The perils of navigating activity-dependent alternative splicing of neurexins
The perils of navigating activity-dependent alternative splicing of neurexins
Neurexins are presynaptic cell-adhesion molecules essential for synaptic function that are expressed in thousands of alternatively spliced isoforms. Recent studies suggested that alternative splicing at splice site 4 (SS4) of Nrxn1 is tightly regulated by an activity-dependent mechanism. Given that Nrxn1 alternative splicing at SS4 controls NMDA-receptor-mediated synaptic responses, activity-dependent SS4 alternative splicing would suggest a new synaptic plasticity mechanism. However, conflicting results confound the assessment of neurexin alternative splicing, prompting us to re-evaluate this issue. We find that in cortical cultures, membrane depolarization by elevated extracellular K+-concentrations produced an apparent shift in Nrxn1-SS4 alternative splicing by inducing neuronal but not astroglial cell death, resulting in persistent astroglial Nrxn1-SS4+ expression and decreased neuronal Nrxn1-SS4- expression. in vivo, systemic kainate-induced activation of neurons in the hippocampus produced no changes in Nrxn1-SS4 alternative splicing. Moreover, focal kainate injections into the mouse cerebellum induced small changes in Nrxn1-SS4 alternative splicing that, however, were associated with large decreases in Nrxn1 expression and widespread DNA damage. Our results suggest that although Nrxn1-SS4 alternative splicing may represent a mechanism of activity-dependent synaptic plasticity, common procedures for testing this hypothesis are prone to artifacts, and more sophisticated approaches will be necessary to test this important question.
Liakath-Ali, Kif
8d5a020c-e976-4901-9195-68f4bc0de74e
Südhof, Thomas C.
172ec4da-ad42-4b1f-bd99-6b7d288e040c
9 March 2021
Liakath-Ali, Kif
8d5a020c-e976-4901-9195-68f4bc0de74e
Südhof, Thomas C.
172ec4da-ad42-4b1f-bd99-6b7d288e040c
Liakath-Ali, Kif and Südhof, Thomas C.
(2021)
The perils of navigating activity-dependent alternative splicing of neurexins.
Frontiers in Molecular Neuroscience, 14, [659681].
(doi:10.3389/fnmol.2021.659681).
Abstract
Neurexins are presynaptic cell-adhesion molecules essential for synaptic function that are expressed in thousands of alternatively spliced isoforms. Recent studies suggested that alternative splicing at splice site 4 (SS4) of Nrxn1 is tightly regulated by an activity-dependent mechanism. Given that Nrxn1 alternative splicing at SS4 controls NMDA-receptor-mediated synaptic responses, activity-dependent SS4 alternative splicing would suggest a new synaptic plasticity mechanism. However, conflicting results confound the assessment of neurexin alternative splicing, prompting us to re-evaluate this issue. We find that in cortical cultures, membrane depolarization by elevated extracellular K+-concentrations produced an apparent shift in Nrxn1-SS4 alternative splicing by inducing neuronal but not astroglial cell death, resulting in persistent astroglial Nrxn1-SS4+ expression and decreased neuronal Nrxn1-SS4- expression. in vivo, systemic kainate-induced activation of neurons in the hippocampus produced no changes in Nrxn1-SS4 alternative splicing. Moreover, focal kainate injections into the mouse cerebellum induced small changes in Nrxn1-SS4 alternative splicing that, however, were associated with large decreases in Nrxn1 expression and widespread DNA damage. Our results suggest that although Nrxn1-SS4 alternative splicing may represent a mechanism of activity-dependent synaptic plasticity, common procedures for testing this hypothesis are prone to artifacts, and more sophisticated approaches will be necessary to test this important question.
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fnmol-14-659681
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Published date: 9 March 2021
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Local EPrints ID: 491454
URI: http://eprints.soton.ac.uk/id/eprint/491454
ISSN: 1662-5099
PURE UUID: cbd5a121-b8b6-4b16-9d88-3677b5ff13c2
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Date deposited: 24 Jun 2024 16:51
Last modified: 25 Jun 2024 02:10
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Author:
Kif Liakath-Ali
Author:
Thomas C. Südhof
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