Early life vitamin D depletion and mechanical loading determine methylation changes in the RUNX2, RXRA, and osterix promoters in mice
Early life vitamin D depletion and mechanical loading determine methylation changes in the RUNX2, RXRA, and osterix promoters in mice
Background: early life vitamin D exposure is linked to later skeletal health with maternal vitamin D status in pregnancy associated with neonatal bone mass. The MAVIDOS study has demonstrated that vitamin D supplementation leads to reduced RXRA DNA methylation. Mice exposed to early life vitamin D deficiency have reduced bone mass and bone accrual in response to mechanical loading. Using the tibiae of these mice, we have examined the effect of diet and mechanical loading on the DNA methylation of promoters of genetic loci important for bone growth and development and their association with bone strength.
Results: mechanical loading of mouse tibiae leads to a reduction of RXRA DNA methylation. Early life vitamin D deficiency is associated with altered methylation of osterix and Runx2 in these bones. Tibia strength was also demonstrated to be associated with a change in DNA methylation status in CpGs of the vitamin D receptor (VDR), ostrix, and RXRA genes.
Conclusions: we have shown for the first time that mechanical loading of bone and early life vitamin D deficiency leads to changes in the epigenome of this tissue in key genes in the vitamin D and osteoblast differentiation pathway.
Bone, Epigenetics, Mechanical loading, Methylation, Osterix, RXRA, Vitamin D
Krstic, Nevena
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Bishop, Nick
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Curtis, Elizabeth
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Cooper, Cyrus
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Harvey, Nicholas
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Lillycrop, Karen
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Murray, Robert
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Owen, Robert
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Reilly, Gwen
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Skerry, Tim M.
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Borg, Steph
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26 May 2022
Krstic, Nevena
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Bishop, Nick
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Curtis, Elizabeth
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Cooper, Cyrus
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Harvey, Nicholas
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Lillycrop, Karen
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Murray, Robert
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Owen, Robert
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Reilly, Gwen
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Skerry, Tim M.
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Borg, Steph
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Krstic, Nevena, Bishop, Nick, Curtis, Elizabeth, Cooper, Cyrus, Harvey, Nicholas, Lillycrop, Karen, Murray, Robert, Owen, Robert, Reilly, Gwen, Skerry, Tim M. and Borg, Steph
(2022)
Early life vitamin D depletion and mechanical loading determine methylation changes in the RUNX2, RXRA, and osterix promoters in mice.
Genes & Nutrition, 17 (1), [7].
(doi:10.1186/s12263-022-00711-0).
Abstract
Background: early life vitamin D exposure is linked to later skeletal health with maternal vitamin D status in pregnancy associated with neonatal bone mass. The MAVIDOS study has demonstrated that vitamin D supplementation leads to reduced RXRA DNA methylation. Mice exposed to early life vitamin D deficiency have reduced bone mass and bone accrual in response to mechanical loading. Using the tibiae of these mice, we have examined the effect of diet and mechanical loading on the DNA methylation of promoters of genetic loci important for bone growth and development and their association with bone strength.
Results: mechanical loading of mouse tibiae leads to a reduction of RXRA DNA methylation. Early life vitamin D deficiency is associated with altered methylation of osterix and Runx2 in these bones. Tibia strength was also demonstrated to be associated with a change in DNA methylation status in CpGs of the vitamin D receptor (VDR), ostrix, and RXRA genes.
Conclusions: we have shown for the first time that mechanical loading of bone and early life vitamin D deficiency leads to changes in the epigenome of this tissue in key genes in the vitamin D and osteoblast differentiation pathway.
Text
s12263-022-00711-0
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Accepted/In Press date: 11 May 2022
Published date: 26 May 2022
Additional Information:
Funding Information:
SB has received a training fellowship from the Medical Research Council which has funded this study, grant reference MR/L002191/1 ( www.mrc.ac.uk ). The funder has no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Publisher Copyright:
© 2022, The Author(s).
Keywords:
Bone, Epigenetics, Mechanical loading, Methylation, Osterix, RXRA, Vitamin D
Identifiers
Local EPrints ID: 458040
URI: http://eprints.soton.ac.uk/id/eprint/458040
ISSN: 1555-8932
PURE UUID: bd1ec375-3166-4cc9-a29a-a27cfb2bc63b
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Date deposited: 27 Jun 2022 16:58
Last modified: 18 Mar 2024 03:38
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Contributors
Author:
Nevena Krstic
Author:
Nick Bishop
Author:
Robert Murray
Author:
Robert Owen
Author:
Gwen Reilly
Author:
Tim M. Skerry
Author:
Steph Borg
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