Graphical Abstract Highlights d MemBright allows for bright and specific staining of EVs d The zebrafish embryo allows tracking of tumor EVs at high spatiotemporal resolution d Circulating tumor EVs are mostly taken up by endothelial cells and patrolling macrophages d Zebrafish melanoma EVs favor metastatic outgrowth in zebrafish embryos
The C. elegans germline is organized as a syncytium in which each germ cell possesses an intercellular bridge that is maintained by a stable actomyosin ring and connected to a common pool of cytoplasm, termed the rachis. How germ cells undergo cytokinesis while maintaining this syncytial architecture is not completely understood. Here, we use live imaging to characterize primordial germ cell (PGC) division in C. elegans first-stage larvae. We show that each PGC possesses a stable intercellular bridge that connects it to a common pool of cytoplasm, which we term the proto-rachis. We further show that the first PGC cytokinesis is incomplete and that the stabilized cytokinetic ring progressively moves towards the proto-rachis and eventually integrates with it. Our results support a model in which the initial expansion of the C. elegans syncytial germline occurs by incomplete cytokinesis, where one daughter germ cell inherits the actomyosin ring that was newly formed by stabilization of the cytokinetic ring, while the other inherits the pre-existing stable actomyosin ring. We propose that such a mechanism of iterative cytokinesis incompletion underpins C. elegans germline expansion and maintenance.
Highlights• MemBright, a new family of membrane probes, allows for bright and specific staining of EVs • Zebrafish melanoma EVs are very similar to human and mouse melanoma EVs in morphology and protein content • The zebrafish embryo is an adapted model to precisely track tumor EVs dynamics and fate in a living organism from light to electron microscopy • Circulating tumor EVs are rapidly uptaken by endothelial cells and patrolling macrophages • Correlated light and electron microscopy can be used in zebrafish to identify cells and compartments uptaking tumor EVs Blurb Dispersion of tumor extracellular vesicles (EVs) throughout the body promotes tumor progression. However the behavior of tumor EVs in body fluids remains mysterious due to their small size and the absence of adapted animal model. Here we show that the zebrafish embryo can be used to track circulating tumor EVs in vivo and provide the first high-resolution description of their dissemination and uptake.
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