Loss of maternal EED results in postnatal overgrowth

Loss of maternal EED results in postnatal overgrowth

Abstract Background Investigating how epigenetic information is transmitted through the mammalian germline is the key to understanding how this information impacts on health and disease susceptibility in offspring. EED is essential for regulating the repressive histone modification, histone 3 lysine...

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Main Authors: Lexie Prokopuk, Jessica M. Stringer, Craig R. White, Rolf H. A. M. Vossen, Stefan J. White, Ana S. A. Cohen, William T. Gibson, Patrick S. Western
Format: Article
Language:English
Published: BMC 2018-07-01
Series:Clinical Epigenetics
Subjects:
Epigenetic inheritance
Germ
Oocyte
Polycomb
Histone
Weaver
Online Access:http://link.springer.com/article/10.1186/s13148-018-0526-8
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spelling doaj-62884fb084604d299cae3ecb012060ec2020-11-25T00:39:57ZengBMCClinical Epigenetics1868-70751868-70832018-07-0110111410.1186/s13148-018-0526-8Loss of maternal EED results in postnatal overgrowthLexie Prokopuk0Jessica M. Stringer1Craig R. White2Rolf H. A. M. Vossen3Stefan J. White4Ana S. A. Cohen5William T. Gibson6Patrick S. Western7Centre for Reproductive Health, Hudson Institute of Medical Research and Department of Molecular and Translational Science, Monash UniversityCentre for Reproductive Health, Hudson Institute of Medical Research and Department of Molecular and Translational Science, Monash UniversityCentre for Geometric Biology, School of Biological Sciences, Monash UniversityLeiden Genome Technology Centre, Department of Human Genetics, Leiden University Medical CenterLeiden Genome Technology Centre, Department of Human Genetics, Leiden University Medical CenterDepartment of Medical Genetics, University of British Columbia and British Columbia Children’s Hospital Research InstituteDepartment of Medical Genetics, University of British Columbia and British Columbia Children’s Hospital Research InstituteCentre for Reproductive Health, Hudson Institute of Medical Research and Department of Molecular and Translational Science, Monash UniversityAbstract Background Investigating how epigenetic information is transmitted through the mammalian germline is the key to understanding how this information impacts on health and disease susceptibility in offspring. EED is essential for regulating the repressive histone modification, histone 3 lysine 27 tri-methylation (H3K27me3) at many developmental genes. Results In this study, we used oocyte-specific Zp3-Cre recombinase (Zp3Cre) to delete Eed specifically in mouse growing oocytes, permitting the study of EED function in oocytes and the impact of depleting EED in oocytes on outcomes in offspring. As EED deletion occurred only in growing oocytes and females were mated to normal wild type males, this model allowed the study of oocyte programming without confounding factors such as altered in utero environment. Loss of EED from growing oocytes resulted in a significant overgrowth phenotype that persisted into adult life. Significantly, this involved increased adiposity (total fat) and bone mineral density in offspring. Similar overgrowth occurs in humans with Cohen-Gibson (OMIM 617561) and Weaver (OMIM 277590) syndromes, that result from de novo germline mutations in EED or its co-factor EZH2, respectively. Consistent with a role for EZH2 in human oocytes, we demonstrate that de novo germline mutations in EZH2 occurred in the maternal germline in some cases of Weaver syndrome. However, deletion of Ezh2 in mouse oocytes resulted in a distinct phenotype compared to that resulting from oocyte-specific deletion of Eed. Conclusions This study provides novel evidence that altering EED-dependent oocyte programming leads to compromised offspring growth and development in the next generation.http://link.springer.com/article/10.1186/s13148-018-0526-8Epigenetic inheritanceGermOocytePolycombHistoneWeaver
collection DOAJ
language English
format Article
sources DOAJ
author Lexie Prokopuk
Jessica M. Stringer
Craig R. White
Rolf H. A. M. Vossen
Stefan J. White
Ana S. A. Cohen
William T. Gibson
Patrick S. Western
spellingShingle Lexie Prokopuk
Jessica M. Stringer
Craig R. White
Rolf H. A. M. Vossen
Stefan J. White
Ana S. A. Cohen
William T. Gibson
Patrick S. Western
Loss of maternal EED results in postnatal overgrowth
Clinical Epigenetics
Epigenetic inheritance
Germ
Oocyte
Polycomb
Histone
Weaver
author_facet Lexie Prokopuk
Jessica M. Stringer
Craig R. White
Rolf H. A. M. Vossen
Stefan J. White
Ana S. A. Cohen
William T. Gibson
Patrick S. Western
author_sort Lexie Prokopuk
title Loss of maternal EED results in postnatal overgrowth
title_short Loss of maternal EED results in postnatal overgrowth
title_full Loss of maternal EED results in postnatal overgrowth
title_fullStr Loss of maternal EED results in postnatal overgrowth
title_full_unstemmed Loss of maternal EED results in postnatal overgrowth
title_sort loss of maternal eed results in postnatal overgrowth
publisher BMC
series Clinical Epigenetics
issn 1868-7075
1868-7083
publishDate 2018-07-01
description Abstract Background Investigating how epigenetic information is transmitted through the mammalian germline is the key to understanding how this information impacts on health and disease susceptibility in offspring. EED is essential for regulating the repressive histone modification, histone 3 lysine 27 tri-methylation (H3K27me3) at many developmental genes. Results In this study, we used oocyte-specific Zp3-Cre recombinase (Zp3Cre) to delete Eed specifically in mouse growing oocytes, permitting the study of EED function in oocytes and the impact of depleting EED in oocytes on outcomes in offspring. As EED deletion occurred only in growing oocytes and females were mated to normal wild type males, this model allowed the study of oocyte programming without confounding factors such as altered in utero environment. Loss of EED from growing oocytes resulted in a significant overgrowth phenotype that persisted into adult life. Significantly, this involved increased adiposity (total fat) and bone mineral density in offspring. Similar overgrowth occurs in humans with Cohen-Gibson (OMIM 617561) and Weaver (OMIM 277590) syndromes, that result from de novo germline mutations in EED or its co-factor EZH2, respectively. Consistent with a role for EZH2 in human oocytes, we demonstrate that de novo germline mutations in EZH2 occurred in the maternal germline in some cases of Weaver syndrome. However, deletion of Ezh2 in mouse oocytes resulted in a distinct phenotype compared to that resulting from oocyte-specific deletion of Eed. Conclusions This study provides novel evidence that altering EED-dependent oocyte programming leads to compromised offspring growth and development in the next generation.
topic Epigenetic inheritance
Germ
Oocyte
Polycomb
Histone
Weaver
url http://link.springer.com/article/10.1186/s13148-018-0526-8
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