A mutation-led search for novel functional domains in MeCP2

Jacky Guy; Beatrice Alexander-Howden; Laura FitzPatrick; Dina DeSousa; Martha V. Koerner; Jim Selfridge; Adrian Bird

doi:10.1093/hmg/ddy159

A mutation-led search for novel functional domains in MeCP2

Jacky Guy, Beatrice Alexander-Howden, Laura FitzPatrick, Dina DeSousa, Martha V. Koerner, Jim Selfridge, Adrian Bird^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Most missense mutations causing Rett syndrome (RTT) affect domains of MeCP2 that have been shown to either bind methylated DNA or interact with a transcriptional co-repressor complex. Several mutations, however, including the C-terminal truncations that account for ~10% of cases, fall outside these characterized domains. We studied the molecular consequences of four of these 'non-canonical' mutations in cultured neurons and mice to see if they reveal additional essential domains without affecting known properties of MeCP2. The results show that the mutations partially or strongly deplete the protein and also in some cases interfere with co-repressor recruitment. These mutations therefore impact the activity of known functional domains and do not invoke new molecular causes of RTT. The finding that a stable C-terminal truncation does not compromise MeCP2 function raises the possibility that small molecules which stabilize these mutant proteins may be of therapeutic value.

Original language	English
Pages (from-to)	2531-2545
Number of pages	15
Journal	Human Molecular Genetics
Volume	27
Issue number	14
Early online date	27 Apr 2018
DOIs	https://doi.org/10.1093/hmg/ddy159
Publication status	Published - 15 Jul 2018

Keywords

phenotype
mutation
DNA
neurons
Rett syndrome
Mice
transcriptional repression
Rett's disorder

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10.1093/hmg/ddy159Licence: Creative Commons: Attribution (CC-BY)

A mutation led PUB OA CC BY ddy159
VC The Author(s) 2018. Published by Oxford University Press. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.
Final published version, 949 KBLicence: Creative Commons: Attribution (CC-BY)

Cite this

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title = "A mutation-led search for novel functional domains in MeCP2",

abstract = "Most missense mutations causing Rett syndrome (RTT) affect domains of MeCP2 that have been shown to either bind methylated DNA or interact with a transcriptional co-repressor complex. Several mutations, however, including the C-terminal truncations that account for ~10% of cases, fall outside these characterized domains. We studied the molecular consequences of four of these 'non-canonical' mutations in cultured neurons and mice to see if they reveal additional essential domains without affecting known properties of MeCP2. The results show that the mutations partially or strongly deplete the protein and also in some cases interfere with co-repressor recruitment. These mutations therefore impact the activity of known functional domains and do not invoke new molecular causes of RTT. The finding that a stable C-terminal truncation does not compromise MeCP2 function raises the possibility that small molecules which stabilize these mutant proteins may be of therapeutic value.",

keywords = "phenotype, mutation, DNA, neurons, Rett syndrome, Mice, transcriptional repression, Rett's disorder",

author = "Jacky Guy and Beatrice Alexander-Howden and Laura FitzPatrick and Dina DeSousa and Koerner, {Martha V.} and Jim Selfridge and Adrian Bird",

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AU - Guy, Jacky

AU - Alexander-Howden, Beatrice

AU - FitzPatrick, Laura

AU - DeSousa, Dina

AU - Koerner, Martha V.

AU - Selfridge, Jim

AU - Bird, Adrian

PY - 2018/7/15

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N2 - Most missense mutations causing Rett syndrome (RTT) affect domains of MeCP2 that have been shown to either bind methylated DNA or interact with a transcriptional co-repressor complex. Several mutations, however, including the C-terminal truncations that account for ~10% of cases, fall outside these characterized domains. We studied the molecular consequences of four of these 'non-canonical' mutations in cultured neurons and mice to see if they reveal additional essential domains without affecting known properties of MeCP2. The results show that the mutations partially or strongly deplete the protein and also in some cases interfere with co-repressor recruitment. These mutations therefore impact the activity of known functional domains and do not invoke new molecular causes of RTT. The finding that a stable C-terminal truncation does not compromise MeCP2 function raises the possibility that small molecules which stabilize these mutant proteins may be of therapeutic value.

AB - Most missense mutations causing Rett syndrome (RTT) affect domains of MeCP2 that have been shown to either bind methylated DNA or interact with a transcriptional co-repressor complex. Several mutations, however, including the C-terminal truncations that account for ~10% of cases, fall outside these characterized domains. We studied the molecular consequences of four of these 'non-canonical' mutations in cultured neurons and mice to see if they reveal additional essential domains without affecting known properties of MeCP2. The results show that the mutations partially or strongly deplete the protein and also in some cases interfere with co-repressor recruitment. These mutations therefore impact the activity of known functional domains and do not invoke new molecular causes of RTT. The finding that a stable C-terminal truncation does not compromise MeCP2 function raises the possibility that small molecules which stabilize these mutant proteins may be of therapeutic value.

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A mutation-led search for novel functional domains in MeCP2

Abstract

Keywords

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Towards understanding and treatment of MeCP2-related disorders

Wellcome Trust Four-year PhD studentship (Laura Ann FitzPatrick)

Adrian Bird

Cite this

A mutation-led search for novel functional domains in MeCP2

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Projects

Towards understanding and treatment of MeCP2-related disorders

Wellcome Trust Four-year PhD studentship (Laura Ann FitzPatrick)

Profiles

Adrian Bird

Cite this