Your search keyword '"Melián, Carlos J."' showing total 6 results

1. Deciphering the Interdependence between Ecological and Evolutionary Networks.

Author

Melián CJ, Matthews B, de Andreazzi CS, Rodríguez JP, Harmon LJ, and Fortuna MA

Subjects

Animals, Invertebrates genetics, Invertebrates physiology, Plant Physiological Phenomena genetics, Vertebrates genetics, Vertebrates physiology, Biological Evolution, Ecosystem, Food Chain, Gene Regulatory Networks, Models, Biological

Abstract

Biological systems consist of elements that interact within and across hierarchical levels. For example, interactions among genes determine traits of individuals, competitive and cooperative interactions among individuals influence population dynamics, and interactions among species affect the dynamics of communities and ecosystem processes. Such systems can be represented as hierarchical networks, but can have complex dynamics when interdependencies among levels of the hierarchy occur. We propose integrating ecological and evolutionary processes in hierarchical networks to explore interdependencies in biological systems. We connect gene networks underlying predator-prey trait distributions to food webs. Our approach addresses longstanding questions about how complex traits and intraspecific trait variation affect the interdependencies among biological levels and the stability of meta-ecosystems., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

2. Eco-evolutionary feedbacks promote fluctuating selection and long-term stability of antagonistic networks.

Author

de Andreazzi CS, Guimarães PR Jr, and Melián CJ

Subjects

Feedback, Models, Biological, Population Dynamics, Selection, Genetic, Adaptation, Biological, Biological Evolution, Ecosystem

Abstract

Studies have shown the potential for rapid adaptation in coevolving populations and that the structure of species interaction networks can modulate the vulnerability of ecological systems to perturbations. Although the feedback loop between population dynamics and coevolution of traits is crucial for understanding long-term stability in ecological assemblages, modelling eco-evolutionary dynamics in species-rich assemblages is still a challenge. We explore how eco-evolutionary feedbacks influence trait evolution and species abundances in 23 empirical antagonistic networks. We show that, if selection due to antagonistic interactions is stronger than other selective pressures, eco-evolutionary feedbacks lead to higher mean species abundances and lower temporal variation in abundances. By contrast, strong selection of antagonistic interactions leads to higher temporal variation of traits and on interaction strengths. Our results present a theoretical link between the study of the species persistence and coevolution in networks of interacting species, pointing out the ways by which coevolution may decrease the vulnerability of species within antagonistic networks to demographic fluctuation., (© 2018 The Author(s).)

Published

2018

3. Does sex speed up evolutionary rate and increase biodiversity?

Author

Melián CJ, Alonso D, Allesina S, Condit RS, and Etienne RS

Subjects

Computer Simulation, DNA Mutational Analysis, Humans, Models, Statistical, Biodiversity, Biological Evolution, DNA genetics, Genetics, Population, Models, Genetic, Sexual Behavior

Abstract

Most empirical and theoretical studies have shown that sex increases the rate of evolution, although evidence of sex constraining genomic and epigenetic variation and slowing down evolution also exists. Faster rates with sex have been attributed to new gene combinations, removal of deleterious mutations, and adaptation to heterogeneous environments. Slower rates with sex have been attributed to removal of major genetic rearrangements, the cost of finding a mate, vulnerability to predation, and exposure to sexually transmitted diseases. Whether sex speeds or slows evolution, the connection between reproductive mode, the evolutionary rate, and species diversity remains largely unexplored. Here we present a spatially explicit model of ecological and evolutionary dynamics based on DNA sequence change to study the connection between mutation, speciation, and the resulting biodiversity in sexual and asexual populations. We show that faster speciation can decrease the abundance of newly formed species and thus decrease long-term biodiversity. In this way, sex can reduce diversity relative to asexual populations, because it leads to a higher rate of production of new species, but with lower abundances. Our results show that reproductive mode and the mechanisms underlying it can alter the link between mutation, evolutionary rate, speciation and biodiversity and we suggest that a high rate of evolution may not be required to yield high biodiversity.

Published

2012

4. Neutral biodiversity theory can explain the imbalance of phylogenetic trees but not the tempo of their diversification.

Author

Davies TJ, Allen AP, Borda-de-Água L, Regetz J, and Melián CJ

Subjects

Biota, Genetic Speciation, Mutation, Phylogeny, Biodiversity, Biological Evolution, Models, Genetic

Abstract

Numerous evolutionary studies have sought to explain the distribution of diversity across the limbs of the tree of life. At the same time, ecological studies have sought to explain differences in diversity and relative abundance within and among ecological communities. Traditionally, these patterns have been considered separately, but models that consider processes operating at the level of individuals, such as neutral biodiversity theory (NBT), can provide a link between them. Here, we compare evolutionary dynamics across a suite of NBT models. We show that NBT can yield phylogenetic tree topologies with imbalance closely resembling empirical observations. In general, metacommunities that exhibit greater disparity in abundance are characterized by more imbalanced phylogenetic trees. However, NBT fails to capture the tempo of diversification as represented by the distribution of branching events through time. We suggest that population-level processes might therefore help explain the asymmetry of phylogenetic trees, but that tree shape might mislead estimates of evolutionary rates unless the diversification process is modeled explicitly., (© 2011 The Author(s). Evolution© 2011 The Society for the Study of Evolution.)

Published

2011

5. Chapter Six - Individual Trait Variation and Diversity in Food Webs.

Author

Melián, Carlos J., Baldó, Francisco, Matthews, Blake, Vilas, César, González-Ortegón, Enrique, Drake, Pilar, and Williams, Richard J.

Subjects

*FOOD chains, *BIODIVERSITY, *PHENOTYPES, *BAYESIAN analysis, *BIOLOGICAL evolution, *ECOLOGICAL research

Abstract

In recent years, there has been a renewed interest in the ecological consequences of individual trait variation within populations. Given that individual variability arises from evolutionary dynamics, to fully understand eco-evolutionary feedback loops, we need to pay special attention to how standing trait variability affects ecological dynamics. There is mounting empirical evidence that intra-specific phenotypic variation can exceed species-level means, but theoretical models of multi-trophic species coexistence typically neglect individual-level trait variability. What is needed are multispecies datasets that are resolved at the individual level that can be used to discriminate among alternative models of resource selection and species coexistence in food webs. Here, using one the largest individual-based datasets of a food web compiled to date, along with an individual trait-based stochastic model that incorporates Approximate Bayesian computation methods, we document intra-population variation in the strength of prey selection by different classes or predator phenotypes which could potentially alter the diversity and coexistence patterns of food webs. In particular, we found that strongly connected individual predators preferentially consumed common prey, whereas weakly connected predators preferentially selected rare prey. Such patterns suggest that food web diversity may be governed by the distribution of predator connectivity and individual trait variation in prey selection. We discuss the consequences of intra-specific variation in prey selection to assess fitness differences among predator classes (or phenotypes) and track longer term food web patterns of coexistence accounting for several phenotypes within each prey and predator species. [ABSTRACT FROM AUTHOR]

Published

2014

6. Chapter Three - Eco-Evolutionary Spatial Dynamics: Rapid Evolution and Isolation Explain Food Web Persistence.

Author

Moya-Laraño, Jordi, Bilbao-Castro, José Román, Barrionuevo, Gabriel, Ruiz-Lupión, Dolores, Casado, Leocadio G., Montserrat, Marta, Melián, Carlos J., and Magalhães, Sara

Subjects

*FOOD chains, *BIOLOGICAL evolution, *PREDATION, *SOIL moisture, *OMNIVORES, *ECOLOGICAL research

Abstract

One of the current challenges in evolutionary ecology is understanding the long-term persistence of contemporary-evolving predator-prey interactions across space and time. To address this, we developed an extension of a multi-locus, multi-trait eco-evolutionary individual-based model that incorporates several interacting species in explicit landscapes. We simulated eco-evolutionary dynamics of multiple species food webs with different degrees of connectance across soil-moisture islands. A broad set of parameter combinations led to the local extinction of species, but some species persisted, and this was associated with (1) high connectance and omnivory and (2) ongoing evolution, due to multi-trait genetic variability of the embedded species. Furthermore, persistence was highest at intermediate island distances, likely because of a balance between predation-induced extinction (strongest at short island distances) and the coupling of island diversity by top predators, which by travelling among islands exert global top-down control of biodiversity. In the simulations with high genetic variation, we also found widespread trait evolutionary changes indicative of eco-evolutionary dynamics. We discuss how the ever-increasing computing power and high-resolution data availability will soon allow researchers to start bridging the in vivo-in silico gap. [ABSTRACT FROM AUTHOR]

Published

2014