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The drug-induced phenotypic landscape of colorectal cancer organoids

Patient-derived organoids resemble the biology of tissues and tumors, enabling ex vivo modeling of human diseases. They have heterogeneous morphologies with unclear biological causes and relationship to treatment response. Here, we use high-throughput, image-based profiling to quantify phenotypes of...

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Published in:Nature communications 2022-06, Vol.13 (1), p.3135-3135, Article 3135
Main Authors: Betge, Johannes, Rindtorff, Niklas, Sauer, Jan, Rauscher, Benedikt, Dingert, Clara, Gaitantzi, Haristi, Herweck, Frank, Srour-Mhanna, Kauthar, Miersch, Thilo, Valentini, Erica, Boonekamp, Kim E., Hauber, Veronika, Gutting, Tobias, Frank, Larissa, Belle, Sebastian, Gaiser, Timo, Buchholz, Inga, Jesenofsky, Ralf, Härtel, Nicolai, Zhan, Tianzuo, Fischer, Bernd, Breitkopf-Heinlein, Katja, Burgermeister, Elke, Ebert, Matthias P., Boutros, Michael
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Language:English
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Summary:Patient-derived organoids resemble the biology of tissues and tumors, enabling ex vivo modeling of human diseases. They have heterogeneous morphologies with unclear biological causes and relationship to treatment response. Here, we use high-throughput, image-based profiling to quantify phenotypes of over 5 million individual colorectal cancer organoids after treatment with >500 small molecules. Integration of data using multi-omics modeling identifies axes of morphological variation across organoids: Organoid size is linked to IGF1 receptor signaling, and cystic vs. solid organoid architecture is associated with LGR5 + stemness. Treatment-induced organoid morphology reflects organoid viability, drug mechanism of action, and is biologically interpretable. Inhibition of MEK leads to cystic reorganization of organoids and increases expression of LGR5 , while inhibition of mTOR induces IGF1 receptor signaling. In conclusion, we identify shared axes of variation for colorectal cancer organoid morphology, their underlying biological mechanisms, and pharmacological interventions with the ability to move organoids along them. The heterogeneity underlying cancer organoid phenotypes is not yet well understood. Here, the authors develop an imaging analysis assay for high throughput phenotypic screening of colorectal organoids that allows to define specific morphological changes that occur following different drug treatments.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-30722-9