Abhineet R Ram scite author profile

Summary Entosis is a cell death mechanism that is executed through neighbor cell ingestion and killing that occurs in cancer tissues and during development. Here, we identify JNK and p38 stress-activated kinase signaling as an inducer of entosis in cells exposed to ultraviolet (UV) radiation. Cells with high levels of stress signaling are ingested and killed by those with low levels, a result of heterogeneity arising within cell populations over time. In stressed cells, entosis occurs as part of mixed-cell death response with parallel induction of apoptosis and necrosis, and we find that inhibition of one form of cell death leads to increased rates of another. Together, these findings identify stress-activated kinase signaling as a new inducer of entosis and demonstrate cross talk between different forms of cell death that can occur in parallel in response to UV radiation.

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ERK signaling dynamics: Lights, camera, transduction

Ram

Albeck

2022

Developmental Cell

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Human Airway Epithelial Cell Temporal Kinase Signaling Dynamics: Connecting Cellular Metabolism, Inflammation, and Kinase Biology

Decuzzi

Murphy

Ram

et al. 2022

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Systems-level properties of EGFR/Ras/ERK signalling amplify local signals to generate gene expression plasticity

Davies

Gillies

Siebert

et al. 2018

Preprint

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The EGFR/Ras/ERK signalling pathway is a driver of cancer cell proliferation and metastasis in tumours that exhibit high cell-to-cell heterogeneity. While the signalling activity of this pathway is frequently amplified in tumours, it is not understood how the kinetic aspects of its activation in tumours differ from normal cellular signalling. Using live-cell reporters of ERK signalling in the breast cancer progression series HMT-3522, we found that ERK activity in invasive cells is similar in amplitude to isogenic non-malignant cells but is highly dynamic and more disordered, leading to more heterogeneous expression of ERK target genes. Our analysis reveals that this diversification arises from systems-level functions of the pathway, including intracellular amplification of amphiregulin-mediated paracrine signalling and differential kinetic filtering by genes including Fra-1, c-Myc, and Egr1. Our findings establish a mechanism for the generation of non-genetic tumour cell plasticity arising from the specific quantitative properties of a signal transduction pathway.

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Abhineet R Ram

Systems-Level Properties of EGFR-RAS-ERK Signaling Amplify Local Signals to Generate Dynamic Gene Expression Heterogeneity

Entosis is induced by ultraviolet radiation

ERK signaling dynamics: Lights, camera, transduction

Human Airway Epithelial Cell Temporal Kinase Signaling Dynamics: Connecting Cellular Metabolism, Inflammation, and Kinase Biology

Systems-level properties of EGFR/Ras/ERK signalling amplify local signals to generate gene expression plasticity

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