Summary
Immunotherapies targeting immune regulators are revolutionizing cancer treatment, most prominently in melanoma, but only for a subset of patients. While it is known that the immune tumor microenvironment (iTME) plays a vital role in this process, there is limited understanding on how distinct tumor, immune and stroma cells interact as a system to collectively define progression and response to treatment, and there is no biomarker to predict patient response. Tumors are spatially organized ecosystems that are comprised of distinct cell types, each of which can assume a variety of phenotypes defined by coexpression of multiple proteins. To underscore this complexity, and move beyond single cells to multicellular interactions, it is essential to interrogate cellular expression patterns within their native context in the tissue.
We have recently pioneered MIBI-TOF (Multiplexed Ion Beam Imaging by Time of Flight), a novel platform that enables simultaneous imaging of forty proteins within intact tissue sections at subcellular resolution. We propose to (1) Use MIBI-TOF to chart the iTME in dozens of clinical samples from melanoma patients and delineate its function in response to different immunotherapies. (2) Profile murine melanoma tumors to elucidate genetic and temporal mechanisms that drive iTME organization in vivo. (3) Develop new experimental tools for tracing and barcoding thousands of cells to decouple the effects of tumor genetics and the immune microenvironment on tumor organization and clonal dynamics. (4) Develop machine-learning-based algorithms to analyze this novel data and facilitate accessibility of the scientific community to high-dimensional imaging to study human malignancies.
This proposal applies state-of-the-art imaging technology and computation to unravel design principles of the iTME in melanoma, with a grand goal to reveal basic principles in tumor immunology and improve treatment and diagnostics.
We have recently pioneered MIBI-TOF (Multiplexed Ion Beam Imaging by Time of Flight), a novel platform that enables simultaneous imaging of forty proteins within intact tissue sections at subcellular resolution. We propose to (1) Use MIBI-TOF to chart the iTME in dozens of clinical samples from melanoma patients and delineate its function in response to different immunotherapies. (2) Profile murine melanoma tumors to elucidate genetic and temporal mechanisms that drive iTME organization in vivo. (3) Develop new experimental tools for tracing and barcoding thousands of cells to decouple the effects of tumor genetics and the immune microenvironment on tumor organization and clonal dynamics. (4) Develop machine-learning-based algorithms to analyze this novel data and facilitate accessibility of the scientific community to high-dimensional imaging to study human malignancies.
This proposal applies state-of-the-art imaging technology and computation to unravel design principles of the iTME in melanoma, with a grand goal to reveal basic principles in tumor immunology and improve treatment and diagnostics.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/948811 |
| Start date: | 01-01-2021 |
| End date: | 30-06-2026 |
| Total budget - Public funding: | 1 613 750,00 Euro - 1 613 750,00 Euro |
Cordis data
Original description
Immunotherapies targeting immune regulators are revolutionizing cancer treatment, most prominently in melanoma, but only for a subset of patients. While it is known that the immune tumor microenvironment (iTME) plays a vital role in this process, there is limited understanding on how distinct tumor, immune and stroma cells interact as a system to collectively define progression and response to treatment, and there is no biomarker to predict patient response. Tumors are spatially organized ecosystems that are comprised of distinct cell types, each of which can assume a variety of phenotypes defined by coexpression of multiple proteins. To underscore this complexity, and move beyond single cells to multicellular interactions, it is essential to interrogate cellular expression patterns within their native context in the tissue.We have recently pioneered MIBI-TOF (Multiplexed Ion Beam Imaging by Time of Flight), a novel platform that enables simultaneous imaging of forty proteins within intact tissue sections at subcellular resolution. We propose to (1) Use MIBI-TOF to chart the iTME in dozens of clinical samples from melanoma patients and delineate its function in response to different immunotherapies. (2) Profile murine melanoma tumors to elucidate genetic and temporal mechanisms that drive iTME organization in vivo. (3) Develop new experimental tools for tracing and barcoding thousands of cells to decouple the effects of tumor genetics and the immune microenvironment on tumor organization and clonal dynamics. (4) Develop machine-learning-based algorithms to analyze this novel data and facilitate accessibility of the scientific community to high-dimensional imaging to study human malignancies.
This proposal applies state-of-the-art imaging technology and computation to unravel design principles of the iTME in melanoma, with a grand goal to reveal basic principles in tumor immunology and improve treatment and diagnostics.
Status
SIGNEDCall topic
ERC-2020-STGUpdate Date
27-04-2024
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