Your search keyword '"Custers, L"' showing total 9 results

1. Familiebedrijven in Nederland 2015-2018

Author

Custers, L., Vrolijk, M., Custers, L., and Vrolijk, M.

Published

2020

2. CUEDC1 is a primary target of ER alpha essential for the growth of breast cancer cells

Author

Lopes, R (Rui Filipe Marques), Korkmaz, G, Revilla, SA, Vliet, R, van der Nagel, R, Custers, L, Kim, Y, van Breugel, P C, Zwart, W, Moumbeini, B, Manber, Z, Elkon, R, Agami, Reuven, Lopes, R (Rui Filipe Marques), Korkmaz, G, Revilla, SA, Vliet, R, van der Nagel, R, Custers, L, Kim, Y, van Breugel, P C, Zwart, W, Moumbeini, B, Manber, Z, Elkon, R, and Agami, Reuven

Published

2018

3. SMARCB1 loss activates patient-specific distal oncogenic enhancers in malignant rhabdoid tumors.

Author

Liu NQ, Paassen I, Custers L, Zeller P, Teunissen H, Ayyildiz D, He J, Buhl JL, Hoving EW, van Oudenaarden A, de Wit E, and Drost J

Subjects

Humans, Child, SMARCB1 Protein genetics, Transcription Factors genetics, Mutation, Promoter Regions, Genetic genetics, Carcinogenesis genetics, Rhabdoid Tumor genetics, Rhabdoid Tumor pathology

Abstract

Malignant rhabdoid tumor (MRT) is a highly malignant and often lethal childhood cancer. MRTs are genetically defined by bi-allelic inactivating mutations in SMARCB1, a member of the BRG1/BRM-associated factors (BAF) chromatin remodeling complex. Mutations in BAF complex members are common in human cancer, yet their contribution to tumorigenesis remains in many cases poorly understood. Here, we study derailed regulatory landscapes as a consequence of SMARCB1 loss in the context of MRT. Our multi-omics approach on patient-derived MRT organoids reveals a dramatic reshaping of the regulatory landscape upon SMARCB1 reconstitution. Chromosome conformation capture experiments subsequently reveal patient-specific looping of distal enhancer regions with the promoter of the MYC oncogene. This intertumoral heterogeneity in MYC enhancer utilization is also present in patient MRT tissues as shown by combined single-cell RNA-seq and ATAC-seq. We show that loss of SMARCB1 activates patient-specific epigenetic reprogramming underlying MRT tumorigenesis., (© 2023. The Author(s).)

Published

2023

4. Neuroblastoma and DIPG Organoid Coculture System for Personalized Assessment of Novel Anticancer Immunotherapies.

Author

M Kholosy W, Derieppe M, van den Ham F, Ober K, Su Y, Custers L, Schild L, M J van Zogchel L, M Wellens L, R Ariese H, Szanto CL, Wienke J, Dierselhuis MP, van Vuurden D, Dolman EM, and Molenaar JJ

Abstract

Cancer immunotherapy has transformed the landscape of adult cancer treatment and holds a great promise to treat paediatric malignancies. However, in vitro test coculture systems to evaluate the efficacy of immunotherapies on representative paediatric tumour models are lacking. Here, we describe a detailed procedure for the establishment of an ex vivo test coculture system of paediatric tumour organoids and immune cells that enables assessment of different immunotherapy approaches in paediatric tumour organoids. We provide a step-by-step protocol for an efficient generation of patient-derived diffuse intrinsic pontine glioma (DIPG) and neuroblastoma organoids stably expressing eGFP-ffLuc transgenes using defined serum-free medium. In contrast to the chromium-release assay, the new platform allows for visualization, monitoring and robust quantification of tumour organoid cell cytotoxicity using a non-radioactive assay in real-time. To evaluate the utility of this system for drug testing in the paediatric immuno-oncology field, we tested our in vitro assay using a clinically used immunotherapy strategy for children with high-risk neuroblastoma, dinutuximab (anti-GD2 monoclonal antibody), on GD2 proficient and deficient patient-derived neuroblastoma organoids. We demonstrated the feasibility and sensitivity of our ex vivo coculture system using human immune cells and paediatric tumour organoids as ex vivo tumour models. Our study provides a novel platform for personalized testing of potential anticancer immunotherapies for aggressive paediatric cancers such as neuroblastoma and DIPG.

Published

2021

5. Single cell derived mRNA signals across human kidney tumors.

Author

Young MD, Mitchell TJ, Custers L, Margaritis T, Morales-Rodriguez F, Kwakwa K, Khabirova E, Kildisiute G, Oliver TRW, de Krijger RR, van den Heuvel-Eibrink MM, Comitani F, Piapi A, Bugallo-Blanco E, Thevanesan C, Burke C, Prigmore E, Ambridge K, Roberts K, Braga FAV, Coorens THH, Del Valle I, Wilbrey-Clark A, Mamanova L, Stewart GD, Gnanapragasam VJ, Rampling D, Sebire N, Coleman N, Hook L, Warren A, Haniffa M, Kool M, Pfister SM, Achermann JC, He X, Barker RA, Shlien A, Bayraktar OA, Teichmann SA, Holstege FC, Meyer KB, Drost J, Straathof K, and Behjati S

Subjects

Adult, Algorithms, Child, Fetus metabolism, Gene Expression Regulation, Developmental, Humans, Kidney embryology, Kidney Neoplasms embryology, Kidney Neoplasms metabolism, Models, Genetic, Signal Transduction genetics, Kidney metabolism, Kidney Neoplasms genetics, RNA, Messenger genetics, RNA-Seq methods, Single-Cell Analysis methods, Transcriptome

Abstract

Tumor cells may share some patterns of gene expression with their cell of origin, providing clues into the differentiation state and origin of cancer. Here, we study the differentiation state and cellular origin of 1300 childhood and adult kidney tumors. Using single cell mRNA reference maps of normal tissues, we quantify reference "cellular signals" in each tumor. Quantifying global differentiation, we find that childhood tumors exhibit fetal cellular signals, replacing the presumption of "fetalness" with a quantitative measure of immaturity. By contrast, in adult cancers our assessment refutes the suggestion of dedifferentiation towards a fetal state in most cases. We find an intimate connection between developmental mesenchymal populations and childhood renal tumors. We demonstrate the diagnostic potential of our approach with a case study of a cryptic renal tumor. Our findings provide a cellular definition of human renal tumors through an approach that is broadly applicable to human cancer.

Published

2021

6. Somatic mutations and single-cell transcriptomes reveal the root of malignant rhabdoid tumours.

Author

Custers L, Khabirova E, Coorens THH, Oliver TRW, Calandrini C, Young MD, Vieira Braga FA, Ellis P, Mamanova L, Segers H, Maat A, Kool M, Hoving EW, van den Heuvel-Eibrink MM, Nicholson J, Straathof K, Hook L, de Krijger RR, Trayers C, Allinson K, Behjati S, and Drost J

Subjects

Cell Differentiation genetics, DNA Methylation, Drug Screening Assays, Antitumor, Gene Expression Profiling, Gene Expression Regulation, Neoplastic drug effects, Histone Deacetylase Inhibitors pharmacology, Humans, Neural Crest pathology, Phylogeny, Rhabdoid Tumor drug therapy, SMARCB1 Protein genetics, Single-Cell Analysis, TOR Serine-Threonine Kinases antagonists & inhibitors, Tissue Culture Techniques methods, Mutation, Rhabdoid Tumor genetics, Rhabdoid Tumor pathology

Abstract

Malignant rhabdoid tumour (MRT) is an often lethal childhood cancer that, like many paediatric tumours, is thought to arise from aberrant fetal development. The embryonic root and differentiation pathways underpinning MRT are not firmly established. Here, we study the origin of MRT by combining phylogenetic analyses and single-cell mRNA studies in patient-derived organoids. Comparison of somatic mutations shared between cancer and surrounding normal tissues places MRT in a lineage with neural crest-derived Schwann cells. Single-cell mRNA readouts of MRT differentiation, which we examine by reverting the genetic driver mutation underpinning MRT, SMARCB1 loss, suggest that cells are blocked en route to differentiating into mesenchyme. Quantitative transcriptional predictions indicate that combined HDAC and mTOR inhibition mimic MRT differentiation, which we confirm experimentally. Our study defines the developmental block of MRT and reveals potential differentiation therapies.

Published

2021

7. In vitro Modeling of Embryonal Tumors.

Author

Custers L, Paassen I, and Drost J

Abstract

A subset of pediatric tumors affects very young children and are thought to arise during fetal life. A common theme is that these embryonal tumors hijack developmental programs, causing a block in differentiation and, as a consequence, unrestricted proliferation. Embryonal tumors, therefore typically maintain an embryonic gene signature not found in their differentiated progeny. Still, the processes underpinning malignant transformation remain largely unknown, which is hampering therapeutic innovation. To gain more insight into these processes, in vitro and in vivo research models are indispensable. However, embryonic development is an extremely dynamic process with continuously changing cellular identities, making it challenging to define cells-of-origin. This is crucial for the development of representative models, as targeting the wrong cell or targeting a cell within an incorrect developmental time window can result in completely different phenotypes. Recent innovations in in vitro cell models may provide more versatile platforms to study embryonal tumors in a scalable manner. In this review, we outline different in vitro models that can be explored to study embryonal tumorigenesis and for therapy development., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Custers, Paassen and Drost.)

Published

2021

8. An organoid biobank for childhood kidney cancers that captures disease and tissue heterogeneity.

Author

Calandrini C, Schutgens F, Oka R, Margaritis T, Candelli T, Mathijsen L, Ammerlaan C, van Ineveld RL, Derakhshan S, de Haan S, Dolman E, Lijnzaad P, Custers L, Begthel H, Kerstens HHD, Visser LL, Rookmaaker M, Verhaar M, Tytgat GAM, Kemmeren P, de Krijger RR, Al-Saadi R, Pritchard-Jones K, Kool M, Rios AC, van den Heuvel-Eibrink MM, Molenaar JJ, van Boxtel R, Holstege FCP, Clevers H, and Drost J

Subjects

Adolescent, Carcinoma, Renal Cell drug therapy, Carcinoma, Renal Cell genetics, Carcinoma, Renal Cell pathology, Cell Culture Techniques methods, Child, Child, Preschool, DNA Methylation, Drug Screening Assays, Antitumor methods, Female, Gene Expression Regulation, Neoplastic, Genetic Heterogeneity, Genotyping Techniques, Humans, Infant, Kidney Neoplasms drug therapy, Kidney Neoplasms pathology, Male, Nephroma, Mesoblastic drug therapy, Nephroma, Mesoblastic genetics, Nephroma, Mesoblastic pathology, Netherlands, Precision Medicine methods, RNA-Seq, Rhabdoid Tumor drug therapy, Rhabdoid Tumor genetics, Rhabdoid Tumor pathology, Single-Cell Analysis, Transfection, Tumor Cells, Cultured, Whole Genome Sequencing, Wilms Tumor drug therapy, Wilms Tumor genetics, Wilms Tumor pathology, Young Adult, Biological Specimen Banks, Kidney pathology, Kidney Neoplasms genetics, Organoids pathology

Abstract

Kidney tumours are among the most common solid tumours in children, comprising distinct subtypes differing in many aspects, including cell-of-origin, genetics, and pathology. Pre-clinical cell models capturing the disease heterogeneity are currently lacking. Here, we describe the first paediatric cancer organoid biobank. It contains tumour and matching normal kidney organoids from over 50 children with different subtypes of kidney cancer, including Wilms tumours, malignant rhabdoid tumours, renal cell carcinomas, and congenital mesoblastic nephromas. Paediatric kidney tumour organoids retain key properties of native tumours, useful for revealing patient-specific drug sensitivities. Using single cell RNA-sequencing and high resolution 3D imaging, we further demonstrate that organoid cultures derived from Wilms tumours consist of multiple different cell types, including epithelial, stromal and blastemal-like cells. Our organoid biobank captures the heterogeneity of paediatric kidney tumours, providing a representative collection of well-characterised models for basic cancer research, drug-screening and personalised medicine.

Published

2020

9. CUEDC1 is a primary target of ERα essential for the growth of breast cancer cells.

Author

Lopes R, Korkmaz G, Revilla SA, van Vliet R, Nagel R, Custers L, Kim Y, van Breugel PC, Zwart W, Moumbeini B, Manber Z, Elkon R, and Agami R

Subjects

Breast Neoplasms metabolism, Breast Neoplasms pathology, CRISPR-Cas Systems, Cell Line, Tumor, Enhancer Elements, Genetic genetics, Estrogen Receptor alpha metabolism, Female, HEK293 Cells, Humans, Intracellular Signaling Peptides and Proteins metabolism, MCF-7 Cells, Breast Neoplasms genetics, Cell Proliferation genetics, Estrogen Receptor alpha genetics, Gene Expression Regulation, Neoplastic, Intracellular Signaling Peptides and Proteins genetics

Abstract

Breast cancer is the most prevalent type of malignancy in women with ∼1.7 million new cases diagnosed annually, of which the majority express ERα (ESR1), a ligand-dependent transcription factor. Genome-wide chromatin binding maps suggest that ERα may control the expression of thousands of genes, posing a great challenge in identifying functional targets. Recently, we developed a CRISPR-Cas9 functional genetic screening approach to identify enhancers required for ERα-positive breast cancer cell proliferation. We validated several candidates, including CUTE, a putative ERα-responsive enhancer located in the first intron of CUEDC1 (CUE-domain containing protein). Here, we show that CUTE controls CUEDC1 expression, and that this interaction is essential for ERα-mediated cell proliferation. Moreover, ectopic expression of CUEDC1, but not a CUE-domain mutant, rescues the defects in CUTE activity. Finally, CUEDC1 expression correlates positively with ERα in breast cancer. Thus, CUEDC1 is a functional target gene of ERα and is required for breast cancer cell proliferation., (Copyright © 2018 The Netherlands cancer Institute. Published by Elsevier B.V. All rights reserved.)

Published

2018