A suppressor screen in Mecp2 mutant mice implicates cholesterol metabolism in Rett syndrome

Buchovecky, Christie; Turley, Stephen D.; Brown, Hannah; Kyle, Stephanie M.; McDonald, Jeffrey G.; Liu, Benny; Pieper, Andrew A.; Huang, Wenhui; Katz, David M.; Russell, David W.; Shendure, Jay; Justice, Monica J.

doi:10.1038/ng.2714

Cited by 197 publications

(252 citation statements)

References 64 publications

(76 reference statements)

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“…Mutations in specific nicotinic receptors can even cause a genetically transmissible form of epilepsy [27]. Moreover, decreases in cholinergic markers have been correlated with clinical severity in RTT patients [28,29]. The link between cholinergic systems and specific RTT phenotypes led us to hypothesize that dysfunction in cholinergic neurons might be involved in RTT.…”

Section: Introductionmentioning

confidence: 99%

Loss of MeCP2 in cholinergic neurons causes part of RTT-like phenotypes via α7 receptor in hippocampus

et al. 2016

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Mutations in the X-linked MECP2 gene cause Rett syndrome (RTT), an autism spectrum disorder characterized by impaired social interactions, motor abnormalities, cognitive defects and a high risk of epilepsy. Here, we showed that conditional deletion of Mecp2 in cholinergic neurons caused part of RTT-like phenotypes, which could be rescued by re-expressing Mecp2 in the basal forebrain (BF) cholinergic neurons rather than in the caudate putamen of conditional knockout (Chat-Mecp2 −/y ) mice. We found that choline acetyltransferase expression was decreased in the BF and that α7 nicotine acetylcholine receptor signaling was strongly impaired in the hippocampus of Chat-Mecp2 −/y mice, which is sufficient to produce neuronal hyperexcitation and increase seizure susceptibility. Application of PNU282987 or nicotine in the hippocampus rescued these phenotypes in Chat-Mecp2 −/y mice. Taken together, our findings suggest that MeCP2 is critical for normal function of cholinergic neurons and dysfunction of cholinergic neurons can contribute to numerous neuropsychiatric phenotypes.

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Section: Introductionmentioning

confidence: 99%

Loss of MeCP2 in cholinergic neurons causes part of RTT-like phenotypes via α7 receptor in hippocampus

et al. 2016

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“…In an alternative approach involving mutagenesis screens in Mecp2-mutant mice, mutations in squalene epoxidase, the rate-limiting enzyme in cholesterol biosynthesis, were identified as suppressing RTT-associated phenotypes. Interestingly, cholesterol metabolism is altered and cholesterol levels are elevated in the brains of Mecp2 -/y male mice, all of which prompted the testing of statins with positive effects on some, but not all, categories of symptoms (14). Loss of function of MECP2 has also been associated with disruption of signaling through the AKT/mTOR pathway (15).…”

Section: Mecp2mentioning

confidence: 99%

PTP1B inhibition suggests a therapeutic strategy for Rett syndrome

Krishnan¹,

Krishnan²,

Connors³

et al. 2015

J. Clin. Invest.

100

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“…One of the mitigating mutations introduced a premature stop codon in Sqle (squalene epoxidase), which encodes a key cholesterol biosynthesis enzyme. The authors showed that treatment of Mecp2 À/À mice with cholesterol-lowering statin drugs significantly improved motor function and lifespan, 73 suggesting that this widely used class of drugs may benefit individuals with Rett syndrome. A recently completed phase 2 clinical trial (NCT02563860) is evaluating this hypothesis, with results forthcoming (see Clinical Trials in Web Resources).…”

Section: Strategies To Identify Genetic Modifiers In Micementioning

confidence: 99%

“…A similar ENU-based mutagenesis screen identified modifier genes in the Mecp2 À/À (methyl CpG binding protein 2) mouse model of Rett syndrome (MIM: 312750). 73 As in humans,…”

Section: Strategies To Identify Genetic Modifiers In Micementioning

confidence: 99%

From Peas to Disease: Modifier Genes, Network Resilience, and the Genetics of Health

Riordan

Nadeau

2017

The American Journal of Human Genetics

119

107

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Phenotypes are rarely consistent across genetic backgrounds and environments, but instead vary in many ways depending on allelic variants, unlinked genes, epigenetic factors, and environmental exposures. In the extreme, individuals carrying the same causal DNA sequence variant but on different backgrounds can be classified as having distinct conditions. Similarly, some individuals that carry disease alleles are nevertheless healthy despite affected family members in the same environment. These genetic background effects often result from the action of so-called ''modifier genes'' that modulate the phenotypic manifestation of target genes in an epistatic manner. While complicating the prospects for gene discovery and the feasibility of mechanistic studies, such effects are opportunities to gain a deeper understanding of gene interaction networks that provide organismal form and function as well as resilience to perturbation. Here, we review the principles of modifier genetics and assess progress in studies of modifier genes and their targets in both simple and complex traits. We propose that modifier effects emerge from gene interaction networks whose structure and function vary with genetic background and argue that these effects can be exploited as safe and effective ways to prevent, stabilize, and reverse disease and dysfunction.

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A suppressor screen in Mecp2 mutant mice implicates cholesterol metabolism in Rett syndrome

Cited by 197 publications

References 64 publications

Loss of MeCP2 in cholinergic neurons causes part of RTT-like phenotypes via α7 receptor in hippocampus

Loss of MeCP2 in cholinergic neurons causes part of RTT-like phenotypes via α7 receptor in hippocampus

PTP1B inhibition suggests a therapeutic strategy for Rett syndrome

From Peas to Disease: Modifier Genes, Network Resilience, and the Genetics of Health

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