Coordinated cortical ER remodeling facilitates actomyosin ring assembly

Abstract

The cortical endoplasmic reticulum (cER) is a reticulated network closely attached to the plasma membrane (PM). In the fission yeast Schizosaccharomyces pombe (S.pombe), ER-PM contacts have been suggested to restrict both the allocation and compaction of large-sized actomyosin assemblies along the lateral cell cortex. However, how cells orchestrate ER-PM contact remodeling in accordance with actomyosin coalescence for contractile ring assembly is unclear. Here, we reveal that actomyosin compaction directs the remodeling of the free tubular cER edges, whereas active exocytosis subsequently promotes the reorganization of the eisosome-bound cER rims by weakening their association or repatterning the eisosome-coated PM furrows. cER-eisosome contacts also act to reserve tubular cER edges and, hence, the ER shaping machinery at the lateral cell cortex. By manipulating or rerouting exocytosis in mutants with compromised actomyosin compaction, due to either the loss of myosin II activity or sheet-like cER morphology, we show that exocytosis facilitates ring formation likely by creating free tubular cER rims allowing robust cER remodeling. We thus propose that coordinated cER remodeling driven by both actomyosin forces and active exocytosis ensures proper contractile ring assembly. Our work also provides mechanistic insights into cER-related modulation in actomyosin ring assembly.