Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Cell state (phenotypic) plasticity is a carefully regulated feature of adult epithelial cells that enables adaptive responses to injury, inflammation, and other forms of stress.Aberrant expansion of the normally restricted capability for cell state plasticity to escape terminal differentiation is a critical aspect of neoplasia. The nongenetic factors and specific programs that mediate aberrant cell state plasticity and impaired differentiationrequire deeper characterization to understand this elusive aspect ofcancer pathogenesis. Using genetically engineered andcarcinogen-induced murine models of intestinal neoplasia, wedemonstrate that impaired differentiation is a conserved eventpreceding cancer development. Single cell RNA-sequencing (scRNA-seq)of neoplastic intestinal lesions from both mouse models and a patientwith familial adenomatous polyposis revealed that cancer initiates byadopting an aberrant transcriptional state characterized bynonoverlapping expression of a regenerative pathway, marked by Ly6a(Sca-1), and a fetal intestinal program, positive for Tacstd2 (Trop2).Genetic inactivation of Sox9 prevented adenoma formation in ApcKOmice, obstructed emergence of aberrant regenerative and fetalintestinal programs, and restored multi-lineage differentiation byscRNA-seq. Expanded chromatin accessibility at regeneration and fetalgenes upon Apc inactivation was reduced by concomitant Sox9suppression. These studies indicate that aberrant cell stateplasticity mediated by unabated regenerative activity anddevelopmental reprogramming precedes cancer development.

Project description:Cell state plasticity is carefully regulated in adult epithelia, enabling adaptive responses to stressors. The nongenetic factors that control aberrant expansion of the normally restricted capability for cell state plasticity to escape terminal differentiation in neoplasia require deeper characterization. Using genetically-engineered and carcinogen-induced murine models of intestinal neoplasia, we demonstrate that impaired differentiation is a conserved event preceding cancer development. Single cell RNA-sequencing (scRNA-seq) of intestinal neoplasia from both mouse models and a patient with hereditary polyposis revealed that cancer initiates by adopting an aberrant transcriptional state characterized by regenerative activity, marked by Ly6a (Sca-1), and reactivation of fetal intestinal genes, including Tacstd2 (Trop2). Genetic inactivation of Sox9 prevented adenoma formation, obstructed emergence of regenerative and fetal programs, and restored multi-lineage differentiation by scRNA-seq. Expanded chromatin accessibility at regeneration and fetal genes upon Apc inactivation was reduced by concomitant Sox9 suppression. These studies indicate that aberrant cell state plasticity mediated by unabated regenerative activity and developmental reprogramming precedes cancer development.

Project description:Cell state (phenotypic) plasticity is a carefully regulated feature of adult epithelial cells that enables adaptive responses to injury, inflammation, and other forms of stress.Aberrant expansion of the normally restricted capability for cell state plasticity to escape terminal differentiation is a critical aspect of neoplasia. The nongenetic factors and specific programs that mediate aberrant cell state plasticity and impaired differentiationrequire deeper characterization to understand this elusive aspect ofcancer pathogenesis. Using genetically engineered andcarcinogen-induced murine models of intestinal neoplasia, wedemonstrate that impaired differentiation is a conserved eventpreceding cancer development. Single cell RNA-sequencing (scRNA-seq)of neoplastic intestinal lesions from both mouse models and a patientwith familial adenomatous polyposis revealed that cancer initiates byadopting an aberrant transcriptional state characterized bynonoverlapping expression of a regenerative pathway, marked by Ly6a(Sca-1), and a fetal intestinal program, positive for Tacstd2 (Trop2).Genetic inactivation of Sox9 prevented adenoma formation in ApcKOmice, obstructed emergence of aberrant regenerative and fetalintestinal programs, and restored multi-lineage differentiation byscRNA-seq. Expanded chromatin accessibility at regeneration and fetalgenes upon Apc inactivation was reduced by concomitant Sox9suppression. These studies indicate that aberrant cell stateplasticity mediated by unabated regenerative activity anddevelopmental reprogramming precedes cancer development.

Project description:Aberrant cell state plasticity mediated by developmental reprogramming precedes colorectal cancer initiation

Project description:Aberrant cell state plasticity mediated by developmental reprogramming precedes colorectal cancer initiation [scRNA-seq]

Project description:Aberrant cell state plasticity mediated by developmental reprogramming precedes colorectal cancer initiation [ATAC-seq]

Project description:Aberrant cell state plasticity mediated by developmental reprogramming precedes cancer initiation [CUT&RUN]

Project description:The field cancerization theory suggests that a group of cells containing oncogenic mutations are predisposed to transformation1, 2. We previously identified single cells in BRAF V600E ;p53 -/- zebrafish that reactivate an embryonic neural crest state before initiating melanoma3-5. Here we show that single cells reactivate the neural crest fate from within large fields of adjacent abnormal melanocytes, which we term the "cancer precursor zone." These cancer precursor zone melanocytes have an aberrant morphology, dysplastic nuclei, and altered gene expression. Using single cell RNA-seq and ATAC-seq, we defined a distinct transcriptional cell attractor state for cancer precursor zones and validated the stage-specific gene expression initiation signatures in human melanoma. We identify the cancer precursor zone driver, ID1, which binds to TCF12 and inhibits downstream targets important for the maintenance of melanocyte morphology and cell cycle control. Examination of patient samples revealed precursor melanocytes expressing ID1, often surrounding invasive melanoma, indicating a role for ID1 in early melanomagenesis. This work reveals a surprising field effect of melanoma initiation in vivo in which tumors arise from within a zone of morphologically distinct, but clinically covert, precursors with altered transcriptional fate. Our studies identify novel targets that could improve early diagnosis and prevention of melanoma.

Project description:Two fundamental elements of pre-implantation embryogenesis are cells' intrinsic self-organization program and their developmental plasticity, which allows embryos to compensate for alterations in cell position and number; yet, these elements are still poorly understood. To be able to decipher these features, we established culture conditions that enable the two fates of blastocysts' extraembryonic lineages-the primitive endoderm and the trophectoderm-to coexist. This plasticity emerges following the mechanisms of the first lineage segregation in the mouse embryo, and it manifests as an extended potential for extraembryonic chimerism during the pre-implantation embryogenesis. Moreover, this shared state enables robust assembly into higher-order blastocyst-like structures, thus combining both the cell fate plasticity and self-organization features of the early extraembryonic lineages.