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Aberrant regulation of a poison exon caused by a non-coding variant in a mouse model of Scn1a-associated epileptic encephalopathy
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Aberrant regulation of a poison exon caused by a non-coding variant in a mouse model of Scn1a-associated epileptic encephalopathy
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Aberrant regulation of a poison exon caused by a non-coding variant in a mouse model of Scn1a-associated epileptic encephalopathy
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Journal Article
Aberrant regulation of a poison exon caused by a non-coding variant in a mouse model of Scn1a-associated epileptic encephalopathy
2021
Overview
Dravet syndrome (DS) is a developmental and epileptic encephalopathy that results from mutations in the Na
v
1.1 sodium channel encoded by
SCN1A
. Most known DS-causing mutations are in coding regions of
SCN1A
, but we recently identified several disease-associated
SCN1A
mutations in intron 20 that are within or near to a cryptic and evolutionarily conserved “poison” exon, 20N, whose inclusion is predicted to lead to transcript degradation. However, it is not clear how these intron 20 variants alter
SCN1A
expression or DS pathophysiology in an organismal context, nor is it clear how exon 20N is regulated in a tissue-specific and developmental context. We address those questions here by generating an animal model of our index case, NM_006920.4(SCN1A):c.3969+2451G>C, using gene editing to create the orthologous mutation in laboratory mice.
Scn1a
heterozygous knock-in (+/
KI
) mice exhibited an ~50% reduction in brain
Scn1a
mRNA and Na
v
1.1 protein levels, together with characteristics observed in other DS mouse models, including premature mortality, seizures, and hyperactivity. In brain tissue from adult
Scn1a
+/+ animals, quantitative RT-PCR assays indicated that ~1% of
Scn1a
mRNA included exon 20N, while brain tissue from
Scn1a +/KI
mice exhibited an ~5-fold increase in the extent of exon 20N inclusion. We investigated the extent of exon 20N inclusion in brain during normal fetal development in RNA-seq data and discovered that levels of inclusion were ~70% at E14.5, declining progressively to ~10% postnatally. A similar pattern exists for the homologous sodium channel Na
v
1.6, encoded by
Scn8a
. For both genes, there is an inverse relationship between the level of functional transcript and the extent of poison exon inclusion. Taken together, our findings suggest that poison exon usage by
Scn1a
and
Scn8a
is a strategy to regulate channel expression during normal brain development, and that mutations recapitulating a fetal-like pattern of splicing cause reduced channel expression and epileptic encephalopathy.
Publisher
Public Library of Science,Public Library of Science (PLoS)
Subject
/ Control
/ Epilepsies, Myoclonic - genetics
/ Epilepsies, Myoclonic - pathology
/ Gene Expression Regulation - genetics
/ Humans
/ Medicine and Health Sciences
/ Mice
/ NAV1.1 Voltage-Gated Sodium Channel - genetics
/ NAV1.6 Voltage-Gated Sodium Channel - genetics
/ Organ Specificity - genetics
/ Research and Analysis Methods
/ RNA-Seq
