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

Project description:Small cell carcinomas from different tissues exhibit transcriptional and epigenetic convergence and suggest common vulnerabilities for therapies

Project description:Small cell carcinomas from different tissues exhibit transcriptional and epigenetic convergence and suggest common vulnerabilities for therapies

Project description:Small cell carcinomas from different tissues exhibit transcriptional and epigenetic convergence and suggest common vulnerabilities for therapies

Project description:Reprogramming normal human epithelial tissues to a common, lethal neuroendocrine cancer lineage (ATAC-seq)

Project description:PARCB Project: Reprogramming normal human epithelial tissues to a common, lethal neuroendocrine cancer lineage

Project description:Reprogramming normal human epithelial tissues to a common, lethal neuroendocrine cancer lineage (RNA-seq)

Project description:Reprogramming normal human epithelial tissues to a common, lethal neuroendocrine cancer lineage (Whole Exome-seq)

Project description:Recently, organoid technology has been used to generate a large repository of breast cancer organoids. Here we present an extensive evaluation of the ability of organoid culture technology to preserve complex stem/progenitor and differentiated cell types via long-term propagation of normal human mammary tissues. Basal/stem and luminal progenitor cells can differentiate in culture to generate mature basal and luminal cell types, including ER+?cells that have been challenging to maintain in culture. Cells associated with increased cancer risk can also be propagated. Single-cell analyses of matched organoid cultures and native tissues by mass cytometry for 38 markers provide a higher resolution representation of the multiple mammary epithelial cell types in the organoids, and demonstrate that protein expression patterns of the tissue of origin can be preserved in culture. These studies indicate that organoid cultures provide a valuable platform for studies of mammary differentiation, transformation, and breast cancer risk.

Project description:Organogenesis and tissue development occur through sequential stepwise processes leading to increased lineage restriction and loss of pluripotency. An exception to this appears in the adult human breast, where rare variant epithelial cells exhibit pluripotency and multilineage differentiation potential when removed from the signals of their native microenvironment. This phenomenon provides a unique opportunity to study mechanisms that lead to cellular reprogramming and lineage plasticity in real time. Here, we show that primary human mammary epithelial cells (HMECs) lose expression of differentiated mammary epithelial markers in a manner dependent on paracrine factors and epigenetic regulation. Furthermore, we demonstrate that HMEC reprogramming is dependent on gene silencing by the DNA methyltransferase DNMT3A and loss of histone transcriptional marks following downregulation of the methyltransferase DOT1L. These results demonstrate that lineage commitment in adult tissues is context dependent and highlight the plasticity of somatic cells when removed from their native tissue microenvironment.