Your search keyword '"Karthaus WR"' showing total 6 results

1. Regenerative potential of prostate luminal cells revealed by single-cell analysis.

Author

Karthaus WR, Hofree M, Choi D, Linton EL, Turkekul M, Bejnood A, Carver B, Gopalan A, Abida W, Laudone V, Biton M, Chaudhary O, Xu T, Masilionis I, Manova K, Mazutis L, Pe'er D, Regev A, and Sawyers CL

Subjects

Androgen Antagonists therapeutic use, Androgen-Binding Protein genetics, Animals, Antigens, Neoplasm genetics, Ataxin-1 genetics, Cell Differentiation genetics, GPI-Linked Proteins genetics, Gene Expression, Homeodomain Proteins genetics, Humans, Male, Mesenchymal Stem Cells physiology, Mice, Neoplasm Proteins genetics, Nerve Growth Factors genetics, Organ Size, Organoids metabolism, Organoids physiology, Prostate metabolism, Prostatic Neoplasms drug therapy, Prostatic Neoplasms metabolism, Sequence Analysis, RNA, Single-Cell Analysis, Thrombospondins genetics, Transcription Factors genetics, Androgens metabolism, Prostate physiology, Prostate surgery, Prostatic Neoplasms surgery, Regeneration genetics

Abstract

Androgen deprivation is the cornerstone of prostate cancer treatment. It results in involution of the normal gland to ~90% of its original size because of the loss of luminal cells. The prostate regenerates when androgen is restored, a process postulated to involve stem cells. Using single-cell RNA sequencing, we identified a rare luminal population in the mouse prostate that expresses stemlike genes ( Sca1 + and Psca + ). In organoids and in mice, both populations contribute equally to prostate regeneration, partly through androgen-driven expression of growth factors (Nrg2, Rspo3) by mesenchymal cells acting in a paracrine fashion on luminal cells. Analysis of human prostate tissue revealed similar differentiated and stemlike luminal subpopulations that likewise acquire enhanced regenerative potential after androgen ablation. We propose that prostate regeneration is driven by nearly all persisting luminal cells, not just by rare stem cells.Nkx3.1 + , Pbsn + ). In organoids and in mice, both populations contribute equally to prostate regeneration, partly through androgen-driven expression of growth factors (Nrg2, Rspo3) by mesenchymal cells acting in a paracrine fashion on luminal cells. Analysis of human prostate tissue revealed similar differentiated and stemlike luminal subpopulations that likewise acquire enhanced regenerative potential after androgen ablation. We propose that prostate regeneration is driven by nearly all persisting luminal cells, not just by rare stem cells., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

2. Prostate Organoid Cultures as Tools to Translate Genotypes and Mutational Profiles to Pharmacological Responses.

Author

Pappas KJ, Choi D, Sawyers CL, and Karthaus WR

Subjects

Animals, Cell Differentiation, Disease Models, Animal, Genotype, Humans, Male, Mice, Mutation, Organoids metabolism, Prostate physiopathology

Abstract

Presented here is a protocol to study pharmacodynamics, stem cell potential, and cancer differentiation in prostate epithelial organoids. Prostate organoids are androgen responsive, three-dimensional (3D) cultures grown in a defined medium that resembles the prostatic epithelium. Prostate organoids can be established from wild-type and genetically engineered mouse models, benign human tissue, and advanced prostate cancer. Importantly, patient derived organoids closely resemble tumors in genetics and in vivo tumor biology. Moreover, organoids can be genetically manipulated using CRISPR/Cas9 and shRNA systems. These controlled genetics make the organoid culture attractive as a platform for rapidly testing the effects of genotypes and mutational profiles on pharmacological responses. However, experimental protocols must be specifically adapted to the 3D nature of organoid cultures to obtain reproducible results. Described here are detailed protocols for performing seeding assays to determine organoid formation capacity. Subsequently, this report shows how to perform drug treatments and analyze pharmacological response via viability measurements, protein isolation, and RNA isolation. Finally, the protocol describes how to prepare organoids for xenografting and subsequent in vivo growth assays using subcutaneous grafting. These protocols yield highly reproducible data and are widely applicable to 3D culture systems.

Published

2019

3. Patient derived organoids to model rare prostate cancer phenotypes.

Author

Puca L, Bareja R, Prandi D, Shaw R, Benelli M, Karthaus WR, Hess J, Sigouros M, Donoghue A, Kossai M, Gao D, Cyrta J, Sailer V, Vosoughi A, Pauli C, Churakova Y, Cheung C, Deonarine LD, McNary TJ, Rosati R, Tagawa ST, Nanus DM, Mosquera JM, Sawyers CL, Chen Y, Inghirami G, Rao RA, Grandori C, Elemento O, Sboner A, Demichelis F, Rubin MA, and Beltran H

Subjects

Animals, Antineoplastic Agents pharmacology, Cell Line, Tumor, Cell Survival drug effects, Cell Survival genetics, Epigenomics methods, Gene Expression Profiling methods, Genomics methods, Humans, Male, Mice, Inbred NOD, Mice, Knockout, Mice, SCID, Neuroendocrine Tumors drug therapy, Neuroendocrine Tumors pathology, Organoids pathology, Phenotype, Prostate pathology, Prostatic Neoplasms drug therapy, Prostatic Neoplasms pathology, Xenograft Model Antitumor Assays, Neuroendocrine Tumors genetics, Organoids metabolism, Prostate metabolism, Prostatic Neoplasms genetics

Abstract

A major hurdle in the study of rare tumors is a lack of existing preclinical models. Neuroendocrine prostate cancer is an uncommon and aggressive histologic variant of prostate cancer that may arise de novo or as a mechanism of treatment resistance in patients with pre-existing castration-resistant prostate cancer. There are few available models to study neuroendocrine prostate cancer. Here, we report the generation and characterization of tumor organoids derived from needle biopsies of metastatic lesions from four patients. We demonstrate genomic, transcriptomic, and epigenomic concordance between organoids and their corresponding patient tumors. We utilize these organoids to understand the biologic role of the epigenetic modifier EZH2 in driving molecular programs associated with neuroendocrine prostate cancer progression. High-throughput organoid drug screening nominated single agents and drug combinations suggesting repurposing opportunities. This proof of principle study represents a strategy for the study of rare cancer phenotypes.

Published

2018

4. ERF mutations reveal a balance of ETS factors controlling prostate oncogenesis.

Author

Bose R, Karthaus WR, Armenia J, Abida W, Iaquinta PJ, Zhang Z, Wongvipat J, Wasmuth EV, Shah N, Sullivan PS, Doran MG, Wang P, Patruno A, Zhao Y, Zheng D, Schultz N, and Sawyers CL

Subjects

Androgens metabolism, Animals, Cell Line, Tumor, Genes genetics, Humans, Male, Mice, Prostate metabolism, Protein Stability, Receptors, Androgen metabolism, Repressor Proteins deficiency, Repressor Proteins metabolism, Serine Endopeptidases deficiency, Serine Endopeptidases metabolism, Signal Transduction, Transcriptional Regulator ERG deficiency, Transcriptional Regulator ERG metabolism, Transcriptome genetics, Tumor Suppressor Proteins metabolism, Up-Regulation, Carcinogenesis genetics, Mutation, Prostate pathology, Prostatic Neoplasms genetics, Prostatic Neoplasms pathology, Proto-Oncogene Proteins c-ets metabolism, Repressor Proteins genetics

Abstract

Half of all prostate cancers are caused by the TMPRSS2-ERG gene-fusion, which enables androgens to drive expression of the normally silent E26 transformation-specific (ETS) transcription factor ERG in prostate cells. Recent genomic landscape studies of such cancers have reported recurrent point mutations and focal deletions of another ETS member, the ETS2 repressor factor ERF. Here we show these ERF mutations cause decreased protein stability and mostly occur in tumours without ERG upregulation. ERF loss recapitulates the morphological and phenotypic features of ERG gain in normal mouse prostate cells, including expansion of the androgen receptor transcriptional repertoire, and ERF has tumour suppressor activity in the same genetic background of Pten loss that yields oncogenic activity by ERG. In the more common scenario of ERG upregulation, chromatin immunoprecipitation followed by sequencing indicates that ERG inhibits the ability of ERF to bind DNA at consensus ETS sites both in normal and in cancerous prostate cells. Consistent with a competition model, ERF overexpression blocks ERG-dependent tumour growth, and ERF loss rescues TMPRSS2-ERG-positive prostate cancer cells from ERG dependency. Collectively, these data provide evidence that the oncogenicity of ERG is mediated, in part, by competition with ERF and they raise the larger question of whether other gain-of-function oncogenic transcription factors might also inactivate endogenous tumour suppressors.

Published

2017

5. Organoid culture systems for prostate epithelial and cancer tissue.

Author

Drost J, Karthaus WR, Gao D, Driehuis E, Sawyers CL, Chen Y, and Clevers H

Subjects

Animals, Cells, Cultured, Culture Media, Serum-Free, Humans, Male, Mice, Time, Epithelial Cells physiology, Organ Culture Techniques methods, Organoids growth & development, Prostate physiology

Abstract

This protocol describes a strategy for the generation of 3D prostate organoid cultures from healthy mouse and human prostate cells (either bulk or FACS-sorted single luminal and basal cells), metastatic prostate cancer lesions and circulating tumor cells. Organoids derived from healthy material contain the differentiated luminal and basal cell types, whereas organoids derived from prostate cancer tissue mimic the histology of the tumor. We explain how to establish these cultures in the fully defined serum-free conditioned medium that is required to sustain organoid growth. Starting with the plating of digested tissue material, full-grown organoids can usually be obtained in ∼2 weeks. The culture protocol we describe here is currently the only one that allows the growth of both the luminal and basal prostatic epithelial lineages, as well as the growth of advanced prostate cancers. Organoids established using this protocol can be used to study many different aspects of prostate biology, including homeostasis, tumorigenesis and drug discovery.

Published

2016

6. Identification of multipotent luminal progenitor cells in human prostate organoid cultures.

Author

Karthaus WR, Iaquinta PJ, Drost J, Gracanin A, van Boxtel R, Wongvipat J, Dowling CM, Gao D, Begthel H, Sachs N, Vries RGJ, Cuppen E, Chen Y, Sawyers CL, and Clevers HC

Subjects

Androgens metabolism, Humans, Male, Stem Cells cytology, Stem Cells metabolism, Organ Culture Techniques, Organoids, Prostate cytology

Abstract

The prostate gland consists of basal and luminal cells arranged as pseudostratified epithelium. In tissue recombination models, only basal cells reconstitute a complete prostate gland, yet murine lineage-tracing experiments show that luminal cells generate basal cells. It has remained challenging to address the molecular details of these transitions and whether they apply to humans, due to the lack of culture conditions that recapitulate prostate gland architecture. Here, we describe a 3D culture system that supports long-term expansion of primary mouse and human prostate organoids, composed of fully differentiated CK5+ basal and CK8+ luminal cells. Organoids are genetically stable, reconstitute prostate glands in recombination assays, and can be experimentally manipulated. Single human luminal and basal cells give rise to organoids, yet luminal-cell-derived organoids more closely resemble prostate glands. These data support a luminal multilineage progenitor cell model for prostate tissue and establish a robust, scalable system for mechanistic studies., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014