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Reversal of phenotypes in MECP2 duplication mice using genetic rescue or antisense oligonucleotides
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Reversal of phenotypes in MECP2 duplication mice using genetic rescue or antisense oligonucleotides
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Journal Article
Reversal of phenotypes in MECP2 duplication mice using genetic rescue or antisense oligonucleotides
2015
Overview
Genetic correction of MeCP2 levels largely reversed the behavioural, molecular and physiological deficits associated with
MECP2
duplication syndrome in a transgenic mouse model; similarly, reduction of MeCP2 levels using an antisense oligonucleotide strategy resulted in phenotypic rescue in adult transgenic mice, and dose-dependently corrected MeCP2 levels in cells from patients with
MECP2
duplication.
Potential reversal of a developmental disorder
MECP2
duplication syndrome is a childhood disorder caused by duplication of the
MECP2
gene and, consequently, increased MECP2 protein levels. Huda Zoghbi and colleagues report that genetic correction of
MECP2
levels largely reverses the behavioural, molecular and physiological deficits in a transgenic mouse model. Reducing
MECP2
levels using an antisense oligonucleotide (ASO) strategy—which has greater potential for therapeutic application—similarly resulted in phenotypic rescue in adult transgenic mice and dose-dependently corrected
MECP2
levels in cells from patients with
MECP2
duplication. These findings suggest that a disorder caused by copy number variation can be reversed after symptoms have emerged.
Copy number variations have been frequently associated with developmental delay, intellectual disability and autism spectrum disorders
1
.
MECP2
duplication syndrome is one of the most common genomic rearrangements in males
2
and is characterized by autism, intellectual disability, motor dysfunction, anxiety, epilepsy, recurrent respiratory tract infections and early death
3
,
4
,
5
. The broad range of deficits caused by methyl-CpG-binding protein 2 (MeCP2) overexpression poses a daunting challenge to traditional biochemical-pathway-based therapeutic approaches. Accordingly, we sought strategies that directly target MeCP2 and are amenable to translation into clinical therapy. The first question that we addressed was whether the neurological dysfunction is reversible after symptoms set in. Reversal of phenotypes in adult symptomatic mice has been demonstrated in some models of monogenic loss-of-function neurological disorders
6
,
7
,
8
, including loss of MeCP2 in Rett syndrome
9
, indicating that, at least in some cases, the neuroanatomy may remain sufficiently intact so that correction of the molecular dysfunction underlying these disorders can restore healthy physiology. Given the absence of neurodegeneration in
MECP2
duplication syndrome, we propose that restoration of normal MeCP2 levels in
MECP2
duplication adult mice would rescue their phenotype. By generating and characterizing a conditional
Mecp2-
overexpressing mouse model, here we show that correction of MeCP2 levels largely reverses the behavioural, molecular and electrophysiological deficits. We also reduced MeCP2 using an antisense oligonucleotide strategy, which has greater translational potential. Antisense oligonucleotides are small, modified nucleic acids that can selectively hybridize with messenger RNA transcribed from a target gene and silence it
10
,
11
, and have been successfully used to correct deficits in different mouse models
12
,
13
,
14
,
15
,
16
,
17
,
18
. We find that antisense oligonucleotide treatment induces a broad phenotypic rescue in adult symptomatic transgenic
MECP2
duplication mice (
MECP2
-TG)
19
,
20
, and corrected
MECP2
levels in lymphoblastoid cells from
MECP2
duplication patients in a dose-dependent manner.
Publisher
Nature Publishing Group UK,Nature Publishing Group
Subject
/ Analysis
/ Animals
/ Attachment Sites, Microbiological - genetics
/ Brain
/ Complications and side effects
/ Epilepsy
/ Humanities and Social Sciences
/ Humans
/ Kinases
/ letter
/ Methyl-CpG-Binding Protein 2 - genetics
/ Methyl-CpG-Binding Protein 2 - metabolism
/ Mice
/ Oligonucleotides, Antisense - genetics
/ Proteins
/ Rodents
/ Science
