Abstract

Machine learning was applied for the automated derivation of causal influences in cellular signaling networks. This derivation relied on the simultaneous measurement of multiple phosphorylated protein and phospholipid components in thousands of individual primary human immune system cells. Perturbing these cells with molecular interventions drove the ordering of connections between pathway components, wherein Bayesian network computational methods automatically elucidated most of the traditionally reported signaling relationships and predicted novel interpathway network causalities, which we verified experimentally. Reconstruction of network models from physiologically relevant primary single cells might be applied to understanding native-state tissue signaling biology, complex drug actions, and dysfunctional signaling in diseased cells.

Keywords

Computational biologySignal transductionCell signalingSystems biologyBiologyBayesian networkDrug discoveryComputer scienceIn silicoCellCell biologyNeuroscienceArtificial intelligenceBioinformaticsBiochemistryGene

Affiliated Institutions

Related Publications

Publication Info

Year
2005
Type
article
Volume
308
Issue
5721
Pages
523-529
Citations
1694
Access
Closed

External Links

View on DOI.org

Social Impact

Altmetric
PlumX Metrics

Social media, news, blog, policy document mentions

Citation Metrics

1694
OpenAlex

Cite This

Karen Sachs, Omar D. Perez, Dana Pe’er et al. (2005). Causal Protein-Signaling Networks Derived from Multiparameter Single-Cell Data. Science , 308 (5721) , 523-529. https://doi.org/10.1126/science.1105809

Identifiers

DOI
10.1126/science.1105809