Strong linkages between depth, longevity and demographic stability across marine sessile species

Understanding the role of the environment in shaping the evolution of life histories remains a major challenge in ecology and evolution. We synthesize longevity patterns of marine sessile species and find strong positive relationships between depth and maximum lifespan across multiple sessile marine...

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Detalhes bibliográficos
Autor principal: Montero-Serra I. (author)
Outros Autores: Linares C. (author), Doak D.F. (author), Ledoux J.B. (author), Garrabou J. (author)
Formato: article
Idioma:eng
Publicado em: 2018
Assuntos:
bivalve
comparative study
coral
deep-sea organism
demography
ecological modeling
environmental gradient
life history
life history theory
longevity
macroalga
marine ecosystem
mortality
population dynamics
sessile species
sponge
vulnerability
Anthozoa
Bivalvia
Corallium rubrum
animal
aquatic species
ecosystem
physiology
seaweed
Animals
Aquatic Organisms
Ecosystem
Longevity
Population Dynamics
Seaweed
Texto completo:https://hdl.handle.net/10216/120495
País:Portugal
Oai:oai:repositorio-aberto.up.pt:10216/120495
Descrição
Resumo:Understanding the role of the environment in shaping the evolution of life histories remains a major challenge in ecology and evolution. We synthesize longevity patterns of marine sessile species and find strong positive relationships between depth and maximum lifespan across multiple sessile marine taxa, including corals, bivalves, sponges and macroalgae. Using long-term demographic data on marine sessile and terrestrial plant species, we show that extreme longevity leads to strongly dampened population dynamics. We also used detailed analyses of Mediterranean red coral, with a maximum lifespan of 532 years, to explore the life-history patterns of long-lived taxa and the vulnerability to external mortality sources that these characteristics can create. Depth-related environmental gradients-including light, food availability, temperature and disturbance intensity-drive highly predictable distributions of life histories that, in turn, have predictable ecological consequences for the dynamics of natural populations. © 2018 The Author(s) Published by the Royal Society. All rights reserved.

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