Your search keyword '"maximum parsimony method"' showing total 3 results

1. Common Methods for Phylogenetic Tree Construction and Their Implementation in R.

Author

Zou, Yue, Zhang, Zixuan, Zeng, Yujie, Hu, Hanyue, Hao, Youjin, Huang, Sheng, and Li, Bo

Subjects

*PARSIMONIOUS models, *RESEARCH questions, *GENE families, *BAYESIAN field theory, *RESEARCH personnel, *MAXIMUM likelihood statistics

Abstract

A phylogenetic tree can reflect the evolutionary relationships between species or gene families, and they play a critical role in modern biological research. In this review, we summarize common methods for constructing phylogenetic trees, including distance methods, maximum parsimony, maximum likelihood, Bayesian inference, and tree-integration methods (supermatrix and supertree). Here we discuss the advantages, shortcomings, and applications of each method and offer relevant codes to construct phylogenetic trees from molecular data using packages and algorithms in R. This review aims to provide comprehensive guidance and reference for researchers seeking to construct phylogenetic trees while also promoting further development and innovation in this field. By offering a clear and concise overview of the different methods available, we hope to enable researchers to select the most appropriate approach for their specific research questions and datasets. [ABSTRACT FROM AUTHOR]

Published

2024

2. Common Methods for Phylogenetic Tree Construction and Their Implementation in R

Author

Yue Zou, Zixuan Zhang, Yujie Zeng, Hanyue Hu, Youjin Hao, Sheng Huang, and Bo Li

Subjects

phylogenetic tree, neighbor-joining method, maximum parsimony method, maximum likelihood method, Bayesian method, tree integration, Technology, Biology (General), QH301-705.5

Abstract

A phylogenetic tree can reflect the evolutionary relationships between species or gene families, and they play a critical role in modern biological research. In this review, we summarize common methods for constructing phylogenetic trees, including distance methods, maximum parsimony, maximum likelihood, Bayesian inference, and tree-integration methods (supermatrix and supertree). Here we discuss the advantages, shortcomings, and applications of each method and offer relevant codes to construct phylogenetic trees from molecular data using packages and algorithms in R. This review aims to provide comprehensive guidance and reference for researchers seeking to construct phylogenetic trees while also promoting further development and innovation in this field. By offering a clear and concise overview of the different methods available, we hope to enable researchers to select the most appropriate approach for their specific research questions and datasets.

Published

2024

3. Testing Phylogenetic Hypotheses

Author

Xia, Xuhua

Published

2000