Premium
Microtubule‐dependent processes precede pathological calcium influx in excitotoxin‐induced axon degeneration
Author(s) -
Tian Nan,
Hanson Kelsey A.,
Canty Alison J.,
Vickers James C.,
King Anna E.
Publication year - 2020
Publication title -
journal of neurochemistry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.75
H-Index - 229
eISSN - 1471-4159
pISSN - 0022-3042
DOI - 10.1111/jnc.14909
Subject(s) - axon , kainic acid , excitotoxicity , calcium , neuroscience , biology , calcium in biology , microbiology and biotechnology , wallerian degeneration , neuron , microtubule , chemistry , programmed cell death , intracellular , biochemistry , glutamate receptor , apoptosis , receptor , organic chemistry
Abstract Axon degeneration and axonal loss is a feature of neurodegenerative disease and injury and occurs via programmed pathways that are distinct from cell death pathways. While the pathways of axonal loss following axon severing are well described, less is known about axonal loss following other neurodegenerative insults. Here we use primary mouse cortical neuron cultures grown in compartmentalized chambers to investigate the role of calcium in the degeneration of axons that occurs following a somal insult by the excitotoxin kainic acid. Calcium influx has been implicated in both excitotoxicity and axon degeneration mechanisms, however the link between a somal insult and axonal calcium increase is unclear. Live imaging of axons demonstrated that pharmacologically preventing intracellular calcium increases through the endoplasmic reticulum or mitochondria significantly ( p < 0.05) reduced axon degeneration. Live calcium‐imaging with the Ca 2+ indicator Fluo‐4 demonstrated that kainic acid exposure to the soma resulted in a rapid, and transient, increase in calcium in the axon, which occured even at low kainic acid concentrations that do not cause axon degeneration within 24 h. However, this calcium transient was followed by a gradual increase in axonal calcium, which was associated with axonal loss. Furthermore, treatment with a range of doses of the microtubule stabilizing drug taxol, which protects against axon fragmentation in this model, prevented this gradual calcium increase, suggesting that the intra‐axonal calcium changes are downstream of microtubule associated events. Biochemical analysis of taxol treated neurons demonstrated a shift in microtubule post‐translational modifications, with a significant ( p < 0.05) increase in acetylated tubulin and a significant ( p < 0.05) decrease in tyrosinated tubulin, suggestive of a more stable microtubule pool. Together our results suggest that axonal degeneration following excitotoxicity is dependent on an increase in axonal calcium, which is downstream of a microtubule‐dependent event.