The growth of axons and dendrites during development and regeneration is regulated by cues in the environment. Many of these cues regulate the actin cytoskeleton of the protrusive structures (like filopodia) of the growth cone that are essential for detecting and responding to cues. Nerve growth factor, which promotes the formation of protrusive structures, stimulated actin polymerization in rat sympathetic growth cones, resulting within 1-2 min in accumulations of F-actin at the distal edge and in splotches of F-actin farther back. We examined the potential involvement of a protein machinery important in at least certain types of actin polymerization in non-neuronal cells. Members of the Arp2/3 complex, p34-Arc and p21-Arc, heavily concentrated in the early accumulations of F-actin, as did one member of the Ena/VASP family (Mena) but not another (VASP). Retention of Arc proteins at preferred sites of actin polymerization did not require polymerization itself. Growth cones of differentiated PC12 cells were similar to sympathetic growth cones in their response to NGF. Introduction into these cells of a peptide that should block the binding of Ena/VASP family proteins to the protein complex at sites of actin polymerization reduced the formation of splotches and filopodia in response to NGF. These results point to the early involvement of the Arp2/3 complex and the Ena/VASP family in growth factor-stimulated actin polymerization that gives rise to protrusive structures at the growth cone.
The growth of axons and dendrites during development and regeneration is regulated by cues in the environment. Many of these cues regulate the actin cytoskeleton of the protrusive structures (like filopodia) of the growth cone that are essential for detecting and responding to cues. Nerve growth factor, which promotes the formation of protrusive structures, stimulated actin polymerization in rat sympathetic growth cones, resulting within 1-2 min in accumulations of F-actin at the distal edge and in splotches of F-actin farther back. We examined the potential involvement of a protein machinery important in at least certain types of actin polymerization in non-neuronal cells. Members of the Arp2/3 complex, p34-Arc and p21-Arc, heavily concentrated in the early accumulations of F-actin, as did one member of the Ena/VASP family (Mena) but not another (VASP). Retention of Arc proteins at preferred sites of actin polymerization did not require polymerization itself. Growth cones of differentiated PC12 cells were similar to sympathetic growth cones in their response to NGF. Introduction into these cells of a peptide that should block the binding of Ena/VASP family proteins to the protein complex at sites of actin polymerization reduced the formation of splotches and filopodia in response to NGF. These results point to the early involvement of the Arp2/3 complex and the Ena/VASP family in growth factor-stimulated actin polymerization that gives rise to protrusive structures at the growth cone.
The cycling of membrane receptors for substrate-bound proteins via their interaction with the actin cytoskeleton at the leading edge of growth cones and other motile cells is important for neurite outgrowth and cell migration. Receptor delivered to the leading edge binds to its ligand, which induces coupling of the receptor to a rearward flowing network of actin filaments. This coupling is thought to facilitate advance. We show here that a soluble growth factor stimulates this cycling. We have used single particle tracking to monitor the effects of nerve growth factor (NGF) on the movements of beta1 integrin in the plane of the plasma membrane of the filopodia of growth cones. Beta1 integrin was visualized by its binding of 0.2 microm beads coated with a monoclonal Ab directed against an extracellular epitope distant from the binding site for extracellular matrix ligands. The beads were observed by video microscopy. Beads coated with a low concentration of antibody, and therefore bound to unliganded receptor with little cross-linking, showed an increase in both diffusion and directed forward transport in response to NGF. Transport had a net velocity of 37 microm/minute and was characterized by brief periods of sustained forward excursions with a velocity of 75–150 microm/minute. There was a 2-fold increase in the number of beads accumulated at the tips of filopodia after 10 minutes, indicating that NGF enhanced the delivery of beta1 integrin to the periphery. Forward transport was dependent on an intact actin cytoskeleton and myosin ATPase, since treatment with cytochalasin D or the myosin ATPase inhibitor butanedione monoxime inhibited the transport but not the diffusion of receptors. NGF also greatly increased the steady rearward migration of beads coated with a high density of (β)1 integrin antibody, indicating that coupling of cross-linked receptor to the retrograde flow of actin is also enhanced. The rate of the retrograde flow of actin was unaffected by NGF. These studies show that a soluble factor can stimulate the coupling of a receptor for substrate-bound factor to two actomyosin-based transport mechanisms and thus facilitate the response of the growth cone to the substrate-bound factor by increasing cycling of the receptor at the periphery.
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