AI Article Synopsis
- Neurodegenerative diseases often progress slowly and have long preclinical phases, but the specific mechanisms of their progression are not well understood.
- In a study of two mouse models of motoneuron disease, researchers found that certain motoneuron axons showed synchronized vulnerability before symptoms emerged, while others were only affected at the onset of symptoms.
- The study reveals that different physiological subtypes of axons exhibit predictable vulnerability patterns, leading to changes like synaptic vesicle stalling, accumulation of protective proteins, and selective pruning of axon branches.
Article Abstract
Neurodegenerative diseases can have long preclinical phases and insidious progression patterns, but the mechanisms of disease progression are poorly understood. Because quantitative accounts of neuronal circuitry affected by disease have been lacking, it has remained unclear whether disease progression reflects processes of stochastic loss or temporally defined selective vulnerabilities of distinct synapses or axons. Here we derive a quantitative topographic map of muscle innervation in the hindlimb. We show that in two mouse models of motoneuron disease (G93A SOD1 and G85R SOD1), axons of fast-fatiguable motoneurons are affected synchronously, long before symptoms appear. Fast-fatigue-resistant motoneuron axons are affected at symptom-onset, whereas axons of slow motoneurons are resistant. Axonal vulnerability leads to synaptic vesicle stalling and accumulation of BC12a1-a, an anti-apoptotic protein. It is alleviated by ciliary neurotrophic factor and triggers proteasome-dependent pruning of peripheral axon branches. Thus, motoneuron disease involves predictable, selective vulnerability patterns by physiological subtypes of axons, episodes of abrupt pruning in the target region and compensation by resistant axons.
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| http://dx.doi.org/10.1038/nn1653 | DOI Listing |
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