Loss of natural Baltic salmon populations can severely reduce metapopulation capacity for retaining genetic variation
Kurland, S., Ryman, N., Hössjer, O. and Laikre, L. (2018). Loss of natural Baltic salmon populations can severely reduce metapopulation capacity for retaining genetic variation. 5th European Congress of Conservation Biology. doi: 10.17011/conference/eccb2018/107735
Päivämäärä
2018Tekijänoikeudet
© the Authors, 2018
The Atlantic salmon of the Baltic Sea is a species of high ecological importance and socioeconomic value. Historically, 94 rivers entering the Baltic Sea held wild salmon populations. Hydro-electric power plant construction during the 19th and 20th centuries has obstructed the salmons’ migratory pathways to upstream spawning grounds, leading to limited reproduction in the wild, and a depletion of natural - likely unique - populations. Today, wild populations remain in 30 of the rivers, of which 11 are self-sustaining. The additional rivers contain wild and released salmon in various stages of self-sustainability, although a few rivers are completely void of salmon (1). This study addresses whether the loss of separate subpopulations has reduced the overall capacity for Baltic salmon to maintain genetic variation, and if so, what the expected magnitude of such a reduction is.
Effective population size (Ne) is a key term in conservation biology as it measures the rate of loss of genetic variation. It was initially developed for a single, isolated population. Although considerable research has been devoted to modelling Ne in subdivided populations (i.e. metapopulations), most of those efforts have used simplifying assumptions such as subpopulations of equal size and standardized models of migration. We apply a novel analytical tool (2, 3) which allows modeling of complex metapopulations with large flexibility in metapopulation structure. This permits modelling highly topical issues on the genetic dynamics of metapopulations that have previously not been possible to address, which we apply to a case study of the Baltic salmon. Our model is parameterized with empirical data from Baltic salmon populations in order to estimate the metapopulation Ne and inbreeding dynamics of Baltic salmon prior to and after the subpopulation decline.
The results show that with subpopulation sizes, migration rates, and migration models mimicking Baltic salmon population structure, metapopulation Ne is drastically reduced following the loss of separate river populations. Compared to the loss expected based on the proportion of populations lost, the observed reduction in metapopulation Ne is larger by orders of magnitude. This indicates that the capacity of the Baltic salmon to maintain genetic diversity and adapt is likely seriously compromised as a consequence of local extinctions. The future survival and adaptive potential of the Baltic salmon critically relies on management efforts retaining remaining wild populations and restoring populations in rivers that have lost their local stocks.
References
1. ICES. 2016. Report of the Baltic Salmon and Trout Assessment Working Group (WGBAST), 30 March–6 April 2016, Klaipeda, Lithuania. ICES CM 2016/ACOM:09. 257 pp.
2. Hössjer O, Olsson F, Laikre L, Ryman N. 2014. A new general analytical approach for modeling patterns of genetic differentiation and effective size of subdivided populations over time. Mathematical Bioscienc
...
Julkaisija
Open Science Centre, University of JyväskyläKonferenssi
ECCB2018: 5th European Congress of Conservation Biology. 12th - 15th of June 2018, Jyväskylä, Finland
Alkuperäislähde
https://peerageofscience.org/conference/eccb2018/107735/Metadata
Näytä kaikki kuvailutiedotKokoelmat
- ECCB 2018 [712]
Lisenssi
Samankaltainen aineisto
Näytetään aineistoja, joilla on samankaltainen nimeke tai asiasanat.
-
Effects of fumonisin B1 on performance of juvenile Baltic salmon (Salmo salar)
Carrera Garcia, Erika (2013)Fumonisin B1 is a mycotoxin produced by fungi of the genus Fusarium that frequently occurs on maize (Zea mays) and feeds containing it. The use of plant-based protein sources in feeds designed for aquaculture has increased ... -
Spatio-temporal differences in the growth of wild and reared Atlantic salmon (Salmo salar L.) in the Baltic Sea
Peltola, Mikko (2013)Syönnösvaellus ja nopea kasvu ovat olennainen osa Atlantin lohen (Salmo salar L.) ekologiaa, niinpä kasvunopeuden selvittäminen on tärkeä osa kalatutkimusta. Tuottavimmat syönnösalueet tulisi tietää, jotta olisi mahdollista ... -
Movements of Individual Salmon (Salmo salar) in the Baltic Sea Revealed by Stable Isotopes
Kiljunen, Mikko; Torniainen, Jyrki; Lensu, Anssi; Keinänen, Marja; Vuorinen, Pekka; Patterson, William P.; Jones, Roger (Open Science Centre, University of Jyväskylä, 2018)Spatial stable isotope variability (“isoscapes”) offer potential for various applications in migration ecology, wherein stable isotope values of animal tissues are compared to values measured from the environment. We used ... -
Migratory connectivity amongst Baltic Sea salmon
Torniainen, Jyrki (University of Jyväskylä, 2014) -
Thiamine Deficiency M74 Developed in Salmon (Salmo salar) Stocks in Two Baltic Sea Areas after the Hatching of Large Year-Classes of Two Clupeid Species : Detected by Fatty Acid Signature Analysis
Vuorinen, Pekka J.; Käkelä, Reijo; Pakarinen, Tapani; Heinimaa, Petri; Ritvanen, Tiina; Nikonen, Soili; Rokka, Mervi; Keinänen, Marja (MDPI AG, 2024)Lipid-related thiamine (vitamin B1) deficiency of Baltic salmon (Salmo salar), the M74 syndrome, is generally caused by feeding on abundant young sprat (Sprattus sprattus) in the Baltic Proper, the main foraging area of ...
Ellei toisin mainittu, julkisesti saatavilla olevia JYX-metatietoja (poislukien tiivistelmät) saa vapaasti uudelleenkäyttää CC0-lisenssillä.