Differential splicing choices made by neurons and astrocytes and their importance when investigating signal-dependent alternative splicing in neural cells

Differential splicing choices made by neurons and astrocytes and their importance when investigating signal-dependent alternative splicing in neural cells

A variety of proteins can be encoded by a single gene via the differential splicing of exons. In neurons this form of alternative splicing can be controlled by activity-dependent calcium signaling, leading to the properties of proteins being altered, including ion channels, neurotransmitter receptor...

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Published in:Frontiers in molecular neuroscience Vol. 16; p. 1214439
Main Authors: Baxter, Paul S, Dando, Owen, Hardingham, Giles E
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 03-07-2023
Frontiers Media S.A
Subjects:
Alternative splicing
Apoptosis
astrocyte-specificity
Astrocytes
Calcium signalling
Cell adhesion molecules
Depolarization
Epigenetics
excitotoxicity
Exons
Gene expression
Genomes
Glutamic acid receptors (ionotropic)
Ion channels
Membrane potential
Molecular Neuroscience
N-Methyl-D-aspartic acid receptors
neurexin
Neurons
Neurotoxicity
Neurotransmitter receptors
Receptor mechanisms
alternative splicing
excitotoxicity
astrocyte-specificity
epigenetics
neurexin
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Summary:A variety of proteins can be encoded by a single gene via the differential splicing of exons. In neurons this form of alternative splicing can be controlled by activity-dependent calcium signaling, leading to the properties of proteins being altered, including ion channels, neurotransmitter receptors and synaptic cell adhesion molecules. The pre-synaptic cell adhesion molecule Neurexin 1 ( ) is alternatively spliced at splice-site 4 (SS4) which governs exon 22 inclusion (SS4 ) and consequently postsynaptic NMDA receptor responses. Nrxn1 was reported to be subject to a delayed-onset shift in SS4 splicing resulting in increased exon 22 inclusion, involving epigenetic mechanisms which, if disrupted, reduce memory stability. Exon inclusion at SS4 represented one of hundreds of exons reported to be subject to a genome-wide shift in fractional exon inclusion following membrane depolarization with high extracellular K that was delayed in onset. We report that high K does not increase the SS4 /SS4 ratio in cortical neurons, but does induce a delayed-onset NMDA receptor-dependent neuronal death. In mixed neuronal/astrocyte cultures this neuronal death results in an increase in the astrocyte: neuron ratio, and a misleading increase in SS4 /SS4 ratio attributable to astrocytes having a far higher SS4 /SS4 ratio than neurons, rather than any change in the neurons themselves. We reassessed the previously reported genome-wide delayed-onset shift in fractional exon inclusion after high K exposure. This revealed that the reported changes correlated strongly with differences in exon inclusion level between astrocytes and neurons, and was accompanied by a strong decrease in the ratio of neuron-specific: astrocyte-specific gene expression. As such, these changes can be explained by the neurotoxic nature of the stimulation paradigm, underlining the importance of NMDA receptor blockade when using high K depolarizing stimuli.
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Reviewed by: Jai Polepalli, National University of Singapore, Singapore; Justin Trotter, Stanford University, United States
These authors have contributed equally to this work
Edited by: Kif Liakath-Ali, Stanford University, United States
ISSN:1662-5099
1662-5099
DOI:10.3389/fnmol.2023.1214439