A study published recently in eNeuro clarifies the mechanisms underlying neural dysfunction in ALS, and also suggests a novel approach to restoring the health of motor neurons in patients with the disease.
The study was conducted by Yuyu Song of Harvard Medical School. She was a Grass Fellow at the Marine Biological Laboratory (MBL), Woods Hole when she took advantage of a powerful research organism in neuroscience, the local squid, to start asking how a mutant protein associated with familial ALS behaves under controlled conditions.
Song focused on how this mutant protein, called G85R-SOD1, affects neurotransmission at the squid “giant synapse,” the junction where neurons transmit chemical signals to muscle fibers, causing the muscle to contract.
The squid giant synapse is one of the few mature nervous systems that mimics human neuromuscular junctions, while allowing precise experimental manipulations and live measurements.
Song showed that the presence of misfolded mutant SOD1 inhibits synaptic transmission and diminishes the pool of synaptic vesicles, whose job is to deliver neurotransmitters critical for neuronal connections.
Surprisingly, synaptic function was restored by intermittent, high-frequency stimulation, which suggested aberrant calcium signaling may underlie SOD1 toxicity to normal synaptic transmission, a media release from Marine Biological Laboratory suggests.
To test this hypothesis, Song used calcium imaging to capture the abnormal calcium influx in the presynaptic terminal and confirmed the protective role of a calcium chelator, which corrected the calcium imbalance without affecting neurotransmission.
This suggests a new approach to therapeutic intervention for ALS, in which chemical or electrical regulation of calcium and its downstream signaling pathways may restore the health of motor neurons.
“Altogether, our results not only demonstrated synaptic dysfunction related to ALS and its underlying molecular pathways, but also extended our understanding of fundamental synaptic physiology,” Song says, in the release.
[Source(s): Marine Biological Laboratory, Science Daily]