. Göttler, F. Mark, and C. Bridges. Special thanks are dedicated to the staff of the Tromsø Aquaculture Research Station and the Centre for Marine Aquaculture. Funding: Funding was received from the research program BIOACID [Biological Impacts of Ocean Acidification by the German Federal Ministry of Education and Research (BMBF), FKZ 03F0655B to H.-O.P. and FKZ 03F0728B to D.S.]. Funding was also received from AQUAculture infrastructures for EXCELlence in European fish research (AQUAEXCEL, TNA 0092/06/08/21 to D.S.). F.T.D., M.B., H.-O.P., and D.S. were supported by the PACES (Polar Regions and Coasts in a Changing Earth System) program of the Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research (AWI). Previous and additional support from grants POLARIZATION (Norwegian Research Council grant no. 214184 to J.N.) and METAFISCH (BMBF grant no. FZK01LS1604A to H.-O.P. and F.T.D.) are also acknowledged. Author contributions: F.T.D. and D.S. devised the study and designed the experiments. F.T.D. conducted the experiments. J.N., V.P., and A.M. provided equipment and facility infrastructure. F.T.D. badyzed the experimental data. M.B. badyzed climate data and generated habitat maps. F.T.D. drafted the manuscript. F.T.D., D.S., M.B., and H.-O.P. wrote the manuscript. J.N., V.P., and A.M. edited the manuscript. Competing interests: The authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Additional data related to this paper may be requested from the authors. The experimental data supporting the findings of this study are available from PANGEA (https://doi.org/10.1594/PANGAEA.868126), a member of the ICSU World Data System.