Project 2: Eph Signaling in Embryonic Motor Neurons Several recent studies have shown that ephrin-A - EphA 'forward' and'reverse' signaling are involvedin controlling motor neuron axon navigation during embryonic development. This grant is directed atunderstanding the mechanisms that control how and where ephrin-A - EphA signaling occurs, in order tounderstand how spinal locomotor circuitry is formed. Cellular and developmental studies of motor neuronshave revealed the inductive interactions that trigger their differentiation, the cellular interactions that controltheir axonal projections, the trophic interactions that support their survival, and the post synaptic interactionsthat lead to maturation of their synapses. The signaling pathways that actually guide motor neuron axons totheir appropriate targets, however, remain poorly defined. During vertebrate development motor neuron subtypes are generated that exhibit distinct cell migrationpatterns and specific preferences for axon pathways. In this grant we propose to examine how a well definedfamily of axon guidance molecules, the EphAs-ephrinAs, are used in sophisticated temporal and spatialways to control the axonal navigation of multiple classes of motor neurons. Genetic studies indicate thatEphA4 is used at multiple choice points for motor neuron pathfinding. This appears to be based on a precisespatial localization of EphA4 protein along the proximo-distal axis of specific motor neuron subtypes.
In Aim1 we will investigate whether this localization is mediated by RNAtransport and selective translation, proteindegradation, and/or temporal regulation of transcription.
In Aim 2 we will examine the mechanisms thatcontrol EphA4 expression in motor neurons by investigating a possible connection between the Lim1 (Lhx1)LIM-HD transcription factor and neuronal activity.
In Aim 3 we examine how EphA proteins can function asligands to reverse signal through ephrin-As expressed by motor neurons, focusing on p75NTR as a possiblecoreceptor. More generally, these studies should provide a better understanding of how a limited number ofguidance molecules can be used in diverse ways to wire the CMS.These findings should help to developinnovative methods for restoring motor function lost due to injury or disease.
| Zhang, Jingming; Lanuza, Guillermo M; Britz, Olivier et al. (2014) V1 and v2b interneurons secure the alternating flexor-extensor motor activity mice require for limbed locomotion. Neuron 82:138-50 |
| Borowska, Joanna; Jones, Christopher T; Zhang, Han et al. (2013) Functional subpopulations of V3 interneurons in the mature mouse spinal cord. J Neurosci 33:18553-65 |
| Bonanomi, Dario; Chivatakarn, Onanong; Bai, Ge et al. (2012) Ret is a multifunctional coreceptor that integrates diffusible- and contact-axon guidance signals. Cell 148:568-82 |
| Levine, Ariel J; Lewallen, Kathryn A; Pfaff, Samuel L (2012) Spatial organization of cortical and spinal neurons controlling motor behavior. Curr Opin Neurobiol 22:812-21 |
| Wang, Biao; Moya, Noel; Niessen, Sherry et al. (2011) A hormone-dependent module regulating energy balance. Cell 145:596-606 |
| Bevins, Nicholas; Lemke, Greg; Reber, Michael (2011) Genetic dissection of EphA receptor signaling dynamics during retinotopic mapping. J Neurosci 31:10302-10 |
| Alaynick, William A; Jessell, Thomas M; Pfaff, Samuel L (2011) SnapShot: spinal cord development. Cell 146:178-178.e1 |
| Bai, Ge; Chivatakarn, Onanong; Bonanomi, Dario et al. (2011) Presenilin-dependent receptor processing is required for axon guidance. Cell 144:106-18 |
| Grossmann, Katja S; Giraudin, Aurore; Britz, Olivier et al. (2010) Genetic dissection of rhythmic motor networks in mice. Prog Brain Res 187:19-37 |
| Garcia-Campmany, Lidia; Stam, Floor J; Goulding, Martyn (2010) From circuits to behaviour: motor networks in vertebrates. Curr Opin Neurobiol 20:116-25 |
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