Abstract
Wildlife species and populations are being driven toward extinction by a combination of historic and emerging stressors (e.g., overexploitation, habitat loss, contaminants, climate change), suggesting that we are in the midst of the planet’s sixth mass extinction. The invisible loss of biodiversity before species have been identified and described in scientific literature has been termed, memorably, dark extinction. The critically endangered Southern Resident killer whale (Orcinus orca) population illustrates its contrast, which we term bright extinction; namely the noticeable and documented precipitous decline of a data-rich population toward extinction. Here we use a population viability analysis to test the sensitivity of this killer whale population to variability in age structure, survival rates, and prey-demography functional relationships. Preventing extinction is still possible but will require greater sacrifices on regional ocean use, urban development, and land use practices, than would have been the case had threats been mitigated even a decade earlier.
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Introduction
Challenges in conservation biology are generally assigned into small population or declining population paradigms1. Resource management typically distinguishes between decisions to protect the welfare of individuals and those to promote recovery of populations2. Below a critical threshold, populations become sufficiently small that demographic stochasticity (i.e., random fluctuations in birth and death rates) can result in extinction, even when the average population growth rate is positive3. Many of these extinction events are taking place undocumented, before a species has even been described scientifically, in a process termed memorably as dark extinction4. The concept of dark extinction could lead some to conclude falsely that extinction is largely an information deficit problem. In other words, if only we knew that a population or species were declining toward extinction, we would step in to mitigate anthropogenic stressors and reverse declines. In our experience, many populations and species are declining toward extinction in plain sight. We call this latter process a bright extinction, with thanks to Boehm and colleagues for inspiring the term.
Small populations can persist despite large variability in environmental conditions around some long-term stationary state, whereas a deteriorating trend in environmental conditions increases extinction risk in small populations5. Drake and Griffen hypothesize that “environmental degradation may cause a tipping point in population dynamics, corresponding to a bifurcation in the underlying population growth equations, beyond which decline to extinction is almost certain”5. In practice, demographic parameters of wild populations are rarely estimated with sufficient precision to detect these early warning signs (a bifurcation in population rates of change) until a decline may be irreversible6,7. Evidence-based conservation requires knowledge of demographic rates, as well as natural and anthropogenic influences on those rates, to guide timely and effective interventions5,8,9. While improved tools for data analyses to assess conservation status and extinction risks are needed urgently to protect data-poor species and populations10,11, not all extinctions can be attributed to an information deficit alone12,13. To complicate matters further, the threats that lead to a legal listing recognizing a population’s endangered status may not represent the same drivers likely to lead to population recovery. Instead, wildlife population dynamics and risk of extinction can be the net result of multiple concurrent, persistent, interacting, and evolving drivers that include both natural ecological and anthropogenic factors14,15.
Population assessment of Southern Resident killer whales (SRKW, Orcinus orca) is extremely data-rich compared with those of many other wild mammals. These whales represent the smallest (75 individuals16) of four separate, non-interbreeding, behaviorally, and culturally distinct, fish- eating ecotypes of killer whales in the eastern North Pacific Ocean. Every individual in the population has been censused annually by the Center for Whale Research and colleagues since the 1970s17. Depleted in the 1960s and 1970s by an unsustainable live-capture fishery for aquaria displays, the population has failed to recover due to a combination of sublethal and lethal stressors, including reduced availability and quality of Chinook salmon (Oncorhynchus tshawytscha), its preferred prey; noise, which further reduces foraging efficiency18; contaminant exposure, which is associated with decreased fecundity, increased calf mortality, and other adverse effects19,20; and vessel strikes21. The whales’ preferred prey, Chinook salmon, are themselves heavily depleted, and the ability of Chinook salmon stocks to support survival, let alone recovery of SRKW has been in question for over two decades22,23. Years with low Chinook salmon abundance are temporally associated with low SRKW reproduction and survival22,23. Ensuring recovery of SRKW and the salmon on which they depend hinges on explicit recognition of the costs and conflicts associated with recovery of predator and prey alike24.
Results and discussion
Given observed demographic rates over the last 40 years, the baseline population dynamics model predicts a mean annual population decline of roughly 1% (Fig. 1a, b). This average decline is characterized by gradual reduction for roughly two generations (~40 years), followed by a stereotypical period of accelerating decline that presages extinction (Fig. 1). This baseline model is optimistic, because all evidence suggests that natural and anthropogenic drivers of population status are dynamic, transient, and multifactorial, and many threats are expected to worsen in future.
By using more recent data, the aforementioned relationships between interannual variability in Chinook salmon and SRKW survival and fecundity25 are changing enough that we predict that prey-mediated changes in SRKW survival and reproduction (Fig. 2a, b) are likely to lead to even more dramatic declines in the coming decades than the prior baseline model suggests (Fig. 3). Our analyses reveal that the population shows lower recovery potential than previously estimated, due to reduced leverage of prey availability on SRKW demography, adverse stochastic effects (e.g., few female offspring in recent years, mortality from vessel strikes), and potentially amplifying effects of inbreeding20,26,27. Ultimately, overexploitation caused the initial decline, but proximate effects of habitat degradation and loss (and possibly destruction) are inhibiting SRKW recovery19. The whales are also obligate prey specialists on the largest, fattiest Chinook salmon, which limits their ability to adapt to a changing environment. Accordingly, SRKW epitomize the naturally rare, wide-ranging or broadly distributed species that may be hardest to protect.
Immediate, multidisciplinary approaches, including supporting Chinook salmon recovery and appropriate veterinary interventions when indicated, will be necessary to stabilize the population (Fig. 4). Although no single scenario can help SRKWs reach one stated recovery objective of 2.3% sustained growth over 28 years, concerted efforts can reverse the decline and possibly reach 1% annual recovery. Slowing or halting the population decline might provide opportunities to develop and implement new strategies to mitigate and facilitate recovery of SRKW that are not yet feasible. In a population of 75 individuals, a single birth or death represents an annual population growth or decline of 1.4%, underscoring the value of each individual in preventing the disappearance of a population.
Recovery considerations
Treating individual wild animals to promote population recovery only benefits conservation when individual animals are known and populations are small enough for individual survival to make a considerable difference28, such as in the recovery of habituated mountain gorillas29, Ethiopian wolves30, and Hawaiian monk seals31. For SRKWs to attain a 1% population growth, non-invasive diagnostic investigations, informed clinical intervention, and ongoing post treatment monitoring of animals that present with serious morbidity or clinical disease is warranted. This extreme conservation measure enables humans to reduce mortality in high value animals, such as reproductively active females. When feasible, post mortem examination of stranded SRKWs is critical to inform future clinical decisions and management options. Interventions should be rank ordered and those injuries attributed to human activities, such as vessel strike or net, line or hook entanglement, or potential oil exposure are priorities that may warrant immediate intervention21. Other future interventions may include remote administration of antiparasitic drugs and other treatments32 for treating disease33. It may be time to discuss more drastic measures, including pre-emptive vaccination to protect individuals against pathogens with known high morbidity and mortality rates among cetaceans (e.g., cetacean morbillivirus, Brucella cetorum, Toxoplasma gondii)34. We encourage transboundary and inter- agency discussions to coordinate emergency plans for veterinary intervention, including permits and decision trees, before a high-profile crisis necessitates implementation. Emergency veterinary intervention plans could be modeled on similar bilateral, multi-agency plans to respond to an oil spill in these transboundary waters35. With timely and effective management actions (such as mandated reduced vessel speeds near whales to minimize vessel strike) to reduce human-caused mortality36, we estimate that up to 28% of natural mortality could be deferred each year (Fig. 4, Supplementary Notes). Given the delay between medical interventions and demographic changes (e.g., survival, growth, fecundity, abundance) regular evaluation of short-term health benchmarks (e.g., body condition, reproductive potential of existing population, behavior, pregnancies, etc.) is critical to strike a balance between risk and reward of any particular intervention.
Southern Resident killer whales are known to be among the most contaminated marine mammals in the world, with polychlorinated biphenyl (PCB) concentrations readily exceeding established thresholds for health effects, including growth and development, immune function, and reproductive performance37. However, PCBs are an important, but not exclusive, contaminant class found in SRKW. Despite their phase-out under the terms of the international Stockholm Convention on Persistent Organic Pollutants (POPs), the persistence of PCBs in the marine environment and resistance to metabolic elimination means that it will take decades before this population is considered to be ‘safe’ from PCB and other legacy contaminant-related health effects38. This lag between mitigation and benefits to wildlife, together with the co-occurrence of many other contaminants, suggest that threats attributable to POPs will decline, but the population consequences will linger. This lag time was accounted for using the predicted PCB level trends in this killer whale population38 and a 1.75× factor was applied to our previously modeled population impact attributed to PCBs to capture the contribution and associated risk of other POPs, including legacy organochlorine pesticides (OCPs). This 1.75× factor was derived from a endocrine disruption risk-based quotient for local harbor seals (Phoca vitulina)27, a species that has been used previously as a surrogate to characterize Resident killer whale contaminant levels and risk in the North Pacific39. Contaminant mitigation alone will be insufficient to promote population growth, but should be considered as one pillar of a comprehensive, ‘action’-oriented plan to protect at-risk coastal cetaceans40,41.
Biological resilience is partially determined by genetic diversity. Due to the decline in the SRKW population from the 1960s, the population is currently so small that there are relatively few breeders (especially males) and, that we anticipate inbreeding will exacerbate this process and population decline (Fig. 1). In this way, the continued loss of genetic diversity will likely hamper the population’s ability to adapt to an ever-evolving threatscape. Kardos et al. found that the SRKW population is already partly inbred and that reduced survival further jeopardizes its recovery potential26. Recovery is currently more difficult than if effective measures had been initiated a few decades ago, although other small marine mammal populations with low genetic diversity have continued to reproduce effectively42.
The time scales needed to detect demographic effects of threats and benefits of mitigation might be too long in this species to be the primary metrics by which we gauge success (Fig. 4). Short-term benchmarks (e.g., body condition, growth rate, pregnancy, behavior, etc.) for measuring the success of mitigation measures are critical given the long lifespan, low reproductive rate, and small sample size in this population. In fact, Canada’s Species At Risk Act outlines a recovery goal to: “ensure the long-term viability of Resident Killer Whale populations by achieving and maintaining demographic conditions that preserve their reproductive potential, genetic variation, and cultural continuity43.” Environmental degradation may manifest in social network fragmentation and loss of cultural traditions (e.g., resting lines and greeting ceremonies) long before demographic effects become detectable against background fluctuations.
Marine species are no more or no less vulnerable than terrestrial counterparts to extinction44. Although indiscriminate exploitation and unintentional bycatch tend to be the dominant factors in decline and extinction of marine taxa, habitat loss is a close second44. Predicting when and how a species is likely to go extinct is extremely challenging, but it is a fundamental task of conservation science45. Without rich demographic data on wildlife populations, extinction risk due to habitat loss can be modeled in a species-area relationship framework. Species-area approaches can overestimate the proportion of habitat loss that would result in the removal of the last individual from a population. An inverse relationship has been found between species diversity and density, so protecting part of a species’ range, without considering density, habitat use, or sampling effort, can lead to a false sense of confidence about population-level protection46. One study found a 53-year average lag between the time of the last sighting of a species and its reported extinction44. None of these statistical issues are at play for SRKW, in which clinically ill and lost animals are recognized through ongoing surveys and a census that is conducted annually.
Although wildlife censuses are rare in conservation biology, many seemingly irreversible and overt population declines are being witnessed in plain sight, even when the causes of these declines are well known. We use the term bright extinction to refer to data-rich cases where a decline toward extinction has been identified early, the driver(s) of the decline have been well quantified, but the population has declined to a precarious state nonetheless despite interventions. The loss of the baiji (Yangtze River dolphin, Lipotes vexillifer) illustrates the bright extinction concept well7. The species was extirpated from part of its range by the 1950s, and a precipitous decline in its core habitat was well documented between the 1980s and 1990s. In this case, the cause was attributed to fisheries-related mortality. By 2006, the population was declared functionally extinct. Proposals to create an ex situ or semi-natural reserve were made and ignored since the 1980s; perhaps policy-makers thought we had more time than we did47. A similar bright-extinction process appears to be underway for vaquita (Phocoena sinus) in the northern Gulf of California, Mexico48. The species has been declining since the 1990s due to unsustainable bycatch levels in fish and shrimp gillnet fisheries. Although the decline is well documented and the cause well understood, management actions have proven insufficient49. By 2018, only nine individuals were thought to be left50. Numbering in the low hundreds, North Atlantic right whales (Eubalaena glacialis) are also facing unsustainable levels of human-caused mortality due to vessel strikes and entanglement in fishing gear51.
Importantly, these select examples represent cases where declines in small and highly vulnerable populations have been detected. The loss of each animal reduces the power to detect decreases in population abundance52. If we are unable to implement timely interventions of these high-profile species, what hope do we have for meeting our current and future biodiversity conservation objectives at large?
Preventing bright extinctions: from knowledge to action
Preventing extirpation of small populations may require extraordinary measures, but several populations of terrestrial and marine wildlife recovered from the brink of extinction offer a useful roadmap to ensure survival and recovery of SRKW.
The California condor (Gymnogyps californianus) was decimated to 27 individuals by 1987, from a combination of poaching, cyanide and lead poisoning, and habitat degradation. Captive breeding saved the population from extinction. Although infectious disease did not cause the initial decline, the US Fish and Wildlife Service has begun testing avian influenza vaccines in captive condors and considers capture and vaccination of wild condors in face of the ongoing multi-year epizootic53. Owing to declines in prairie dog (Cynomys sp.) (prey species) and their habitat, the black-footed ferret (Mustela nigripes) was once thought to be extinct; however, after the species was rediscovered in Wyoming in 1981, captive breeding and reintroductions, habitat protection, vaccination against canine distemper and cloning helped restore this species to over 300 free-ranging animals. Like SKRW, black-footed ferrets were largely dependent on a single prey species, prairie dogs. All of those conservation efforts for the black-footed ferret could be undone by a single outbreak of plague in their prey, necessitating management vigilance to prevent a disease outbreak54. By the time the whooping crane was listed as endangered in 1967, only 50 birds remained. Whooping cranes (Grus americana) remain one of North America’s most threatened birds, but their recovery to an estimated 600 birds today is a testament to the progress that is made possible by acting decisively55. Mountain gorillas (Gorilla beringei beringei) were thought to be extinct by the end of the 20th century, but a large population now resides in protected forest in Uganda, Rwanda, and the Democratic Republic of the Congo29. Extreme vigilance in the form of veterinary monitoring and intervention is now needed to prevent backsliding and gorilla mortality56. Other populations brought back from the brink include black robin (Petroica traversi)57 and the Eastern barred bandicoot (Perameles gunnii)57. In both cases, low levels of genetic diversity did not prevent recovery. Brazil’s golden lion tamarin (Leontopithecus rosalia) was recovered from a few hundred individuals in the 1970s to about 3700 individuals in 2014 after actions were taken to restore habitat, re-establish connectivity via wildlife corridors, and release captive animals and conduct translocations among wild tamarins58. A yellow-fever epidemic in 2017–2018 reduced the population to about 2600 individuals, a decline that would have doomed the species had their habitat and population numbers not been previously recovered58.
Meanwhile, as Caughley warned1, many previously wide-ranging species have declined in plain sight. Boreal woodland caribou (Rangifer tarandus caribou) have been extirpated from vast sections of their range due to habitat loss and hunting, with few signs of success following recovery efforts59. Having failed to address those root causes, predation on calves now appears to be inhibiting population growth60. Karner blue butterfly (Plebejus samuelis) are dependent on the native sundial lupine, which has been eliminated from much of its range due to habitat loss and replacement in the northeast by Lupinus polyphyllus, a western species that has been introduced in the east. Conservation of Karner blue butterfly cannot be assured without aggressive measures to reduce ultimate population stressors and protect the microsites on which large fractions of the population depend61. Decades of warnings failed to prevent the functional extinction of northern white rhino (Ceratotherium simum cottoni) due to hunting and poaching, while conservation organizations and governments debated if, when, how, and who should act62. There is an ongoing debate whether radical proposals to clone the northern white rhino may come at the cost of urgently needed measures to prevent the extinction of southern white rhinos63.
While many species have been brought back from the brink through interventions such as captive breeding programs, SRKW recovery will require aggressive actions to protect and restore their habitat, which includes mitigating effects to both SRKWs and their primary prey, Chinook salmon. Our analysis showed that the threat with the greatest impact to SRKW population growth is the availability of Chinook salmon (Fig. 3, Supplementary Fig. S20). Salmon recovery is a crucial component of achieving SRKW recovery. Although no salmon recovery scenario alone resulted in a fully recovered SRKW population, all of the successful multi-threat mitigation scenarios included some ambitious salmon recovery scenario.
Vessel noise can reduce the amount of time SRKWs spend foraging18, but it can also have a direct impact on the behavior of prey species64, limiting the number of salmon available to SRKWs. Efforts to mitigate impacts from vessel noise include a suite of approaches ranging from building quieter ships to designating slowdown areas65. Voluntary efforts to slow ships in important feeding areas for SRKWs has been shown to reduce noise levels by nearly half 66, which in turn results in increased foraging activity by killer whales18. While efforts are underway to reduce noise from existing ships, a number of development applications are underway that would increase shipping traffic in the region67. It may be necessary to consider ocean noise budgets, caps, or limits that allow killer whales to hunt scarce prey efficiently.
Protecting SRKWs appears to be impossible without restoring diminished populations of Chinook salmon, which in turn requires effective implementation of conservation and precautionary resource management measures. Implementation will require acknowledgement of the potential trade-offs involved between conservation and resource management, including harvest, and open dialog between involved agencies and stakeholders24. Both Canada and the USA have produced recovery plans and strategies for SRKW43,68. Those plans have recognized the need to ensure adequate prey sources for survival and recovery of SRKW since at least 2008. In a declining population, the longer the lag time between knowledge and mitigation, the more draconian the recovery actions can become, with a larger social cost, and a higher risk that harm reduction actions may not work69,70. Unfortunately, a legal species listing alone is insufficient to ensure survival and recovery of threatened taxa63. In the face of bright extinction, targeted threat reduction measures and community involvement, in addition to monitoring, are needed to reverse declines71. Yet the capacity to determine what we can do often outstrips our ability to decide what we will do; a dilemma that leads to delays in threat reduction measures and perpetuates extinction debt, especially in long-lived species72.
Abundant examples, however, of successful rescues of plants, insects, and animals in aquatic, terrestrial, and aerial environments confirm that we can halt the loss of endangered wild species and that extraordinary measures can even recover critically imperiled ones. Unfortunately, these eleventh-hour rescues carry higher environmental and societal costs than earlier actions might have. Preventing extinctions of populations on the brink require a high degree of planning and coordination by scientists, managers, decision makers, stakeholders, and affected communities, and may require higher levels of threat reduction than would have been the case had actions been taken sooner. The benefits of species recovery may be difficult to define, both in terms of reversing global biodiversity loss and to the long-term resiliency and health of ecosystems. Rising to the challenge of biodiversity conservation requires robust data on species and threats, but also acting on those threats in a timely manner73.
Methods
We used program Vortex 10.6.0 to parameterize a population viability analysis (PVA) model (software and manual available at scti.tools/vortex) for Southern Resident killer whales (SRKW)20 with demographic rates observed over 1976 through 2022. We tested the sensitivity of population growth to variability and uncertainty in fecundity and survival rates (by age class), and prey-demography functional relationships22,23. Next, we constructed a PVA that explores population consequences of the three primary anthropogenic threats to SRKWs identified in Canadian and USA recovery plans, namely prey limitation (Chinook salmon), noise-mediated disruption of foraging, and effects of contaminants (e.g., PCBs).
We ran more speculative scenarios to consider the threat of not only PCBs, but also other POPs including legacy organochlorine pesticides (OCPs), pathways of effects of contaminants on calf survival74,75, climate-mediated impacts of Chinook salmon on SRKW demography22,23, climate- and fisheries-related declines in the size of Chinook salmon76, and increased oil spill risk related to industrial development applications in the Salish Sea67. In addition to modeling population consequences of threats, efforts were made to model the likely population-level benefits of management measures intended to mitigate human-caused impacts to abundance and population structure from fisheries.
Addressing prey needs requires increasing the abundance of large, older Chinook. Increased abundance and quality of prey within SRKW critical habitat can be realized by changing fishing practices. Moving Pacific Salmon Treaty fisheries in Alaska and BC away from Chinook rearing grounds and migration routes into terminal river and estuarine locations results in an immediate increase of Chinook salmon in critical habitat of up to 25% (Supplementary Table S2). Secondly, transitioning marine fisheries to terminal (river-based) areas can recover a more archetypical Chinook age structure (early- mid 20th century). By not harvesting immature fish in marine fisheries, and then allowing large females to pass through terminal fisheries to spawning grounds, a size increase up to 40% can occur over a 50-year period. Scaling these scenarios to consider both improved value and abundance of mature Chinook salmon in critical habitat results in increases of 35%, 28%, 18%, and 9% at the end of 50 years, if scaled for effectiveness at 100%, 75%, 50%, and 25% (Supplementary Table S2). While not quantified, freshwater habitat restoration and protection would further support recovery of wild Chinook abundance.
The relative importance of each threat and mitigation opportunities were explored by projecting the population growth across the possible range of each threat. Finally, we used the PVA to explore the degree to which threats would have to be mitigated, alone or in combination, to stop the decline and achieve positive population growth toward recovery68.
For the baseline model, parameters for fecundity and survival (for calves; subadults young, older, and post-reproductive adult females; young and older adult males) were estimated from 1976 to 2022 data (Table 1). Prey availability was drawn from the Chinook prey indexed to the mean from 1976 to 2022 (i.e., impacts scaled such that when Chinook = 1, demographic rates are the means over that time span). The prey-demography relationship of killer whale breeding rate and survival of each age class to the Chinook salmon index was drawn from a recent re-analysis77. Inputs for noise (disturbance) impacts and its effect on feeding were as in Lacy et al.20. We used the model from Hall et al.74 for PCB accumulation and depuration parameters and the impact on calf survival was estimated through a comparison between a sympatric killer whale population, Northern Resident killer whales and SRKWs. A 1.75× factor was applied to our previously modeled population impact attributed to only PCBs to capture the contribution and associated risk of other POPs, including legacy OCPs. The factor was derived from a risk-based quotient for endocrine disruption for local harbor seals (Phoca vitulina)27. Inputs for variance in male breeding success were sampled from beta distribution (mean = SD = 0.40). Effects of inbreeding depression were set to 6.29 lethal equivalents per diploid, imposed via reduced calf survival.
Data availability
Please see additional technical details on methods and results in the Supplementary Notesfile. The data needed to replicate the model can be found on Zenodo at: Lacy, Robert C, & Williams, Rob. (2023). Vortex project file for PVA of Southern Resident Killer Whale — manuscript by Williams et al. (1.0) [Data set]. Zenodo. https://doi.org/10.5281/zenodo.8099710.
Code availability
The Vortex code needed to replicate the model can also be found on Zenodo at: Lacy, Robert C, & Williams, Rob. (2023). Vortex project file for PVA of Southern Resident Killer Whale — manuscript by Williams et al. (1.0) [Data set]. Zenodo. https://doi.org/10.5281/zenodo.8099710.
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Acknowledgements
We are grateful to Puget Sound Partnership for funding this study, with special thanks to Scott Redman. This project was a collaborative, interdisciplinary endeavor. We thank both US and Canadian government, community, and non-profit partners who contributed to and attended a webinar on “Assessing the status, threats, and options for the Southern Resident killer whale”. The Vortex PVA software is made freely available by the Species Conservation Toolkit Initiative and its sponsoring organizations. Open Access page charges were covered by the BC Ministry of Agriculture and Lands and SeaDoc Society, a program of the UC Davis Karen C. Drayer Wildlife Health Center.
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R.W. conceived of the study, coordinated the project, and contributed to writing. R.C.L. conceived of the study, performed all statistical modeling with custom code, and contributed to writing and editing. E.A. conceived of the study and contributed to writing. L.B.L. contributed to writing. T.M.B. contributed to writing. J.K.G. contributed to writing and editing. F.G. contributed to writing. M.M. contributed to writing and editing. B.W.N. parameterized the prey-demography part of the model. K.A.N. generated figures and contributed to writing and editing. H.N. contributed to writing, particularly related to veterinary interventions. S.Raverty contributed to writing. S.Reiss assisted with project coordination. P.S.R. contributed to writing, particularly related to prey impacts. M.S.C. generated figures and contributed to writing and editing. R.S. contributed to writing. P.P. contributed to writing and editing.
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Communications Earth & Environment thanks Robert Harcourt and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Primary Handling Editor: Clare Davis. A peer review file is available.
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Williams, R., Lacy, R.C., Ashe, E. et al. Warning sign of an accelerating decline in critically endangered killer whales (Orcinus orca). Commun Earth Environ 5, 173 (2024). https://doi.org/10.1038/s43247-024-01327-5
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DOI: https://doi.org/10.1038/s43247-024-01327-5
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