Oxidative Stress-Induced Axon Fragmentation Is a Consequence of Reduced Axonal Transport in Hereditary Spastic Paraplegia SPAST Patient Neurons

Gautam Wali,Carolyn M Sue,Ratneswary Sutharsan,Jin-Sung Park,Nicholas F Blair,Erandhi Liyanage,Alan Mackay-Sim

doi:10.3389/fnins.2020.00401

Abstract

Hereditary spastic paraplegia (HSP) is a group of inherited disorders characterized by progressive spasticity and paralysis of the lower limbs. Autosomal dominant mutations in SPAST gene account for ∼40% of adult-onset patients. We have previously shown that SPAST patient cells have reduced organelle transport and are therefore more sensitive to oxidative stress. To test whether these effects are present in neuronal cells, we first generated 11 induced pluripotent stem (iPS) cell lines from fibroblasts of three healthy controls and three HSP patients with different SPAST mutations. These cells were differentiated into FOXG1-positive forebrain neurons and then evaluated for multiple aspects of axonal transport and fragmentation. Patient neurons exhibited reduced levels of SPAST encoded spastin, as well as a range of axonal deficits, including reduced levels of stabilized microtubules, lower peroxisome transport speed as a consequence of reduced microtubule-dependent transport, reduced number of peroxisomes, and higher density of axon swellings. Patient axons fragmented significantly more than controls following hydrogen peroxide exposure, suggesting for the first time that the SPAST patient axons are more sensitive than controls to the deleterious effects of oxidative stress. Treatment of patient neurons with tubulin-binding drugs epothilone D and noscapine rescued axon peroxisome transport and protected them against axon fragmentation induced by oxidative stress, showing that SPAST patient axons are vulnerable to oxidative stress-induced degeneration as a consequence of reduced axonal transport.

Highlights

Hereditary spastic paraplegia (HSP) is an inherited neurological disorder that predominantly affects the corticospinal tracts, leading to lower limb weakness, spasticity, and paralysis (Salinas et al, 2008)
Glutamatergic neurons differentiated from induced pluripotent stem (iPS) cells from two patients with the same non-sense mutation in the SPAST gene (c.1684C > T) (p.R562X), had fewer axon mitochondria moving in retrograde compared to controls (Havlicek et al, 2014)
To determine whether the tubulin-binding drugs could rescue axon degeneration induced by oxidative stress, patient cells were treated with 2 nM epothilone D or 10 μM noscapine for 24 h prior to H2O2 treatment and degeneration index (DI) was measured

Summary

INTRODUCTION

Hereditary spastic paraplegia (HSP) is an inherited neurological disorder that predominantly affects the corticospinal tracts, leading to lower limb weakness, spasticity, and paralysis (Salinas et al, 2008). Glutamatergic neurons differentiated from iPS cells from two patients with the same non-sense mutation in the SPAST gene (c.1684C > T) (p.R562X), had fewer axon mitochondria moving in retrograde compared to controls (Havlicek et al, 2014). To test if these deficits are present in neurons and measure the impact the deficits have on neuronal function, we first generated six iPS cell lines from three SPAST patients and five iPS cell lines from three healthy controls. We show that two tubulin-binding drugs, epothilone D and noscapine, can rescue microtubule-dependent peroxisome axon transport in patient axons and protect them against the effects of oxidative stress This represents a significant step toward the development of effective treatments for SPAST-related HSP

Participants

RESULTS

DISCUSSION