Abstract
Salmonid fishes are among the most adaptable and resilient to change of any fish group but also among the most threatened. The pace of change in today’s world and the ever-increasing human footprint are limiting the ability of these remarkable fish to successfully adapt. Land use modifications, the introduction of non-native salmonids, aquaculture, pollution, and diminishing water supply all threaten salmonid populations across the globe. Climate change adds significant threats to populations that may already on the brink. We ask “How do we ensure the future of salmonids in this rapidly changing world?” and provide a three-part strategy for stream conservation consisting of (1) protecting and restoring important habitats and populations, (2) building resistance and resilience to disturbance, and (3) forming alliances with diverse interests to solve common problems. Conservation in the twenty-first century is challenged by twin complications of climate change and demands of an ever-growing human population. As we look into the future of salmonid and stream conservation, novel approaches such as World Heritage Site designations and the growing Rights of Nature movement should receive more attention. Ultimately, conservation success will be driven as much or more by societal perceptions and desires than by scientific principles.
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References
Armour C, Duff D, Elmore W (1994) The effects of livestock grazing on western riparian and stream ecosystem. Fisheries 19(9):9–12
Armstrong JB, Fullerton AH et al (2021) The importance of warm habitat to the growth regime of cold-water fishes. Nat Clim Change 11:354–361
Belsky AJ, Matzke A, Uselman S (1999) Survey of livestock influences on stream and riparian ecosystems in the western United States. J Soil Water Cons 54:419–431
Bisson PA, Reeves GH et al (1997) Watershed management and Pacific salmon: desired future conditions. In: Stouder DJ et al (eds) Pacific salmon and their ecosystems: status and future options. Chapman and Hall, New York, pp 447–474
Borgwardt F, Unfer G et al (2020) Direct and indirect climate change impacts on Brown Trout in Central Europe: how thermal regimes reinforce physiological stress and support the emergence of diseases. Front Env Sci 8:59
Carlson SM, Satterwaite WH (2011) Weakened portfolio effect in a collapsed salmon population complex. Can J Fish Aquat Sci 68:1579–1589
Challe T (2021) The Rights of Nature – can an ecosystem bear legal rights? Columbia Climate School. https://news.climate.columbia.edu/2021/04/22/rights-of-nature-lawsuits/. Accessed 1 Dec 2021
Colyer WT, Kershner JL, Hilderbrand RH (2005) Movements of fluvial Bonneville cutthroat trout in the Thomas Fork of the Bear River, Idaho-Wyoming. N Am J Fish Man 25:954–963
Dauwalter DC, Sanderson JS et al (2011) Identification and implementation of native fish conservation areas in the upper Colorado River basin. Fisheries 36:278–288
Dauwalter DC, Vail-Muse SL et al (2019) Partnering on multispecies aquatic assessments to inform efficient conservation delivery. In: Dauwalter DC et al (eds) Multispecies and watershed approaches to freshwater fish conservation. American Fisheries Society Symposium 91, Bethesda, MD, pp 11–32
Dauwalter DC et al (2020) A call for global action to conserve native trout in the 21st Century and beyond. Eco Fresh Fish 00:1–4
Dunham JB et al (1997) Habitat fragmentation and extinction risk of Lahontan cutthroat trout. N Am J Fish Man 17:1126–1133
Dunham JB, Rieman BE, Peterson JT (2002) Patch-based models to predict species occurrence: lessons from salmonid fishes in streams. In: Scott JM et al (eds) Predicting species occurrences: issues of accuracy and scale. Island Press, Washington, DC, pp 327–334
Fausch KD (2015) For the love of rivers: a scientist’s journey. Oregon State University Press, Corvallis, OR
Fausch KD, Rieman BE et al (2009) Invasion versus isolation: trade-offs in managing native salmonids with barriers to upstream movement. Cons Bio 23:859–870
Figge F (2004) Bio-folio: applying portfolio theory to biodiversity. Bio Cons 13:827–849
Foley JA et al (2005) Global consequences of land use. Science 309(5734):570–574
Garrett GP, Birdsong TW et al (2019) Chihuahuan desert native fish conservation areas: a multispecies and watershed approach to preservation of freshwater fish diversity. In: Dauwalter DC et al (eds) Multispecies and watershed approaches to freshwater fish conservation. American Fisheries Society Symposium 91, Bethesda, MD, pp 231–252
Haak AL, Williams JE (2012) Spreading the risk: native trout management in a warmer and less-certain future. N Am J Fish Man 32:387–401
Haak AL, Williams JE (2013) Using native trout restoration to jumpstart freshwater conservation planning in the Interior West. J Cons Plan 9:38–52
Henderson R et al (2000) Timing and location of spawning by nonnative wild Rainbow Trout and native Cutthroat Trout in the South Fork Snake River, Idaho, with implications for hybridization. N Am J Fish Man 20:584–596
Hendrickson DA, Tomelleri JR (2019) Native trout of Mexico: treasures of the Sierra Madre. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 251–278
Higgins J, Zablocki J et al (2021) Durable freshwater protection: a framework for establishing and maintaining long-term protection for freshwater ecosystems and the values they sustain. Sustainability 13:1950
Hilborn R, Quinn TP et al (2003) Biocomplexity and fisheries sustainability. Proc Natl Acad Sci U S A 100:6564–6568
Hilderbrand RH, Kershner JL (2000) Conserving inland cutthroat trout in small streams: how much habitat is enough? N Am J Fish Man 20:513–520
Hudy M, Thieling TM et al (2008) Distribution, status, and landuse characteristics of subwatersheds within the native range of Brook Trout in the eastern United States. N Am J Fish Man 28:1069–1085
Hume M (2021) Fish caught in the middle of the catch-and-release debate. Globe and Mail. https://theglobeandmail.com/opinion/article-fish-are-caught-in-the-middle-of-the-catch-and-release-debate/. Accessed 1 Dec 2021
Isaak DJ, Muhlfeld CC et al (2012) The past as prelude to the future for understanding 21st-Century climate effects on Rocky Mountain trout. Fisheries 37:542–556
Isaak DJ, Young MK et al (2014) Coldwater as a climate shield to preserve native trout through the 21st Century. In: Carline RF, LoSapio C (eds) Wild Trout Symposium XI. West Yellowstone, Montana, pp 110–116
IUCN (International Union for Conservation of Nature) (2018) The IUCN red list of threatened species. https://www.iucnredlist.org/. Accessed 22 Dec 2021
Jonsson B, Jonsson N (2009) A review of the likely effects of climate change on anadromous Atlantic salmon Salmo salar and brown trout Salmo trutta, with particular reference to water temperature and flow. J Fish Biol 75:2381–2447
Jonsson B et al (2019) Life history diversity. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 141–191
Just Economics (2021) Dead loss: the high cost of poor farming practices and mortalities on salmon farms. Just Economics Research, Bristol
Keleher CJ, Rahel FJ (1996) Thermal limits to salmonid distributions in the Rocky Mountain region and potential habitat loss due to global warming: a geographic information system (GIS) approach. Trans Am Fish Soc 125:1–13
Kershner JL, Williams JE et al (2019) Introduction. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 1–14
Knapp RA, Matthews KR (1996) Livestock grazing, golden trout, and streams in the golden trout wilderness, California: impacts and management implications. N Am J Fish Man 16:805–820
Kovach RP, Al-Chokhachy R et al (2017) Climate, invasive species and land use drive population dynamics of a cold-water specialist. J Appl Ecol 545:638–647
Kovach RP, Jonsson B et al (2019) Climate change and the future of trout and char. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 685–716
Krkosek M, Gottesfeld A et al (2007) Effects of host migration, diversity and aquaculture on sea lice threats to Pacific salmon populations. Proc Royal Soc B 274:3141–3149
Leary RF, Allendorf FW et al (1984) Introgression between Westslope Cutthroat and Rainbow Trout in the Clark Fork River drainage, Montana. Proc Montana Acad Sci 43:1–18
Leopold A (1949) A sand county almanac, and sketches here and there. Oxford University Press, New York
Lisle TE, Hilton S (1992) The volume of fine sediment in pools: an index of sediment supply in gravel-bed streams. Water Res Bull 28:371–383
Lobón-Cerviá J, Esteve M et al (2019) Trout and char of central and southern Europe and northern Africa. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 379–410
Markevich G, Esin E (2019) Trout and char of Russia. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 517–571
McClure MM, Carlson SM et al (2008) Evolutionary consequences of habitat loss for Pacific anadromous salmonids. Evol Appl 1(2):300–318
McIntosh BA, Sedell JR et al (2000) Historical changes in pool habitats in the Columbia River Basin. Ecol Appl 10:1478–1496
Montgomery DR (2003) King of fish: the thousand-year run of salmon. Westview Press, Boulder, CO
Morita K (2019) Trout and char of Japan. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 487–515
Muhlfeld CM, Dauwalter DC et al (2018) Trout in hot water: a call for global action. Science 360(6391):866–867
Muhlfeld CM, Dauwaulter DC et al (2019) Global status of trout and char: conservation challenges in the twenty-first century. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 717–760
NASA (National Aeronautics and Space Administration) (2021) 2020 tied for warmest year on record, NASA analysis shows. https://www.nasa.gov/press-release/2020-tied-for-warmest-year-on-record-nasa-analysis-shows. Accessed 11 Nov 2021
Neville HM et al (2006) Landscape attributes and life history variability shape genetic structure of trout populations in a stream network. Landscape Ecol 21:901–916
Pechony O, Shindell DT (2010) Driving forces of global wildfires over the past millennium and the forthcoming century. Proc Natl Acad Sci U S A 107:19167–19170
Pess GR, Quinn TP et al (2014) Re-colonization of Atlantic and Pacific rivers by anadromous fishes: linkages between life history and the benefits of barrier removal. Rev Fish Biol Fish 24:881–900
Platts WS (1981) Effects of livestock grazing. In: Meehan WR (ed) Influence of forest and rangeland management on anadromous fish habitat in western North America. USDA Forest Service General Technical Report PNW-124, pp 1–19
Propst DL, Turner TF et al (2020) Ecology, politics, and conservation of Gila trout. In: Propst DL, Williams JE et al (eds) Standing between life and extinction: ethics and ecology of conserving aquatic species in North American deserts. University of Chicago Press, Chicago, IL, pp 295–315
Pujolar JM, Vincenzi S et al (2016) Temporal changes in allele frequencies in a small marble trout Salmo marmoratus population threatened by extreme flood events. J Fish Biol 88:1175–1190
Quinn TP (2005) The behavior and ecology of Pacific salmon and trout. University of Washington Press, Seattle, WA
Rahel FJ, Olden JD (2008) Assessing the effects of climate change on aquatic invasive species. Cons Biol 22:521–533
Ramankutty N, Evan AT et al (2008) Farming the planet: 1. Geographic distribution of global agricultural lands in the year 2000. Global Biogeochem Cy 22:GB1003
Rieman BE, Allendorf FW (2001) Effective population size and genetic conservation criteria for bull trout. N Am J Fish Man 21:756–764
Rieman BE, Clayton J (1997) Wildfire and native fish: issues of forest health and conservation of sensitive species. Fisheries 22(11):6–15
Rieman BE et al (1997) Distribution, status, and likely future trends of Bull Trout within the Columbia River and Klamath River basins. N Am J Fish Man 17:1111–1125
Saunders WC, Fausch KD (2012) Grazing management influences the subsidy of terrestrial prey to trout in central Rocky Mountain streams (USA). Fresh Biol 57:1512–1529
Schäfer T (2021) Legal protection schemes for free-flowing rivers in Europe: an overview. Sustainability 13:6423
Schöfmann J et al (2019) Trout of Southeast Europe, Western and Central Asia. In: Kershner JL, Williams JE et al (eds) Trout and char of the world. American Fisheries Society, Bethesda, MD, pp 379–456
Schindler DE, Hilborn R et al (2010) Population diversity and the portfolio effect in an exploited species. Nature (London) 465:609–612
Shea D, Bateman A et al (2020) Environmental DNA from multiple pathogens is elevated near active Atlantic Salmon farms. Proc Royal Soc B 287:2020
Smialek N et al (2021) Environmental threats and conservation implications for Atlantic salmon and brown trout during their critical freshwater phases of spawning, egg development and juvenile emergence. Fish Man Ecol 28:437–467
Southwood TRE (1977) Habitat, the template for ecological strategies? J Anim Ecol 46:337–365
Talabere AG (2002) Influence of water temperature and beaver ponds on Lahontan cutthroat trout in a high-desert stream, southeastern Oregon. Thesis, Oregon State University
Thomas SM et al (2016) Beyond cool: adapting upland streams for climate change using riparian woodlands. Glob Change Biol 22:310–324
Thorstad EB, Finstad B (2018) Impacts of salmon lice emanating from salmon farms on wild Atlantic salmon and sea trout. NINA Rep 1449:1–22
Tickner D et al (2020) Bending the curve of global freshwater biodiversity loss: an emergency recovery plan. BioScience 70(4):330–342
UNESCO (2019) Leaving no one behind. The United Nations World Water Report
Vincenzi S, Crivelli AJ et al (2012) Translocation of stream-dwelling salmonids in headwaters: insights from a 15-year reintroduction experience. Rev Fish Biol Fish 22:437–455
Williams JE, Williams RN et al (2011) Native fish conservation areas: a vision for large-scale conservation of native fish communities. Fisheries 36:267–277
Williams JE, Neville HM et al (2015) Climate change adaptation and restoration of western trout streams: opportunities and strategies. Fisheries 40:304–317
Williams JE, Rummel S et al (2016) Engaging a community of interest in water quality protection: anglers monitoring wadeable streams. J Soil Water Cons 71:114A–119A
Woodsmith RD, Buffington JM (1996) Multivariate geomorphic analysis of forest streams: implications for assessment of land use impacts on channel conditions. Earth Surf Process Landf 21:377–393
World Wildlife Fund (2001) The status of Wild Atlantic Salmon: a river by river assessment. https://wwf.panda.org/wwf_news/?3729/The-Status-of-Wild-Atlantic-Salmon-A-River-by-River-Assessment. Accessed 11 Nov 2021
World Wildlife Fund (2004) Rivers at risk: dams and the future of freshwater ecosystems. https://wwf.panda.org/wwf_news/?13716/Rivers-at-Risk-Dams-and-the-future-of-freshwater-ecosystems. Accessed 11 Nov 2021
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Williams, J.E., Kershner, J.L., Zablocki, J.A. (2024). The Future of Salmonids in a Rapidly Changing World. In: Lobon-Cervia, J., Budy, P., Gresswell, R. (eds) Advances in the Ecology of Stream-Dwelling Salmonids. Fish & Fisheries Series, vol 44. Springer, Cham. https://doi.org/10.1007/978-3-031-44389-3_28
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