Abstract

Permanent loss of vital functions after central nervous system (CNS) injury, e.g., blindness in traumatic optic nerve (ON) injury or paralysis in spinal cord injury, occurs in part because axons in the adult mammalian CNS do not regenerate after injury. Growth failure is due to the diminished intrinsic regenerative capacity of mature neurons and the inhibitory environment of the adult CNS. Neutralizing extracellular inhibitory molecules genetically or pharmacologically yields only limited regeneration and functional recovery, highlighting the critical importance of neuron-intrinsic factors. To explore the intrinsic regenerative signaling molecules, a relatively simple but robust in vivo model that replicates CNS traumatic injury and permits straightforward interpretation is required. Mouse retinal ganglion cell (RGC) and ON provide a valuable in vivo neural injury system to study intrinsic growth mechanisms in adult CNS neurons (Figure 1). Retina and ON are CNS structures that are essential for visual functions. RGC is the only neuronal type to relay visual information from retina to brain. The ON is formed by the projection axons sent exclusively from RGCs; it has the simplicity of a unidirectional axon pathway, which insures that any nerve fibers observed distal to a complete crush injury have regenerated and do not represent spared axons that underwent collateral sprouting or efferent axons from the brain to the retina. Its easy access allows adeno-associated viruses to be injected directly into the vitreous chamber of the eye and express transgenes specifically and efficiently in adult RGCs. This spatially and temporally controlled genetic manipulation allows us to overcome developmental issues associated with germ line manipulation and to test interventions that can potentially be translated to therapies. Exploiting the anatomical and technical advantages of the RGC/ON crush model to understand the intrinsic mechanisms of regenerative failure led us to the finding that deletion of phosphatase and tensin homolog (PTEN) promoted significant ON regeneration (Park et al., 2008). PTEN, a lipid phosphatase, is a major negative regulator of the phosphatidylinositol 3-kinase (PI3K)-mammalian target of rapamycin complex 1 (mTORC1) pathway. Similar axon regeneration phenotypes after PTEN deletion have been reported for mouse cortical motor neurons (Liu et al., 2010), drosophila sensory neurons (Song et al., 2012) and C. elegans motor neurons (Byrne et al., 2014), presumably through activating PI3K-mTORC1-controlled cell growth (Figure 2). Direct activation of mTORC1 also promotes axon regeneration in dopaminergic neurons (Kim et al., 2011) and peripheral nerves (Abe et al., 2010), further support for the critical role of mTORC1 in axon regeneration.

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