Litcius/Paper detail

Multi-omic network inference from time-series data

María Moscardó Garcia, Atte Aalto, Arthur N. Montanari, Alexander Skupin, Jorge Gonçalves

2025npj Systems Biology and Applications7 citationsDOIOpen Access PDF

Abstract

Biological phenotypes emerge from complex interactions across molecular layers. Yet, data-driven approaches to infer these regulatory networks have primarily focused on single-omic studies, overlooking inter-layer regulatory relationships. To address these limitations, we developed MINIE, a computational method that integrates multi-omic data from bulk metabolomics and single-cell transcriptomics through a Bayesian regression approach that explicitly models the timescale separation between molecular layers. We validate the method on both simulated datasets and experimental Parkinson's disease data. MINIE exhibits accurate and robust predictive performance across and within omic layers, including curated multi-omic networks and the lac operon. Benchmarking demonstrated significant improvements over state-of-the-art methods while ranking among the top performers in comprehensive single-cell network inference analysis. The integration of regulatory dynamics across molecular layers and temporal scales provides a powerful tool for comprehensive multi-omic network inference.

Topics & Concepts

InferenceComputer scienceData miningBenchmarkingBayesian networkRanking (information retrieval)Machine learningGene regulatory networkArtificial intelligenceDynamic Bayesian networkBayesian probabilityBayesian inferenceData integrationNetwork modelBiological networkRegressionGenomicsGraphical modelComplex networkComputational biologyData modelingSynthetic dataBayes' theoremFrequentist inferenceNoisy dataApproximate inferenceExperimental dataParticle filterBioinformatics and Genomic NetworksGene Regulatory Network AnalysisMicrobial Metabolic Engineering and Bioproduction