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Advisor(s)
Abstract(s)
In the last decades, the rising interest in trait-based ecology
is closely related to a growing demand for knowledge on
ecosystems’ functioning and on mechanisms generating
ecological patterns and processes, and with the urgency
for approaches that allow to predict the consequences
of climate change and anthropogenic impacts (McGill
et al., 2006; De Bello et al., 2021a,b). This fundamental
knowledge is difficult to obtain when considering specific
species (i.e., taxonomic-based ecology), therefore ecologists are increasingly using functional diversity approaches
(i.e., trait-based ecology), with the added advantage of
allowing the comparison across different ecosystems and
biogeographical regions, which due to biogeographical
reasons support different species compositions (e.g.,
Henriques et al., 2017a,b).
Functional diversity (FD) refers to the distribution and
range of what species do (as determined by their functional
traits) in a given ecosystem, influencing how the ecosystem
operates or functions (e.g., stability, dynamics, productivity; Tilman, 2001; Petchey and Gaston, 2006). Currently,
the most accepted definition of the trait was proposed by
Violle and colleagues in which a trait is defined as “any
morphological, physiological or phenological feature measurable at the individual level, from the cell to the whole
organism” (Violle et al., 2007). For a trait to be considered
a functional trait, it needs to influence organismal performance (fitness), meaning its growth, reproduction, and/or
survival (McGill et al., 2006; Violle et al., 2007). Additionally, traits can also be related to the effect of organisms
on ecosystem properties, or on the other hand, to how they
respond to a disturbance or environmental change (Hooper
et al., 2005). In this way, traits can be further divided into the
following: (1) effect traits, those that significantly affect
another trophic level (e.g., predator-prey interactions)
and/or an ecosystem process (e.g., nutrient cycling, primary
productivity), regardless of whether they affect or not the
organismal performance; (2) response traits, those that
allow organisms to survive, grow, and reproduce under different disturbances and/or environmental conditions (biotic
and abiotic factors; Lavorel and Garnier, 2002).
Description
Keywords
Ecology Ecosystems Climate change Anthropogenic impacts Marine fish assemblages
Pedagogical Context
Citation
Henriques, S., Dolbeth, M., Matos, P., Pecuchet, L., Bernardo, C. P., Weigel, B., McLean, M., Hidalgo, M, Tzanatos, E. & Vasconcelos, R. P. (2025). Functional diversity in marine fish assemblages. In H. Cabral, M. Lepage, J. Lobry & O. Le Pape (Ed.). Ecology of Marine Fish (pp. 267-293). Academic Press. https://doi.org/10.1016/B978-0-323-99036-3.00004-0
Publisher
Academic Press