Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data

Abstract Background A fundamental fact in biology states that genes do not operate in isolation, and yet, methods that infer regulatory networks for single cell gene expression data have been slow to emerge. With single cell sequencing methods now becoming accessible, general network inference algor...

Full description

Bibliographic Details
Main Authors: Shuonan Chen, Jessica C. Mar
Format: Article
Language:English
Published: BMC 2018-06-01
Series:BMC Bioinformatics
Subjects:
Online Access:http://link.springer.com/article/10.1186/s12859-018-2217-z
id doaj-d1af4b29286549a6a83563cab50a7607
record_format Article
spelling doaj-d1af4b29286549a6a83563cab50a76072020-11-25T00:24:20ZengBMCBMC Bioinformatics1471-21052018-06-0119112110.1186/s12859-018-2217-zEvaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression dataShuonan Chen0Jessica C. Mar1Department of Systems and Computational Biology, Albert Einstein College of MedicineDepartment of Systems and Computational Biology, Albert Einstein College of MedicineAbstract Background A fundamental fact in biology states that genes do not operate in isolation, and yet, methods that infer regulatory networks for single cell gene expression data have been slow to emerge. With single cell sequencing methods now becoming accessible, general network inference algorithms that were initially developed for data collected from bulk samples may not be suitable for single cells. Meanwhile, although methods that are specific for single cell data are now emerging, whether they have improved performance over general methods is unknown. In this study, we evaluate the applicability of five general methods and three single cell methods for inferring gene regulatory networks from both experimental single cell gene expression data and in silico simulated data. Results Standard evaluation metrics using ROC curves and Precision-Recall curves against reference sets sourced from the literature demonstrated that most of the methods performed poorly when they were applied to either experimental single cell data, or simulated single cell data, which demonstrates their lack of performance for this task. Using default settings, network methods were applied to the same datasets. Comparisons of the learned networks highlighted the uniqueness of some predicted edges for each method. The fact that different methods infer networks that vary substantially reflects the underlying mathematical rationale and assumptions that distinguish network methods from each other. Conclusions This study provides a comprehensive evaluation of network modeling algorithms applied to experimental single cell gene expression data and in silico simulated datasets where the network structure is known. Comparisons demonstrate that most of these assessed network methods are not able to predict network structures from single cell expression data accurately, even if they are specifically developed for single cell methods. Also, single cell methods, which usually depend on more elaborative algorithms, in general have less similarity to each other in the sets of edges detected. The results from this study emphasize the importance for developing more accurate optimized network modeling methods that are compatible for single cell data. Newly-developed single cell methods may uniquely capture particular features of potential gene-gene relationships, and caution should be taken when we interpret these results.http://link.springer.com/article/10.1186/s12859-018-2217-zGene regulatory networkSingle cell genomicsBayesian networkCorrelation network
collection DOAJ
language English
format Article
sources DOAJ
author Shuonan Chen
Jessica C. Mar
spellingShingle Shuonan Chen
Jessica C. Mar
Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
BMC Bioinformatics
Gene regulatory network
Single cell genomics
Bayesian network
Correlation network
author_facet Shuonan Chen
Jessica C. Mar
author_sort Shuonan Chen
title Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
title_short Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
title_full Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
title_fullStr Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
title_full_unstemmed Evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
title_sort evaluating methods of inferring gene regulatory networks highlights their lack of performance for single cell gene expression data
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2018-06-01
description Abstract Background A fundamental fact in biology states that genes do not operate in isolation, and yet, methods that infer regulatory networks for single cell gene expression data have been slow to emerge. With single cell sequencing methods now becoming accessible, general network inference algorithms that were initially developed for data collected from bulk samples may not be suitable for single cells. Meanwhile, although methods that are specific for single cell data are now emerging, whether they have improved performance over general methods is unknown. In this study, we evaluate the applicability of five general methods and three single cell methods for inferring gene regulatory networks from both experimental single cell gene expression data and in silico simulated data. Results Standard evaluation metrics using ROC curves and Precision-Recall curves against reference sets sourced from the literature demonstrated that most of the methods performed poorly when they were applied to either experimental single cell data, or simulated single cell data, which demonstrates their lack of performance for this task. Using default settings, network methods were applied to the same datasets. Comparisons of the learned networks highlighted the uniqueness of some predicted edges for each method. The fact that different methods infer networks that vary substantially reflects the underlying mathematical rationale and assumptions that distinguish network methods from each other. Conclusions This study provides a comprehensive evaluation of network modeling algorithms applied to experimental single cell gene expression data and in silico simulated datasets where the network structure is known. Comparisons demonstrate that most of these assessed network methods are not able to predict network structures from single cell expression data accurately, even if they are specifically developed for single cell methods. Also, single cell methods, which usually depend on more elaborative algorithms, in general have less similarity to each other in the sets of edges detected. The results from this study emphasize the importance for developing more accurate optimized network modeling methods that are compatible for single cell data. Newly-developed single cell methods may uniquely capture particular features of potential gene-gene relationships, and caution should be taken when we interpret these results.
topic Gene regulatory network
Single cell genomics
Bayesian network
Correlation network
url http://link.springer.com/article/10.1186/s12859-018-2217-z
work_keys_str_mv AT shuonanchen evaluatingmethodsofinferringgeneregulatorynetworkshighlightstheirlackofperformanceforsinglecellgeneexpressiondata
AT jessicacmar evaluatingmethodsofinferringgeneregulatorynetworkshighlightstheirlackofperformanceforsinglecellgeneexpressiondata
_version_ 1725352571328004096