Ontogeny-driven rDNA rearrangement, methylation, and transcription, and paternal influence

Gene rearrangement occurs during development in some cell types and this genome dynamics is modulated by intrinsic and extrinsic factors, including growth stimulants and nutrients. This raises a possibility that such structural change in the genome and its subsequent epigenetic modifications may als...

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Veröffentlicht in:	PloS one 2011-07, Vol.6 (7), p.e22266
Hauptverfasser:	Shiao, Yih-Horng, Leighty, Robert M, Wang, Cuiju, Ge, Xin, Crawford, Erik B, Spurrier, Joshua M, McCann, Sean D, Fields, Janet R, Fornwald, Laura, Riffle, Lisa, Driver, Craig, Quiñones, Octavio A, Wilson, Ralph E, Kasprzak, Kazimierz S, Travlos, Gregory S, Alvord, W Gregory, Anderson, Lucy M
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal tissues Animals B cells Base Sequence Biology Cell division CpG Islands - genetics Deoxyribonucleic acid DNA DNA methylation DNA Methylation - genetics DNA, Ribosomal - genetics Drosophila Embryos Epigenesis, Genetic Epigenetic inheritance Epigenetics Exposure Gene expression Gene polymorphism Gene rearrangement Gene Rearrangement - genetics Genes Genetic aspects Genetic testing Genomes Genomics Haplotypes Haplotypes - genetics House mouse Insects Laboratories Lung cancer Lungs Male Mammals Methylation Mice Models, Genetic Molecular Sequence Data Neurodegeneration Nutrients Ontogeny Paternal Exposure Polymorphism Promoter Regions, Genetic - genetics RNA RNA polymerase rRNA Science Sequence Analysis, DNA Single nucleotide polymorphisms Single-nucleotide polymorphism Stimulants Studies Toxicology Transcription (Genetics) Transcription, Genetic
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creator	Shiao, Yih-Horng Leighty, Robert M Wang, Cuiju Ge, Xin Crawford, Erik B Spurrier, Joshua M McCann, Sean D Fields, Janet R Fornwald, Laura Riffle, Lisa Driver, Craig Quiñones, Octavio A Wilson, Ralph E Kasprzak, Kazimierz S Travlos, Gregory S Alvord, W Gregory Anderson, Lucy M
description	Gene rearrangement occurs during development in some cell types and this genome dynamics is modulated by intrinsic and extrinsic factors, including growth stimulants and nutrients. This raises a possibility that such structural change in the genome and its subsequent epigenetic modifications may also take place during mammalian ontogeny, a process undergoing finely orchestrated cell division and differentiation. We tested this hypothesis by comparing single nucleotide polymorphism-defined haplotype frequencies and DNA methylation of the rDNA multicopy gene between two mouse ontogenic stages and among three adult tissues of individual mice. Possible influences to the genetic and epigenetic dynamics by paternal exposures were also examined for Cr(III) and acid saline extrinsic factors. Variables derived from litters, individuals, and duplicate assays in large mouse populations were examined using linear mixed-effects model. We report here that active rDNA rearrangement, represented by changes of haplotype frequencies, arises during ontogenic progression from day 8 embryos to 6-week adult mice as well as in different tissue lineages and is modifiable by paternal exposures. The rDNA methylation levels were also altered in concordance with this ontogenic progression and were associated with rDNA haplotypes. Sperm showed highest level of methylation, followed by lungs and livers, and preferentially selected haplotypes that are positively associated with methylation. Livers, maintaining lower levels of rDNA methylation compared with lungs, expressed more rRNA transcript. In vitro transcription demonstrated haplotype-dependent rRNA expression. Thus, the genome is also dynamic during mammalian ontogeny and its rearrangement may trigger epigenetic changes and subsequent transcriptional controls, that are further influenced by paternal exposures.
doi_str_mv	10.1371/journal.pone.0022266
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We report here that active rDNA rearrangement, represented by changes of haplotype frequencies, arises during ontogenic progression from day 8 embryos to 6-week adult mice as well as in different tissue lineages and is modifiable by paternal exposures. The rDNA methylation levels were also altered in concordance with this ontogenic progression and were associated with rDNA haplotypes. Sperm showed highest level of methylation, followed by lungs and livers, and preferentially selected haplotypes that are positively associated with methylation. Livers, maintaining lower levels of rDNA methylation compared with lungs, expressed more rRNA transcript. In vitro transcription demonstrated haplotype-dependent rRNA expression. 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This raises a possibility that such structural change in the genome and its subsequent epigenetic modifications may also take place during mammalian ontogeny, a process undergoing finely orchestrated cell division and differentiation. We tested this hypothesis by comparing single nucleotide polymorphism-defined haplotype frequencies and DNA methylation of the rDNA multicopy gene between two mouse ontogenic stages and among three adult tissues of individual mice. Possible influences to the genetic and epigenetic dynamics by paternal exposures were also examined for Cr(III) and acid saline extrinsic factors. Variables derived from litters, individuals, and duplicate assays in large mouse populations were examined using linear mixed-effects model. 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some cell types and this genome dynamics is modulated by intrinsic and extrinsic factors, including growth stimulants and nutrients. This raises a possibility that such structural change in the genome and its subsequent epigenetic modifications may also take place during mammalian ontogeny, a process undergoing finely orchestrated cell division and differentiation. We tested this hypothesis by comparing single nucleotide polymorphism-defined haplotype frequencies and DNA methylation of the rDNA multicopy gene between two mouse ontogenic stages and among three adult tissues of individual mice. Possible influences to the genetic and epigenetic dynamics by paternal exposures were also examined for Cr(III) and acid saline extrinsic factors. Variables derived from litters, individuals, and duplicate assays in large mouse populations were examined using linear mixed-effects model. We report here that active rDNA rearrangement, represented by changes of haplotype frequencies, arises during ontogenic progression from day 8 embryos to 6-week adult mice as well as in different tissue lineages and is modifiable by paternal exposures. The rDNA methylation levels were also altered in concordance with this ontogenic progression and were associated with rDNA haplotypes. Sperm showed highest level of methylation, followed by lungs and livers, and preferentially selected haplotypes that are positively associated with methylation. Livers, maintaining lower levels of rDNA methylation compared with lungs, expressed more rRNA transcript. In vitro transcription demonstrated haplotype-dependent rRNA expression. Thus, the genome is also dynamic during mammalian ontogeny and its rearrangement may trigger epigenetic changes and subsequent transcriptional controls, that are further influenced by paternal exposures.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>21765958</pmid><doi>10.1371/journal.pone.0022266</doi><tpages>e22266</tpages><oa>free_for_read</oa></addata></record>
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identifier	ISSN: 1932-6203
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subjects	Animal tissues Animals B cells Base Sequence Biology Cell division CpG Islands - genetics Deoxyribonucleic acid DNA DNA methylation DNA Methylation - genetics DNA, Ribosomal - genetics Drosophila Embryos Epigenesis, Genetic Epigenetic inheritance Epigenetics Exposure Gene expression Gene polymorphism Gene rearrangement Gene Rearrangement - genetics Genes Genetic aspects Genetic testing Genomes Genomics Haplotypes Haplotypes - genetics House mouse Insects Laboratories Lung cancer Lungs Male Mammals Methylation Mice Models, Genetic Molecular Sequence Data Neurodegeneration Nutrients Ontogeny Paternal Exposure Polymorphism Promoter Regions, Genetic - genetics RNA RNA polymerase rRNA Science Sequence Analysis, DNA Single nucleotide polymorphisms Single-nucleotide polymorphism Stimulants Studies Toxicology Transcription (Genetics) Transcription, Genetic
title	Ontogeny-driven rDNA rearrangement, methylation, and transcription, and paternal influence
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