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

Project description:The Epithelial-to-Mesenchymal Transition (EMT) is a dynamic cellular program that is frequently used by cancer cells to increase migratory and invasive cell characteristics. It is a key contributor to both heterogeneity and chemo-resistance and metastasis in many solid tumors, including triple negative breast cancer. In particular, the intermediate or hybrid EMT state has increased tumor initiating and stem-like properties. Here, we have identified multiple distinct EMT states derived from the human breast cell line, SUM149PT, including three unique intermediate states, possessing distinct migratory, tumor initiating, and metastatic qualities. We have used this model to interrogate the epigenetic landscape of these distinct EMT states in a multi-omics approach, identifying and RUNX2 as relevant in regulating the intermediate state, as well as to develop a novel multiplexed staining approach to evaluate E-M heterogeneity (EMH) and overall EMT score in orthotopic tumors as well as patient tumor samples. This model reveals insights into the complex EMT spectrum of cell states, the networks that control them, and how EMT plasticity contributes to tumor heterogeneity in breast cancer.

Project description:The Epithelial-to-Mesenchymal Transition (EMT) is a dynamic cellular program that is frequently used by cancer cells to increase migratory and invasive cell characteristics. It is a key contributor to both heterogeneity and chemo-resistance and metastasis in many solid tumors, including triple negative breast cancer. In particular, the intermediate or hybrid EMT state has increased tumor initiating and stem-like properties. Here, we have identified multiple distinct EMT states derived from the human breast cell line, SUM149PT, including three unique intermediate states, possessing distinct migratory, tumor initiating, and metastatic qualities. We have used this model to interrogate the epigenetic landscape of these distinct EMT states in a multi-omics approach, identifying and RUNX2 as relevant in regulating the intermediate state, as well as to develop a novel multiplexed staining approach to evaluate E-M heterogeneity (EMH) and overall EMT score in orthotopic tumors as well as patient tumor samples. This model reveals insights into the complex EMT spectrum of cell states, the networks that control them, and how EMT plasticity contributes to tumor heterogeneity in breast cancer.

Project description:Phenotypic heterogeneity driven by plasticity of the intermediate EMT state governs disease progression and metastasis in breast cancer

Project description:Phenotypic heterogeneity driven by plasticity of the intermediate EMT state governs disease progression and metastasis in breast cancer [RNA-seq]

Project description:Phenotypic heterogeneity driven by plasticity of the intermediate EMT state governs disease progression and metastasis in breast cancer [ATAC-seq]

Project description:Genetic and phenotypic heterogeneity contribute to the generation of diverse tumor cell populations, thus enhancing cancer aggressiveness and therapy resistance. Compared to genetic heterogeneity, a consequence of mutational events, phenotypic heterogeneity arises from dynamic, reversible cell state transitions in response to varying intracellular/extracellular signals. Such phenotypic plasticity enables rapid adaptive responses to various stressful conditions and can have a strong impact on cancer progression. Herein, we have reviewed relevant literature on mechanisms associated with dynamic phenotypic changes and cellular plasticity, such as epithelial-mesenchymal transition (EMT) and cancer stemness, which have been reported to facilitate cancer metastasis. We also discuss how non-cell-autonomous mechanisms such as cell-cell communication can lead to an emergent population-level response in tumors. The molecular mechanisms underlying the complexity of tumor systems are crucial for comprehending cancer progression, and may provide new avenues for designing therapeutic strategies.

Project description:Tumor cells demonstrate substantial plasticity in their genotypic and phenotypic characteristics. Epithelial-mesenchymal plasticity (EMP) can be characterized into dynamic intermediate states and can be orchestrated by many factors, either intercellularly via epigenetic reprograming, or extracellularly via growth factors, inflammation and/or hypoxia generated by the tumor stromal microenvironment. EMP has the capability to alter phenotype and produce heterogeneity, and thus by changing the whole cancer landscape can attenuate oncogenic signaling networks, invoke anti-apoptotic features, defend against chemotherapeutics and reprogram angiogenic and immune recognition functions. We discuss here the role of phenotypic plasticity in tumor initiation, progression and metastasis and provide an update of the modalities utilized for the molecular characterization of the EMT states and attributes of cellular behavior, including cellular metabolism, in the context of EMP. We also summarize recent findings in dynamic EMP studies that provide new insights into the phenotypic plasticity of EMP flux in cancer and propose therapeutic strategies to impede the metastatic outgrowth of phenotypically heterogeneous tumors.

Project description:Phenotype switching is a form of cellular plasticity in which cancer cells reversibly move between two opposite extremes - proliferative versus invasive states. While it has long been hypothesised that such switching is triggered by external cues, the identity of these cues has remained elusive. Here, we demonstrate that mechanical confinement mediates phenotype switching through chromatin remodelling. Using a zebrafish model of melanoma coupled with human samples, we profiled tumor cells at the interface between the tumor and surrounding microenvironment. Morphological analysis of interface cells showed elliptical nuclei suggestive of mechanical confinement by adjacent tissue. Spatial and single-cell transcriptomics demonstrated that the interface cells adopted a gene program of neuronal invasion, including acquisition of an acetylated tubulin cage that protects the nucleus during migration. We identified the DNA-bending protein HMGB2 as a confinement-induced mediator of the neuronal state. HMGB2 is upregulated in confined cells, and quantitative modelling revealed that confinement prolongs contact time between HMGB2 and chromatin, leading to changes in chromatin configuration that favor the neuronal phenotype. Genetic disruption of HMGB2 showed that it regulates the trade-off between proliferative and invasive states, in which confined HMGB2high tumor cells are less proliferative but more drug resistant. Our results implicate the mechanical microenvironment as a mechanism driving phenotype switching in melanoma.

Project description:Triple negative breast cancer (TNBC) is the most lethal breast cancer subgroup, as lack of targeted therapies and drug resistance reduce survival rates. Cellular plasticity enables cells to adapt non-genetically and overcome therapeutic pressure, thereby embodying a critical clinical hurdle. The epithelial-mesenchymal transition (EMT) is an example of phenotypic reprogramming linked to plasticity, drug resistance and metastasis. However, its exact impact on population diversity under therapeutic pressure is unknown. Here, we used single cell transcriptomics to investigate phenotypic diversity dynamics upon drug treatment in two human in vitro models of TNBC plasticity.