Project description:The awakening of dormant disseminated cancer cells is responsible for the clinical relapses of patients whose primary tumors have been cured months and even years earlier. In the present study, we demonstrate that dormant breast cancer cells lodged in the lungs reside in a highly mesenchymal, non-proliferative phenotypic state. The awakening of these cells does not occur because of a cancer cell-autonomous process. Instead, inflammation and wound-healing of the surrounding tissue microenvironment causes them to shift from a highly mesenchymal to a quasi-mesenchymal phenotypic state in which they acquire stemness and proliferative ability. Once awakened, these cells can stably reside in this quasi-mesenchymal state and maintain their stemness, doing so without ongoing heterotypic signaling from the lung microenvironment. EGFR ligands released by the cells of the injured tissue microenvironment, including notably M2 type macrophages, promote dormant cancer cells to move toward this quasi-mesenchymal state, a transition that is essential for the awakening process. An understanding of the mechanisms of metastatic awakening may lead in the future to treatment strategies designed to prevent such awakening and resulting metastatic relapse.

Project description:The awakening of dormant disseminated cancer cells is responsible for the clinical relapses of patients whose primary tumors have been cured months and even years earlier. In the present study, we demonstrate that dormant breast cancer cells lodged in the lungs reside in a highly mesenchymal, non-proliferative phenotypic state. The awakening of these cells does not occur because of a cancer cell-autonomous process. Instead, inflammation and wound-healing of the surrounding tissue microenvironment causes them to shift from a highly mesenchymal to a quasi-mesenchymal phenotypic state in which they acquire stemness and proliferative ability. Once awakened, these cells can stably reside in this quasi-mesenchymal state and maintain their stemness, doing so without ongoing heterotypic signaling from the lung microenvironment. EGFR ligands released by the cells of the injured tissue microenvironment, including notably M2 type macrophages, promote dormant cancer cells to move toward this quasi-mesenchymal state, a transition that is essential for the awakening process. An understanding of the mechanisms of metastatic awakening may lead in the future to treatment strategies designed to prevent such awakening and resulting metastatic relapse.

Project description:The awakening of dormant disseminated cancer cells appears to be responsible for the clinical relapses of patients whose primary tumors have been successfully cured months and even years earlier. In the present study, we demonstrate that dormant breast cancer cells lodged in the lungs reside in a highly mesenchymal, non-proliferative phenotypic state. The awakening of these cells is not triggered by a cancer cell-autonomous process. Instead, lung inflammation induced by the chemotherapeutic agent bleomycin effectively awakens dormant cancer cells, providing useful models for studying metastatic awakening. Mechanistically, the awakened cells shift from a highly mesenchymal to a quasi-mesenchymal phenotypic state in which they acquire tumorigenicity and proliferative ability. Once awakened, these cells can stably reside in this quasi-mesenchymal state and maintain their tumor-initiating ability, doing so without ongoing heterotypic signaling from the lung microenvironment. EGFR ligands released by the cells of the injured tissue microenvironment, including notably M2 type macrophages, promote dormant cancer cells to move toward this quasi-mesenchymal state, a transition that is critical for the awakening process. An understanding of the mechanisms of metastatic awakening may lead in the future to treatment strategies designed to prevent such awakening and resulting metastatic relapse.

Project description:p63/p73 are master transcriptional regulators of ITGB4-hi cancer stem cells and are required to maintain CSCs in a quasi-mesenchymal state and for metastatic colonization

Project description:p63/p73 are master transcriptional regulators of ITGB4-hi cancer stem cells and are required to maintain CSCs in a quasi-mesenchymal state and for metastatic colonization

Project description:p63/p73 are master transcriptional regulators of ITGB4-hi cancer stem cells and are required to maintain CSCs in a quasi-mesenchymal state and for metastatic colonization

Project description:p63/p73 are master transcriptional regulators of ITGB4-hi cancer stem cells and are required to maintain CSCs in a quasi-mesenchymal state and for metastatic colonization

Project description:p63/p73 are master transcriptional regulators of ITGB4-hi cancer stem cells and are required to maintain CSCs in a quasi-mesenchymal state and for metastatic colonization

Project description:The goal of this study is to compare the trancriptome of proliferative THEP3 cells to their dormant counterpart DHEP3 and an awaken version through DDR1 receptor depletion (shRNA control verus shRNA DDR1) to identify target genes involved in the dormancy state and the awakening process from where metatsiss will arise.

Project description:This model is based on: Computational Modeling of the Crosstalk Between Macrophage Polarization and Tumor Cell Plasticity in the Tumor Microenvironment. Abstract: Tumor microenvironments contain multiple cell types interacting among one another via different signaling pathways. Furthermore, both cancer cells and different immune cells can display phenotypic plasticity in response to these communicating signals, thereby leading to complex spatiotemporal patterns that can impact therapeutic response. Here, we investigate the crosstalk between cancer cells and macrophages in a tumor microenvironment through in silico (computational) co-culture models. In particular, we investigate how macrophages of different polarization (M1 vs. M2) can interact with epithelial-mesenchymal plasticity of cancer cells, and conversely, how cancer cells exhibiting different phenotypes (epithelial vs. mesenchymal) can influence the polarization of macrophages. Based on interactions documented in the literature, an interaction network of cancer cells and macrophages is constructed. The steady states of the network are then analyzed. Various interactions were removed or added into the constructed-network to test the functions of those interactions. Also, parameters in the mathematical models were varied to explore their effects on the steady states of the network. In general, the interactions between cancer cells and macrophages can give rise to multiple stable steady-states for a given set of parameters and each steady state is stable against perturbations. Importantly, we show that the system can often reach one type of stable steady states where cancer cells go extinct. Our results may help inform efficient therapeutic strategies.