KIF5A downregulation in spinal muscular atrophy links axonal regeneration defects with ALS
Tetsuya Akiyama, Yi Zeng, Caiwei Guo, Olivia Gautier, Lauren Koepke, Heankel Lyons, Elana Molotsky, Juliane S. Bombosch, Odilia Sianto, Jay P. Ross, Phuong Hoang, Luke Zhao, Cole Spencer, Charlotte J. Sumner, Michelle Monje, John W. Day, Aaron D. Gitler
Tetsuya Akiyama, Yi Zeng, Caiwei Guo, Olivia Gautier, Lauren Koepke, Heankel Lyons, Elana Molotsky, Juliane S. Bombosch, Odilia Sianto, Jay P. Ross, Phuong Hoang, Luke Zhao, Cole Spencer, Charlotte J. Sumner, Michelle Monje, John W. Day, Aaron D. Gitler
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Research Article Genetics Neuroscience

KIF5A downregulation in spinal muscular atrophy links axonal regeneration defects with ALS

Abstract

Spinal muscular atrophy (SMA) is a devastating neuromuscular disorder caused by mutations in the survival motor neuron 1 (SMN1) gene leading to decreased SMN protein levels and motor neuron dysfunction. SMN-restoring therapies offer clinical benefit, but the downstream molecular consequences of SMN reduction remain incompletely understood. SMN deficiency resulted in downregulation of kinesin heavy chain isoform 5A (KIF5A) in human neurons and in a mouse model of SMA. SMN associated with KIF5A mRNA and contributed to its stability. Reduced SMN levels impaired axon regeneration, which was rescued by KIF5A overexpression. Because KIF5A has also been connected to ALS, these findings provide evidence of a molecular link between SMA and ALS pathophysiology, highlighting KIF5A as an SMN-regulated factor. Our findings suggest that SMN-independent interventions targeting KIF5A could represent a complementary therapeutic approach for SMA and other motor neuron diseases.

Authors

Tetsuya Akiyama, Yi Zeng, Caiwei Guo, Olivia Gautier, Lauren Koepke, Heankel Lyons, Elana Molotsky, Juliane S. Bombosch, Odilia Sianto, Jay P. Ross, Phuong Hoang, Luke Zhao, Cole Spencer, Charlotte J. Sumner, Michelle Monje, John W. Day, Aaron D. Gitler

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Figure 4

KIF5A overexpression rescues axonal regeneration defects in SMN-deficient neurons.

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KIF5A overexpression rescues axonal regeneration defects in SMN-deficien...
(A) Experimental timeline and schema: i3Ns underwent SMN-KD for 12 days, followed by axonal transection using a microfluidic device. To overexpress KIF5A in SMN-deficient neurons, cells were infected with lentivirus expressing KIF5A 2 days after initiating SMN-KD. Axonal regeneration was assessed by live-cell imaging at 24 and 48 hours after transection on microfluidic device (XC-450, Xona Microfluidics). (B) Representative live-cell images before and after axonal transection. Axons extend from the cell body compartment (left) into the axonal compartment (right). The length of each microchannel is 450 μm. (C) Quantification of regenerating axons per microfluidic channel. Data represent the average number of regenerating axons per channel, normalized to control conditions (n = 3 images per condition from 2 independent experiments; 17–20 channels per image; >100 channels total). Statistical analysis was performed using 1-way ANOVA followed by Tukey’s multiple comparisons test.