Image of a worm lacking mitochondria (magenta) in its axons (green), which causes degeneration, leaving a gap between the axons and the nerve ring in the worm’s head (bottom left). Image credit: Chen Ding (CC BY 4.0)
Within the cell are various compartments that carry out specific roles. This includes the mitochondria, which are responsible for generating the chemical energy that powers the cell. Some of the most power-hungry cells are nerve cells, which have long, slender projections called axons that relay signals from one part of the nervous system to another. If the mitochondria do not work properly, the axons break down which can lead to neurodegenerative diseases, such as Alzheimer’s and Parkinson’s disease.
Previous studies showed that defects in how mitochondria are transported cause axons in the roundworm Caenorhabditis elegans to spontaneously deteriorate with age. These transparent worms are often used to study biological questions related to the nervous system. Here, Ding et al. have used this model organism to identify a molecular pathway that stops axons from degenerating.
Random mutations were introduced into the genome of C. elegans that are unable to transport mitochondria in to their axons. Ding et al. then searched for mutant strains that still had intact axons despite this mitochondrial defect. This revealed that mutations that activate a protein called CaMKII stop axons from breaking down. Further experiments showed that CAMKII does this by switching on a series of signals, including the protein Sarm1, that eventually turn on another protein that suppresses degeneration.
The protective role of Sarm1 is surprising given that this protein has been shown to promote axon degeneration after injury in flies and mammals. This suggests that the gene for Sarm1 as well as others likely play different roles depending on the context in which they are activated.
These findings could help researchers identify new drug targets and strategies for treating neurodegenerative diseases caused by mitochondrial defects. However, further work is needed to see if this newly discovered pathway works the same way in other model systems, such as flies and mammals.
