In the early syncytial Drosophila embryo, rapid changes in filamentous actin networks and membrane trafficking pathways drive the formation and remodeling of cortical and furrow morphologies. Interestingly, genomic integrity and the completion of mitoses during cell cycles 10-13 depends on the formation of transient membrane furrows that serve to separate and anchor individual spindles during division. While substantial work has led to a better understanding of the core network components that are responsible for the formation of these furrows, less is known about the regulation that controls cytoskeletal and trafficking function. The DOCK protein Sponge was one of the first proteins identified as being required for syncytial furrow formation, and disruption of Sponge deeply compromises F-actin populations in the early embryo, but how this occurs is less clear. Here, we perform quantitative analysis of the effects of Sponge disruption on cortical cap growth, furrow formation, membrane trafficking, and cytoskeletal network regulation through live-imaging of the syncytial embryo. We find that membrane trafficking is relatively unaffected by the defects in branched actin networks that occur after Sponge disruption, but that Sponge acts as a master regulator of a diverse cohort of Arp2/3 regulatory proteins. As DOCK family proteins have been implicated in regulating GTP exchange on small GTPases, we also suggest that Rac GTPase activity bridges Sponge regulation to the regulators of Arp2/3 function. Finally, we demonstrate the phasic requirements for branched F-actin and linear F-actin networks in potentiating furrow ingression. In total, these results provide quantitative insights into how a large DOCK scaffolding protein coordinates the activity of a variety of different actin regulatory proteins to direct the remodeling of the apical cortex into cytokinetic-like furrows.
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