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

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. One Sentence Summary Multilineage plasticity results from expansion of stem–like luminal cells with JAK/STAT activation, serving as a therapeutic target.

[1]  Vianne R. Gao,et al.  Signatures of plasticity, metastasis, and immunosuppression in an atlas of human small cell lung cancer. , 2021, Cancer cell.

[2]  Jun Luo,et al.  Reciprocal YAP1 loss and INSM1 expression in neuroendocrine prostate cancer , 2021, The Journal of pathology.

[3]  M. Loda,et al.  Temporal evolution of cellular heterogeneity during the progression to advanced AR-negative prostate cancer , 2021, Nature Communications.

[4]  P. Nelson,et al.  Inter- and intra-tumor heterogeneity of metastatic prostate cancer determined by digital spatial gene expression profiling , 2021, Nature communications.

[5]  T. H. van der Kwast,et al.  Single-cell analysis reveals transcriptomic remodellings in distinct cell types that contribute to human prostate cancer progression , 2021, Nature Cell Biology.

[6]  Henry W. Long,et al.  Subtype heterogeneity and epigenetic convergence in neuroendocrine prostate cancer , 2020, Nature Communications.

[7]  A. Regev,et al.  Transcriptional mediators of treatment resistance in lethal prostate cancer , 2020, Nature Medicine.

[8]  Oh-Joon Kwon,et al.  Sox2 is necessary for androgen ablation-induced neuroendocrine differentiation from Pten null Sca-1+ prostate luminal cells , 2020, Oncogene.

[9]  M. Loda,et al.  A single-cell atlas of the mouse and human prostate reveals heterogeneity and conservation of epithelial progenitors , 2020, bioRxiv.

[10]  D. Pe’er,et al.  Regenerative potential of prostate luminal cells revealed by single-cell analysis , 2020, Science.

[11]  D. Pe’er,et al.  Lineage plasticity in cancer: a shared pathway of therapeutic resistance , 2020, Nature Reviews Clinical Oncology.

[12]  P. Nelson,et al.  Molecular profiling stratifies diverse phenotypes of treatment-refractory metastatic castration-resistant prostate cancer. , 2019, The Journal of clinical investigation.

[13]  M. Loda,et al.  The Role of Lineage Plasticity in Prostate Cancer Therapy Resistance , 2019, Clinical Cancer Research.

[14]  Yi Mi Wu,et al.  Genomic correlates of clinical outcome in advanced prostate cancer , 2019, Proceedings of the National Academy of Sciences.

[15]  Deanna M. Church,et al.  The emergent landscape of the mouse gut endoderm at single-cell resolution , 2019, Nature.

[16]  Samantha Riesenfeld,et al.  EmptyDrops: distinguishing cells from empty droplets in droplet-based single-cell RNA sequencing data , 2019, Genome Biology.

[17]  R. Satija,et al.  Normalization and variance stabilization of single-cell RNA-seq data using regularized negative binomial regression , 2019, Genome Biology.

[18]  Andrew J. Hill,et al.  The single cell transcriptional landscape of mammalian organogenesis , 2019, Nature.

[19]  D. Pe’er,et al.  Characterization of cell fate probabilities in single-cell data with Palantir , 2019, Nature Biotechnology.

[20]  Venkat S. Malladi,et al.  A Cellular Anatomy of the Normal Adult Human Prostate and Prostatic Urethra , 2018, bioRxiv.

[21]  Simon G. Coetzee,et al.  ONECUT2 is a targetable master regulator of lethal prostate cancer that suppresses the androgen axis , 2018, Nature Medicine.

[22]  T. Graeber,et al.  Reprogramming normal human epithelial tissues to a common, lethal neuroendocrine cancer lineage , 2018, Science.

[23]  Ambrose J. Carr,et al.  Single-Cell Map of Diverse Immune Phenotypes in the Breast Tumor Microenvironment , 2018, Cell.

[24]  D. Spector,et al.  POU2F3 is a master regulator of a tuft cell-like variant of small cell lung cancer , 2018, Genes & development.

[25]  M. Rubin,et al.  Aberrant Activation of a Gastrointestinal Transcriptional Circuit in Prostate Cancer Mediates Castration Resistance. , 2017, Cancer cell.

[26]  Michael D. Nyquist,et al.  Androgen Receptor Pathway-Independent Prostate Cancer Is Sustained through FGF Signaling. , 2017, Cancer cell.

[27]  M. Rubin,et al.  Transdifferentiation as a Mechanism of Treatment Resistance in a Mouse Model of Castration-Resistant Prostate Cancer. , 2017, Cancer discovery.

[28]  Donavan T. Cheng,et al.  Mutational Landscape of Metastatic Cancer Revealed from Prospective Clinical Sequencing of 10,000 Patients , 2017, Nature Medicine.

[29]  Henry W. Long,et al.  Rb1 and Trp53 cooperate to suppress prostate cancer lineage plasticity, metastasis, and antiandrogen resistance , 2017, Science.

[30]  M. Rubin,et al.  SOX2 promotes lineage plasticity and antiandrogen resistance in TP53- and RB1-deficient prostate cancer , 2017, Science.

[31]  Matteo Benelli,et al.  Divergent clonal evolution of castration resistant neuroendocrine prostate cancer , 2016, Nature Medicine.

[32]  V. Arora,et al.  Emerging mechanisms of resistance to androgen receptor inhibitors in prostate cancer , 2015, Nature Reviews Cancer.

[33]  Sean C. Bendall,et al.  Data-Driven Phenotypic Dissection of AML Reveals Progenitor-like Cells that Correlate with Prognosis , 2015, Cell.

[34]  E. Cuppen,et al.  Identification of Multipotent Luminal Progenitor Cells in Human Prostate Organoid Cultures , 2014, Cell.

[35]  Hans Clevers,et al.  Organoid Cultures Derived from Patients with Advanced Prostate Cancer , 2014, Cell.

[36]  F. Saad,et al.  Enzalutamide in metastatic prostate cancer before chemotherapy. , 2014, The New England journal of medicine.

[37]  Kurt Miller,et al.  Increased survival with enzalutamide in prostate cancer after chemotherapy. , 2012, The New England journal of medicine.

[38]  Arturo Molina,et al.  Abiraterone and increased survival in metastatic prostate cancer. , 2011, The New England journal of medicine.

[39]  B. Foster,et al.  E2f binding-deficient Rb1 protein suppresses prostate tumor progression in vivo , 2010, Proceedings of the National Academy of Sciences.

[40]  R. Sherwood,et al.  Transcriptional dynamics of endodermal organ formation , 2009, Developmental dynamics : an official publication of the American Association of Anatomists.

[41]  P. Nelson,et al.  Prostate-specific deletion of the murine Pten tumor suppressor gene leads to metastatic prostate cancer. , 2003, Cancer cell.