Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.

Many automatic classifiers were introduced to aid inference of phenotypical effects of uncategorised nsSNVs (nonsynonymous Single Nucleotide Variations) in theoretical and medical applications. Lately, several meta-estimators have been proposed that combine different predictors, such as PolyPhen and...

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Main Authors: Ilia Korvigo, Andrey Afanasyev, Nikolay Romashchenko, Mikhail Skoblov
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2018-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC5851551?pdf=render
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spelling doaj-6063047dfde242fdbc1cb8940d9c4cec2020-11-25T02:05:28ZengPublic Library of Science (PLoS)PLoS ONE1932-62032018-01-01133e019282910.1371/journal.pone.0192829Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.Ilia KorvigoAndrey AfanasyevNikolay RomashchenkoMikhail SkoblovMany automatic classifiers were introduced to aid inference of phenotypical effects of uncategorised nsSNVs (nonsynonymous Single Nucleotide Variations) in theoretical and medical applications. Lately, several meta-estimators have been proposed that combine different predictors, such as PolyPhen and SIFT, to integrate more information in a single score. Although many advances have been made in feature design and machine learning algorithms used, the shortage of high-quality reference data along with the bias towards intensively studied in vitro models call for improved generalisation ability in order to further increase classification accuracy and handle records with insufficient data. Since a meta-estimator basically combines different scoring systems with highly complicated nonlinear relationships, we investigated how deep learning (supervised and unsupervised), which is particularly efficient at discovering hierarchies of features, can improve classification performance. While it is believed that one should only use deep learning for high-dimensional input spaces and other models (logistic regression, support vector machines, Bayesian classifiers, etc) for simpler inputs, we still believe that the ability of neural networks to discover intricate structure in highly heterogenous datasets can aid a meta-estimator. We compare the performance with various popular predictors, many of which are recommended by the American College of Medical Genetics and Genomics (ACMG), as well as available deep learning-based predictors. Thanks to hardware acceleration we were able to use a computationally expensive genetic algorithm to stochastically optimise hyper-parameters over many generations. Overfitting was hindered by noise injection and dropout, limiting coadaptation of hidden units. Although we stress that this work was not conceived as a tool comparison, but rather an exploration of the possibilities of deep learning application in ensemble scores, our results show that even relatively simple modern neural networks can significantly improve both prediction accuracy and coverage. We provide open-access to our finest model via the web-site: http://score.generesearch.ru/services/badmut/.http://europepmc.org/articles/PMC5851551?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Ilia Korvigo
Andrey Afanasyev
Nikolay Romashchenko
Mikhail Skoblov
spellingShingle Ilia Korvigo
Andrey Afanasyev
Nikolay Romashchenko
Mikhail Skoblov
Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
PLoS ONE
author_facet Ilia Korvigo
Andrey Afanasyev
Nikolay Romashchenko
Mikhail Skoblov
author_sort Ilia Korvigo
title Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
title_short Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
title_full Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
title_fullStr Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
title_full_unstemmed Generalising better: Applying deep learning to integrate deleteriousness prediction scores for whole-exome SNV studies.
title_sort generalising better: applying deep learning to integrate deleteriousness prediction scores for whole-exome snv studies.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2018-01-01
description Many automatic classifiers were introduced to aid inference of phenotypical effects of uncategorised nsSNVs (nonsynonymous Single Nucleotide Variations) in theoretical and medical applications. Lately, several meta-estimators have been proposed that combine different predictors, such as PolyPhen and SIFT, to integrate more information in a single score. Although many advances have been made in feature design and machine learning algorithms used, the shortage of high-quality reference data along with the bias towards intensively studied in vitro models call for improved generalisation ability in order to further increase classification accuracy and handle records with insufficient data. Since a meta-estimator basically combines different scoring systems with highly complicated nonlinear relationships, we investigated how deep learning (supervised and unsupervised), which is particularly efficient at discovering hierarchies of features, can improve classification performance. While it is believed that one should only use deep learning for high-dimensional input spaces and other models (logistic regression, support vector machines, Bayesian classifiers, etc) for simpler inputs, we still believe that the ability of neural networks to discover intricate structure in highly heterogenous datasets can aid a meta-estimator. We compare the performance with various popular predictors, many of which are recommended by the American College of Medical Genetics and Genomics (ACMG), as well as available deep learning-based predictors. Thanks to hardware acceleration we were able to use a computationally expensive genetic algorithm to stochastically optimise hyper-parameters over many generations. Overfitting was hindered by noise injection and dropout, limiting coadaptation of hidden units. Although we stress that this work was not conceived as a tool comparison, but rather an exploration of the possibilities of deep learning application in ensemble scores, our results show that even relatively simple modern neural networks can significantly improve both prediction accuracy and coverage. We provide open-access to our finest model via the web-site: http://score.generesearch.ru/services/badmut/.
url http://europepmc.org/articles/PMC5851551?pdf=render
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