Bone morphogenetic proteins, eye patterning, and retinocollicular map formation in the mouse.

Patterning events during early eye formation determine retinal cell fate and can dictate the behavior of retinal ganglion cell (RGC) axons as they navigate toward central brain targets. The temporally and spatially regulated expression of bone morphogenetic proteins (BMPs) and their receptors in the retina are thought to play a key role in this process, initiating gene expression cascades that distinguish different regions of the retina, particularly along the dorsoventral axis. Here, we examine the role of BMP and a potential downstream effector, EphB, in retinotopic map formation in the lateral geniculate nucleus (LGN) and superior colliculus (SC). RGC axon behaviors during retinotopic map formation in wild-type mice are compared with those in several strains of mice with engineered defects of BMP and EphB signaling. Normal RGC axon sorting produces axon order in the optic tract that reflects the dorsoventral position of the parent RGCs in the eye. A dramatic consequence of disrupting BMP signaling is a missorting of RGC axons as they exit the optic chiasm. This sorting is not dependent on EphB. When BMP signaling in the developing eye is genetically modified, RGC order in the optic tract and targeting in the LGN and SC are correspondingly disrupted. These experiments show that BMP signaling regulates dorsoventral RGC cell fate, RGC axon behavior in the ascending optic tract, and retinotopic map formation in the LGN and SC through mechanisms that are in part distinct from EphB signaling in the LGN and SC.

Pretarget sorting of retinocollicular axons in the mouse.

The map of the retina onto the optic tectum is a highly conserved feature of the vertebrate visual system; the mechanism by which this mapping is accomplished during development is a long-standing problem of neurobiology. The early suggestion by Roger Sperry that the map is formed through interactions between retinal ganglion cell axons and target cells within the tectum has gained significant experimental support and widespread acceptance. Nonetheless, reports in a variety of species indicate that some aspects of retinotopic order exist within the optic tract, leading to the suggestion that this "preordering" of retinal axons may play a role in the formation of the mature tectal map. A satisfactory account of pretarget order must provide the mechanism by which such axon order develops. Insofar as this mechanism must ultimately be determined genetically, the mouse suggests itself as the natural species in which to pursue these studies. Quantitative and repeatable methods are required to assess the contribution of candidate genes in mouse models. For these reasons, we have undertaken a quantitative study of the degree of retinotopic order within the optic tract and nerve of wild-type mice both before and after the development of the retinotectal map. Our methods are based on tract tracing using lipophilic dyes, and our results indicate that there is a reestablishment of dorsoventral but not nasotemporal retinal order when the axons pass through the chiasm and that this order is maintained throughout the subsequent tract. Furthermore, this dorsoventral retinotopic order is well established by the day after birth, long before the final target zone is discernible within the tectum. We conclude that pretarget sorting of axons according to origin along the dorsoventral axis of the retina is both spatially and chronologically appropriate to contribute to the formation of the retinotectal map, and we suggest that these methods be used to search for the molecular basis of such order by using available mouse genetic models.