Abstract
Cytokinesis in many eukaryotes involves a tension-generating actomyosin-based contractile ring. Many components of actomyosin rings turn over during contraction, although the significance of this turnover has remained enigmatic. Here, using Schizosaccharomyces japonicus, we investigate the role of turnover of actin and myosin II in its contraction. Actomyosin ring components self-organize into ∼1-µm-spaced clusters instead of undergoing full-ring contraction in the absence of continuous actin polymerization. This effect is reversed when actin filaments are stabilized. We tested the idea that the function of turnover is to ensure actin filament homeostasis in a synthetic system, in which we abolished turnover by fixing rings in cell ghosts with formaldehyde. We found that these rings contracted fully upon exogenous addition of a vertebrate myosin. We conclude that actin turnover is required to maintain actin filament homeostasis during ring contraction and that the requirement for turnover can be bypassed if homeostasis is achieved artificially.
Highlights
An actomyosin-based contractile machinery containing F-actin, myosin II, and actin cross-linkers is instrumental in tension generation in diverse cellular processes (Murrell et al, 2015)
Theoretical studies of actomyosin ring contraction suggest a requirement of actin turnover in supporting myosin II–dependent contraction (Stachowiak et al, 2014; Oelz et al, 2015; Oelz and Mogilner, 2016)
In studies of actomyosin ring contraction in S. japonicus using FRAP, we observed a dynamic turnover of many ring components including Rlc1, Cdc15 (F-BAR protein), Myo2 and Myp2, and Rng2 (IQGAP; Fig. S1 A)
Summary
An actomyosin-based contractile machinery containing F-actin, myosin II, and actin cross-linkers is instrumental in tension generation in diverse cellular processes (Murrell et al, 2015). In the majority of rings in cell ghosts, Rlc1-GFP formed clusters upon ATP addition, and these rings failed to contract further (Fig. 1 C and Video 1). We tested whether fluorescence intensity of actin filaments was reduced in rings in cell ghosts incubated with ATP.
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