Genetic and Epigenetic Variation, but Not Diet, Shape the Sperm Methylome

Jeremy M. Shea; Ryan W. Serra; Benjamin R. Carone; Hennady P. Shulha; Alper Kucukural; Michael J. Ziller; Markus P. Vallaster; Hongcang Gu; Andrew R. Tapper; Paul D. Gardner; Alexander Meissner; Manuel Garber; Oliver J. Rando

doi:10.1016/j.devcel.2015.11.024

Genetic and Epigenetic Variation, but Not Diet, Shape the Sperm Methylome

Jeremy M. Shea, Ryan W. Serra, Benjamin R. Carone, Hennady P. Shulha, Alper Kucukural, Michael J. Ziller, Markus P. Vallaster, Hongcang Gu, Andrew R. Tapper, Paul D. Gardner, Alexander Meissner, Manuel Garber, Oliver J. Rando

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

115 Scopus citations

Abstract

Paternal diet can impact metabolic phenotypes in offspring, but mechanisms underlying such intergenerational information transfer remain obscure. Here, we interrogate cytosine methylation patterns in sperm obtained from mice consuming one of three diets, generating whole genome methylation maps for four pools of sperm samples and for 12 individual sperm samples, as well as 61 genome-scale methylation maps. We find that "epivariation," either stochastic or due to unknown demographic or environmental factors, was a far stronger contributor to the sperm methylome than was the diet consumed. Variation in cytosine methylation was particularly dramatic over tandem repeat families, including ribosomal DNA (rDNA) repeats, but rDNA methylation was strongly correlated with genetic variation in rDNA copy number and was not influenced by paternal diet. These results identify loci of genetic and epigenetic lability in the mammalian genome but argue against a direct role for sperm cytosine methylation in dietary reprogramming of offspring metabolism.

Original language	English (US)
Pages (from-to)	750-758
Number of pages	9
Journal	Developmental Cell
Volume	35
Issue number	6
DOIs	https://doi.org/10.1016/j.devcel.2015.11.024
State	Published - Dec 21 2015
Externally published	Yes

All Science Journal Classification (ASJC) codes

Molecular Biology
General Biochemistry, Genetics and Molecular Biology
Developmental Biology
Cell Biology

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10.1016/j.devcel.2015.11.024

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title = "Genetic and Epigenetic Variation, but Not Diet, Shape the Sperm Methylome",

abstract = "Paternal diet can impact metabolic phenotypes in offspring, but mechanisms underlying such intergenerational information transfer remain obscure. Here, we interrogate cytosine methylation patterns in sperm obtained from mice consuming one of three diets, generating whole genome methylation maps for four pools of sperm samples and for 12 individual sperm samples, as well as 61 genome-scale methylation maps. We find that {"}epivariation,{"} either stochastic or due to unknown demographic or environmental factors, was a far stronger contributor to the sperm methylome than was the diet consumed. Variation in cytosine methylation was particularly dramatic over tandem repeat families, including ribosomal DNA (rDNA) repeats, but rDNA methylation was strongly correlated with genetic variation in rDNA copy number and was not influenced by paternal diet. These results identify loci of genetic and epigenetic lability in the mammalian genome but argue against a direct role for sperm cytosine methylation in dietary reprogramming of offspring metabolism.",

author = "Shea, {Jeremy M.} and Serra, {Ryan W.} and Carone, {Benjamin R.} and Shulha, {Hennady P.} and Alper Kucukural and Ziller, {Michael J.} and Vallaster, {Markus P.} and Hongcang Gu and Tapper, {Andrew R.} and Gardner, {Paul D.} and Alexander Meissner and Manuel Garber and Rando, {Oliver J.}",

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doi = "10.1016/j.devcel.2015.11.024",

language = "English (US)",

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T1 - Genetic and Epigenetic Variation, but Not Diet, Shape the Sperm Methylome

AU - Shea, Jeremy M.

AU - Serra, Ryan W.

AU - Carone, Benjamin R.

AU - Shulha, Hennady P.

AU - Kucukural, Alper

AU - Ziller, Michael J.

AU - Vallaster, Markus P.

AU - Gu, Hongcang

AU - Tapper, Andrew R.

AU - Gardner, Paul D.

AU - Meissner, Alexander

AU - Garber, Manuel

AU - Rando, Oliver J.

PY - 2015/12/21

Y1 - 2015/12/21

N2 - Paternal diet can impact metabolic phenotypes in offspring, but mechanisms underlying such intergenerational information transfer remain obscure. Here, we interrogate cytosine methylation patterns in sperm obtained from mice consuming one of three diets, generating whole genome methylation maps for four pools of sperm samples and for 12 individual sperm samples, as well as 61 genome-scale methylation maps. We find that "epivariation," either stochastic or due to unknown demographic or environmental factors, was a far stronger contributor to the sperm methylome than was the diet consumed. Variation in cytosine methylation was particularly dramatic over tandem repeat families, including ribosomal DNA (rDNA) repeats, but rDNA methylation was strongly correlated with genetic variation in rDNA copy number and was not influenced by paternal diet. These results identify loci of genetic and epigenetic lability in the mammalian genome but argue against a direct role for sperm cytosine methylation in dietary reprogramming of offspring metabolism.

AB - Paternal diet can impact metabolic phenotypes in offspring, but mechanisms underlying such intergenerational information transfer remain obscure. Here, we interrogate cytosine methylation patterns in sperm obtained from mice consuming one of three diets, generating whole genome methylation maps for four pools of sperm samples and for 12 individual sperm samples, as well as 61 genome-scale methylation maps. We find that "epivariation," either stochastic or due to unknown demographic or environmental factors, was a far stronger contributor to the sperm methylome than was the diet consumed. Variation in cytosine methylation was particularly dramatic over tandem repeat families, including ribosomal DNA (rDNA) repeats, but rDNA methylation was strongly correlated with genetic variation in rDNA copy number and was not influenced by paternal diet. These results identify loci of genetic and epigenetic lability in the mammalian genome but argue against a direct role for sperm cytosine methylation in dietary reprogramming of offspring metabolism.

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JO - Developmental Cell

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IS - 6

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Genetic and Epigenetic Variation, but Not Diet, Shape the Sperm Methylome

Abstract

All Science Journal Classification (ASJC) codes

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