Early development of the optic nerve in the turtle Mauremys leprosa.

We show the distribution of the neural and non-neural elements in the early development of the optic nerve in the freshwater turtle, Mauremys leprosa, using light and electron microscopy. The first optic axons invaded the ventral periphery of the optic stalk in close relationship to the radial neuroepithelial processes. Growth cones were thus exclusively located in the ventral margin. As development progressed, growth cones were present in ventral and dorsal regions, including the dorsal periphery, where they intermingled with mature axons. However, growth cones predominated in the ventral part and axonal profiles dorsally, reflecting a dorsal to ventral gradient of maturation. The size and morphology of growth cones depended on the developmental stage and the region of the optic nerve. At early stages, most growth cones were of irregular shape, showing abundant lamellipodia. At the following stages, they tended to be larger and more complex in the ventral third than in intermediate and dorsal portions, suggesting a differential behavior of the growth cones along the ventro-dorsal axis. The arrival of optic axons at the optic stalk involved the progressive transformation of neuroepithelial cells into glial cells. Simultaneously with the fiber invasion, an important number of cells died by apoptosis in the dorsal wall of the optic nerve. These findings are discussed in relation to the results described in the developing optic nerve of other vertebrates.

It's all in the assay: a new model for retinotectal topographic mapping.

Ephrin-As have been implicated as topographic mapping labels in the retinotectal system, but the underlying molecular mechanisms for their activities in this context remain somewhat mysterious. Hansen et al. (this issue of Neuron) developed an assay that reveals new mechanisms for ephrins in topographic mapping and suggest a model whereby retinal axons grow and terminate in the tectum via a balance of growth promotion and repulsion, with the balance point depending on retinal position and concentration of ephrin-As.