Summary
The immune system uses both short- and long-range communication mechanisms to mount the coordinated and sophisticated cellular responses required to control microbial infections or fight tumors. Yet, our understanding of how immunological signals are integrated and propagated by individual cells in complex tissue microenvironments remains largely limited.
ENLIGHTEN is a research program dedicated to establish new mechanisms by which the immune system fight tumors or infections, based on the direct manipulation of immunological signals in vivo. In relevant mouse models of human disease, we will combine intravital imaging, fluorescent sensors and optogenetic actuators to control single cell functions in real-time. We wish to understand how T cells sense and interpret cell-contacts in lymphoid organs and in developing tumors at steady state or during immunotherapy. In addition, we aim to establish how cytokine and chemokine gradients form in tissues and are interpreted by immune cells during infection or cancer.
By determining the functional contribution of single immune cells in vivo, we aim to identify new paradigms for information transfer in the immune system during cancer or infection and to establish the combination of optogenetics and intravital imaging as a powerful strategy for decoding immune reactions in the context of disease pathogenesis.
ENLIGHTEN is a research program dedicated to establish new mechanisms by which the immune system fight tumors or infections, based on the direct manipulation of immunological signals in vivo. In relevant mouse models of human disease, we will combine intravital imaging, fluorescent sensors and optogenetic actuators to control single cell functions in real-time. We wish to understand how T cells sense and interpret cell-contacts in lymphoid organs and in developing tumors at steady state or during immunotherapy. In addition, we aim to establish how cytokine and chemokine gradients form in tissues and are interpreted by immune cells during infection or cancer.
By determining the functional contribution of single immune cells in vivo, we aim to identify new paradigms for information transfer in the immune system during cancer or infection and to establish the combination of optogenetics and intravital imaging as a powerful strategy for decoding immune reactions in the context of disease pathogenesis.
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/741167 |
Start date: | 01-01-2018 |
End date: | 31-12-2023 |
Total budget - Public funding: | 2 499 994,00 Euro - 2 499 994,00 Euro |
Cordis data
Original description
The immune system uses both short- and long-range communication mechanisms to mount the coordinated and sophisticated cellular responses required to control microbial infections or fight tumors. Yet, our understanding of how immunological signals are integrated and propagated by individual cells in complex tissue microenvironments remains largely limited.ENLIGHTEN is a research program dedicated to establish new mechanisms by which the immune system fight tumors or infections, based on the direct manipulation of immunological signals in vivo. In relevant mouse models of human disease, we will combine intravital imaging, fluorescent sensors and optogenetic actuators to control single cell functions in real-time. We wish to understand how T cells sense and interpret cell-contacts in lymphoid organs and in developing tumors at steady state or during immunotherapy. In addition, we aim to establish how cytokine and chemokine gradients form in tissues and are interpreted by immune cells during infection or cancer.
By determining the functional contribution of single immune cells in vivo, we aim to identify new paradigms for information transfer in the immune system during cancer or infection and to establish the combination of optogenetics and intravital imaging as a powerful strategy for decoding immune reactions in the context of disease pathogenesis.
Status
SIGNEDCall topic
ERC-2016-ADGUpdate Date
27-04-2024
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