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Self-supervised deep learning encodes high-resolution features of protein subcellular localization

Hirofumi Kobayashi, Keith Cheveralls, Manuel D. Leonetti, Löıc A. Royer

2022Nature Methods133 citationsDOIOpen Access PDF

Abstract

Explaining the diversity and complexity of protein localization is essential to fully understand cellular architecture. Here we present cytoself, a deep-learning approach for fully self-supervised protein localization profiling and clustering. Cytoself leverages a self-supervised training scheme that does not require preexisting knowledge, categories or annotations. Training cytoself on images of 1,311 endogenously labeled proteins from the OpenCell database reveals a highly resolved protein localization atlas that recapitulates major scales of cellular organization, from coarse classes, such as nuclear and cytoplasmic, to the subtle localization signatures of individual protein complexes. We quantitatively validate cytoself's ability to cluster proteins into organelles and protein complexes, showing that cytoself outperforms previous self-supervised approaches. Moreover, to better understand the inner workings of our model, we dissect the emergent features from which our clustering is derived, interpret them in the context of the fluorescence images, and analyze the performance contributions of each component of our approach.

Topics & Concepts

Protein subcellular localization predictionCluster analysisArtificial intelligenceSubcellular localizationComputer scienceComputational biologyDeep learningNuclear localization sequenceProfiling (computer programming)Pattern recognition (psychology)CytoplasmMachine learningBiologyGeneCell biologyGeneticsOperating systemCell Image Analysis TechniquesImage Processing Techniques and ApplicationsAdvanced Fluorescence Microscopy Techniques
Self-supervised deep learning encodes high-resolution features of protein subcellular localization | Litcius