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ARTICLE
Age structure affects population productivity in an exploited fish species
Jan Ohlberger,
Øystein Langangen,
Leif Chr. Stige,
Corresponding Author
Jan Ohlberger
School of Aquatic and Fishery Sciences, University of Washington, Seattle, Washington, USA
Correspondence
Jan Ohlberger
Email: [email protected]
Search for more papers by this authorØystein Langangen
Department of Biosciences, University of Oslo, Oslo, Norway
Search for more papers by this authorLeif Chr. Stige
Department of Biosciences, University of Oslo, Oslo, Norway
Norwegian Veterinary Institute, Ås, Norway
Search for more papers by this authorJan Ohlberger,
Øystein Langangen,
Leif Chr. Stige,
Corresponding Author
Jan Ohlberger
School of Aquatic and Fishery Sciences, University of Washington, Seattle, Washington, USA
Correspondence
Jan Ohlberger
Email: [email protected]
Search for more papers by this authorØystein Langangen
Department of Biosciences, University of Oslo, Oslo, Norway
Search for more papers by this authorLeif Chr. Stige
Department of Biosciences, University of Oslo, Oslo, Norway
Norwegian Veterinary Institute, Ås, Norway
Search for more papers by this authorHandling Editor: Marissa Leanne Baskett
Funding information: The Research Council, Grant/Award Numbers: 280467, 280468
Abstract
Long-term changes in the age and size structure of animal populations are well documented, yet their impacts on population productivity are poorly understood. Fishery exploitation can be a major driver of changes in population age–size structure because fisheries significantly increase mortality and often selectively remove larger and older fish. Climate change is another potential driver of shifts in the demographic structure of fish populations. Northeast Arctic (NEA) cod is the largest population of Atlantic cod (Gadus morhua) and one of the world's most important commercial fish stocks. This population has experienced considerable changes in population age–size structure over the past century, largely in response to fishing. In this study, we investigate whether changes in spawner age structure have affected population productivity in NEA cod, measured as recruits per spawning stock biomass, over the past 75 years. We find evidence that shifts in age structure toward younger spawners negatively affect population productivity, implying higher recruitment success when the spawning stock is composed of older individuals. The positive effect of an older spawning stock is likely linked to maternal effects and higher reproductive output of larger females. Our results indicate a threefold difference in productivity between the youngest and oldest spawning stock that has been observed since the 1950s. Further, our results suggest a positive effect of environmental temperature and a negative effect of intraspecific cannibalism by older juveniles on population productivity, which partly masked the effect of spawner age structure unless accounted for in the model. Collectively, these findings emphasize the importance of population age structure for the productivity of fish populations and suggest that harvest-induced demographic changes can have negative feedbacks for fisheries that lead to a younger spawning stock. Incorporating demographic data into harvest strategies could thus facilitate sustainable fishery management.
CONFLICT OF INTEREST
The authors declare no conflict of interest.
Open Research
DATA AVAILABILITY STATEMENT
Data and code (Ohlberger, 2022) are available from Zenodo: 10.5281/zenodo.5851638.
Supporting Information
| Filename | Description |
|---|---|
| eap2614-sup-0001-Appendix_S1.pdfPDF document, 392.9 KB | Appendix S1 |
| eap2614-sup-0002-DataS1.zipZip archive, 147.2 KB | Data S1 |
Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.
REFERENCES
- Ahrens, R. N. M., M. S. Allen, C. Walters, and R. Arlinghaus. 2020. “Saving Large Fish through Harvest Slots Outperforms the Classical Minimum-Length Limit when the Aim Is to Achieve Multiple Harvest and Catch-Related Fisheries Objectives.” Fish and Fisheries 21: 483–510.
- Andersen, K. H., N. S. Jacobsen, and P. D. van Denderen. 2019. “Limited Impact of Big Fish Mothers for Population Replenishment.” Canadian Journal of Fisheries and Aquatic Sciences 76: 347–9.
- Anderson, C. N. K., C. H. Hsieh, S. A. Sandin, R. Hewitt, A. Hollowed, J. Beddington, R. M. May, and G. Sugihara. 2008. “Why Fishing Magnifies Fluctuations in Fish Abundance.” Nature 452: 835–9.
- Anderson, J., and R. S. Gregory. 2000. “Factors Regulating Survival of Northern Cod (NAFO 2J3KL) during their First 3 years of Life.” ICES Journal of Marine Science 57: 349–59.
- Audzijonyte, A., S. A. Richards, R. D. Stuart-Smith, G. Pecl, G. J. Edgar, N. S. Barrett, N. Payne, and J. L. Blanchard. 2020. “Fish Body Sizes Change with Temperature but Not all Species Shrink with Warming.” Nature Ecology & Evolution 4: 809–14.
- Barneche, D. R., D. R. Robertson, C. R. White, and D. J. Marshall. 2018. “Fish Reproductive-Energy Output Increases Disproportionately with Body Size.” Science 360: 642–4.
- Barnett, L. A. K., T. A. Branch, R. A. Ranasinghe, and T. E. Essington. 2017. “Old-Growth Fishes Become Scarce under Fishing.” Current Biology 27: 2843–8.
- Baudron, A. R., C. L. Needle, A. D. Rijnsdorp, and C. T. Marshall. 2014. “Warming Temperatures and Smaller Body Sizes: Synchronous Changes in Growth of North Sea Fishes.” Global Change Biology 20: 1023–31.
- Beamish, R. J., G. A. McFarlane, and A. Benson. 2006. “Longevity Overfishing.” Progress in Oceanography 68: 289–302.
- Berkeley, S. A., M. A. Hixon, R. J. Larson, and M. S. Love. 2004. “Fisheries Sustainability Via Protection of Age Structure and Spatial Distribution of Fish Populations.” Fisheries Oceanography 29: 23–32.
10.1577/1548-8446(2004)29[23:FSVPOA]2.0.CO;2 Google Scholar
- Birkeland, C., and P. Dayton. 2005. “The Importance in Fishery Management of Leaving the Big Ones.” Trends in Ecology & Evolution 20: 356–8.
- Bogstad, B., G. R. Lilly, S. Mehl, O. K. Palsson, and G. Stefansson. 1994. “Cannibalism and Year-Class Strength in Atlantic Cod (Gadus morhua L.) in Arcto-Boreal Ecosystems (Barents Sea, Iceland, and Eastern Newfoundland).” ICES Marine Science Symposia 198: 576–99.
- Botsford, L. W., M. D. Holland, J. C. Field, and A. Hastings. 2014. “Cohort Resonance: A Significant Component of Fluctuations in Recruitment, Egg Production, and Catch of Fished Populations.” ICES Journal of Marine Science 71: 2158–70.
- Brunel, T. 2010. “Age-Structure-Dependent Recruitment: A Meta-Analysis Applied to Northeast Atlantic Fish Stocks.” ICES Journal of Marine Science 67: 1921–30.
- Brunel, T., and G. J. Piet. 2013. “Is Age Structure a Relevant Criterion for the Health of Fish Stocks?” ICES Journal of Marine Science 70: 270–83.
- K. P. Burnham, and D. R. Anderson, eds. 2002. Model Selection and Multimodel Inference, Second ed. New York, NY: Springer-Verlag.
- Daufresne, M., K. Lengfellner, and U. Sommer. 2009. “Global Warming Benefits the Small in Aquatic Ecosystems.” Proceedings of the National Academy of Sciences USA 106: 12788–93.
- Denderen, D., H. Gislason, J. Heuvel, and K. H. Andersen. 2020. “Global Analysis of Fish Growth Rates Shows Weaker Responses to Temperature than Metabolic Predictions.” Global Ecology and Biogeography 29: 2203–13.
- Drinkwater, K. 2005. “The Response of Atlantic Cod (Gadus morhua) to Future Climate Change.” ICES Journal of Marine Science 62: 1327–37.
- Eikeset, A. M., A. P. Richter, D. J. Dankel, E. S. Dunlop, M. Heino, U. Dieckmann, and N. C. Stenseth. 2013. “A Bio-economic Analysis of Harvest Control Rules for the Northeast Arctic Cod Fishery.” Marine Policy 39: 172–81.
- Eikeset, A. M., E. S. Dunlop, M. Heino, G. Storvik, N. C. Stenseth, and U. Dieckmann. 2016. “Roles of Density-Dependent Growth and Life History Evolution in Accounting for Fisheries-Induced Trait Changes.” Proceedings of the National Academy of Sciences USA 113: 15030–5.
- Forster, J., A. G. Hirst, and D. Atkinson. 2012. “Warming-Induced Reductions in Body Size Are Greater in Aquatic than Terrestrial Species.” Proceedings of the National Academy of Sciences USA 109: 19310–4.
- Gardner, J. L., A. Peters, M. Kearney, L. Joseph, and R. Heinsohn. 2011. “Declining Body Size: A Third Universal Response to Warming?” Trends in Ecology & Evolution 26: 285–91.
- Hamre, J. 1994. “Biodiversity and Exploitation of the Main Fish Stocks in the Norwegian - Barents Sea Ecosystem.” Biodiversity and Conservation 3: 473–92.
- Heino, M., B. Díaz Pauli, and U. Dieckmann. 2015. “Fisheries-Induced Evolution.” Annual Review of Ecology and Systematics 46: 461–80.
10.1146/annurev-ecolsys-112414-054339 Google Scholar
- Hixon, M. A., D. W. Johnson, and S. M. Sogard. 2014. “BOFFFFs: On the Importance of Conserving Old-Growth Age Structure in Fishery Populations.” ICES Journal of Marine Science 71: 2171–85.
- Hjermann, D. Ø., B. Bogstad, A. M. Eikeset, G. Ottersen, H. Gjøsæter, and N. C. Stenseth. 2007. “Food Web Dynamics Affect Northeast Arctic Cod Recruitment.” Proceedings of the Royal Society B: Biological Sciences 274: 661–9.
- Holt, R. E., and C. Jørgensen. 2014. “Climate Warming Causes Life-History Evolution in a Model for Atlantic Cod (Gadus morhua).” Conservation Physiology 2: cou050. https://doi.org/10.1093/conphys/cou050.
- Holt, R. E., B. Bogstad, J. M. Durant, A. V. Dolgov, and G. Ottersen. 2019. “Barents Sea Cod (Gadus morhua) Diet Composition: Long-Term Interannual, Seasonal, and Ontogenetic Patterns.” ICES Journal of Marine Science 76: 1641–52.
- Hsieh, C.-H., A. Yamauchi, T. Nakazawa, and W. F. Wang. 2010. “Fishing Effects on Age and Spatial Structures Undermine Population Stability of Fishes.” Aquatic Sciences 72: 165–78.
- Huss, M., M. Lindmark, P. Jacobson, R. M. van Dorst, and A. Gårdmark. 2019. “Experimental Evidence of Gradual Size-Dependent Shifts in Body Size and Growth of Fish in Response to Warming.” Global Change Biology 25: 2285–95.
- ICES. 2009. “Report of the ICES Advisory Committee 2009.” ICES Advice 2009.
- ICES. 2020. “Arctic Fisheries Working Group (AFWG).” ICES Scientific Reports 2: 52. https://doi.org/10.17895/ices.pub.6050.
10.17895/ices.pub.6050 Google Scholar
- Jørgensen, T. 1990. “Long-Term Chanes in Age at Sexual Maturity of Northeast Arctic Cod (Gadus morhua L.).” ICES Journal of Marine Science 46: 235–48.
10.1093/icesjms/46.3.235 Google Scholar
- Jørgensen, C., K. Enberg, E. S. Dunlop, R. Arlinghaus, D. S. Boukal, K. Brander, B. Ernande, et al. 2007. “Ecology: Managing Evolving Fish Stocks.” Science 318: 1247–8.
- Jørgensen, C., B. Ernande, Ø. Fiksen, and U. Dieckmann. 2006. “The Logic of Skipped Spawning in Fish.” Canadian Journal of Fisheries and Aquatic Sciences 63: 200–11.
- Kjesbu, O. S., P. Solemdal, P. Bratland, and M. Fonn. 1996. “Variation in Annual Egg Production in Individual Captive Atlantic Cod (Gadus morhua).” Canadian Journal of Fisheries and Aquatic Sciences 53: 610–20.
- Kjesbu, O. S., B. Bogstad, J. A. Devine, H. Gjøsæter, D. Howell, R. B. Ingvaldsen, R. D. M. Nash, and J. E. Skjæraasen. 2014. “Synergies between Climate and Management for Atlantic Cod Fisheries at High Latitudes.” Proceedings of the National Academy of Sciences USA 111: 3478–83.
- Köster, F. W., E. A. Trippel, and J. Tomkiewicz. 2013. “Linking Size and Age at Sexual Maturation to Body Growth, Productivity and Recruitment of Atlantic Cod Stocks Spanning the North Atlantic.” Fisheries Research 138: 52–61.
- Kuparinen, A., and J. Merilä. 2007. “Detecting and managing fisheries-induced evolution.” Trends in Ecology & Evolution 22: 652–9.
- Langangen, Ø., J. Ohlberger, L. C. Stige, J. M. Durant, E. Ravagnan, N. C. Stenseth, and D. Ø. Hjermann. 2017. “Cascading Effects of Mass Mortality Events in Arctic Marine Communities.” Global Change Biology 23: 283–92.
- Langangen, Ø., L. Färber, L. C. Stige, F. K. Diekert, J. M. I. Barth, M. Matschiner, P. R. Berg, et al. 2019. “Ticket to Spawn: Combining Economic and Genetic Data to Evaluate the Effect of Climate and Demographic Structure on Spawning Distribution in Atlantic Cod.” Global Change Biology 25: 134–43.
- Langangen, Ø., and L. C. Stige. 2021. “Shedding Light on the Link between the Spatial Distribution of Eggs and Survival in Northeast Arctic Cod.” Fisheries Oceanography 30: 429–36.
- Law, R. 2000. “Fishing, Selection, and Phenotypic Evolution.” ICES Journal of Marine Science 57(57): 659–68.
- Marshall, C. T., C. L. Needle, A. Thorsen, O. S. Kjesbu, and N. A. Yaragina. 2006. “Systematic Bias in Estimates of Reproductive Potential of an Atlantic Cod (Gadus morhua) Stock: Implications for Stock-Recruit Theory and Management.” Canadian Journal of Fisheries and Aquatic Sciences 63: 980–94.
- Marshall, D. J., M. Bode, M. Mangel, R. Arlinghaus, and E. J. Dick. 2021. “Reproductive Hyperallometry and Managing the World's Fisheries.” Proceedings of the National Academy of Sciences USA 118: e2100695118.
- Marteinsdottir, G., and K. Thorarinsson. 1998. “Improving the Stock-Recruitment Relationship in Icelandic Cod (Gadus morhua) by Including Age Diversity of Spawners.” Canadian Journal of Fisheries and Aquatic Sciences 55: 1372–7.
- Murawski, S. 2001. “Impacts of Demographic Variation in Spawning Characteristics on Reference Points for Fishery Management.” ICES Journal of Marine Science 58: 1002–14.
- Nissling, A., R. Larsson, L. Vallin, and K. Frohlund. 1998. “Assessment of Egg and Larval Viability in Cod, Gadus morhua: Methods and Results from an Experimental Study.” Fisheries Research 38: 169–86.
- Ohlberger, J. 2013. “Climate Warming and Ectotherm Body Size - from Individual Physiology to Community Ecology.” Functional Ecology 27: 991–1001.
- Ohlberger, J. 2022. “janohlberger/EcolAppl2021Ohlberger: Code for Ohlberger, et al. 2022 Ecological Applications (v.1).” Zenodo. https://doi.org/10.5281/zenodo.5851638.
10.5281/zenodo.5851638 Google Scholar
- Ohlberger, J., L. A. Rogers, and N. C. Stenseth. 2014. “Stochasticity and Determinism: How Density-Independent and Density-Dependent Processes Affect Population Variability.” PLoS One 9: e98940.
- Ohlberger, J., D. E. Schindler, R. J. Brown, J. M. S. Harding, M. D. Adkison, A. R. Munro, L. Horstmann, and J. Spaeder. 2020. “The Reproductive Value of Large Females: Consequences of Shifts in Demographic Structure for Population Reproductive Potential in Chinook Salmon.” Canadian Journal of Fisheries and Aquatic Sciences 77: 1292–301.
- Olsen, E., S. Aanes, S. Mehl, J. C. Holst, A. Aglen, and H. Gjøsæter. 2010. “Cod, Haddock, Saithe, Herring, and Capelin in the Barents Sea and Adjacent Waters: A Review of the Biological Value of the Area.” ICES Journal of Marine Science 67: 87–101.
- Opdal, A. F., and C. Jørgensen. 2015. “Long-Term Change in a Behavioural Trait: Truncated Spawning Distribution and Demography in Northeast Arctic Cod.” Global Change Biology 21: 1521–30.
- Ottersen, G. 2008. “Pronounced Long-Term Juvenation in the Spawning Stock of Arcto-Norwegian Cod (Gadus Morhua) and Possible Consequences for Recruitment.” Canadian Journal of Fisheries and Aquatic Sciences 65: 523–34.
- Ottersen, G., and H. Loeng. 2000. “Covariability in Early Growth and Year-Class Strength of Barents Sea Cod, Haddock, and Herring: The Environmental Link.” ICES Journal of Marine Science 57: 339–48.
- Ottersen, G., D. Ø. Hjermann, and N. C. Stenseth. 2006. “Changes in Spawning Stock Structure Strengthen the Link between Climate and Recruitment in a Heavily Fished Cod (Gadus morhua) Stock.” Fisheries Oceanography 15: 230–43.
- Ottersen, G., and N. C. Stenseth. 2001. “Atlantic Climate Governs Oceanographic and Ecological Variability in the Barents Sea.” Limnology and Oceanography 46: 1774–80.
- Ottersen, G., L. C. Stige, J. M. Durant, K.-S. Chan, T. A. Rouyer, K. F. Drinkwater, and N. C. Stenseth. 2013. “Temporal Shifts in Recruitment Dynamics of North Atlantic Fish Stocks: Effects of Spawning Stock and Temperature.” Marine Ecology Progress Series 480: 205–25.
- Ottersen, G., B. Bogstad, N. A. Yaragina, L. C. Stige, F. B. Vikebø, and P. Dalpadado. 2014. “A Review of Early Life History Dynamics of Barents Sea Cod (Gadus morhua).” ICES Journal of Marine Science 71: 2064–87.
- Peck, L. S., M. S. Clark, S. A. Morley, A. Massey, and H. Rossetti. 2009. “Animal Temperature Limits and Ecological Relevance: Effects of Size, Activity and Rates of Change.” Functional Ecology 23: 248–56.
- R Core Team. 2020. R: A Language and Environment for Statistical Computing. Vienna: R Foundation for Statistical Computing https://www.R-project.org/.
- Ricker, W. E. 1954. “Stock and Recruitment.” Journal of the Fisheries Research Board of Canada 11: 559–623.
10.1139/f54-039 Google Scholar
- van Rijn, I., Y. Buba, J. DeLong, M. Kiflawi, and J. Belmaker. 2017. “Large but Uneven Reduction in Fish Size across Species in Relation to Changing Sea Temperatures.” Global Change Biology 23: 3667–74.
- Schielzeth, H. 2010. “Simple Means to Improve the Interpretability of Regression Coefficients.” Methods in Ecology and Evolution 1: 103–13.
- Scott, B. E., G. Marteinsdottir, G. A. Begg, P. J. Wright, and O. S. Kjesbu. 2006. “Effects of Population Size/Age Structure, Condition and Temporal Dynamics of Spawning on Reproductive Output in Atlantic Cod (Gadus morhua).” Ecological Modelling 191: 383–415.
- Sharpe, D. M. T., and A. P. Hendry. 2009. “Life History Change in Commercially Exploited Fish Stocks: An Analysis of Trends across Studies.” Evolutionary Applications 2: 260–75.
- Shelton, A. O., and M. Mangel. 2011. “Fluctuations of Fish Populations and the Magnifying Effects of Fishing.” Proceedings of the National Academy of Sciences USA 108: 7075–80.
- Shelton, A. O., J. A. Hutchings, R. S. Waples, D. M. Keith, H. R. Akçakaya, and N. K. Dulvy. 2015. “Maternal Age Effects on Atlantic Cod Recruitment and Implications for Future Population Trajectories.” ICES Journal of Marine Science 72: 1769–78.
- Solemdal, P. 1997. “Maternal Effects - a Link between the Past and the Future.” Journal of Sea Research 37: 213–27.
- Stige, L. C., K. Ø. Kvile, B. Bogstad, and Ø. Langangen. 2018. “Predator–Prey Interactions Cause Apparent Competition between Marine Zooplankton Groups.” Ecology 25: 151–10.
- Stige, L. C., G. Ottersen, P. Dalpadado, K. S. Chan, D. Ø. Hjermann, D. L. Lajus, N. A. Yaragina, and N. C. Stenseth. 2010. “Direct and Indirect Climate Forcing in a Multi-Species Marine System.” Proceedings of the Royal Society B: Biological Sciences 277: 3411–20.
- Stige, L. C., N. A. Yaragina, Ø. Langangen, B. Bogstad, N. C. Stenseth, and G. Ottersen. 2017. “Effect of a Fish stock's Demographic Structure on Offspring Survival and Sensitivity to Climate.” Proceedings of the National Academy of Sciences USA 114: 1347–52.
- Sundby, S., and O. Nakken. 2008. “Spatial Shifts in Spawning Habitats of Arcto-Norwegian Cod Related to Multidecadal Climate Oscillations and Climate Change.” ICES Journal of Marine Science 65: 953–62.
- Swain, D., A. Sinclair, and J. M. Hanson. 2007. “Evolutionary Response to Size-Selective Mortality in an Exploited Fish Population.” Proceedings of the Royal Society B: Biological Sciences 274: 1015–22.
- Tereschenko V. V. 1996. “Seasonal and Year-to-Year Variations of Temperature and Salinity along the Kola Meridian Transect.” ICES CM 1996/C:11.
- Vallin, L., and A. Nissling. 2000. “Maternal Effects on Egg Size and Egg Buoyancy of Baltic Cod, Gadus morhua: Implications for Stock Structure Effects on Recruitment.” Fisheries Research 49: 21–37.
- Wright, P. J., and E. A. Trippel. 2009. “Fishery-Induced Demographic Changes in the Timing of Spawning: Consequences for Reproductive Success.” Fish and Fisheries 10: 283–304.
- Yaragina, N. A., B. Bogstad, and Y. A. Kovalev. 2009. “Variability in Cannibalism in Northeast Arctic Cod (Gadus morhua) during the Period 1947–2006.” Marine Biology Research 5: 75–85.
- Zhukova, N. G., V. N. Nesterova, I. P. Prokopchuk, and G. B. Rudneva. 2009. “Winter Distribution of Euphausiids (Euphausiacea) in the Barents Sea (2000–2005).” Deep Sea Research II 56: 1959–67.
10.1016/j.dsr2.2008.11.007 Google Scholar
- Zuur, A. F., E. Ieno, and C. Elphick. 2010. “A protocol for data exploration to avoid common statistical problems.” Methods in Ecology and Evolution 1: 3–14.
