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Single-cell morphology encodes functional subtypes of senescence in aging human dermal fibroblasts

Pratik Kamat, Nicolas C. Macaluso, Yukang Li, Anshika Agrawal, Aaron Winston, Lauren Pan, Teasia Stewart, Bartholomew Starich, Nicholas Milcik, Chanhong Min, Pei-Hsun Wu, Jeremy Walston, Jean Fan, Jude M. Phillip

2025Science Advances13 citationsDOIOpen Access PDF

Abstract

Cellular senescence, a hallmark of aging, reveals context-dependent phenotypes across multiple biological length scales. Despite its mechanistic importance, identifying and characterizing senescence across cell populations is challenging. Using primary dermal fibroblasts, we combined single-cell imaging, machine learning, several induced senescence conditions, and multiple protein biomarkers to define functional senescence subtypes. Single-cell morphology analysis revealed 11 distinct morphology clusters. Among these, we identified three as bona fide senescence subtypes (C7, C10, and C11), with C10 exhibiting the strongest age dependence within an aging cohort. In addition, we observed that a donor's senescence burden and subtype composition were indicative of susceptibility to doxorubicin-induced senescence. Functional analysis revealed subtype-dependent responses to senotherapies, with C7 being most responsive to the combination of dasatinib and quercetin. Our single-cell analysis framework, SenSCOUT, enables robust identification and classification of senescence subtypes, offering applications in next-generation senotherapy screens, with potential toward explaining heterogeneous senescence phenotypes based on the presence of senescence subtypes.

Topics & Concepts

SenescencePhenotypeBiologyCellCell biologyCellular senescenceContext (archaeology)GeneticsGenePaleontologyTelomeres, Telomerase, and SenescenceSingle-cell and spatial transcriptomicsAdvanced Fluorescence Microscopy Techniques