Myosin II activity facilitates microtubule bundling in the neuronal growth cone neck.

The cell biological processes underlying axon growth and guidance are still not well understood. An outstanding question is how a new segment of the axon shaft is formed in the wake of neuronal growth cone advance. For this to occur, the highly dynamic, splayed-out microtubule (MT) arrays characteristic of the growth cone must be consolidated (bundled together) to form the core of the axon shaft. MT-associated proteins stabilize bundled MTs, but how individual MTs are brought together for initial bundling is unknown. Here, we show that laterally moving actin arcs, which are myosin II-driven contractile structures, interact with growing MTs and transport them from the sides of the growth cone into the central domain. Upon Myosin II inhibition, the movement of actin filaments and MTs immediately stopped and MTs unbundled. Thus, Myosin II-dependent compressive force is necessary for normal MT bundling in the growth cone neck.

Myosin II functions in actin-bundle turnover in neuronal growth cones.

Retrograde actin flow works in concert with cell adhesion to generate traction forces that are involved in axon guidance in neuronal growth cones. Myosins have been implicated in retrograde flow, but identification of the specific myosin subtype(s) involved has been controversial. Using fluorescent speckle microscopy (FSM) to assess actin dynamics, we report that inhibition of myosin II alone decreases retrograde flow by 51% and the remaining flow can be almost fully accounted for by the 'push' of plus-end actin assembly at the leading edge of the growth cone. Interestingly, actin bundles that are associated with filopodium roots elongated by approximately 83% after inhibition of myosin II. This unexpected result was due to decreased rates of actin-bundle severing near their proximal (minus or pointed) ends which are located in the transition zone of the growth cone. Our study reveals a mechanism for the regulation of actin-bundle length by myosin II that is dependent on actin-bundle severing, and demonstrate that retrograde flow is a steady state that depends on both myosin II contractility and actin-network treadmilling.