Abstract
BackgroundPhylogenetic analysis is a key way to understand current research in the biological processes and detect theory in evolution of natural selection. The evolutionary relationship between species is generally reflected in the form of phylogenetic trees. Many methods for constructing phylogenetic trees, are based on the optimization criteria. We extract the biological data via modeling features, and then compare these characteristics to study the biological evolution between species.ResultsHere, we use maximum likelihood and Bayesian inference method to establish phylogenetic trees; multi-chain Markov chain Monte Carlo sampling method can be used to select optimal phylogenetic tree, resolving local optimum problem. The correlation model of phylogenetic analysis assumes that phylogenetic trees are built on homogeneous data, however there exists a large deviation in the presence of heterogeneous data. We use conscious detection to solve compositional heterogeneity. Our method is evaluated on two sets of experimental data, a group of bacterial 16S ribosomal RNA gene data, and a group of genetic data with five homologous species.ConclusionsOur method can obtain accurate phylogenetic trees on the homologous data, and also detect the compositional heterogeneity of experimental data. We provide an efficient method to enhance the accuracy of generated phylogenetic tree.
Highlights
Phylogenetic analysis is a key way to understand current research in the biological processes and detect theory in evolution of natural selection
The correlation model of phylogenetic analysis assumes that phylogenetic trees are built on homogeneous data, there exists a large deviation in the presence of heterogeneous data
Our method is evaluated on two sets of experimental data, a group of bacterial 16S ribosomal Ribonucleic acid (RNA) gene data, and a group of genetic data with five homologous species
Summary
Phylogenetic analysis is a key way to understand current research in the biological processes and detect theory in evolution of natural selection. Phylogenetic analysis keeps an important role to understand current research in the biological processes and detect theory in evolution of natural selection. Many methods for constructing the phylogenetic tree, are based on optimization criteria, such as maximum parsimony, maximum likelihood and minimum evolution. Maximum likelihood (ML) approach [4, 5] tries to estimate trees by formulating a probabilistic model of evolution and applying known statistical method. It involves that phylogenetic tree yields the highest probability of evolutionary relationship.
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