Concentration-dependent stimulation and inhibition of growth cone behavior and neurite elongation by protein kinase inhibitors KT5926 and K-252a.

We examined the concentration- and time-dependent effects of two related protein kinase inhibitors, KT5926 and K-252a, on neurite formation and nerve growth cone migration of chick embryo sensory neurons. The effects of these drugs on neurite formation over an 18-h period were dissimilar. KT5926 stimulated neurite formation at concentrations between 100 and 500 nM and inhibited neurite formation at 5 microM. K-252a had no stimulatory effects on neurite formation, and it inhibited neurite formation at concentrations above 50 nM. This difference may occur because K-252a inhibits activation of the nerve growth factor receptor trk A, while KT5926 does not inhibit trk A. Both drugs, however, had similar immediate effects on growth cone migration. Growth cone migration and lamellipodial spreading were rapidly stimulated by 500 nM concentrations of KT5926 and K-252a. At 2 microM levels of either drug, growth cone spreading was still stimulated, but growth cone migration was inhibited by both drugs. These results show that changes in protein phosphorylation/dephosphorylation can rapidly regulate the cellular machinery that is responsible for driving growth cone migration and neurite elongation. The different effects of 2 microM concentrations of either KT5926 or K-252a on growth cone spreading versus migration suggests that the actin-dependent protrusive motility of the growth cone leading margin is regulated differently by changes in protein phosphorylation and dephosphorylation than the cytoskeletal mechanism that drives neurite elongation.

Chick sensory neuronal growth cones distinguish fibronectin from laminin by making substratum contacts that resemble focal contacts.

The adhesive interactions of nerve growth cones stabilize elongating nerve fibers and mediate transmembrane signaling to regulate growth cone behaviors. We used interference reflection microscopy and immunocytochemistry to examine the dynamics and composition of substratum contacts that growth cones of chick sensory neurons make with extracellular adhesive glycoproteins, fibronectin and laminin. Interference reflection microscopy indicated that sensory neuronal growth cones on fibronectin-treated substrata, but not on laminin, make contacts that have the appearance and immobility of fibroblastic focal contacts. Interference reflection microscopy and subsequent immunocytochemical staining showed that beta 1 integrin and phosphotyrosine residues were concentrated at growth cone sites that resemble focal contacts. Two other components of focal contacts, paxillin and zyxin, were also co-localized with concentrated phosphotyrosine residues at sites that resemble focal contacts. Such staining patterns were not observed on laminin-treated substrata. Growth cone migration on fibronectin-treated substrata was inhibited by herbimycin A, a tyrosine kinase inhibitor. We conclude that sensory neuronal growth cones distinguish fibronectin from laminin by making contacts with distinct organization and regulation of cytoskeletal components at the adhesive sites. This finding suggests that growth cone interactions with different adhesive molecules lead to distinctive transmembrane organization and signaling to regulate nerve fiber elongation.

Interactions of Schwann cells with neurites and with other Schwann cells involve the calcium-dependent adhesion molecule, N-cadherin.

During embryogenesis, Schwann cells interact with axons and other Schwann cells, as they migrate, ensheath axons, and participate in organizing peripheral nervous tissues. The experiments reported here indicate that the calcium-dependent molecule, N-cadherin, mediates adhesion of Schwann cells to neurites and to other Schwann cells. Cell cultures from chick dorsal root ganglia and sciatic nerves were maintained in media containing either 2 mM Ca++ or 0.2 mM Ca++, a concentration that inactivates calcium-dependent cadherins. When the leading lamellae of Schwann cells encountered migrating growth cones in medium with 2 mM Ca++, they usually remained extended, and the growth cones often advanced onto the Schwann cell upper surface. In the low Ca++ medium, the frequency of withdrawal of the Schwann cell lamella after contact with a growth cone was much greater, and withdrawal was the most common reaction to growth cone contact in medium with 2 mM Ca++ and anti-N-cadherin. Similarly, when motile leading margins of two Schwann cells touched in normal Ca++ medium, they often formed stable areas of contact. N-cadherin and vinculin were co-concentrated at these contact sites between Schwann cells. However, in low Ca++ medium or in the presence of anti-N-cadherin, interacting Schwann cells usually pulled away from each other in a behavior reminiscent of contact inhibition between fibroblasts. In cultures of dissociated cells in normal media, Schwann cells frequently were aligned along neurites, and ultrastructural examination showed extensive close apposition between plasma membranes of neurites and Schwann cells. When dorsal root ganglia explants were cultured with normal Ca++, Schwann cells migrated away from the explants in close association with extending neurites. All these interactions were disrupted in media with 0.2 mM Ca++. Alignment of Schwann cells along neurites was infrequent, as were extended close apposition between axonal and Schwann cell plasma membranes. Finally, migration of Schwann cells from ganglionic explants was reduced by disruption of adhesive contact with neurites. The addition of antibodies against N-cadherin to medium with normal Ca++ levels had similar effects as lowering the Ca++ concentration, but antibodies against the neuronal adhesive molecule, L1, had no effects on interactions between Schwann cells and neurites.

Nerve growth cone migration onto Schwann cells involves the calcium-dependent adhesion molecule, N-cadherin.

The role of calcium-dependent adhesion molecules in the migration of nerve growth cones onto the top of Schwann cells was probed by examination of sensory growth cone-Schwann cell interactions in medium containing either 1.0 mM Ca2+ or 0.1 mM Ca2+. In the presence of 1.0 mM Ca2+ growth cones rapidly migrated onto Schwann cells, spread, and remained for extended periods. However, in 0.1 mM Ca2+ growth cones still made frequent contacts with Schwann cells, but migration onto the upper cell surface was much reduced. This contrast in growth cone-Schwann cell interactions could be switched rapidly by changing the Ca2+ concentration of the culture medium. Growth cones of retinal neurons showed similar calcium-dependence in their migration onto Schwann cells. Antibodies to the calcium-dependent adhesion molecule, N-cadherin, also blocked growth cone migration onto Schwann cells, but antibodies to another neuronal adhesion molecule, L1, had no effect on growth cone-Schwann cell interactions. Immunocytochemical staining for N-cadherin and L1 indicated that growth cones and Schwann cells have N-cadherin on their surfaces, while L1 is present only on axons and growth cones. These results provide two kinds of evidence that N-cadherin is important in the initial interactions of growth cones and Schwann cells.