Although many aspects of optic pathway development are beginning to be understood, the mechanisms promoting the growth of retinal ganglion cell (RGC) axons toward visual targets remain largely unknown. Down syndrome cell adhesion molecule (Dscam) is expressed by mouse RGCs shortly after they differentiate at embryonic day 12 and is essential for multiple aspects of postnatal visual system development. Here we show that Dscam is also required during embryonic development for the fasciculation and growth of RGC axons. Dscam is expressed along the developing optic pathway in a pattern consistent with a role in regulating RGC axon outgrowth. In mice carrying spontaneous mutations in Dscam (Dscam), RGC axons pathfind normally, but growth from the chiasm toward their targets is impaired, resulting in a delay in RGC axons reaching the dorsal thalamus compared with that seen in wild-type littermates. Conversely, Dscam gain of function results in exuberant growth into the dorsal thalamus. The growth of ipsilaterally projecting axons is particularly affected. Axon organization in the optic chiasm and tract and RGC growth cone morphologies are also altered in Dscam mutants. In vitro DSCAM promotes RGC axon growth and fasciculation, and can act independently of cell contact. In vitro and in situ DSCAM is required both in the RGC axons and in their environment for the promotion of axon outgrowth, consistent with a homotypic mode of action. These findings identify DSCAM as a permissive signal that promotes the growth and fasciculation of RGC axons, controlling the timing of when RGC axons reach their targets.axon guidance | development | growth cone | optic chiasm | visual system T he developing vertebrate visual system has proven to be one of the most informative model systems for studying axon growth and guidance decision (1). In mice, retinal ganglion cell (RGC) axons grow into the brain from embryonic day (E) 12.5, although mapping within visual targets is not complete until postnatal stages (1). Molecules have been identified that are important for multiple aspects of RGC axon growth and pathfinding, including guidance out of the eye, constraining the general path followed by RGC axons and midline routing at the optic chiasm underlying the establishment of stereovision (1); however, the majority of these molecules induce inhibitory responses in RGC axons. Much less is known about the growth-promoting mechanisms that drive RGC axon extension.Down syndrome cell adhesion molecule 1 (Dscam1) is a homophilic adhesion molecule essential for multiple aspects of neural circuit formation in Drosophila, including axon growth, fasciculation, and pathfinding; dendritic field organization; and synaptic specificity and targeting (2, 3). Although vertebrate Dscam lacks the extensive alternative splicing of fly Dscam1, it is required for many of the same developmental processes, including dendritic arborization and synaptic lamination and refinement (4).Dscam is expressed by mouse RGCs from E12.5 (5) and, through regulation of cell deat...
Absence of the developing lens results in severe eye defects, including substantial reductions in eye size. How the lens controls eye expansion and the underlying signalling pathways are very poorly defined. We identified RDH10, a gene crucial for retinoic acid synthesis during embryogenesis, as a key factor downregulated in the peripheral retina (presumptive ciliary body region) of lens-removed embryonic chicken eyes prior to overt reductions in eye size. This is associated with a significant decrease in retinoic acid synthesis by lens-removed eyes. Restoring retinoic acid signalling in lens-removed eyes by implanting beads soaked in retinoic acid or retinal, but not vitamin A, rescued eye size. Conversely, blocking retinoic acid synthesis decreased eye size in lens-containing eyes. Production of collagen II and collagen IX, which are major vitreal proteins, is also regulated by the lens and retinoic acid signalling. These data mechanistically link the known roles of both the lens and retinoic acid in normal eye development, and support a model whereby retinoic acid production by the peripheral retina acts downstream of the lens to support vitreous production and eye expansion.
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