Live Tracking of Inter-organ Communication by Endogenous Exosomes In Vivo

Frederik J Verweij; Celine Revenu; Guillaume Arras; Florent Dingli; Damarys Loew; D Michiel Pegtel; Gautier Follain; Guillaume Allio; Jacky G Goetz; Pascale Zimmermann; Philippe Herbomel; Filippo Del Bene; Graça Raposo; Guillaume van Niel

doi:https://doi.org/10.1016/j.devcel.2019.01.004

Live Tracking of Inter-organ Communication by Endogenous Exosomes In Vivo

Frederik J Verweij, Celine Revenu, Guillaume Arras, Florent Dingli, Damarys Loew, D Michiel Pegtel, Gautier Follain, Guillaume Allio, Jacky G Goetz, Pascale Zimmermann, Philippe Herbomel, Filippo Del Bene, Graça Raposo, Guillaume van Niel

Research output: Contribution to journal › Article › Academic › peer-review

210 Citations (Scopus)

Abstract

Extracellular vesicles (EVs) are released by most cell types but providing evidence for their physiological relevance remains challenging due to a lack of appropriate model organisms. Here, we developed an in vivo model to study EV function by expressing CD63-pHluorin in zebrafish embryos. A combination of imaging methods and proteomic analysis allowed us to study biogenesis, composition, transfer, uptake, and fate of individual endogenous EVs. We identified a subpopulation of EVs with exosome features, released in a syntenin-dependent manner from the yolk syncytial layer into the blood circulation. These exosomes are captured, endocytosed, and degraded by patrolling macrophages and endothelial cells in the caudal vein plexus (CVP) in a scavenger receptor- and dynamin-dependent manner. Interference with exosome biogenesis affected CVP growth, suggesting a role in trophic support. Altogether, our work represents a system for studying endogenous EV function in vivo with high spatiotemporal accuracy, demonstrating functional inter-organ communication by exosomes.

Original language	English
Pages (from-to)	573-589.e4
Journal	Developmental Cell
Volume	48
Issue number	4
DOIs	https://doi.org/10.1016/j.devcel.2019.01.004
Publication status	Published - 25 Feb 2019

Keywords

CD63-pHluorin
exosome internalization
exosomes
extracellular vesicles
in situ electron microscopy
live-tracking
macrophages
scavenger endothelial cells
yolk syncytial layer
zebrafish

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title = "Live Tracking of Inter-organ Communication by Endogenous Exosomes In Vivo",

abstract = "Extracellular vesicles (EVs) are released by most cell types but providing evidence for their physiological relevance remains challenging due to a lack of appropriate model organisms. Here, we developed an in vivo model to study EV function by expressing CD63-pHluorin in zebrafish embryos. A combination of imaging methods and proteomic analysis allowed us to study biogenesis, composition, transfer, uptake, and fate of individual endogenous EVs. We identified a subpopulation of EVs with exosome features, released in a syntenin-dependent manner from the yolk syncytial layer into the blood circulation. These exosomes are captured, endocytosed, and degraded by patrolling macrophages and endothelial cells in the caudal vein plexus (CVP) in a scavenger receptor- and dynamin-dependent manner. Interference with exosome biogenesis affected CVP growth, suggesting a role in trophic support. Altogether, our work represents a system for studying endogenous EV function in vivo with high spatiotemporal accuracy, demonstrating functional inter-organ communication by exosomes.",

keywords = "CD63-pHluorin, exosome internalization, exosomes, extracellular vesicles, in situ electron microscopy, live-tracking, macrophages, scavenger endothelial cells, yolk syncytial layer, zebrafish",

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AU - Verweij, Frederik J

AU - Revenu, Celine

AU - Arras, Guillaume

AU - Dingli, Florent

AU - Loew, Damarys

AU - Pegtel, D Michiel

AU - Follain, Gautier

AU - Allio, Guillaume

AU - Goetz, Jacky G

AU - Zimmermann, Pascale

AU - Herbomel, Philippe

AU - Del Bene, Filippo

AU - Raposo, Graça

AU - van Niel, Guillaume

PY - 2019/2/25

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N2 - Extracellular vesicles (EVs) are released by most cell types but providing evidence for their physiological relevance remains challenging due to a lack of appropriate model organisms. Here, we developed an in vivo model to study EV function by expressing CD63-pHluorin in zebrafish embryos. A combination of imaging methods and proteomic analysis allowed us to study biogenesis, composition, transfer, uptake, and fate of individual endogenous EVs. We identified a subpopulation of EVs with exosome features, released in a syntenin-dependent manner from the yolk syncytial layer into the blood circulation. These exosomes are captured, endocytosed, and degraded by patrolling macrophages and endothelial cells in the caudal vein plexus (CVP) in a scavenger receptor- and dynamin-dependent manner. Interference with exosome biogenesis affected CVP growth, suggesting a role in trophic support. Altogether, our work represents a system for studying endogenous EV function in vivo with high spatiotemporal accuracy, demonstrating functional inter-organ communication by exosomes.

AB - Extracellular vesicles (EVs) are released by most cell types but providing evidence for their physiological relevance remains challenging due to a lack of appropriate model organisms. Here, we developed an in vivo model to study EV function by expressing CD63-pHluorin in zebrafish embryos. A combination of imaging methods and proteomic analysis allowed us to study biogenesis, composition, transfer, uptake, and fate of individual endogenous EVs. We identified a subpopulation of EVs with exosome features, released in a syntenin-dependent manner from the yolk syncytial layer into the blood circulation. These exosomes are captured, endocytosed, and degraded by patrolling macrophages and endothelial cells in the caudal vein plexus (CVP) in a scavenger receptor- and dynamin-dependent manner. Interference with exosome biogenesis affected CVP growth, suggesting a role in trophic support. Altogether, our work represents a system for studying endogenous EV function in vivo with high spatiotemporal accuracy, demonstrating functional inter-organ communication by exosomes.

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KW - exosome internalization

KW - exosomes

KW - extracellular vesicles

KW - in situ electron microscopy

KW - live-tracking

KW - macrophages

KW - scavenger endothelial cells

KW - yolk syncytial layer

KW - zebrafish

UR - http://www.mendeley.com/research/live-tracking-interorgan-communication-endogenous-exosomes-vivo

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SP - 573-589.e4

JO - Developmental Cell

JF - Developmental Cell

IS - 4

ER -

Live Tracking of Inter-organ Communication by Endogenous Exosomes In Vivo

Abstract

Keywords

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