Figure 1.

Examples of unconventional roles for unconventional myosins. (a) Tension sensing: members of the myosin-1 family can act as tension sensors owing to their structural and kinetic properties. Myosins-1 have a two-step working stroke, the second step of which is sensitive to applied force [21]. When tension is applied to the myosin, it is less likely to release ADP and remains bound to the actin filament for longer periods of time. (b) Dynamic tethers: rather than acting to transport organelles along F-actin tracks, there is growing evidence that unconventional myosins (such as myosins-5a and -5b) instead function to tether organelles to cortical F-actin after their delivery to the cell periphery along microtubules by kinesin [23,25]. These myosin tethers are proposed to be very dynamic and their effect reversible, such that organelles or vesicles can be released and sent back down microtubules to the cell interior via dynein-mediated transport [27]. (c) F-actin organization during endocytosis: myosins-1c and -1e have been shown to organize the assembly of F-actin during endo- and exocytosis [27,35,36]; here, compensatory endocytosis is shown. Myosin-1 localizes to the vesicle or granule before the formation of the F-actin coat and is required to organize the F-actin to facilitate its endocytosis. (d) Mitotic spindle structure: myosins-10 and -15 have been found to be involved in maintaining mitotic spindle structure [55–57]; here, for simplicity, just myosin-10 is shown. Myosin-10 localizes to the actin-rich cell cortex and to the mitotic spindle and functions in spindle length regulation, spindle pole structure and spindle anchoring [57]. These functions could be partly mediated through possible connections between cortical myosin-10 and astral microtubules or through separate functions by myosin-10 in the spindle interior.