Abstract
Neuronal injury leads to rapid, programmed disintegration of axons distal to the site of lesion. Much like other forms of axon degeneration (e.g. developmental pruning, toxic insult from neurodegenerative disorder), Wallerian degeneration associated with injury is preceded by spheroid formation along axons. The mechanisms by which injury leads to formation of spheroids and whether these spheroids have a functional role in degeneration remain elusive. Here, using neonatal mouse primary sympathetic neurons, we investigate the roles of players previously implicated in the progression of Wallerian degeneration in injury-induced spheroid formation. We find that intra-axonal calcium flux is accompanied by actin-Rho dependent growth of calcium rich axonal spheroids that eventually rupture, releasing material to the extracellular space prior to catastrophic axon degeneration. Importantly, after injury, Sarm1−/− and DR6−/−, but not Wlds (excess NAD+) neurons, are capable of forming spheroids that eventually rupture, releasing their contents to the extracellular space to promote degeneration. Supplementation of exogenous NAD+ or expressing WLDs suppresses Rho-dependent spheroid formation and degeneration in response to injury. Moreover, injured or trophically deprived Sarm1−/− and DR6−/−, but not Wlds neurons, are resistant to degeneration induced by conditioned media collected from wild-type axons after spheroid rupture. Taken together, these findings place Rho-actin and NAD+ upstream of spheroid formation and may suggest that other mediators of degeneration, such as DR6 and SARM1, mediate post-spheroid rupture events that lead to catastrophic axon disassembly.
Highlights
Neuronal injury leads to rapid, programmed disintegration of axons distal to the site of lesion
Cell bodies of sympathetic neurons were enucleated by aspiration of the cell body chamber in phosphate buffered saline (PBS), which leaves axons residing in the distal axon chamber and microgrooves intact
Among three Wallerian degeneration (WD) deficient mutants, only Wlds suppresses spheroid formation, suggesting that depletion of axonal NMNAT/NAD+ acts upstream of spheroid formation during the latent phase, whereas SARM1 and death receptor 6 (DR6) activation might promote degeneration during catastrophic phase (Fig. 7). This is somewhat surprising given that the mechanism of SARM1 action is thought to be through NAD+ degradation[23,24]. This sets up a scenario whereby N Alzheimer’s disease (AD)+ may be acting at different points in the degeneration timeline after injury
Summary
Neuronal injury leads to rapid, programmed disintegration of axons distal to the site of lesion. Injured or trophically deprived Sarm1−/− and DR6−/−, but not Wlds neurons, are resistant to degeneration induced by conditioned media collected from wild-type axons after spheroid rupture Taken together, these findings place Rho-actin and NAD+ upstream of spheroid formation and may suggest that other mediators of degeneration, such as DR6 and SARM1, mediate post-spheroid rupture events that lead to catastrophic axon disassembly. In addition to calcium flux, severed axons display cessation of axonal transport, formation of axonal swellings called spheroids, fragmentation of neurofilaments and removal of debris by recruited phagocytes This rapid and near synchronous axonal disintegration period is called the catastrophic/execution phase of degeneration and can be observed in developmental and other pathological regressive contexts[11,12,13]. Whether Rho regulates WD through mechanisms similar to developmental degeneration requires further investigation
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