A novel approach based on multiobjective variable mesh optimization to Phylogenetics

Cristian Zambrano-Vega; Byron Oviedo Bayas; Stalin Carreño; Amilkar Puris; Oscar Moncayo

Autores/as

Cristian Zambrano-Vega Universidad Técnica Estatal de Quevedo
Byron Oviedo Bayas Universidad Técnica Estatal de Quevedo
Stalin Carreño Universidad Técnica Estatal de Quevedo
Amilkar Puris Universidad Técnica Estatal de Quevedo
Oscar Moncayo Universidad Técnica Estatal de Quevedo

Palabras clave:

Multiobjective Optimization, Phylogenetic Inference, Evolutionary Computation, Bioinformatics.

Resumen

One of the most relevant problems in Bioinformaticsand Computational Biology is the search and reconstruction ofthe most accurate phylogenetic tree that explains, as exactly aspossible, the evolutionary relationships among species from agiven dataset. Different criteria have been employed to evaluatethe accuracy of evolutionary hypothesis in order to guide a searchalgorithm towards the best tree. However, these criteria may leadto distinct phylogenies, which are often conflicting among them.Therefore, a multi-objective approach can be useful. In this work,we present a phylogenetic adaptation of a multiobjective variablemesh optimization algorithm for inferring phylogenies, to tacklethe phylogenetic inference problem according to two optimalitycriteria: maximum parsimony and maximum likelihood. Theaim of this approach is to propose a complementary view ofphylogenetics in order to generate a set of trade-off phylogenetictopologies that represent a consensus between both criteria.Experiments on four real nucleotide datasets show that ourproposal can achieve promising results, under both multiobjectiveand biological approaches, with regard to other classical andrecent multiobjective metaheuristics from the state-of-the-art.

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