npj | ocean sustainability Perspective https://doi.org/10.1038/s44183-024-00078-2 Rethinking sustainability of marine fisheries for a fast-changing planet Check for updates Callum Roberts1 , Christophe Béné2, Nathan Bennett3,4,5, James S. Boon6,7, William W. L. Cheung5, Philippe Cury8, Omar Defeo9, Georgia De Jong Cleyndert6,10, Rainer Froese11, Didier Gascuel12, Christopher D. Golden13, Julie Hawkins1, Alistair J. Hobday14, Jennifer Jacquet15, Paul Kemp16, Mimi E. Lam17, Frédéric Le Manach18, Jessica J. Meeuwig19, Fiorenza Micheli20, Telmo Morato21, Catrin Norris1, Claire Nouvian18, Daniel Pauly5, Ellen Pikitch22, Fabian Piña Amargos23,24, Andrea Saenz-Arroyo25, U. Rashid Sumaila5, Louise Teh5, Les Watling26 & Bethan C. O’Leary1,6 Many seafood productsmarketed as “sustainable” are not.More exacting sustainability standards are needed to respond to a fast-changing world and support United Nations SDGs. Future fisheries must operate on principles that minimise impacts on marine life, adapt to climate change and allow regeneration of depleted biodiversity, while supporting and enhancing the health, wellbeing and resilience of people and communities. We set out 11 actions to achieve these goals. Healthy oceans are critical for nature, human wellbeing and planetary sta- bility. Marine life, including exploited species, are essential to that health, driving biological, chemical and physical processes integral to ecosystem functioning and services to people1,2. Yet most countries are failing to meet targets under the Paris Agreement, the United Nations Sustainable Devel- opment Goals (SDGs) for poverty reduction, zero hunger and adequate nutrition, climate action, reduced inequalities, environmental and ocean protection3, as well as the Global Biodiversity Framework4. To meet these global aspirations, we must move beyond business as usual, reimagine sustainability standards for fishing that will be resilient and adaptable in the face of rapid global change, and develop creative ways to implement them. Marine fish contribute significantly to global food and nutritional security, particularly through subsistence, artisanal and commercial small- scale fisheries and in the Global South5. The healthier nutritional profile of seafood versus terrestrial animal foods has led to increased promotion of seafood6 with the global rate of its consumption continuing to outpace that of human population growth5 and projected to nearly double by 20507. Today, wild seafood is sourced through an extraordinary diversity of social- ecological systems that operate from coastal habitats through to the open ocean and target a plethora of animals and plants8.Managing fisheriesmore sustainably is a global imperative given the increasing numbers of people living in hunger9. Many of the world’s fish populations remain overfished and in decline5,10, despite improvements in fisheries management and fishing practices for some species and in some countries11. Numerous fishing companies operate in ways that generate wide environmental impacts on 1Centre for Ecology and Conservation, University of Exeter, Cornwall, UK. 2Institute of Development Studies, Library Road, Brighton, BN1 9RE, UK. 3Global Science, WWF, Washington DC, USA. 4People and the Ocean Specialist Group, Commission on Environmental, Economic and Social Policy, International Union for the Conservation of Nature, Gland, Switzerland. 5Institute for the Oceans and Fisheries, University of British Columbia, Vancouver, Canada. 6Department of Environment and Geography, University of York, York, UK. 7School of Geography, University of Nottingham, Nottingham, UK. 8MARBEC, IRD Sète, Univ Montpellier, CNRS, Ifremer, France. 9UNDECIMAR, Faculty of Sciences, Montevideo, Uruguay. 10Cumbria Wildlife Trust, Crook Rd, Kendal, LA8 8LX, UK. 11GEOMAR,Wischhofstr. 1-3, 24148 Kiel, Germany. 12Research unit Dynamics and sustainability of ecosystems: from source to sea (DECOD), Institut Agro / Inrae / Ifremer, Rennes, France. 13Department of Nutrition, Harvard THChan School of Public Health, Boston,MA, 02115, USA. 14CSIROEnvironment, Hobart, Tasmania, 7000, Australia. 15Department of Environmental Science and Policy, Rosenstiel School of Marine, Atmospheric, and Earth Sciences, University of Miami, 4600 Rickenbacker Causeway, Key Biscayne, FL, 33149, USA. 16Department of Civil, Maritime and Environmental Engineering, Faculty of Engineering and Physical Sciences, Boldrewood InnovationCampus,University of Southampton, Southampton,UK. 17Centre for theStudyof theSciences and theHumanities, University of Bergen, P.O. Box 7805, N-5020 Bergen, Norway. 18BLOOM, 16 rue Martel, 75010 Paris, France. 19Marine Futures Lab and Oceans Institute, University of Western Australia, Crawley, WA, 6008, Australia. 20Oceans Department, Hopkins Marine Station, and Stanford Center for Ocean Solutions, Stanford University, Pacific Grove, CA, 93950, USA. 21Institute of Marine Sciences—Okeanos, University of the Azores, Horta, Portugal. 22Institute for Ocean Conservation Science, School of Marine and Atmospheric Sciences, Stony Brook University, Stony Brook, NY, 11794, USA. 23Environmental Advisor, Blue Sanctuary-Avalon, Jardines de la Reina,Cuba. 24Center forMarineResearch, University ofHavana, LaHabana, Cuba. 25DepartamentodeConservaciónde laBiodiversidad, ElColegio de la Frontera Sur (ECOSUR), Avenida Rancho Polígono 2-A, Ciudad Industrial, 24500 Lerma Campeche, Campeche, Mexico. 26School of Life Sciences, University of Hawaii at Manoa, Honolulu, HI, 96822, USA. e-mail: c.m.roberts@exeter.ac.uk npj Ocean Sustainability | (2024) 3:41 1 12 34 56 78 90 (): ,; 12 34 56 78 90 (): ,; http://crossmark.crossref.org/dialog/?doi=10.1038/s44183-024-00078-2&domain=pdf http://crossmark.crossref.org/dialog/?doi=10.1038/s44183-024-00078-2&domain=pdf http://crossmark.crossref.org/dialog/?doi=10.1038/s44183-024-00078-2&domain=pdf mailto:c.m.roberts@exeter.ac.uk www.nature.com/npjoceansustain ecosystems and habitats. Adding to these systemic problems, maximum sustainable yield (MSY), internationally recognised as the standard for sustainable fishing, is based on a single-species approach that takes into account neither interactions among species nor impacts on habitat or ecosystemroles playedby target species12. Repeated calls andmuch evidence for the need for an ecosystem-based approach to fishery management13,14 and guidance for its implementation15 have had limited influence to date. The impacts of fishing on marine life and the people that depend on them are exacerbated further by climate change and other anthropogenic stressors16. The world is changing fast, and fisheries management, as presently practiced, largely lacks measures to ensure long-term ecological resilience and social equity17,18 in not only sustainable, but also ethical fisheries19. We must transition towards viewing fishing as a privilege, rather than a right. Privatefishers andfishing enterprises should exploit publicfishery resources with attendant ethical responsibilities to limit environmental harm and promote societal benefit20,21. The slow pace of change towards more sus- tainable practices guarantees that marine fisheries will not, on their present trajectory, meet the urgency of global challenges. How then, can we adapt and future-proof fisheries in the face of long-term climate change and uncertainty? Reform of marine fisheries is a central mechanism to improve ocean health, offering the opportunity tominimise the ecological impact of one of the largest and most widespread direct drivers of degradation22–25. Such reform will also amplify societal benefits from marine fisheries to human health, wellbeing and livelihoods26–28. Here we offer a vision for the future of ocean exploitation inwhichmarine life andfisheries play a central role in the delivery of the SDGs. The Vision: Marine fisheries should minimise the eco- logical impact of every fish caught and maximise its societal benefit Marine fisheries are managed as social-ecological systems that recognise and respect relational values between humans and nature, support thriving oceans, and amplify the value of marine life to people and the planet. Their management recognises that fish and invertebrates are wild animals, the use of which entails reciprocal obligations to safeguard species and the wider environment. Fishing, when allowed, should be conducted in ways that sus- tain and recover ecological integrity and function, now and into the future, including measures to mitigate and adapt to climate change. Fishing mini- mises disruption to the natural world, in recognition of ocean health and the life support systems on which people and nature depend. Fishing provides for direct human consumption and food and nutrition security, is undertaken in ways that are socially just and equitable, promote human wellbeing and protect human rights, including the rights of Indigenous Peoples and small- scale fishers. Fisheries are managed within institutionally robust and trans- parent systems underpinned by effective and collaborative principles and participatory procedures that focus on community and economic viability. Detailed social-economic (e.g. access, allocation, employment, economic benefits, wellbeing) and environmental data (e.g. quota allocation, geoloca- tion data) relating to commercial fisheries are made publicly available by national governments or intergovernmental regulatory bodies. Fisheries support decent jobs and livelihoods within environmental limits unsupported by harmful subsidies; internalise the economic, social, and environmental costs offishing, including on ecosystem goods and services; and account for the full economic, social and cultural values of the fishery. This view was deliberated and agreed upon by the co-authors, including ecologists, fisheries scientists, conservationists, social scientists, ethicists, economists, and food systems specialists. It challengesmainstream perception and practice, particularly for fisheries that employmethods with large environmental impacts, such as trawls and gillnets. To achieve sys- temic change to fishing practices and management, we must widen the present narrow objectives of traditional stock assessment to support diverse and healthy oceans and communities. Fishery managers, fishers, fishing companies and retailers must take responsibility to recover, protect and supportmarine life, and thereby sustainhumanwellbeing and their business interests. Such actionswill improve resilience andpromote adaptation to the growing risks posed by climate change. In the following we present two core principles and a series of key actions to transform fisheries for the future (Fig. 1). Principles for sustainable marine fisheries Principle 1: Fisheries must minimise environmental harm, allow for the regeneration of marine life and habitats, and adapt to climate change Marine life and habitats provide the natural capital basis of economic via- bility for fishing businesses. Against a global context of rapid environmental change, robust ecosystem functioning and resilience are foundational pre- requisites for future fisheries sustainability and continued delivery of critical ecosystem services. These attributes are poorly served by the present focus on single species managed for maximum productivity. Managers must instead, by default, consider the wider ecosystem impacts of fishing and prioritise lower impact activities, coupled with measures that protect and promote ecosystem regeneration such as rebuilding depleted populations, creating fully protected marine protected areas, managing coastal devel- opment and restoring critical habitats. Healthy ecosystems function better than degraded ones and support services important towider society, such as carbon sequestration and good water quality. Fisheries must also address their own contributions to the climate crisis through activities that are polluting (e.g. ghost gear andplastics) or carbon intensive (e.g. towedfishing gears) or destructive (e.g. disturbance of sediment carbon stores and slow growing habitat forming species). Action 1: Fish less and manage fisheries for lower impact Overfishing, by which we mean excessive take leading to population depletion below productive levels, has many causes. The most common are inadequate (or absent) regulation and enforcement, overcapacity, insuffi- cient or inaccurate understandingof stock status, amisguided concentration on andflawed application of the concept ofmaximumsustainable yield, and insufficient attention to the difficulty of managing mixed species fisheries. The latter illustrates one of the most fundamental failings of conventional management: the impossibility of simultaneously fishing for all species at MSY29,30. Historically, species with life histories vulnerable even to low levels of fishing mortality (large size, slow growth, late maturation, long-lifespan, often from high trophic levels), have been progressively depleted and lost frommixed-species fisheries, leading to eventual industry dependence on a few resilient species, often from low trophic levels, such as prawns, scallops orflatfish31,32.While suchfisheriesmay still be productive andprofitable, the loss of other species leads to ecosystem simplification, impairing function and resilience31,33. Ecosystem functioning can also be compromised directly by removal of large volumes of planktivorous species (often called forage fish), which further negatively impacts higher trophic levels, including animals like seabirds and marine mammals that are not targets of fishing34. Governing fisheries to support higher biomass levels in the wild for both target andnon-target specieswould rebuild ecosystemfunctioning and resilience, reduce management risk, increase room for error and buffer the effects of environmental fluctuations and change. Reducing exploitation rates, combined with shifting to more selective fishing gears, e.g. increasing mesh size12, or to placeswith lowerbycatchand less sensitive habitats, would produce higher population sizes, increase catch per unit effort, reduce fishing costs and cause less damage to habitats and non-target species12,35. Lower exploitation rates may also align more closely with maximum eco- nomic yield, the point of highest fisheries profitability36. Considerable dis- agreement exists surrounding the level of biomass towhich a populationhas to fall relative to its unfished state before it is considered overexploited37–39, with some estimates as low as 20%40,41. Reducing the abundance of marine life to low levels leaves very little room for uncertainty in estimates and error in management. Further management jeopardy arises because the unexploited biomass of a population on which reference points are based is often unknown or unobtainable and may become irrelevant under climate https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 2 www.nature.com/npjoceansustain change or some other environmental shock. Such reductions also amplify population variability in exploited species42 as well as adverse ecosystem consequences from fishing43. Climate-adaptive fisheries management, particularly for exploited populations in need of rebuilding, requires fishing levels to be well below MSY44.Maintaininghigherbiomass could also enhance the ocean’s ability to sequester carbon45,46. Adopting a biomass target of at least 60% of unfished levels (or appropriate population benchmark for naturally highly variable populations), would better secure ecosystem function andminimise risk47,48. In the absence of detailed stock assessment data, precautionary exploitation rates canbe adoptedbasedon local ecological knowledge and/or values from better monitored populations of the same or comparable species. Action 2: Rule out gears and fisheries that generate significant collateral damage Some fishing methods, such as fishing with explosives or poisons, are so destructive to habitats and ecosystems that they are already prohibited almost everywhere.Many currently allowedfishingmethods, however, have significant destructive impacts that are not fully acknowledged or accepted for reasons of long use due to historic legacy and culture, resistance to change or lack of political will. Seabed-contacting mobile gears such as trawls, demersal seines and dredges fall into this category. They scrape, dig upandpulverisemarine life in theprocess of catchingfish and shellfish, such that regularly fished areas come to be dominated by shifting gravel, sands and mud, while marine animal forests such as mussel and oyster beds disappear49,50.While fishing is changing the functioning of the ocean carbon pump51, a key process for mitigating climate change, bottom trawls, demersal seines and dredges have an additional specific impact by dis- rupting nature’s carbon stores and causing re-release of greenhouse gases to ocean and, potentially atmosphere, although themagnitude of this release is still uncertain52,53. The lack of selectivity of mobile gears contributes to the problem of bycatch, and fishers’ associated action of discarding, which causes waste and ecosystem disruption and threatens species with vulner- able life histories. Their continued use has contributed to the loss of other target fishery species, often long ago, and prevents the re-establishment of complex, flourishing ecosystems that support larger bodied fish and other wildlife and act as active carbon stores54. Other fishing methods result in large amounts of bycatch and eco- system disruption, including gillnetting, surface longlining and the use of drifting fish aggregating devices (dFADs) in purse seine fisheries. The impacts vary with the specificity of the catch, for example purse seines targeting free-swimming single species schools result in cleaner catches than those targeting mixed schools associated with dFADs55. The waste asso- ciated with bycatch of undersized, unwanted or over-quota species has long been accepted as a necessary cost of fishing. Even sustainability standards that claim to promote low impact fishing have internalised this logic, per- mitting substantial bycatch, including seabirds and marine mammals, in eco-certified fisheries56. Such bycatch has been justified by recourse to the specious argument that it is insufficient to further endanger these species (or prevent their recovery). However, as this impact is often assessed at vessel or company-level, the full cumulative impact across all vessels in a givenfishery is neither properly quantified nor considered. Bycatch can be reduced by switching fishing gear, redesigning it or altering fishing practices (e.g. setting at a different time of day or avoiding places with high levels of bycatch species), although there are technological and economic limits to effectiveness57. Economic instruments canbe used as in Namibia, for example, where fishers are required to land all bycatch and they are charged for any they land58. As interactions with fishing gear Fig. 1 | Roadmap to fisheries reform. The two principles and 11 actions required to transition to sustainable marine fisheries. https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 3 www.nature.com/npjoceansustain represent risk and danger for all species, even when not immediately fatal59, the cumulative effect is often further decline, especially for rare and endangered species with low reproductive output60.Where fishingmethods cannot be modified to sufficiently mitigate collateral damage, continued exploitation runs counter to sustainability principles and so should cease. For culturally important species, this raises the difficult issue of how to sustain cultural connections to vulnerable wildlife. Regardless of who it is that does the fishing, sustainable use is necessary to secure long-term rights and opportunities to natural resources. Cultural connections can be severed by traditional uses as well as by external operators using industrialmethods. Targeting species that can be caught more selectively with less dama- ging gear is important. Using static bottom gears such as longlines or handlines, for example, may reduce environmental harms61 and mitigate unwanted catches62. Selective fisheries have the further advantage of sim- plifying stock assessments, thereby improving management advice and success of implementation. Action 3: Set limits on the size of boats and gears A gradual increase in fishing power over time—technological creep—is a near universal tendency of fisheries63,64. One manifestation is the growth in size of fishing vessels and gear deployed, and another is the increasing sophisticationof the technologies theydeploy.These trends also concentrate capital into fewer hands, sometimes creating monopolies, narrowing the distribution of economic and social benefits from fishing65. Many fisheries are highly carbon intensive, burning large quantities of fossil fuels often made cheaper by capacity-enhancing government subsidies. Among the worst performers in terms of fuel burned per tonne of landings are crus- tacean fisheries66, fisheries that operate in distant waters, deploy heavy mobile gears like trawls, or target high value, low yield species like swordfish67; most of them are propped up by subsidies68,69. Economic considerations dictate that more powerful vessels con- centratefishing effort in placeswith high catch rates, but the scale of impacts increases with higher capacity. In combination, these attributes can lead to localised depletion of target and non-target species. Even where quotas are low relative to estimated overall stock size, such as with Antarctic krill, fishing sub-stock by sub-stock could exacerbate climate change ecosystem effects and accumulate over time into widespread decline70,71. Fleets made up of smaller boats can theoretically more easily match fishing effort to stock productivity, spread effort over wider areas, and avoid the serious impacts associated with higher-capacity gears. They are usually employment-intensive, sharing the economic rent of fishing among many fishers, and more generally participating in the economic, social lives, cul- ture and wellbeing of coastal communities. Nonetheless, small-scale fish- eries have problems of their own. There are many examples of overfishing, species loss and environmental damage in intensive artisanal fisheries, which are as important to resolve as issues affecting industrial fishing72,73. All fisheries use gears that can either be incidentally or, in some cases, purposefully lost during or after operation. Lost or discarded fishing gears often make up the largest category of plastic waste in the open sea74. Excluding gear deliberately disposed of by unscrupulous fishers when damaged or redundant, some gears are especially prone to loss such as gill nets, traps anddriftingfish aggregatingdevices75.Gears lostwhile inusemay continue to ghost-fish for weeks, months or even years, causing long term harm to marine life through pollution, entanglement and mortality. Man- datory labelling of fishing gear could encourage better stewardship as penalties could be levied on lost and retrieved gear. Awareness of the pervasive impacts of ocean-borne plastic pollution has increased dramatically in recent years. An increasing number of recyclable gears are being tested and facilities to properly dispose of and recycle unwantedgear are becomingwidespread.More generally, thefishing sector has to engage in the circular economy if it is to promote the sus- tainability of its products. The concept of fisheries sustainability must embrace the full impact of fishing on the environment and society, ruling out those fisheries that wilfully or carelessly contribute to overfishing, loss of livelihoods and wildlife and the burden of ocean pollution. Action 4: Source only from fisheries with good governance, sustainable stocks, and sufficient data to assure sustainability Over 90% of the world’s marine species are transboundary76, meaning fisheries often exploit populations shared by multiple countries18. Their management is therefore a collective responsibility undertaken through negotiationbygovernment representatives. Such arrangements often lead to risk-prone decisions whereby quotas are set higher than is considered safe by scientific assessments and overfishing ensues, even in places like Europe where good scientific advice is often readily available77,78. The Eastern Atlantic bluefin tuna was a notorious victim of serial mismanagement but also illustrates how stocks can recover following more responsible decision making79. Similarly, the status of many other major tuna stocks has also improved in the last decade, in part the result of a turn toward (hypothe- tically) apoliticalmanagement frameworks knownas harvest control rules80. In particular, small-island developing states in the Pacific have demon- strated how rights-based management may be effective even for trans- boundary, highly migratory fish81, and these nations have asserted substantial governing power in an industry still dominated by foreign fishing companies82. In this part of the world, access to fishing in island state waters is basedon an annual vessel effort limit, rather than a species quota or volume limit. As of 2021, all tuna populations in the Western and Central Pacificwere consideredbiologically healthy,which is no small feat givenhalf of the global tuna catch comes from here83. At the same time, some gov- ernments continue to act irresponsibly under international management frameworks and set excessive quotas in the short term that drive fisheries further into overfishing, as is the case, for example, for yellowfin tuna in the Indian Ocean84. Their actions are incompatible with sustainability. A frequent response to overfishing is to diversify into catching other, less exploited species e.g ref. 85. The approach is encouraged by fisheries managers and directed subsidies, even in the absence of data on the new target species, the logic being that unfished or little-exploited populations are abundant enough not to need management control. The result, often repeated through history, is that the new species are soon overfished, and management action, when it is taken, is reactive, slow, insufficient and lacks transparency86–88. The plentiful examples of this problem demonstrate that sustainable fishing requires foreknowledge of stocks and pre-emptive reg- ulation, especially in countries with industrial scale fleets and well- developed management capacity. Moreover, these unfished or little exploited populations can hold significant ecological roles that underpin other fisheries and key ecosystem services; without knowing better, the consequences of their exploitation could be far-reaching. A clear example is the growing exploitation interest towards the exceptionally high biomass of krill and mesopelagic fish which are key to the processes of carbon sequestration89. As the world looks for ways to promote nature-based solutions to the climate crisis90, fishing for species that play a vital role in the carbon cycle makes no sense other than in narrow fishery economic terms. Before being opened, all fisheries should require long-term data sets from which sound scientific advice and clear management rules can be set to avoid repeated cycles of failure. A basic working principle is that the less one knows about a fish and its place in the ecosystem and world, the more precautionary fishery management should be91,92. Although small-scale fisheries often operate with less data and man- agement capacity than industrial fisheries, sustainability can still be pursued by applying local ecological knowledge to better match fishing pressure to levels species can support, adoptingmeasures to reduce the impact offishing on habitats and bycatch species, and establishing participatory institutions to set and enforce local rules93–96. Action 5: Pro-actively incorporate ecosystem protection into fisheries management Fisheries managers have rarely considered pro-active nature protection to be within their remit, even though protection of habitat and ecosystem integritymaybe fundamental to theproductivity of the species theymanage, e.g. juvenile cod in the Gulf of Maine survive better in untrawled habitats97. Instead, managers assume that sufficient habitat of good enough quality https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 4 www.nature.com/npjoceansustain exists, justifying their focus on target species in isolation. The narrowness of this view has likely contributed to many instances of species decline. If fisheries are to be sustainable in a wider sense, managers should not ignore their responsibility to protect habitats that are critical to life stages,maintain the functioning of ecosystems and sustain the wildlife they affect. This includes considering when, where and how fishing is conducted, and its broader impacts. Spatial and temporal conservation measures must become an integral feature ofmodern fisheries management, to avoid adverse interactions with wildlife, protect habitats or promote their recovery, and direct fishing away from species or places of high ecological vulnerability or that are difficult to effectively monitor. Proactive nature protection measures safeguard and rebuild the natural capital on which fisheries are built. Examples of good practice include the temporal and spatial separation of lobster trap fisheries from feeding grounds of endangered right whales in Canada to prevent entanglement mortality98, the use of networked no-take marine reserves to support artisanal reef fisheries in the Caribbean99, and only allowing low impact staticfishingmethods in anareadesigned toallow recoveryof seabed habitats impacted by mobile gears in Lyme Bay, UK100. Action 6: Place the most vulnerable species and areas off limits Some species and places are inherently more vulnerable to fishing than others, such as fragile habitats fished using destructive gears, or the deep-sea relative to shallower waters. Some fish and shark species have life histories that are incompatible with even low levels of exploitation. The same is true for many sponges, corals and other sessile invertebrates101. Fishing deeper than 500m with large-scale, industrialised gears should not be undertaken. The extreme conditions of darkness, high pressure and cold mean that productivity is low across much of the deep sea, and species there often possess highly vulnerable life histories meaning they are extremely slow to recover once depleted102. Many exploited deep-sea species are also parti- cularly vulnerable to ocean warming, deoxygenation, acidification and changes in export production103,104. These features mean that, with few exceptions, the deep sea cannot support fisheries that are sufficiently pro- ductive to be economically viable at sustainable fishing rates105. Areas with near-natural structures, processes and functions are important reference sites that canhelp set conservationgoals, guide recovery trajectories of impacted sites, inform adaptive management and contribute to rebuilding exploited fish stocks. Fishing in these areas should be avoided. A related concept is “freezing the fishing footprint” whereby the spatial extent of fishing activities is constrained. In the deep-sea, freezing the bot- tom fishing footprint prevents expansion into areas not yet disturbed, thereby creating reference sites that allow us to understand anthropogenic changes in the deep sea. A freezing of the deep-sea fishing footprint would also protect areas that likely contain cold-water corals, deep-sea sponges and other vulnerable biogenic habitats, e.g.106. Polar regions also lend themselves to freezing the footprint to prevent damaging expansion of fisheries into some of the most climate-change sensitive ecosystems in the world107. Principle 2: Fisheries must support and enhance the health, wellbeing and resilience of people and communities, not just corporations Fisheries are an underperforming global asset. The difference between potential and actual net economic benefits from fisheries exceeds $ 80 billion per year, largely due to overexploitation108. Over the years, fisheries have become evermore technologically powerful.However, greater fishing power does not equate to greater production, with efficiencies often only slowing catch decline relative to the falling abundance of target species63. When functions of marine life that are difficult to value in monetary terms—including climate regulation, nutrient cycling, habitat provision, water quality, nutritional and cultural values27,109—are accounted for, marine life is dramatically undervalued. Fisheries management has historically focused on economic output with limited consideration of social value and effects, e.g.110,111. Yet human labour, along with marine life, provides the basis for these outputs and all parties that work in the fisheries sector should benefit from it, including women, who represent a large fraction of fisheries workers, particularly in processing and trade, but have generally lower benefits and agency5.We take the view that marine life is a public asset, and its exploitation and man- agement should work for the benefit of local communities and the public, with traditional users as rights-holders and citizens as central stakeholders and decision makers. Action 7: End fisheries that abuse human rights, including those that threaten foodsecurity and livelihoodsof people in theplaces they fish There is now abundant evidence of widespread human rights abuses in fishing, including coercive practices, bonded, slave and child labour, and unsafe, indecent and unsanitary living and working conditions112,113. These practices represent cost-cutting subsidies to fisheries whose profitability is falling because of overfishing and/or rising costs69.Human rights abuses and infringement of safe labourpractices are especially prevalent indistantwater fisheries where boats are at sea for months or years at a time112. Fisheries found to be complicit in such human rights abuses should be boycotted and dismantled. Distantwaterfisheriesmayalso infringeonhumanrights, access rights, wellbeing, food security and livelihoods of local communities in the places they fish. For example, fisheries operating under access agreements or illegally in West Africa have led to loss of fishing opportunities for local, small-scale, nearshore fishing fleets114. In an era of food scarcity, fisheries should both contribute to global food security (where all people at all times have access to safe and nutritious foods115) and operate in ways that maintain or increase access to fish and seafood for the world’s under- nourished and impoverished coastal populations. But many do not, with sanctioned or illegal industrial fisheries undermining local catches and food security114,116,117. We need to refocus fisheries that do not contribute to food security towards production of premium products and supply of local markets with greater profit retention by small-scale actors including fishers, processors, traders and local communities, e.g.118. To reflect the true broader values of marine life, fish should be targeted for direct human consumption at local scales with short supply chains and not exploited as subsidised, cheap commodities to supply distant markets in rich countries, let alone for markets such as pet food, nutraceuticals, agri- or aquaculture, which may themselves have large environmental impacts. These sorts of supply chain dysfunctions and inefficiencies have led to global shortfalls of critical nutritional support for people119. Action 8: Create fisheries management systems that fairly and transparently distribute access and benefits Decisions on access and allocation of fishing rights are contentious, often made behind closed doors and typically based on historical precedent120. This approach favours some groups over others, often fishery sectors with the most concentrated capital, greatest lobbying power and high environ- mental impact, e.g.121–123. To increase fairness and transparency in fisheries management systems, two changes are needed. First, fisheries need clear policy mandates to consider equity (and not just sustainability) in man- agement, and established mechanisms to determine equitable allocation of access and benefits to various groups124. For example, the inherent rights of IndigenousPeoples and small-scalefishers to livelihoods and food should be considered before allocation to industrial fleets. Second, representative, inclusive and participatory decision-making processes are needed to embed local rights holders and stakeholders. Cooperatives and other coalitions and networks of fishers and fish pro- cessors can support actors’ participation in decision making and distribu- tionof benefits125. To enhance social benefits fromfishing,wider recognition and representation of rights-holders (e.g. Indigenous Peoples, small-scale fishers, traditional resource users) and stakeholder groups is necessary, including civil society. Indeed, non-governmental stakeholders, such as environmental NGOs and Indigenous groups, are increasingly valued and https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 5 www.nature.com/npjoceansustain active participants in decision-making processes126. At the same time, depending on the tactics and resources used to support themissions of these groups (e.g. private foundation funding), their motives may also be viewed as opaque, especially by fisheries managers in low-income countries127. To alleviate these concerns, government-associated fisheries managers as well as stakeholders from the private sector should be mandated to adequately and transparently consider, evaluate and report decisions on access and benefits to achieve the diverse objectives of the UN SDGs. Action 9: Apply good practices wherever fishing companies operate Multinational companies are often criticised for applying different stan- dards across their global supply chains, for example employing child labour or exposing people to dangerous working conditions in less regulated jur- isdictions, e.g.112,113,128,129. Allied to this, companies often operate under flags of convenience, benefiting from less rigorous or non-existent regulatory regimes130. Reduced operating costs represent the upside for the businesses involved.However, just because a practice is legal does notmake it ethical or morally acceptable. Risk of illegal, unreported and unregulated fishing and labour abuses is higher when a fishing vessel operates under a flag state with poor control over corruption or is largely ownedby countries other than the flag state131. A more inclusive definition of sustainability rejects that avoidable human and environmental costs are justified in the pursuit of profit. Responsible companies apply good practices wherever they operate, do not illegally fish, and do not hide behind flags of convenience. Responsible companies also engage in corporate social responsibility practices, such as benefit sharing and local hiring, and move beyond a focus on no harm to human rights, towards promoting wellbeing in local populations132. Action 10: End the flow of harmful subsidies to fisheries Harmful subsidies are anathema to sustainable, low impactfishing. They are defined as capacity-enhancing subsidies, which increase fishing power by artificially inflating private fishing company profits133. They include, for example, tax breaks on fuel, discounted fishing gears, support for vessel construction costs134 or payments for access to foreign waters135. Harmful subsidies have long been recognised to contribute to overfishing and management failure134 and, more recently, greenhouse gas emissions136. Globally, public entities provided capacity-enhancing subsidies of an esti- mated $ 22.2 billion in 2018134. Most of this (>80%) went to large-scale industrialised fishing activities thus conferring an inequitable competitive advantage over small-scale fisheries137. Using taxpayers’ money to fund capacity-enhancing subsidies also increases risk of labour abuses138, fosters ecosystemdegradationand represents extremelypoor social investment and value for money. The provision of harmful subsidies also runs counter to legal recognition of everyone’s right to a “safe, clean, healthy and sustainable environment”139. After decades of negotiation, the World Trade Organisation (WTO) agreed in 2022 to implement a ban on capacity-enhancing subsidies, albeit only for fisheries engaged in illegal, unreported or unregulated (IUU) fishing, those targeting overfished stocks, and fisheries in areas of the high seas outside the competence of a regional fisheries management organisa- tion/authority140. The banwill only come into force when at least two-thirds of WTOmembers formally accept it, and if they do so within 4 years (as of July 2024, 82 of 164 WTO members had accepted). However, many sub- sidies that contribute to overcapacity and overfishing were excluded from the final agreement due to lack of consensus141, such as subsidies for equipment/machinery, fuel, ice, access to foreign waters, bait, personnel, social charges or insurance. Action 11: Apply zero-tolerance to companies that engage in illegal fishing Illegal fishing is not only wrong in law, it undermines both fisheries man- agement and human rights and retailers should adopt a zero-tolerance approach to it in procurement practices. It leads to uncertain estimates of target species removals and population sizes making it harder to allocate access or prevent overexploitation. IUU fishing has been linked to trans- national organised crime, modern slavery and labour abuses, undermining of food security and loss of government revenue113,131,138,142–144. Globally, illegal fishing is estimated to land between 8 and 14millionmetric tons with gross revenues of $ 9–17 billion142. Illegal fisheries are fostered by weak deterrence, with typically low fines that are seen by some as worthwhile business costs, especiallywhere catching power is falling and costs rising due to poor management. Poor governance and lenient treatment of fisheries violations encourages repeat offending, e.g.145–147, with those found guilty often still receiving government subsidies, or certifications of sustainability. Fishing vessels that are more likely to engage in illegal fishing and labour abusesmore often use ports in countries that have not ratified the Port State Measures Agreement due to their less rigorous procedures131. Therefore, companies associatedwith IUUfishing andvessels that landfish inports not regulated by the Port State Measures Agreement, should be avoided. Implementation The biggest challenge in achieving lasting fisheries sustainability lies in the implementation of the actions we outline. Fisheries are as multifaceted and complex as human societies and what works in one context may not in another. Further work should look to integrate our actions into specific social-ecological contexts to develop locally appropriate sustainability plans with all relevant stakeholders. That said, nearly all the actions we describe have been demonstrated to work somewhere. For example, Australia’s supertrawler ban of 2014148, its fishing of northern prawns at MEY rather than MSY149, and the UK’s closure of sand eel fishing in 2023 to protect seabirds150. Inmost cases, a combinationof complementary strategieswill be required to achieve the package of actions required for full sustainability151. Success is most likely, where two elements come together: good gov- ernance and realigned incentives152,153. On the incentives side, the most systemic shift towards better fisheries practice will come from the with- drawal of harmful subsidies, especially tax breaks on fuel. Many of themost destructive fisheries will simply become uneconomic when this prop is withdrawn. We are not yet there, but progress continues at the WTO, and within countries154. Subsidies can be repurposed to incentivise good practice too, such as compensating fishers for adopting less impactful gears155 or for supporting protected areas99. Wholesalers and retailers can proactively incentivise change, offering market access or better prices for fish caught from fisheries that meet more stringent sustainability standards. The fra- mework we outline in this paper offers them a blueprint by which to judge performance. As the twin climate andbiodiversity crises demandmore urgent action, realigning of incentives will happen to control harm by fisheries. Fisheries decision making has typically been inward looking, mindless of negative consequences for environment, society or human wellbeing. Subsidies to fleets of the Global North under distant water access agreements, for example, conflict with efforts to reduce malnutrition or poverty in the Global South114. Environmental quality, conservation and climate mitiga- tion targets are undermined by destructive fishing. Better fisheries gov- ernance is therefore imperative to broader societal goals, as expressed in the SDGs. Meeting those targets requires a shift to more integrated decision making and restructuring of incentives to resolve policy conflicts and achieve multi-dimensional objectives. Governance reform often only happens in response to shocks, like stock collapses, or external pressure. Environmental NGOs have become a potent force driving fisheries reform. After coordinated campaigns by eNGOs, the EU banned electric pulse trawling and bottom trawling below 800m deep, and measures were taken to recover Atlantic bluefin tuna. These campaigns draw upon diminishing public tolerance for destructive behaviour by private industry156, which allied with increasing consolidation of fishing companies into global giants, makes such pressures easier to leverage with potential for broader benefits when successful157. Good gov- ernance may be harder in places lacking strong institutions. However, successes have been achieved through co-management between https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 6 www.nature.com/npjoceansustain government and local communities158. For example, government support for customary laws and local leadership in Indonesia has brought destruc- tive fishing under control in Raja Ampat and fostered support for lower impact methods and marine protected areas159. Conclusions How future fisheries aremanaged is important for sustainable development and society, but it is also important because marine life is a public good that should be valued andused for the benefit of society andnature, not exploited solely for private profit160. Given the urgency of addressing societal chal- lenges, wemust go further and faster to prepare for future risks andmitigate the already apparent effects of rapid global change and human population growth.Weneed tourgently scale up efforts to transformfisheries to protect marine life and support society. It is the shared responsibility of policy makers, fisheries managers, fishers and retailers to minimise the environ- mental impact of fishing and amplify its social benefits, of which profit is only one element. This means making better choices regarding the why, what, how, and where of capture fisheries. Importantly, examples of suc- cessful conservation of marine spaces and species do exist, often where human capacity and resources would appear limited132,161–163. In the context of fisheries, work aimed at improving our understanding of key drivers of effective governance frameworks and remediation activities should con- tinue in earnest given themultitude of diverse challenges that persist in both large and small-scale operations around the world. We propose that all fisheries adopt and report on the two connected principles and associated actions elucidated above, to better serve human- kind and nature and support progress towards multiple SDGs. Adopting our priority actions will integrate nature conservation into management, incorporate local ecological knowledge in decision making, improve size- based and species-based gear selectivity, end the use of destructive gears, prioritise access and support to lower impact gears and fisheries with more just distribution of benefits, remove capacity-enhancing subsidies and reduce fishing effort and overcapacity. Consumers increasingly demand that fisheries are conscious of bio- diversity, people and climate. Using their reach to accelerate change, fish- eries need to adopt greener, more equitable practices. For businesses this means measuring not only carbon but their overall ecological footprint, improving the fuel efficiency of vessels, auditing supply chains, reducing waste, engaging in circular economy, converting to non-destructive fishing methods, applyinghigh standardswherever theyfish, avoidinguseofflagsof convenience or taking advantage of weaker local rules. Strategies to build resilience as well as policy and management con- siderations, potential trade-offs, and social and economic contexts differ among fisheries, communities and the countries within which they operate. Industrialised fisheries are often poorly performing businesses that may have appalling environmental and social records. By adopting the reforms needed to reduce harm, widen access to and redistribute benefits, the environmental gains, long-term profits and overall societal benefits will, we argue, far outweigh losses. In fact, if wisely managed as argued for in this contribution, humanity can expect to receive benefits forever, achieving what has been described as ‘infinity fish’160. Given a background of inten- sifying climate change, sustainable fisheries management must also be climate-adaptative and contribute positively to carbon mitigation. For artisanal and subsistencefisheries, which have amore direct link to local communities through local and domestic fish consumption, the challenge will be to design interventions that support economic develop- ment but that positively address social and environmental impacts. How- ever, the gains tofish stocks andhabitats achievedby reducing the impacts of industrial fishing, will provide opportunities to increase social benefits, reduce environmental costs and increase resilience of these fisheries. The above principles and actions redefine the notion of sustainable fisheries to balance environmental, social, economic and institutional dimensions to rebuild marine life, restore and regenerate ecosystems, sup- port climate changemitigation and adaptation, promote systemresilience to shocks and opportunities, and improve human wellbeing. 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C.M.R., B.C.O’L, J.P.H., F.LeM. and C.N. conceived the study and obtained funding support and organised the workshops from which this manuscript was developed. We are very grateful to insights shared with us by Laurenne Schiller. The research was very kindly supported by the Levine Family Foundation, and we are very grateful to Miranda Levine for her unwavering support, despite multiple setbacks from the global pandemic. Author contributions C.M.R., C.B., N.B., J.S.B.,W.W.L.C., P.C., O.D., Gd.J.C., R.F., D.G., C.D.G., J.H., A.J.H., J.J., P.K., M.E.L., F.Le.M., J.J.M., F.M., T.M., C.Nor., C.Nou., D.P., E.P., F.P.A., A.S.-A., U.R.S., L.T., L.W. and B.C.O’L. participated in the workshops, helpedwrite the text andcommentedonmultiple versionsof the manuscript and read and approved the final submission. Competing interests The authors declare no competing interests. Additional information Correspondence and requests for materials should be addressed to Callum Roberts. 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To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. © The Author(s) 2024 https://doi.org/10.1038/s44183-024-00078-2 Perspective npj Ocean Sustainability | (2024) 3:41 11 http://www.nature.com/reprints http://creativecommons.org/licenses/by/4.0/ www.nature.com/npjoceansustain Rethinking sustainability of marine fisheries for a fast-changing planet The Vision: Marine fisheries should minimise the ecological impact of every fish caught and maximise its societal benefit Principles for sustainable marine fisheries Principle 1: Fisheries must minimise environmental harm, allow for the regeneration of marine life and habitats, and adapt to climate change Action 1: Fish less and manage fisheries for lower impact Action 2: Rule out gears and fisheries that generate significant collateral damage Action 3: Set limits on the size of boats and gears Action 4: Source only from fisheries with good governance, sustainable stocks, and sufficient data to assure sustainability Action 5: Pro-actively incorporate ecosystem protection into fisheries management Action 6: Place the most vulnerable species and areas off limits Principle 2: Fisheries must support and enhance the health, wellbeing and resilience of people and communities, not just corporations Action 7: End fisheries that abuse human rights, including those that threaten food security and livelihoods of people in the places they fish Action 8: Create fisheries management systems that fairly and transparently distribute access and benefits Action 9: Apply good practices wherever fishing companies operate Action 10: End the flow of harmful subsidies to fisheries Action 11: Apply zero-tolerance to companies that engage in illegal fishing Implementation Conclusions References Acknowledgements Author contributions Competing interests Additional information