Eels' individual migratory behavior stems from a complex syndrome involving cognition, behavior, physiology, and life history
成果类型:
Article
署名作者:
De Russi, Gaia; Lanzoni, Mattia; Bisazza, Angelo; Domenici, Paolo; Castaldelli, Giuseppe; Bertolucci, Cristiano; Lucon-Xiccato, Tyrone
署名单位:
University of Ferrara; University of Ferrara; University of Padua; Consiglio Nazionale delle Ricerche (CNR); Istituto di Biofisica (IBF-CNR)
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-12040
DOI:
10.1073/pnas.2407804121
发表日期:
2024-11-19
关键词:
anguilla-anguilla
european eel
metabolic-rate
fresh-water
animal personality
phenotypic plasticity
ventilation frequency
level consistency
comacchio lagoon
trade-offs
摘要:
Variability within species is key for adaptability and biological evolution. To understand individualities in the context of animal movement, we focused on one of the most remarkable migrations-the journey of the endangered European eel from their birthplace in the Sargasso Sea to freshwater environments. Laboratory observations unveiled a continuum of diverse phenotypes of migrating eels: Some displayed a heightened tendency to swim against a constant water flow, while others a greater propensity to climb obstacles. Looking for the biological underpinnings of this migratory diversity, we characterized the eels' individual differences in traits of four key domains: life history, physiology, behavior, and cognition, among which we found significant variance and interconnectedness. Upon reducing this variance to its primary multivariate axes, we found that these predict the migratory types. Eels with 1) low exploration, high activity, low boldness, and high lateralization; 2) strong lateralization, enhanced quantitative abilities, short problem- solving time, high boldness, and low growth rates; or 3) enhanced problem- solving, reduced spatial learning, high cognitive flexibility, and shorter time to solve the cognitive tasks were more likely to display the climbing migratory type. Field sampling revealed how specific traits' combinations seemed to influence the distribution of eels once they begin to settle in the freshwater environment. Our study underscores the impressive diversity of individuals during this critical migration, emphasizing an intrinsic connection to multidomain trait variance. Preserving this diversity becomes paramount, as it likely contributes to the resilience and adaptability of endangered migratory species.