Graded distributions of extracellular cues guide developing axons toward their targets. A network of second messengers, Ca2+ and cyclic nucleotides, shapes cue-derived information into either attractive or repulsive signals that steer growth cones bidirectionally. Emerging evidence suggests that such guidance signals create a localized imbalance between exocytosis and endocytosis, which in turn redirects membrane, adhesion and cytoskeletal components asymmetrically across the growth cone to bias the direction of axon extension. These recent advances allow us to propose a unifying model of how the growth cone translates shallow gradients of environmental information into polarized activity of the steering machinery for axon guidance.
Asymmetric elevation of the Ca(2+) concentration in the growth cone can mediate both attractive and repulsive axon guidance. Ca(2+) signals that are accompanied by Ca(2+)-induced Ca(2+) release (CICR) trigger attraction, whereas Ca(2+) signals that are not accompanied by CICR trigger repulsion. The molecular machinery downstream of Ca(2+) signals, however, remains largely unknown. Here we report that asymmetric membrane trafficking mediates growth cone attraction. Local photolysis of caged Ca(2+), together with CICR, on one side of the growth cone of a chick dorsal root ganglion neuron facilitated the microtubule-dependent centrifugal transport of vesicles towards the leading edge and their subsequent vesicle-associated membrane-protein 2 (VAMP2)-mediated exocytosis on the side with an elevated Ca(2+) concentration. In contrast, Ca(2+) signals without CICR had no effect on the vesicle transport. Furthermore, pharmacological inhibition of VAMP2-mediated exocytosis prevented growth cone attraction, but not repulsion. These results strongly suggest that growth cone attraction and repulsion are driven by distinct mechanisms, rather than using the same molecular machinery with opposing polarities.
Asymmetric Ca(2+) elevations across the axonal growth cone mediate its turning responses to attractive and repulsive guidance cues. Here we show that clathrin-mediated endocytosis acts downstream of Ca(2+) signals as driving machinery for growth cone turning. In dorsal root ganglion neurons, the formation of clathrin-coated pits is facilitated asymmetrically across the growth cone by a directionally applied chemorepellent, semaphorin 3A, or by Ca(2+) signals that mediate repulsive guidance. In contrast, coated pit formation remains symmetric in the presence of attractive Ca(2+) signals. Inhibition of clathrin-mediated endocytosis abolishes growth cone repulsion, but not attraction, induced by Ca(2+) or extracellular physiological cues. Furthermore, asymmetric perturbation of the balance of endocytosis and exocytosis in the growth cone is sufficient to initiate its turning toward the side with less endocytosis or more exocytosis. With our previous finding that growth cone attraction involves asymmetric exocytosis, we propose that the balance between membrane addition and removal dictates bidirectional axon guidance.
The cell adhesion molecule L1 (L1-CAM) plays critical roles in neurite growth. Its cytoplasmic domain (L1CD) binds to ankyrins that associate with the spectrin–actin network. This paper demonstrates that L1-CAM interactions with ankyrinB (but not with ankyrinG) are involved in the initial formation of neurites. In the membranous protrusions surrounding the soma before neuritogenesis, filamentous actin (F-actin) and ankyrinB continuously move toward the soma (retrograde flow). Bead-tracking experiments show that ankyrinB mediates L1-CAM coupling with retrograde F-actin flow in these perisomatic structures. Ligation of the L1-CAM ectodomain by an immobile substrate induces L1CD–ankyrinB binding and the formation of stationary ankyrinB clusters. Neurite initiation preferentially occurs at the site of these clusters. In contrast, ankyrinB is involved neither in L1-CAM coupling with F-actin flow in growth cones nor in L1-based neurite elongation. Our results indicate that ankyrinB promotes neurite initiation by acting as a component of the clutch module that transmits traction force generated by F-actin flow to the extracellular substrate via L1-CAM.
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