Publication date: 3 July 2018
Source:Cell Reports, Volume 24, Issue 1
Author(s): Kelly Kawabata Galbraith, Kazuto Fujishima, Hiroaki Mizuno, Sung-Jin Lee, Takeshi Uemura, Kenji Sakimura, Masayoshi Mishina, Naoki Watanabe, Mineko Kengaku
Dendritic filopodia of developing neurons function as environmental sensors, regulating the spatial organization of dendrites and proper targeting to presynaptic partners. Dendritic filopodia morphology is determined by the balance of F-actin assembled via two major nucleating pathways, the ARP2/3 complex and formins. The inverse-BAR protein MTSS1 is highly expressed in Purkinje cells (PCs) and has been shown to upregulate ARP2/3 activity. PCs in MTSS1 conditional knockout mice showed dendrite hypoplasia due to excessive contact-induced retraction during development. This phenotype was concomitant with elongated dendritic filopodia and was phenocopied by overactivation of the actin nucleator formin DAAM1 localized in the tips of PC dendritic protrusions. Cell biology assays including single-molecule speckle microscopy demonstrated that MTSS1's C terminus binds to DAAM1 and paused DAAM1-mediated F-actin polymerization. Thus, MTSS1 plays a dual role as a formin inhibitor and ARP2/3 activator in dendritic filopodia, determining final neuronal morphology.
Graphical abstract
Teaser
Kawabata Galbraith et al. demonstrate MTSS1's function at the intersection of two major actin-nucleating pathways, ARP2/3 and formins, in the dendritic protrusions of Purkinje cells. Loss of MTSS1 critically impacts actin-based microstructure morphology and ultimately the final structure of the dendritic arbor.https://ift.tt/2lPVYvx
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