2020
DOI: 10.1186/s12864-020-07144-2
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Functional module detection through integration of single-cell RNA sequencing data with protein–protein interaction networks

Abstract: Background Recent advances in single-cell RNA sequencing have allowed researchers to explore transcriptional function at a cellular level. In particular, single-cell RNA sequencing reveals that there exist clusters of cells with similar gene expression profiles, representing different transcriptional states. Results In this study, we present scPPIN, a method for integrating single-cell RNA sequencing data with protein–protein interac… Show more

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Cited by 15 publications
(7 citation statements)
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“…For example, to pinpoint critical genes and metabolites scMetNet [ 39 ] constructs a metabolic network based on KEGG and then finds submodules with significant differential expression across cell populations. Similarly, scPPIN was developed for identification of differentially active modules in protein–protein interaction networks based on scRNA-seq data [ 67 ], but may be also applicable to metabolic networks. Another alternative is reporter metabolite analysis, such as perturb-Met, which aims to identify affected metabolites by analyzing changes in expression of metabolite-associated genes [ 40 ].…”
Section: Modelling Approachesmentioning
confidence: 99%
“…For example, to pinpoint critical genes and metabolites scMetNet [ 39 ] constructs a metabolic network based on KEGG and then finds submodules with significant differential expression across cell populations. Similarly, scPPIN was developed for identification of differentially active modules in protein–protein interaction networks based on scRNA-seq data [ 67 ], but may be also applicable to metabolic networks. Another alternative is reporter metabolite analysis, such as perturb-Met, which aims to identify affected metabolites by analyzing changes in expression of metabolite-associated genes [ 40 ].…”
Section: Modelling Approachesmentioning
confidence: 99%
“…Moreover, the manually selected FDR allows users to selectively tune the value of this parameter to influence which genes are in the inferred altered subnetwork, analogous to ''p-hacking'' (Ioannidis, 2005;Head et al, 2015;Nuzzo, 2015). Indeed, recently published analyses using heinz use a wide range of FDR values, ranging anywhere from 10 -25 to 0:05 (Liang et al, 2012;Choi et al, 2016;He et al, 2017;Klimm et al, 2019). See the Supplementary Data for more details on the differences between heinz and NetMix.…”
Section: Netmix: a Network-structured Mixture Model 475mentioning
confidence: 99%
“…Subsequently, Dittrich et al (2008) introduced heinz as ''the first approach that really tackles and solves the original problem raised by Ideker et al (2002) to optimality.'' jActiveModules and heinz have since become widely used tools with diverse applications; a few recent examples include mass-spectrometry proteomics (Kim and Hwang, 2016;Liu et al, 2018), damaging de novo mutations in schizophrenia and other neurological disorders (Gulsuner et al, 2013;Choi et al, 2016), and single-cell RNA-seq (Soul et al, 2015;Guo et al, 2016;Klimm et al, 2019).…”
Section: Introductionmentioning
confidence: 99%
“…Practically speaking, the authors modeled the problem as the PCSTP with a degree constraint at the root node. Their problem was solved using the code from Bailly‐Bechet et al [11] Most recently, Klimm et al [144] combined single‐cell RNA‐sequencing data with protein–protein interaction networks to detect active modules in cells of different transcriptional states. The open‐source code by Leitner et al [153] was employed to solve their underlying MWCS model.…”
Section: Old and New Applications Of The Stpmentioning
confidence: 99%