LGR5+ epithelial tumor stem-like cells generate a 3D-organoid model for ameloblastoma
Penn collection
Degree type
Discipline
Subject
Animals
Carcinogenesis
Cell Line
Tumor
Cell Proliferation
Cell Self Renewal
Drug Resistance
Neoplasm
Epithelial Cells
Epithelial-Mesenchymal Transition
Male
Mice
Nude
Neoplastic Stem Cells
Organoids
Phenotype
Proto-Oncogene Proteins B-raf
Receptors
G-Protein-Coupled
Spheroids
Cellular
Thrombospondins
vemurafenib
B Raf kinase
BRAF protein
human
G protein coupled receptor
LGR5 protein
human
thrombospondin
ameloblastoma
animal experiment
animal model
Article
cancer stem cell
cell subpopulation
controlled study
epithelial cell line
epithelial mesenchymal transition
epithelium cell
epithelium tumor
female
gene expression
histopathology
human
human cell
human tissue
in vitro study
in vivo study
Lgr5+ stem cell line
male
mouse
nonhuman
organoid
pathogenesis
priority journal
tumor model
tumor recurrence
tumor spheroid
ameloblastoma
animal
cancer stem cell
carcinogenesis
cell proliferation
cell self-renewal
drug resistance
metabolism
multicellular spheroid
nude mouse
pathology
phenotype
tumor cell line
Dentistry
Oral and Maxillofacial Surgery
Oral Biology and Oral Pathology
Funder
Grant number
License
Copyright date
Distributor
Related resources
Author
Contributor
Abstract
Ameloblastoma (AM) is a benign but locally aggressive tumor with high recurrences. Currently, underlying pathophysiology remains elusive, and radical surgery remains the most definitive treatment with severe morbidities. We have recently reported that AM harbors a subpopulation of tumor epithelial stem-like cells (AM-EpiSCs). Herein, we explored whether LGR5+ epithelial cells in AM possess stem-like cell properties and their potential contribution to pathogenesis and recurrence of AM. We found that LGR5 and stem cell-related genes were co-expressed in a subpopulation of AM epithelial cells both in vivo and in vitro, which were enriched under 3D-spheroid culture. As compared to LGR5− counterparts, LGR5+ AM epithelial cells showed increased expression of various EMT- and stemness-related genes, and functionally, exhibited increased capacity to form 3D-spheroids and generate human tumor 3D organoids, which recapitulated the histopathologic features of distinct subtypes of solid AM, thus, contributing a useful human tumor platform for targeted therapeutic screening. Treatment with a selective BRAFV600E inhibitor, vemurafenib, unexpectedly enriched the subpopulation of LGR5+ AM-EpiSCs in tumor 3D organoids, which may have explained therapeutic resistances and recurrences. These findings suggest that LGR5+ AM-EpiSCs play a pivotal role in pathogenesis and progression of AM and targeted inhibition of both BRAF and LGR5 potentially serves a novel nonsurgical adjuvant therapeutic approach for this aggressively benign jaw tumor. © 2020, The Author(s).