microRNA-9 regulates axon extension and branching by targeting Map1b in mouse cortical neurons
Nature neuroscience, 2012•nature.com
The capacity of neurons to develop a long axon and multiple dendrites defines neuron
connectivity in the CNS. The highly conserved microRNA-9 (miR-9) is expressed in both
neuronal precursors and some post-mitotic neurons, and we detected miR-9 expression in
the axons of primary cortical neurons. We found that miR-9 controlled axonal extension and
branching by regulating the levels of Map1b, an important protein for microtubule stability.
Following microfluidic separation of the axon and the soma, we found that miR-9 repressed …
connectivity in the CNS. The highly conserved microRNA-9 (miR-9) is expressed in both
neuronal precursors and some post-mitotic neurons, and we detected miR-9 expression in
the axons of primary cortical neurons. We found that miR-9 controlled axonal extension and
branching by regulating the levels of Map1b, an important protein for microtubule stability.
Following microfluidic separation of the axon and the soma, we found that miR-9 repressed …
Abstract
The capacity of neurons to develop a long axon and multiple dendrites defines neuron connectivity in the CNS. The highly conserved microRNA-9 (miR-9) is expressed in both neuronal precursors and some post-mitotic neurons, and we detected miR-9 expression in the axons of primary cortical neurons. We found that miR-9 controlled axonal extension and branching by regulating the levels of Map1b, an important protein for microtubule stability. Following microfluidic separation of the axon and the soma, we found that miR-9 repressed Map1b translation and was a functional target for the BDNF-dependent control of axon extension and branching. We propose that miR-9 links regulatory signaling processes with dynamic translation mechanisms, controlling Map1b protein levels and axon development.
nature.com