FN Archimer Export Format PT J TI Opposing life stage‐specific effects of ocean warming at source and sink populations of range‐shifting coral‐reef fishes BT AF Monaco, Cristian Nagelkerken, Ivan Booth, David J. Figueira, Will F. Gillanders, Bronwyn M. Schoeman, David S. Bradshaw, Corey J.A. AS 1:1,2;2:1;3:3;4:4;5:1;6:5,6;7:7; FF 1:PDG-RBE-RMPF;2:;3:;4:;5:;6:;7:; C1 Southern Seas Ecology Laboratories School of Biological Sciences and The Environment Institute University of Adelaide, Australia Ifremer, IRD, Institut Louis‐Malardé, Univ Polynésie française, EIO, F‐98719 Taravao Tahiti Polynésie française, France School of the Life Sciences University of Technology Sydney ,Australia School of Life and Environmental Sciences University of Sydney ,Australia Global‐Change Ecology Research Group School of Science and Engineering University of the Sunshine Coast ,Australia Centre for African Conservation Ecology Department of Zoology Nelson Mandela University, Australia Global Ecology College of Science and Engineering Flinders University ,Australia C2 UNIV ADELAIDE, AUSTRALIA IFREMER, FRANCE UNIV SYDNEY, AUSTRALIA UNIV SYDNEY, AUSTRALIA UNIV SUNSHINE COAST, AUSTRALIA UNIV NELSON MANDELA, AUSTRALIA UNIV FLINDERS, AUSTRALIA SI TAHITI SE PDG-RBE-RMPF UM EIO IN WOS Ifremer UMR copubli-int-hors-europe IF 5.608 TC 3 UR https://archimer.ifremer.fr/doc/00660/77204/78638.pdf LA English DT Article DE ;climate change;coral reefs;global warming;marine fishes;range shifts;species distribution;temperate ecosystems;transient population dynamics AB Climate change is altering the latitudinal distributions of species, with their capacity to keep pace with a shifting climate depending on the stochastic expression of population growth rates, and the influence of compensatory density feedback on age‐specific survival rates. We use population‐abundance time series at the leading edge of an expanding species’ range to quantify the contribution of stochastic environmental drivers and density feedbacks to the dynamics of life stage‐specific population growth. 2. Using a tropical, range‐shifting Indo‐Pacific damselfish (Abudefduf vaigiensis) as a model organism, we applied variants of the phenomenological Gompertz‐logistic model to a 14‐year dataset to quantify the relative importance of density feedback and stochastic environmental drivers on the separate and aggregated population growth rates of settler and juvenile life stages. 3. The top‐ranked models indicated that density feedback negatively affected the growth of tropical settlers and juveniles. Rates of settlement were negatively linked to temperatures experienced by parents at potential source populations in the tropics, but their subsequent survival and that of juveniles increased with the temperatures experienced at the temperate sink. Including these stochastic effects doubled the deviance explained by the models, corroborating an important role of temperature. By incorporating sea‐surface temperature projections for the remainder of this century into these models, we anticipate improved conditions for the population growth of juvenile coral‐reef fishes, but not for settlers in temperate ecosystems. 4. Previous research has highlighted the association between temperature and the redistribution of species. Our analyses reveal the contrasting roles of different life stages in the dynamics of range‐shifting species responding to climate change, as they transition from vagrancy to residency in their novel ranges. PY 2021 PD MAR SO Journal Of Animal Ecology SN 0021-8790 PU Wiley VL 90 IS 3 UT 000596884900001 BP 615 EP 627 DI 10.1111/1365-2656.13394 ID 77204 ER EF