Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Prostate epithelium develops from multipotent stem cells (SCs) which are replaced in adult life by different lineage-restricted basal and luminal unipotent SCs that sustain the homeostasis in a regionalized manner. Deletion of Pten re-induces multipotency in basal cells (BC). However, the molecular mechanisms regulating cell plasticity and tumor initiation are poorly understood. Here, we showed that Pten deletion in BCs led to distinct cell fate reprograming and tumor initiation in a regionalized manner. In anterior and dorsal prostates, BCs were reprogrammed into a Hillock like state that progressed into a basal-luminal hybrid state, which further transitioned into a proximal-like luminal state before progressing to tumorigenesis. In the ventral prostate, BC expressing Nkx3.1 gave rise to distal-like luminal state that are less plastic and progress more slowly to tumorigenesis. Single-cell sequencing and ATAC-seq analysis showed that the reprograming into hillock and proximal states induced activation of the innate immunity pathway during the cellular reprograming and tumor formation. Targeting Il-1, JAK/STAT and Nfkb inhibits Pten-induced cell plasticity and oncogenic reprograming, opening new opportunities in the prevention and treatment of prostate cancer.

Project description:Inhibiting the androgen receptor (AR) is effective for advanced prostate cancers because of their AR-dependent luminal epithelial cell identity. Tumors progress during therapy to castration resistant prostate cancer (CRPC) by restoring AR signaling and maintaining luminal identity or by converting through lineage plasticity to a neuroendocrine identity (NEPC) or double negative CRPC lacking luminal and neuroendocrine identity (DNPC). Here, we show that DNPC cells express genes defining basal, club, and hillock epithelial cells from benign prostate. We identified KLF5 as a regulator of DNPC growth and expression of genes defining this mixed basal, club, and hillock cell identity. KLF5-mediated upregulation of RARG exposed a DNPC growth sensitivity to retinoic acid receptor agonists, which down-regulated KLF5 and up-regulated AR. These findings offer new CRPC classifications based on prostate epithelial cell identities, and nominate KLF5 and RARG as therapeutic targets for CRPC displaying a mixed basal, club, and hillock identity.

Project description:We used RNA-seq to compare the expression profiles of mouse prostate tumors originated from epithelial basal cells to those originated from luminal cells. We next generated expression signatures for both basal and luminal origin tumors by comparison of tumor samples to their respective controls. By comparing luminal to basal signatures we identified a prognostic molecular signature for prostate cancer patient survival. Pten was deleted in prostate basal or luminal cells to induce tumor formation and tumor expression profiles were analyzed by RNA-seq.

Project description:Glandular epithelia, including mammary gland (MG) and prostate, are composed of luminal and basal cells. During embryonic development, glandular epithelia arise from multipotent stem cells (SCs) giving rise to basal and luminal cells. However, these multipotent SCs are replaced after birth by unipotent basal and unipotent luminal SCs. Different conditions, such as basal cell transplantation, luminal cell ablation, and oncogene expression, can reinduce multipotency in adult basal SC (BaSCs) of different glandular epithelia. The mechanisms regulating the reactivation of multipotency in BaSCs are incompletely understood. Here, we compared the transcriptional signature of BaSCs from MG and prostate in different conditions associated with multipotency in adult mice and uncovered that Collagen I expression was commonly upregulated across the different conditions associated with multipotency. Using MG and prostate organoids, we demonstrated that increasing collagen concentration or stiffness of the extracellular matrix (ECM) promote BaSC multipotency. Single cell RNA-seq of MG organoids in the presence of high concentration of Collagen I or in a stiffer ECM activate a hybrid bipotent state and uncovered a gene signature and signaling pathways associated with bipotent BaSCs. Finally, we demonstrated the importance of 1integrin/FAK/AP-1 axis in the regulation of BaSC multipotency in response to Col1 signaling and ECM stiffness. Altogether our study uncovers the key role of Collagen signaling and ECM stiffness in the regulation of multipotency in glandular epithelia.

Project description:Glandular epithelia, including mammary gland (MG) and prostate, are composed of luminal and basal cells. During embryonic development, glandular epithelia arise from multipotent stem cells (SCs) giving rise to basal and luminal cells. However, these multipotent SCs are replaced after birth by unipotent basal and unipotent luminal SCs. Different conditions, such as basal cell transplantation, luminal cell ablation, and oncogene expression, can reinduce multipotency in adult basal SC (BaSCs) of different glandular epithelia. The mechanisms regulating the reactivation of multipotency in BaSCs are incompletely understood. Here, we compared the transcriptional signature of BaSCs from MG and prostate in different conditions associated with multipotency in adult mice and uncovered that Collagen I expression was commonly upregulated across the different conditions associated with multipotency. Using MG and prostate organoids, we demonstrated that increasing collagen concentration or stiffness of the extracellular matrix (ECM) promote BaSC multipotency. Single cell RNA-seq of MG organoids in the presence of high concentration of Collagen I or in a stiffer ECM activate a hybrid bipotent state and uncovered a gene signature and signaling pathways associated with bipotent BaSCs. Finally, we demonstrated the importance of 1integrin/FAK/AP-1 axis in the regulation of BaSC multipotency in response to Col1 signaling and ECM stiffness. Altogether our study uncovers the key role of Collagen signaling and ECM stiffness in the regulation of multipotency in glandular epithelia.