A new ensemble coevolution system for detecting HIV-1 protein coevolution

Background: A key challenge in the field of HIV-1 protein evolution is the identification of coevolving amino acids at the molecular level. In the past decades, many sequence-based methods have been designed to detect position-specific coevolution within and between different proteins. However, an e...

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Autores:
Tipo de recurso:
Fecha de publicación:
2015
Institución:
Universidad del Rosario
Repositorio:
Repositorio EdocUR - U. Rosario
Idioma:
eng
OAI Identifier:
oai:repository.urosario.edu.co:10336/23525
Acceso en línea:
https://doi.org/10.1186/s13062-014-0031-8
https://repository.urosario.edu.co/handle/10336/23525
Palabra clave:
Human immunodeficiency virus 1
Gag protein
Human immunodeficiency virus proteinase
Protein binding
Viral protein
Area under the curve
Biology
Chemistry
Genetics
Human
Human immunodeficiency virus 1
Molecular evolution
Molecular model
Procedures
Protein database
Protein tertiary structure
Reproducibility
Statistical model
Area Under Curve
Computational Biology
HIV Protease
HIV-1
Humans
Protein Binding
Reproducibility of Results
Viral Proteins
Ensemble coevolution system
Gag
HIV-1
Protease
Protein coevolution
Sequence-based method
gag
Human Immunodeficiency Virus
Molecular
Molecular
Protein
Statistical
Tertiary
Databases
Evolution
Gag Gene Products
Gene Products
Models
Models
Protein Structure
Rights
License
Abierto (Texto Completo)
Description
Summary:Background: A key challenge in the field of HIV-1 protein evolution is the identification of coevolving amino acids at the molecular level. In the past decades, many sequence-based methods have been designed to detect position-specific coevolution within and between different proteins. However, an ensemble coevolution system that integrates different methods to improve the detection of HIV-1 protein coevolution has not been developed. Results: We integrated 27 sequence-based prediction methods published between 2004 and 2013 into an ensemble coevolution system. This system allowed combinations of different sequence-based methods for coevolution predictions. Using HIV-1 protein structures and experimental data, we evaluated the performance of individual and combined sequence-based methods in the prediction of HIV-1 intra- and inter-protein coevolution. We showed that sequence-based methods clustered according to their methodology, and a combination of four methods outperformed any of the 27 individual methods. This four-method combination estimated that HIV-1 intra-protein coevolving positions were mainly located in functional domains and physically contacted with each other in the protein tertiary structures. In the analysis of HIV-1 inter-protein coevolving positions between Gag and protease, protease drug resistance positions near the active site mostly coevolved with Gag cleavage positions (V128, S373-T375, A431, F448-P453) and Gag C-terminal positions (S489-Q500) under selective pressure of protease inhibitors. Conclusions: This study presents a new ensemble coevolution system which detects position-specific coevolution using combinations of 27 different sequence-based methods. Our findings highlight key coevolving residues within HIV-1 structural proteins and between Gag and protease, shedding light on HIV-1 intra- and inter-protein coevolution. Reviewers: This article was reviewed by Dr. Zoltán Gáspári. © Li et al.

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