Abstract
Missense mutations in the human TUBB3 gene cause a variety of neurological disorders associated with defects in axon guidance and neuronal migration, but the underlying molecular mechanisms are not well understood. Recent studies have shown that direct coupling of dynamic TUBB3 in microtubules with netrin receptors is required for netrin-1-mediated axon guidance, and the interaction of netrin-1 repulsive receptor UNC5C with TUBB3 is involved in netrin-1 mediated axonal repulsion. Here, we report that TUBB3 mutations perturb netrin-1/UNC5C repulsive signaling in the developing nervous system. Among twelve mutants reported in previous studies, five of them show significantly reduced interaction with UNC5C in comparison to the wild-type TUBB3. TUBB3 mutants R262C and R62Q exhibit decreased subcellular colocalization with UNC5C in the peripheral area of the growth cone of primary mouse neurons. Netrin-1 reduces the colocalization of UNC5C with wild-type TUBB3, but not TUBB3 mutants R262C or R62Q, in the growth cone. Results from the in vitro cosedimentation assay indicate that netrin-1 inhibits cosedimentation of UNC5C with polymerized microtubules in primary mouse neurons expressing the wild-type TUBB3, but not R262C or R62Q. Expression of either R262C or R62Q not only blocks netrin-1-induced growth cone collapse and axonal repulsion of primary EGL cells in vitro, but also results in axon projections defects of chicken dorsal root ganglion neurons in ovo. Our study reveals that human TUBB3 mutations specifically perturb netrin-1/UNC5C-mediated repulsion.
Highlights
Microtubules are polarized hollow structure assembled by guanosine triphosphate (GTP)dependent polymerization of α/β tubulin heterodimers
Recent genetic and functional studies have shown that missense mutations in the Tubulin Beta-III (TUBB3) gene disturb microtubule dynamics, impair kinesin interactions, and cause various neurological disorders characterized by defects in axon guidance and neuronal migration that include agenesis or hypoplasia of anterior commissure (AC), corpus callosum (CC), corticospinal tracts, and cranial nerves as well as malformations of cortical development (MCD) associated with neuronal migration and differentiation abnormalities [16, 17]
Mutations in the tubulin genes perturb microtubule dynamics and result in a broad spectrum of brain malformations associated with axon guidance and neuronal migration defects [6, 14]
Summary
Microtubules are polarized hollow structure assembled by guanosine triphosphate (GTP)dependent polymerization of α/β tubulin heterodimers. Recent genetic and functional studies have shown that missense mutations in the TUBB3 gene disturb microtubule dynamics, impair kinesin interactions, and cause various neurological disorders characterized by defects in axon guidance and neuronal migration that include agenesis or hypoplasia of anterior commissure (AC), corpus callosum (CC), corticospinal tracts, and cranial nerves as well as malformations of cortical development (MCD) associated with neuronal migration and differentiation abnormalities [16, 17]. These findings demonstrate that TUBB3 is involved in axon guidance during brain development, but the underlying molecular mechanisms are not well characterized
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