Neurospheres obtained from the ciliary margin of the chicken eye possess positional values and retinal ganglion cells differentiated from them respond to EphA/ephrin-A system.

In the Central Nervous System (CNS) there are some niches of undifferentiated, neural progenitor/stem cells that produce active neurogenesis originating functionally integrated neurons. In the chicken eye, there is a neurogenic niche in the ciliary margin (CM) which has the ability to originate all the cell types of the neural retina. During retinal development, cells acquire positional values along the radial and tangential axes.

Molecular complexity of visual mapping: a challenge for regenerating therapy.

Investigating the cellular and molecular mechanisms involved in the development of topographically ordered connections in the central nervous system constitutes an important issue in neurobiology because these connections are the base of the central nervous system normal function. The dominant model to study the development of topographic maps is the projection from the retinal ganglion cells to the optic tectum/colliculus. The expression pattern of Eph/ephrin system in opposing gradients both in the retina and the tectum, labels the local addresses on the target and gives specific sensitivities to growth cones according to their topographic origin in the retina.

Regulation of axonal EphA4 forward signaling is involved in the effect of EphA3 on chicken retinal ganglion cell axon growth during retinotectal mapping.

The Eph and ephrins are involved in the genesis of topographic ordered connections at the visual system. Previously we demonstrated that tectal EphA3 stimulates axon growth of nasal retinal ganglion cells (RGCs) toward the caudal tectum preventing them from branching in the rostral tectum. Now we investigated whether tectal EphA3 plays this role by modulating the axonal EphA4 forward signaling or throughout axonal ephrin-As reverse signaling.