Your search keyword '"Koen C. Oost"' showing total 8 results

1. Supplementary Data from Liver Colonization by Colorectal Cancer Metastases Requires YAP-Controlled Plasticity at the Micrometastatic Stage

Author

Hugo J.G. Snippert, Onno Kranenburg, Michiel Vermeulen, Jacco van Rheenen, Martijn Gloerich, Prisca Liberali, Inne H.M. Borel Rinkes, Ingrid Verlaan-Klink, Joris H. Hageman, Gustavo de Medeiros, Mirjam C. van der Net, Arianna Fumagalli, Lisa van Voorthuijsen, Rik G.H. Lindeboom, Koen C. Oost, Niek A. Peters, and Maria C. Heinz

Abstract

Supplementary Data from Liver Colonization by Colorectal Cancer Metastases Requires YAP-Controlled Plasticity at the Micrometastatic Stage

Published

2023

2. Data from Liver Colonization by Colorectal Cancer Metastases Requires YAP-Controlled Plasticity at the Micrometastatic Stage

Author

Hugo J.G. Snippert, Onno Kranenburg, Michiel Vermeulen, Jacco van Rheenen, Martijn Gloerich, Prisca Liberali, Inne H.M. Borel Rinkes, Ingrid Verlaan-Klink, Joris H. Hageman, Gustavo de Medeiros, Mirjam C. van der Net, Arianna Fumagalli, Lisa van Voorthuijsen, Rik G.H. Lindeboom, Koen C. Oost, Niek A. Peters, and Maria C. Heinz

Abstract

Micrometastases of colorectal cancer can remain dormant for years prior to the formation of actively growing, clinically detectable lesions (i.e., colonization). A better understanding of this step in the metastatic cascade could help improve metastasis prevention and treatment. Here we analyzed liver specimens of patients with colorectal cancer and monitored real-time metastasis formation in mouse livers using intravital microscopy to reveal that micrometastatic lesions are devoid of cancer stem cells (CSC). However, lesions that grow into overt metastases demonstrated appearance of de novo CSCs through cellular plasticity at a multicellular stage. Clonal outgrowth of patient-derived colorectal cancer organoids phenocopied the cellular and transcriptomic changes observed during in vivo metastasis formation. First, formation of mature CSCs occurred at a multicellular stage and promoted growth. Conversely, failure of immature CSCs to generate more differentiated cells arrested growth, implying that cellular heterogeneity is required for continuous growth. Second, early-stage YAP activity was required for the survival of organoid-forming cells. However, subsequent attenuation of early-stage YAP activity was essential to allow for the formation of cell type heterogeneity, while persistent YAP signaling locked micro-organoids in a cellularly homogenous and growth-stalled state. Analysis of metastasis formation in mouse livers using single-cell RNA sequencing confirmed the transient presence of early-stage YAP activity, followed by emergence of CSC and non-CSC phenotypes, irrespective of the initial phenotype of the metastatic cell of origin. Thus, establishment of cellular heterogeneity after an initial YAP-controlled outgrowth phase marks the transition to continuously growing macrometastases.Significance:Characterization of the cell type dynamics, composition, and transcriptome of early colorectal cancer liver metastases reveals that failure to establish cellular heterogeneity through YAP-controlled epithelial self-organization prohibits the outgrowth of micrometastases.See related commentary by LeBleu, p. 1870

Published

2023

3. Reconstructing single-cell karyotype alterations in colorectal cancer identifies punctuated and gradual diversification patterns

Author

Sippe G. de Vries, Wigard P. Kloosterman, Holger Rehmann, William Cross, Myrna van den Bos, Sander Boymans, Bingxin Lu, Susanne M.A. Lens, Hugo J. Snippert, Yannik Bollen, Markus J. van Roosmalen, Maximilian Mossner, Nicolle Besselink, Ellen Stelloo, Christopher Kimberley, Edwin Cuppen, Chris P. Barnes, Petra van Leenen, Bas Ponsioen, Ana C. F. Bolhaqueiro, Koen C. Oost, Bastiaan van der Roest, Trevor A. Graham, Andrea Sottoriva, Geert J. P. L. Kops, Leon W.M.M. Terstappen, Hubrecht Institute for Developmental Biology and Stem Cell Research, KNAW Humanities Cluster, TechMed Centre, and Medical Cell Biophysics

Subjects

Cell division, Karyotype, Gene Dosage, Mitosis, Spindle Apparatus, Biology, Chromosomes, Article, DNA sequencing, Cell Proliferation/genetics, 03 medical and health sciences, 0302 clinical medicine, Single-cell analysis, Genetics, medicine, Chromosomes, Human, Humans, Cell Proliferation, 030304 developmental biology, Microscopy, 0303 health sciences, Microscopy, Confocal, Chromatin/genetics, Cell growth, Time-lapse imaging, Single-Cell Analysis/methods, Cancer, medicine.disease, Colorectal cancer, Colorectal Neoplasms/genetics, Chromatin, Human genetics, 3. Good health, Organoids, Evolutionary biology, Confocal, Karyotyping, 030220 oncology & carcinogenesis, Spindle Apparatus/genetics, Single-Cell Analysis, Colorectal Neoplasms, Human, Organoids/growth & development

Abstract

Central to tumor evolution is the generation of genetic diversity. However, the extent and patterns by which de novo karyotype alterations emerge and propagate within human tumors are not well understood, especially at single-cell resolution. Here, we present 3D Live-Seq—a protocol that integrates live-cell imaging of tumor organoid outgrowth and whole-genome sequencing of each imaged cell to reconstruct evolving tumor cell karyotypes across consecutive cell generations. Using patient-derived colorectal cancer organoids and fresh tumor biopsies, we demonstrate that karyotype alterations of varying complexity are prevalent and can arise within a few cell generations. Sub-chromosomal acentric fragments were prone to replication and collective missegregation across consecutive cell divisions. In contrast, gross genome-wide karyotype alterations were generated in a single erroneous cell division, providing support that aneuploid tumor genomes can evolve via punctuated evolution. Mapping the temporal dynamics and patterns of karyotype diversification in cancer enables reconstructions of evolutionary paths to malignant fitness., Analysis of live-cell imaging and single-cell genome sequencing data of colorectal cancer organoids identifies temporal dynamics of sub-chromosomal copy-number amplifications.

Published

2021

4. Liver Colonization by Colorectal Cancer Metastases Requires YAP-Controlled Plasticity at the Micrometastatic Stage

Author

Maria C. Heinz, Niek A. Peters, Koen C. Oost, Rik G.H. Lindeboom, Lisa van Voorthuijsen, Arianna Fumagalli, Mirjam C. van der Net, Gustavo de Medeiros, Joris H. Hageman, Ingrid Verlaan-Klink, Inne H.M. Borel Rinkes, Prisca Liberali, Martijn Gloerich, Jacco van Rheenen, Michiel Vermeulen, Onno Kranenburg, and Hugo J.G. Snippert

Subjects

Mice, Cancer Research, Oncology, Neoplasm Micrometastasis, Proteomics and Chromatin Biology, Liver Neoplasms, Neoplastic Stem Cells, Animals, Humans, Colorectal Neoplasms, Molecular Biology

Abstract

Micrometastases of colorectal cancer can remain dormant for years prior to the formation of actively growing, clinically detectable lesions (i.e., colonization). A better understanding of this step in the metastatic cascade could help improve metastasis prevention and treatment. Here we analyzed liver specimens of patients with colorectal cancer and monitored real-time metastasis formation in mouse livers using intravital microscopy to reveal that micrometastatic lesions are devoid of cancer stem cells (CSC). However, lesions that grow into overt metastases demonstrated appearance of de novo CSCs through cellular plasticity at a multicellular stage. Clonal outgrowth of patient-derived colorectal cancer organoids phenocopied the cellular and transcriptomic changes observed during in vivo metastasis formation. First, formation of mature CSCs occurred at a multicellular stage and promoted growth. Conversely, failure of immature CSCs to generate more differentiated cells arrested growth, implying that cellular heterogeneity is required for continuous growth. Second, early-stage YAP activity was required for the survival of organoid-forming cells. However, subsequent attenuation of early-stage YAP activity was essential to allow for the formation of cell type heterogeneity, while persistent YAP signaling locked micro-organoids in a cellularly homogenous and growth-stalled state. Analysis of metastasis formation in mouse livers using single-cell RNA sequencing confirmed the transient presence of early-stage YAP activity, followed by emergence of CSC and non-CSC phenotypes, irrespective of the initial phenotype of the metastatic cell of origin. Thus, establishment of cellular heterogeneity after an initial YAP-controlled outgrowth phase marks the transition to continuously growing macrometastases. Significance: Characterization of the cell type dynamics, composition, and transcriptome of early colorectal cancer liver metastases reveals that failure to establish cellular heterogeneity through YAP-controlled epithelial self-organization prohibits the outgrowth of micrometastases. See related commentary by LeBleu, p. 1870

Published

2022

5. Introducing the Stem Cell ASCL2 Reporter STAR into Intestinal Organoids

Author

Hugo J. Snippert, Koen C. Oost, and Maria C. Heinz

Subjects

Transposable element, Biology, Star (graph theory), Genome, General Biochemistry, Genetics and Molecular Biology, Mice, Organoid, Basic Helix-Loop-Helix Transcription Factors, Protocol, Animals, Humans, Intestinal Mucosa, lcsh:Science (General), General Immunology and Microbiology, Staining and Labeling, General Neuroscience, Stem Cells, Intestinal organoids, Phenotype, Cell biology, Intestines, Organoids, Adult Stem Cells, Stem cell, Adult stem cell, lcsh:Q1-390

Abstract

Summary Patient-derived organoids maintain functional and phenotypic characteristics of the original tissue such as cell-type diversity. Here, we provide protocols on how to label intestinal (cancer) stem cells by integrating the stem cell ASCL2 reporter (STAR) into human and mouse genomes via two different strategies: (1) lentiviral transduction or (2) transposon-based integration. Organoid technology, in combination with the user-friendly nature of STAR, will facilitate basic research in human and mouse adult stem cell biology. For complete details on the use and execution of this protocol, please refer to Oost et al. (2018)., Graphical Abstract, Highlights • Choose the optimal STAR plasmid suited for your research • Tips and tricks on how to prepare organoids for STAR integration • Diverse protocols for STAR integration: lentiviral and transposon-based approaches, Patient-derived organoids maintain functional and phenotypic characteristics of the original tissue such as cell-type diversity. Here, we provide protocols on how to label intestinal (cancer) stem cells by integrating the stem cell ASCL2 reporter (STAR) into the human and mouse genome via two different strategies: (1) lentiviral transduction or (2) a transposon-based system. Organoid technology, in combination with the user-friendly nature of STAR, will facilitate basic research in human and mouse adult stem cell biology.

Published

2020

6. High-resolution 3D imaging of fixed and cleared organoids

Author

Johanna F, Dekkers, Maria, Alieva, Lianne M, Wellens, Hendrikus C R, Ariese, Paul R, Jamieson, Annelotte M, Vonk, Gimano D, Amatngalim, Huili, Hu, Koen C, Oost, Hugo J G, Snippert, Jeffrey M, Beekman, Ellen J, Wehrens, Jane E, Visvader, Hans, Clevers, and Anne C, Rios

Subjects

Microscopy, Confocal, Tissue Fixation, Colon, Optical Imaging, Kidney, Immunohistochemistry, Organoids, Mice, Imaging, Three-Dimensional, Liver, Microscopy, Fluorescence, Animals, Humans, Female, Breast

Abstract

In vitro 3D organoid systems have revolutionized the modeling of organ development and diseases in a dish. Fluorescence microscopy has contributed to the characterization of the cellular composition of organoids and demonstrated organoids' phenotypic resemblance to their original tissues. Here, we provide a detailed protocol for performing high-resolution 3D imaging of entire organoids harboring fluorescence reporters and upon immunolabeling. This method is applicable to a wide range of organoids of differing origins and of various sizes and shapes. We have successfully used it on human airway, colon, kidney, liver and breast tumor organoids, as well as on mouse mammary gland organoids. It includes a simple clearing method utilizing a homemade fructose-glycerol clearing agent that captures 3D organoids in full and enables marker quantification on a cell-by-cell basis. Sample preparation has been optimized for 3D imaging by confocal, super-resolution confocal, multiphoton and light-sheet microscopy. From organoid harvest to image analysis, the protocol takes 3 d.

Published

2018

7. A surgical orthotopic organoid transplantation approach in mice to visualize and study colorectal cancer progression

Author

Saskia J.E. Suijkerbuijk, Evelyne Beerling, Hugo J. Snippert, Harry Begthel, Koen C. Oost, Jacco van Rheenen, Jarno Drost, and Arianna Fumagalli

Subjects

CRISPR-Cas9 genome editing, 0301 basic medicine, Mouse, Colorectal cancer, Biochemistry, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Mice, In vivo, Mice, Inbred NOD, Organoid, Medicine, Animals, Humans, Stage (cooking), Cancer models, Gene Editing, Biochemistry, Genetics and Molecular Biology(all), business.industry, Liver Neoplasms, Colonoscopy, medicine.disease, Xenograft Model Antitumor Assays, Epithelium, Colon cancer, Transplantation, Gene Expression Regulation, Neoplastic, Organoids, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Cell Transformation, Neoplastic, Tumor progression, Colonic Neoplasms, Cancer research, CRISPR-Cas Systems, business, Colorectal Neoplasms, Intravital microscopy, Genetics and Molecular Biology(all)

Abstract

Most currently available colorectal cancer (CRC) mouse models are not suitable for studying progression toward the metastatic stage. Recently, establishment of tumor organoid lines, either from murine CRC models or patients, and the possibility of engineering them with genome-editing technologies, have provided a large collection of tumor material faithfully recapitulating phenotypic and genetic heterogeneity of native tumors. To study tumor progression in the natural in vivo environment, we developed an orthotopic approach based on transplantation of CRC organoids into the cecal epithelium. The 20-min procedure is described in detail here and enables growth of transplanted organoids into a single tumor mass within the intestinal tract. Due to long latency, tumor cells are capable of spreading through the blood circulation and forming metastases at distant sites. This method is designed to generate tumors suitable for studying CRC progression, thereby providing the opportunity to visualize tumor cell dynamics in vivo in real time by intravital microscopy.

Published

2018

8. Interplay between metabolic identities in the intestinal crypt supports stem cell function

Author

Nanda M. Verhoeven-Duif, Boudewijn M.T. Burgering, Andrea Sacchetti, Edwin C. A. Stigter, Maaike Meerlo, Mia L. Pras-Raves, Maria J. Rodriguez-Colman, Hugo J. Snippert, Johan Gerrits, Matthias Schewe, Riccardo Fodde, Koen C. Oost, Marten Hornsveld, and Pathology

Subjects

0301 basic medicine, Multidisciplinary, Cellular differentiation, Research Support, Non-U.S. Gov't, Crypt, LGR5, Oxidative phosphorylation, Mitochondrion, Biology, Research Support, digestive system, Cell biology, 03 medical and health sciences, 030104 developmental biology, Cell Self Renewal, Immunology, Journal Article, Stem cell, Non-U.S. Gov't, Homeostasis

Abstract

The small intestinal epithelium self-renews every four or five days. Intestinal stem cells (Lgr5(+) crypt base columnar cells (CBCs)) sustain this renewal and reside between terminally differentiated Paneth cells at the bottom of the intestinal crypt. Whereas the signalling requirements for maintaining stem cell function and crypt homeostasis have been well studied, little is known about how metabolism contributes to epithelial homeostasis. Here we show that freshly isolated Lgr5(+) CBCs and Paneth cells from the mouse small intestine display different metabolic programs. Compared to Paneth cells, Lgr5(+) CBCs display high mitochondrial activity. Inhibition of mitochondrial activity in Lgr5(+) CBCs or inhibition of glycolysis in Paneth cells strongly affects stem cell function, as indicated by impaired organoid formation. In addition, Paneth cells support stem cell function by providing lactate to sustain the enhanced mitochondrial oxidative phosphorylation in the Lgr5(+) CBCs. Mechanistically, we show that oxidative phosphorylation stimulates p38 MAPK activation by mitochondrial reactive oxygen species signalling, thereby establishing the mature crypt phenotype. Together, our results reveal a critical role for the metabolic identity of Lgr5(+) CBCs and Paneth cells in supporting optimal stem cell function, and we identify mitochondria and reactive oxygen species signalling as a driving force of cellular differentiation.

Published

2017