Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-08T16:27:48.417Z Has data issue: false hasContentIssue false

Alternative restocking strategy could reverse declines of a critically endangered sturgeon

Published online by Cambridge University Press:  20 January 2022

Joshua H Daskin*
Affiliation:
US Fish and Wildlife Service, Division of Conservation and Classification, Falls Church, VA22041, USA Current address: Archbold Biological Station, Venus, FL33960, USA
Andrew R Tilman
Affiliation:
University of Pennsylvania, Department of Biology, Philadelphia, PA19104, USA
*
Author for correspondence: Dr Joshua H Daskin, Email: [email protected]

Summary

Demographic modelling can reveal options for improved conservation management, especially for rare or long-lived species not amenable to experimentation. Sturgeon (Acipenseridae) include many such species, endangered by demand for caviar, their unfertilized roe, and by dams blocking their migrations. Restocking of sturgeon populations with farm-raised individuals has probably prevented extinctions and widespread extirpations of some species, but it has rarely led to true recovery in Eurasia, given ongoing harvest. We used modified Leslie matrix models to test whether restocking with year-old juveniles instead of weeks-old fry could recover the critically endangered Amur sturgeon (Acipenser schrenckii), endemic to the Amur River basin along the Russia–China border. Without restocking, or even releasing an expert-recommended annual volume of young fry (10 million), we project that three of four Amur sturgeon populations will be nearly extirpated within 30 years. However, restocking with 5% as many (500 000) year-old juveniles annually could grow three populations (currently 0–425 mature females) and slow declines in another so that each has over 6400 mature females within 30 years. Retooling stocking efforts to use fewer juveniles that survive at higher rates than do small fry could buy time to reduce harvesting pressure on Amur sturgeon and for other related sturgeon species.

Type
Report
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of Foundation for Environmental Conservation

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Armbruster, P, Fernando, P, Lande, R (1999) Time frames for population viability analysis of species with long generations: an example with Asian elephants. Animal Conservation 2: 6973.CrossRefGoogle Scholar
Beissinger, SR, McCullough, DR (2002) Population Viability Analysis. Chicago, IL, USA: University of Chicago Press.Google Scholar
Billard, R, Lecointre, G (2000) Biology and conservation of sturgeon and paddlefish. Reviews in Fish Biology and Fisheries 10: 355392.CrossRefGoogle Scholar
Birstein, VJ, Waldman, JR, Bemis, WE (2006) Sturgeon Biodiversity and Conservation. Berlin, Germany: Springer Science+Business Media.Google Scholar
Boyce, MS (1992) Population viability analysis. Annual review of Ecology and Systematics 23: 481497.CrossRefGoogle Scholar
Bronzi, P, Chebanov, M, Michaels, JT, Wei, Q, Rosenthal, H, Gessner, J (2019) Sturgeon meat and caviar production: global update 2017. Journal of Applied Ichthyology 35: 257266.CrossRefGoogle Scholar
Caswell, H (2006) Age-classified matrix models. In: Matrix Population Models (pp. 834). Sunderland, MA, USA: Sinauer Associates, Inc.Google Scholar
CITES, UNEP-WCMC (2021) CITES trade database [www document]. URL https://trade.cites.org Google Scholar
Fantle-Lepczyk, J, Taylor, A, Duffy, DC, Crampton, LH, Conant, S (2018) Using population viability analysis to evaluate management activities for an endangered Hawaiian endemic, the Puaiohi (Myadestes palmeri) PLoS ONE13: e0198952.CrossRefGoogle Scholar
Harris, L, Shiraishi, H (2018) Understanding the global caviar market. Results of a rapid assessment of trade in sturgeon caviar. TRAFFIC and WWF joint report [www document]. URL https://www.traffic.org/publications/reports/understanding-the-global-caviar-market/ Google Scholar
Heppell, SS, Crouse, DT, Crowder, LB (2000) Using matrix models to focus research and management efforts in conservation. In: Quantitative Methods for Conservation Biology (pp. 148168). New York, NY, USA: Springer.CrossRefGoogle Scholar
Jager, HI, Chandler, JA, Lepla, KB, Van Winkle, W (2001) A theoretical study of river fragmentation by dams and its effects on white sturgeon populations. Environmental Biology of Fishes 60: 347361.CrossRefGoogle Scholar
Jager, HI, Van Winkle, W, Chandler, JA, Lepla, KB, Bates, P, Counihan, TD (2002) A simulation study of factors controlling white sturgeon recruitment in the Snake River. In: Van Winkle, W, Anders, PJ, Secor, DH, Dixon, DA DA (eds), Biology, Management, and Protection of North American Sturgeon (pp. 127150). Bethesda, MD, USA: American Fisheries Society.Google Scholar
Jarić, I, Gessner, J (2013) A life-stage population model of the European sturgeon (Acipenser sturio) in the Elbe River. Part I: general model outline and potential applications. Journal of Applied Ichthyology 29: 483493.CrossRefGoogle Scholar
King, T, Chamberlan, C, Courage, A (2014) Assessing reintroduction success in long-lived primates through population viability analysis: western lowland gorillas Gorilla gorilla gorilla in Central Africa. Oryx 48: 294303.CrossRefGoogle Scholar
Koshelev, VN, Ruban, G, Shmigirilov, A (2014a) Spawning migrations and reproductive parameters of the kaluga sturgeon, Huso dauricus (Georgi, 1775), and Amur sturgeon, Acipenser schrenckii (Brandt, 1869). Journal of Applied Ichthyology 30: 11251132.CrossRefGoogle Scholar
Koshelev, V, Shmigirilov, A, Ruban, G (2014b) Current status of feeding stocks of the kaluga sturgeon Huso dauricus Georgi, 1775, and Amur sturgeon Acipenser schrenckii Brandt, 1889, in Russian waters. Journal of Applied Ichthyology 30: 13101318.CrossRefGoogle Scholar
Krykhtin, ML, Svirskii, VG (1997) Endemic sturgeons of the Amur River: kaluga, Huso dauricus, and Amur sturgeon, Acipenser schrenckii . Environmental Biology of Fishes 48: 231239.CrossRefGoogle Scholar
Levin, S, Goodyear, C (1980) Analysis of an age-structured fishery model. Journal of Mathematical Biology 9: 245274.CrossRefGoogle Scholar
McCusker, MR, Curtis, JMR, Lovejoy, NR, Mandrak, NE (2017) Exploring uncertainty in population viability analysis and its implications for the conservation of a freshwater fish. Aquatic Conservation: Marine and Freshwater Ecosystems 27: 780788.CrossRefGoogle Scholar
McDougall, CA, Nelson, PA, Aiken, JK, Burnett, DC, Barth, CC, MacDonell, DS et al. (2020) Hatchery rearing of lake sturgeon to age 1 prior to stocking: a path forward for species recovery in the Upper Nelson River, Manitoba, Canada. North American Journal of Fisheries Management 40: 807827.CrossRefGoogle Scholar
McDougall, CA, Pisiak, DJ, Barth, CC, Blanchard, MA, MacDonell, DS, Macdonald, D (2014) Relative recruitment success of stocked age-1 vs age-0 lake sturgeon (Acipenser fulvescens Rafinesque, 1817) in the Nelson River, northern Canada. Journal of Applied Ichthyology 30: 14511460.CrossRefGoogle Scholar
McGowan, CP, Allan, N, Servoss, J, Hedwall, S, Wooldridge, B (2017) Incorporating population viability models into species status assessment and listing decisions under the U.S. Endangered Species Act. Global Ecology and Conservation 12: 119130.CrossRefGoogle Scholar
Novomodny, G, Sharov, P, Zolotukhin, S (2004) Amur Fish: Wealth and Crisis. Vladivostok, Russia: WWF.Google Scholar
Ruban, G, Qiwei, W (2010) IUCN Red List of Threatened Species: Acipenser schrenckii [www document]. URL https://www.iucnredlist.org/en Google Scholar
Saunders, SP, Cuthbert, FJ, Zipkin, EF (2018) Evaluating population viability and efficacy of conservation management using integrated population models. Journal of Applied Ecology 55: 13801392.CrossRefGoogle Scholar
Simonov, EA, Dahmer, TD (2008) Amur–Heilong River Basin Reader. Hong Kong: WWF and Ecosystems, Ltd.Google Scholar
Tucker, AM, McGowan, CP, Mulero Oliveras, ES, Angeli, NF, Zegarra, JP (2021) A demographic projection model to support conservation decision making for an endangered snake with limited monitoring data. Animal Conservation 24: 291301.CrossRefGoogle Scholar
Vaisman, A, Fomenko, P (2006) Siberia’s Black Gold: Harvest and Trade in Amur River Sturgeons in the Russian Federation. Brussels, Belgium: TRAFFIC Europe.Google Scholar
Wang, T, Gao, X, Jakovlić, I, Liu, H-Z (2017) Life tables and elasticity analyses of Yangtze River fish species with implications for conservation and management. Reviews in Fish Biology and Fisheries 27: 255266.CrossRefGoogle Scholar
Wei, Q, Zhang, J, Zhuang, P, Luo, J, Zhou, R, Yang, W (1997) Biology, fisheries, and conservation of sturgeons and paddlefish in China. Environmental Biology of Fishes 48: 241255.CrossRefGoogle Scholar
Wei, QW, Zou, Y, Li, P, Li, L (2011) Sturgeon aquaculture in China: progress, strategies and prospects assessed on the basis of nation-wide surveys (2007–2009). Journal of Applied Ichthyology 27: 162168.CrossRefGoogle Scholar
WSCS, WWF, CoE (2018) Pan-European action plan for sturgeon [www document]. URL https://rm.coe.int/pan-european-action-plan-for-sturgeons/16808e84f3 Google Scholar
Zhuang, P, Kynard, B, Zhang, L, Zhang, T, Zhang, Z, Li, D (2002) Overview of biology and aquaculture of Amur sturgeon (Acipenser schrenckii) in China. Journal of Applied Ichthyology 18: 659664.CrossRefGoogle Scholar
Supplementary material: File

Daskin and Tilman supplementary material

Daskin and Tilman supplementary material 1

Download Daskin and Tilman supplementary material(File)
File 5.9 KB
Supplementary material: File

Daskin and Tilman supplementary material

Daskin and Tilman supplementary material 2

Download Daskin and Tilman supplementary material(File)
File 93.2 KB
Supplementary material: File

Daskin and Tilman supplementary material

Daskin and Tilman supplementary material 3

Download Daskin and Tilman supplementary material(File)
File 271.7 KB