Actin Y53 Phosphorylation Regulates Somatic F-actin Radial Translocation to Promote Neuronal Polarization

Abstract

AbstractHow neurons accomplish the growth of an axon, and several dendrites sequentially is a cellular process not well understood. Here, we show that preferential somatic F-actin delivery to neurites inhibits neurite growth during axon formation. Thus, the neurite receiving less somatic F-actin is growing as an axon. During dendrites outgrowth, radial somatic F-actin translocation into all neurites is drastically diminished suggesting that cellular growth is restricted by the somatic F-actin flow into the growing neurites. Mechanistically, we report that radial somatic F-actin translocation is mediated via the Myosin II motor. Pharmacological inhibition of these molecular motors promotes neurite elongation and precludes F-actin translocation into neurites. Moreover, we show that actin phosphorylation at Y53, which promotes F-actin instability, is enriched selectively in some neurite shafts to exclude/minimize translocation of somatic F-actin only into those neurites. Therefore, enrichment of actin pY53 in the neurite shaft correlates with the longer neurite during axon formation. Accordingly, the Kinesin-1 motor domain, which accumulates transiently in neurites of stage 2 neurons and only in the emerging axon of stage 3 neurons, localizes preferentially in the neurite with the increased actin pY53 signal in the neurite shaft. Finally, we demonstrate that microtubule acetylation promotes actin phosphorylation, and these cytoskeleton modifications coexist in the longest neurite that grows as an axon. Collectively, our data support a model in which somatic F-actin translocation into undifferentiated neurites impedes growth counteracted by actin pY53, consequently, supporting neuronal polarization during axon formation.