Covariate-adjusted construction of gene regulatory networks using a combination of generalized linear model and penalized maximum likelihood

Many machine learning techniques have been used to construct gene regulatory networks (GRNs) through precision matrix that considers conditional independence among genes, and finally produces sparse version of GRNs. This construction can be improved using the auxiliary information like gene expressi...

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Bibliographic Details
Published in:PloS one 2025-01, Vol.20 (1), p.e0309556
Main Authors: Chatrabgoun, Omid, Daneshkhah, Alireza, Torkaman, Parisa, Johnston, Mark, Sohrabi Safa, Nader, Kashif Bashir, Ali
Format: Article
Language:English
Subjects:
Algorithms
Analysis
Biology and Life Sciences
Computer and Information Sciences
Gene expression
Gene Expression Profiling - methods
Gene Regulatory Networks
Generalized linear models
Genes
Genetic markers
Genetic research
Genomics
Humans
Information theory
Likelihood Functions
Linear Models
Linear models (Statistics)
Linear regression models
Machine Learning
Methods
Models, Genetic
Multivariate analysis
Normal distribution
Optimization
Physical Sciences
Physiological aspects
Random variables
Regularization
Research and Analysis Methods
Statistical methods
Statistical models
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Summary:Many machine learning techniques have been used to construct gene regulatory networks (GRNs) through precision matrix that considers conditional independence among genes, and finally produces sparse version of GRNs. This construction can be improved using the auxiliary information like gene expression profile of the related species or gene markers. To reach out this goal, we apply a generalized linear model (GLM) in first step and later a penalized maximum likelihood to construct the gene regulatory network using Glasso technique for the residuals of a multi-level multivariate GLM among the gene expressions of one species as a multi-levels response variable and the gene expression of related species as a multivariate covariates. By considering the intrinsic property of the gene data which the number of variables is much greater than the number of available samples, a bootstrap version of multi-response multivariate GLM is used. To find most appropriate related species, a cross-validation technique has been used to compute the minimum square error of the fitted GLM under different regularization. The penalized maximum likelihood under a lasso or elastic net penalty is applied on the residual of fitted GLM to find the sparse precision matrix. Finally, we show that the presented algorithm which is a combination of fitted GLM and applying the penalized maximum likelihood on the residual of the model is extremely fast, and can exploit sparsity in the constructed GRNs. Also, we exhibit flexibility of the proposed method presented in this paper by comparing with the other methods to demonstrate the super validity of our approach.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0309556