Prediction of Co-Receptor Usage of HIV-1 from Genotype

Dybowski, J. Nikolaj; Heider, Dominik; Hoffmann, Daniel

doi:10.1371/journal.pcbi.1000743

Cited by 51 publications

(103 citation statements)

References 40 publications

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“…The type of co-receptor is crucial for the aggressiveness of the virus and the available treatment options. Hence, Dybowski et al [16] proposed to predict co-receptor usage based on the viral genome sequences. A random forest based method is developed to predict co-receptor usage for new sequences using structures and sequences of "gp120".…”

Section: Biological Sequence Analysismentioning

confidence: 99%

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Random Forest for Bioinformatics

2012

Ensemble Machine Learning

567

344

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Section: Biological Sequence Analysismentioning

confidence: 99%

“…A random forest based method is developed to predict co-receptor usage for new sequences using structures and sequences of "gp120". The good accuracy achieved in [16] made random forest a strong candidate for computational diagnosis of viral diseases.…”

Section: Biological Sequence Analysismentioning

confidence: 99%

Random Forest for Bioinformatics

2012

Ensemble Machine Learning

567

344

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“…Random Forests are increasingly popular in the biomedical community and enjoy good predictive success even against other machine learning algorithms in a wide variety of applications (Lunetta et al, 2004;Segal et al, 2004;Bureau et al 2005; Diaz-Uriarte and Alvarez de Andes 2006; Qi, Bar-Joseph and Klein-Seetharaman 2006; Xu et al, 2007;Archer and Kimes 2008;Pers et al 2009;Tuv et al, 2009;Dybowski, Heider and Hoffman 2010;Geneur et al, 2010). Random Forests have been used in HIV disease to examine phenotypic properties of the virus.…”

Section: Use In Biomedical Applicationsmentioning

confidence: 99%

“…Segal et al used Random Forests to examine the role of mutations in polymerase in HIV-1 to viral replication capacity . Random Forests have also been used to predict HIV-1 coreceptor usage from sequence data (Xu et al, 2007;Dybowski et al, 2010). Qi et al found that Random Forests had excellent predictive capabilities in the prediction of protein interaction compared to six other machine learning methods (Qi et al, 2006).…”

Section: Use In Biomedical Applicationsmentioning

confidence: 99%

Nonparametric Variable Selection Using Machine Learning Algorithms in High Dimensional (Large P, Small N) Biomedical Applications

Kitchen¹

2011

Biomedical Engineering, Trends in Electronics, Communications and Software

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“…To date, many bioinformatics methods for tropism prediction have been developed and tested. These bioinformatics predictors include support vector machines (SVM) [4,5], neural networks (NN) [6], decision trees [7], random forest [8], instance based reasoning [9], position specific scoring matrices (PSSM) [10], multiple linear regression [11], and the 11/25 rule [12]. However, these methods generally are developed by fitting a model onto the respective training set, and might not perform as well in independent or unseen datasets [13].…”

Section: Introductionmentioning

confidence: 99%

A Case-Based Reasoning System for Genotypic Prediction of Hiv-1 Co-Receptor Tropism

Evans¹,

Paquet²,

Huang³

et al. 2013

J. Bioinform. Comput. Biol.

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Accurate co-receptor tropism (CRT) determination is critical for making treatment decisions in HIV management. We created a genotypic tropism prediction tool by utilizing the case-based reasoning (CBR) technique that attempts to solve new problems through applying the solution from similar past problems. V3 loop sequences from 732 clinical samples with diverse characteristics were used to build a case library. Additional sequence and molecular properties of the V3 loop were examined and used for similarity assessment. A similarity metric was defined based on each attribute's frequency in the CXCR4-using viruses. We implemented three other genotype-based tropism predictors, support vector machines (SVM), position specific scoring matrices (PSSM), and the 11/25 rule, and evaluated their performance as the ability to predict CRT compared to Monogram's enhanced sensitivity Trofile® assay (ESTA). Overall concordance of the CBR based tropism prediction algorithm was 81%, as compared to ESTA. Sensitivity to detect CXCR4 usage was 90% and specificity was at 73%. In comparison, sensitivity of the SVM, PSSM, and the 11/25 rule were 85%, 81% and 36% respectively while achieving a specificity of 90% by SVM, 75% by PSSM, and 97% by the 11/25 rule. When we evaluated these predictors in an unseen dataset, higher sensitivity was achieved by the CBR algorithm (87%), compared to SVM (82%), PSSM (76%), and the 11/25 rule (33%), while maintaining similar level of specificity. Overall this study suggests that CBR can be utilized as a genotypic tropism prediction tool, and can achieve improved performance in independent datasets compared to model or rule based methods.

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Prediction of Co-Receptor Usage of HIV-1 from Genotype

Cited by 51 publications

References 40 publications

Random Forest for Bioinformatics

Random Forest for Bioinformatics

Nonparametric Variable Selection Using Machine Learning Algorithms in High Dimensional (Large P, Small N) Biomedical Applications

A Case-Based Reasoning System for Genotypic Prediction of Hiv-1 Co-Receptor Tropism

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