A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
Eco‐evolutionary dynamics driven by fishing : from single species models to dynamic evolution within complex food webs (2020)


Perälä, T., & Kuparinen, A. (2020). Eco‐evolutionary dynamics driven by fishing : from single species models to dynamic evolution within complex food webs. Evolutionary Applications, 13(10), 2507-2520. https://doi.org/10.1111/eva.13058


JYU-tekijät tai -toimittajat


Julkaisun tiedot

Julkaisun kaikki tekijät tai toimittajatPerälä, Tommi; Kuparinen, Anna

Lehti tai sarjaEvolutionary Applications

eISSN1752-4571

Julkaisuvuosi2020

Ilmestymispäivä05.07.2020

Volyymi13

Lehden numero10

Artikkelin sivunumerot2507-2520

KustantajaWiley-Blackwell

JulkaisumaaYhdysvallat (USA)

Julkaisun kielienglanti

DOIhttps://doi.org/10.1111/eva.13058

Linkki tutkimusaineistoonhttps://doi.org/10.5061/dryad.x3ffbg7fc

Julkaisun avoin saatavuusAvoimesti saatavilla

Julkaisukanavan avoin saatavuusKokonaan avoin julkaisukanava

Julkaisu on rinnakkaistallennettu (JYX)https://jyx.jyu.fi/handle/123456789/72865


Tiivistelmä

Evidence of contemporary evolution across ecological time scales stimulated research on the eco‐evolutionary dynamics of natural populations. Aquatic systems provide a good setting to study eco‐evolutionary dynamics owing to a wealth of long‐term monitoring data and the detected trends in fish life‐history traits across intensively harvested marine and freshwater systems. In the present study, we focus on modelling approaches to simulate eco‐evolutionary dynamics of fishes and their ecosystems. Firstly, we review the development of modelling from single‐species to multispecies approaches. Secondly, we advance the current state‐of‐the‐art methodology by implementing evolution of life‐history traits of a top predator into the context of complex food web dynamics as described by the allometric trophic network (ATN) framework. The functioning of our newly developed eco‐evolutionary ATNE framework is illustrated using a well‐studied lake food web. Our simulations show how both natural selection arising from feeding interactions and size‐selective fishing cause evolutionary changes in the top predator and how those feed back to its prey species and further cascade down to lower trophic levels. Finally, we discuss future directions, particularly the need to integrate genomic discoveries into eco‐evolutionary projections.


YSO-asiasanatekosysteemit (ekologia)evoluutioevoluutiobiologiaravintoketjutahven

Vapaat asiasanataquatic ecosystems; co‐evolution; community dynamics; ecosystem dynamics; Eurasian Perch; food webs; lake constance; life‐history evolution; predator‐prey dynamics


Liittyvät organisaatiot


Hankkeet, joissa julkaisu on tehty


OKM-raportointiKyllä

Raportointivuosi2020

JUFO-taso2


Viimeisin päivitys 2024-26-03 klo 09:18