Abstract
Cancer cell-derived extracellular vesicles (EVs) are increasingly being recognized as genuine invasive structures as they contribute to many aspects of invasion and metastasis. Unfortunately, the mechanisms underlying EV biogenesis or release are still poorly understood. Recent reports however indicate a role of the actin cytoskeleton in this process. In this study, we have exploited thoroughly characterized camelid nanobodies against actin binding proteins cortactin and fascin-1, a branched actin regulator and actin bundler, respectively, in order to assess their roles in EV biogenesis or release. Using this strategy, we demonstrate a role of the cortactin NTA and SH3 domains in EV release. Fascin-1 also regulates EV release, independently of its actin-bundling activity. We show a contribution of these protein domains in endosomal trafficking, a crucial step in EV biogenesis, and we confirm that EVs are preferentially released at invadopodia, the latter being actin-rich invasive cell protrusions in which cortactin and fascin-1 perform essential roles. Accordingly, EVs are enriched with invadopodial proteins such as the matrix metalloproteinase MT1-MMP and exert gelatinolytic activity. Based on our findings, we report that both cortactin and fascin-1 play key roles in EV release by regulating endosomal trafficking or invadopodia formation and function.
Highlights
Extracellular vesicles (EVs) are nanometer-sized vesicles secreted by myriad of cells
extracellular vesicles (EVs) were isolated from pre-purified conditioned medium (CM) derived from parental MDA-MB-231 breast cancer cells by means of OptiPrep density gradient (ODG) centrifugation
We have investigated CTTN and FSCN1 function in EV release, using invadopodia-forming MDA-MB-231 breast cancer cells as a model cell line
Summary
Extracellular vesicles (EVs) are nanometer-sized vesicles secreted by myriad of cells. Other mediators of the invasive cell phenotype are invadopodia[5]. Invadopodia formation is a complex process and requires an intricate interplay between a distinct set of signalling proteins and actin binding proteins (ABPs), necessary for correct actin assembly and branching[7]. Cortactin (CTTN) is a key branched actin regulator and scaffolding protein, linking signalling, membrane trafficking and other ABPs to dynamic actin networks[8]. (SH3) domain that serves as a docking place for a large number of proline-rich interacting proteins, including dynamin-29, N-WASP10 and WIP11. The latter two proteins enhance ARP2/3-mediated actin polymerization[10,11]. FSCN1 was only recently detected in invadopodia where it acts as a stabilizer, enabling long invadopodium lifetime[12,24]
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