Single-cell network biology enabling cell-type-resolved disease genetics

被引：0

作者：

Junha Cha ^{[1
]}

Insuk Lee ^{[1
]}

机构：

[1] Department of Biotechnology, College of Life Science and Biotechnology, Yonsei University, Seoul

来源：

Genomics & Informatics | / 23卷 / 1期

基金：

新加坡国家研究基金会;

关键词：

Cell-type-resolved genetics; Cell-type-specific networks; Single-cell network biology;

D O I：

10.1186/s44342-025-00042-7

中图分类号：

学科分类号：

摘要：

Gene network models provide a foundation for graph theory approaches, aiding in the novel discovery of drug targets, disease genes, and genetic mechanisms for various biological functions. Disease genetics must be interpreted within the cellular context of disease-associated cell types, which cannot be achieved with datasets consisting solely of organism-level samples. Single-cell RNA sequencing (scRNA-seq) technology allows computational distinction of cell states which provides a unique opportunity to understand cellular biology that drives disease processes. Importantly, the abundance of cell samples with their transcriptome-wide profile allows the modeling of systemic cell-type-specific gene networks (CGNs), offering insights into gene-cell-disease relationships. In this review, we present reference-based and de novo inference of gene functional interaction networks that we have recently developed using scRNA-seq datasets. We also introduce a compendium of CGNs as a useful resource for cell-type-resolved disease genetics. By leveraging these advances, we envision single-cell network biology as the key approach for mapping the gene-cell-disease axis. © The Author(s) 2025.

引用

共 38 条

[1]

Barabasi A.L., Oltvai Z.N., Network biology: understanding the cell's functional organization, Nat Rev Genet, 5, 2, pp. 101-113, (2004)

[2]

Barabasi A.L., Gulbahce N., Loscalzo J., Network medicine: a network-based approach to human disease, Nat Rev Genet, 12, 1, pp. 56-68, (2011)

[3]

Sahni N., Yi S., Zhong Q., Jailkhani N., Charloteaux B., Cusick M.E., Et al., Edgotype: a fundamental link between genotype and phenotype, Curr Opin Genet Dev, 23, 6, pp. 649-657, (2013)

[4]

Barrett T., Wilhite S.E., Ledoux P., Evangelista C., Kim I.F., Tomashevsky M., Et al., NCBI GEO: archive for functional genomics data sets–update, Nucleic Acids Res, 41, Database issue, pp. D991-D995, (2013)

[5]

Chan T.E., Stumpf M.P.H., Babtie A.C., Gene regulatory network inference from single-cell data using multivariate information measures, Cell Syst, 5, 3, pp. 251-250, (2017)

[6]

Yamawaki T.M., Lu D.R., Ellwanger D.C., Bhatt D., Manzanillo P., Arias V., Et al., Systematic comparison of high-throughput single-cell RNA-seq methods for immune cell profiling, BMC Genomics, 22, 1, (2021)

[7]

Skinnider M.A., Squair J.W., Foster L.J., Evaluating measures of association for single-cell transcriptomics, Nat Methods, 16, 5, pp. 381-386, (2019)

[8]

Cha J., Lee I., Single-cell network biology for resolving cellular heterogeneity in human diseases, Exp Mol Med, 52, 11, pp. 1798-1808, (2020)

[9]

Duurland C.L., Santegoets S.J., Abdulrahman Z., Loof N.M., Sturm G., Wesselink T.H., Et al., CD161 expression and regulation defines rapidly responding effector CD4+ T cells associated with improved survival in HPV16-associated tumors, J Immunother Cancer, 10, 1, (2022)

[10]

Cha J., Kim D.H., Kim G., Cho J.W., Sung E., Baek S., Et al., Single-cell analysis reveals cellular and molecular factors counteracting HPV-positive oropharyngeal cancer immunotherapy outcomes, J Immunother Cancer, 12, 6, (2024)

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