Ephrin/Eph ligands and receptors are best known for their prominent role in topographic mapping of neural connectivity. Despite the large amount of work centered on ephrin/Eph-dependent signaling pathways in various cellular contexts, the molecular mechanisms of action of Eph receptors in neural mapping, requiring dynamic interactions between complementary gradients of ephrins and Eph receptors, remain largely unknown. Here, we investigated in vivo the signaling mechanisms of neural mapping mediated by the EphA4 receptor, previously shown to control topographic specificity of thalamocortical axons in the mouse somatosensory system. Using axon tracing analyses of knock-in mouse lines displaying selective mutations for the Epha4 gene, we determined for the first time which intracellular domains of an Eph receptor are required for topographic mapping. We provide direct in vivo evidence that the tyrosine kinase domain of EphA4, as well as a tight regulation of its activity, are required for topographic mapping of thalamocortical axons, whereas non-catalytic functional modules, such as the PDZ-binding motif (PBM) and the Sterile-␣ motif (SAM) domain, are dispensable. These data provide a novel insight into the molecular mechanisms of topographic mapping, and constitute a physiological framework for the dissection of the downstream signaling cascades involved. Development 133, 4415-4420 (2006) DEVELOPMENT 4416 is conceivable that distinct ephrin/Eph signaling mechanisms may be used specifically to achieve topographic mapping, but nothing is known about these.
KEY WORDS: Topographic mapping, Ephrin, Eph, ThalamocorticalWe have previously shown that EphA4, which is expressed in a graded fashion in the somatosensory thalamic ventrobasal nucleus (VB), is required to generate proper topography of TC axons within the somatosensory cortex S1, which expresses a complementary gradient of ephrin A5 (Dufour et al., 2003). The somatosensory TC system thus constitutes an attractive system of topographic mapping that is dependent upon EphA4 signaling.To try to gain insight into the signaling mechanisms of Ephdependent mapping, we analyzed EphA4-dependent TC mapping in several mouse knock-in lines displaying distinct targeted mutations for EphA4 (Egea et al., 2005; Grunwald et al., 2004; Kullander et al., 2001). This set of mouse models had previously enabled the demonstration of distinct signaling mechanisms involved in EphA4-dependent midline pathfinding (Kullander et al., 2001), and suggested a differential requirement of EphA4 kinase regulation for repulsion at the midline and TC mapping (Egea et al., 2005). Here, we extended the analysis of TC mapping to all EphA4 alleles available and determined for the first time which intracellular domains of an Eph receptor are required for topographic mapping in vivo. We provide direct in vivo evidence that the tyrosine kinase domain of EphA4, as well as dynamic regulation of its activity, are required for the mapping of TC axons, whereas noncatalytic modules, such as the PBM and the SAM...
