STENIPATH | Stem and niche cell dynamics in normal and pathological conditions

Summary
Coherent tissue growth and repair require an interplay between stem cells and their local and systemic environment. The dynamics of this process remains poorly defined particularly at the intersection with disease. Cellular quiescence is adopted by many adult stem cells, conferring them several features including a smaller cell volume and reduced metabolic demand, suggesting that quiescence preserves stem cell properties making them less responsive to external cues. We examined the status of skeletal muscle stem (MuSC) and niche cells during an influenza virus infection (lung) and cancer cachexia (tumour) in mice. Unexpectedly, quiescent MuSCs remodelled their cellular, metabolic, and transcriptome properties extensively, and tissue regeneration was impaired, prompting us to define a novel cell state, GPath. Whether GPath represents a coordinated response of stem cells to pathology, or uncontrolled deregulation, is unclear.
MuSCs exhibit remarkable diversity in gene regulation and function in distinct anatomical locations (head/limb). We discovered that cranial MuSCs display higher resistance to the pathologies compared to those in limb. These observations have led us into a novel area of research, to the best of my knowledge largely unexplored in model organisms and humans: how stem and niche cells in one organ respond to pathologies present at a distal site. We will examine the response of muscle and blood stem and niche cells to distal pathologies by defining their cellular, metabolic, molecular, epigenetic, and functional properties, and their modes of cell division. We will employ diverse multiomics approaches and novel medium/high-throughput intravital and ex vivo imaging pipelines. This work should provide new knowledge and tools to address an important, but under-investigated area of research where stem cell biology and pathologies converge. The knowledge gained will be widely applicable to other stem cell systems and inform on human pathologies.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101055234
Start date: 01-09-2022
End date: 31-08-2027
Total budget - Public funding: 2 499 600,00 Euro - 2 499 600,00 Euro
Cordis data

Original description

Coherent tissue growth and repair require an interplay between stem cells and their local and systemic environment. The dynamics of this process remains poorly defined particularly at the intersection with disease. Cellular quiescence is adopted by many adult stem cells, conferring them several features including a smaller cell volume and reduced metabolic demand, suggesting that quiescence preserves stem cell properties making them less responsive to external cues. We examined the status of skeletal muscle stem (MuSC) and niche cells during an influenza virus infection (lung) and cancer cachexia (tumour) in mice. Unexpectedly, quiescent MuSCs remodelled their cellular, metabolic, and transcriptome properties extensively, and tissue regeneration was impaired, prompting us to define a novel cell state, GPath. Whether GPath represents a coordinated response of stem cells to pathology, or uncontrolled deregulation, is unclear.
MuSCs exhibit remarkable diversity in gene regulation and function in distinct anatomical locations (head/limb). We discovered that cranial MuSCs display higher resistance to the pathologies compared to those in limb. These observations have led us into a novel area of research, to the best of my knowledge largely unexplored in model organisms and humans: how stem and niche cells in one organ respond to pathologies present at a distal site. We will examine the response of muscle and blood stem and niche cells to distal pathologies by defining their cellular, metabolic, molecular, epigenetic, and functional properties, and their modes of cell division. We will employ diverse multiomics approaches and novel medium/high-throughput intravital and ex vivo imaging pipelines. This work should provide new knowledge and tools to address an important, but under-investigated area of research where stem cell biology and pathologies converge. The knowledge gained will be widely applicable to other stem cell systems and inform on human pathologies.

Status

SIGNED

Call topic

ERC-2021-ADG

Update Date

09-02-2023
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Horizon Europe
HORIZON.1 Excellent Science
HORIZON.1.1 European Research Council (ERC)
HORIZON.1.1.0 Cross-cutting call topics
ERC-2021-ADG ERC ADVANCED GRANTS
HORIZON.1.1.1 Frontier science
ERC-2021-ADG ERC ADVANCED GRANTS