Multilineage plasticity in prostate cancer through expansion of stem–like luminal epithelial cells with elevated inflammatory signaling.

Samir Zaidi*, Jimmy L. Zhao*, Joseph Chan*, Martine P. Roudier, Kristine M. Wadosky, Anuradha Gopalan, Wouter R. Karthaus, Jungmin Choi, Kayla Lawrence, Ojasvi Chaudhary, Tianhao Xu, Ignas Masilionis, Linas Mazutis, Ronan Chaligne, Irina Linkov, Afsar Barlas, Achim Jungbluth, Natasha Rekhtman, Joachim Silber, Katia Manova–Todorova, Philip A. Watson, Lawrence D. True, Peter S. Nelson, Howard I. Scher, Dana E. Rathkopf, Michael J. Morris, Michael C. Haffner, David W. Goodrich, Dana Pe’er, Charles L. Sawyers. Multilineage plasticity in prostate cancer through expansion of stem–like luminal epithelial cells with elevated inflammatory signaling. bioRxiv 2021 Nov 3. https://www.biorxiv.org/content/10.1101/2021.11.01.466599v1

Lineage plasticity is a well–established mechanism of resistance to targeted therapies in lung and prostate cancer, where tumors transition from adenocarcinoma to small–cell or neuroendocrine carcinoma. Through single–cell analysis of a cohort of heavily–treated castration–resistant human prostate cancers (CRPC), we report a greater degree of plasticity than previously appreciated, with multiple distinct neuroendocrine (NEPC), mesenchymal (EMT–like), and other subpopulations detected within single biopsies. To explore the steps leading to this plasticity, we turned to two genetically engineered mouse models of prostate cancer that recapitulate progression from adenocarcinoma to neuroendocrine disease. Time course studies reveal expansion of stem–like luminal epithelial cells (Sca1+, Psca+, called L2) that, based on trajectories, gave rise to at least 4 distinct subpopulations, NEPC (Ascl1+), POU2F3 (Pou2f3+), TFF3 (Tff3+) and EMT–like (Vim+, Ncam1+)––these populations are also seen in human prostate and small cell lung cancers. Transformed L2–like cells express stem–like and gastrointestinal endoderm–like transcriptional programs, indicative of reemerging developmental plasticity programs, as well as elevated Jak/Stat and interferon pathway signaling. In sum, while the magnitude of multilineage heterogeneity, both within and across patients, raises considerable treatment challenges, the identification of highly plastic luminal cells as the likely source of this heterogeneity provides a target for more focused therapeutic intervention.