Reduced CpG Methylation is Associated with Transcriptional Activation of the Bone-specific Rat Osteocalcin Gene in Osteoblasts

Overview

Journal J Cell Biochem

Specialties Biochemistry
Cell Biology

Date 2002 Mar 14

PMID 11891855

Citations 51

Authors

Alejandro Villagra

Jose Gutierrez

Roberto Paredes

Jose Sierra

Marcia Puchi

Maria Imschenetzky

Andre van Wijnen Av

Jane Lian

Gary Stein

Janet Stein

Martin Montecino

Affiliations

Soon will be listed here.

Abstract

Chromatin remodeling of the bone-specific rat osteocalcin (OC) gene accompanies the onset and increase in OC expression during osteoblast differentiation. In osseous cells expressing OC, the promoter region contains two nuclease hypersensitive sites that encompass the elements that regulate basal tissue-specific and vitamin D-enhanced OC transcription. Multiple lines of evidence indicate that DNA methylation is involved in maintaining a stable and condensed chromatin organization that represses eukaryotic transcription. Here we report that DNA methylation at the OC gene locus is associated with the condensed chromatin structure found in cells not expressing OC. In addition, we find that reduced CpG methylation of the OC gene accompanies active transcription in ROS 17/2.8 rat osteosarcoma cells. Interestingly, during differentiation of primary diploid rat osteoblasts in culture, as the OC gene becomes increasingly expressed, CpG methylation of the OC promoter is significantly reduced. Inhibition of OC transcription does not occur by a direct mechanism because in vitro methylated OC promoter DNA is still recognized by the key regulators Runx/Cbfa and the vitamin D receptor complex. Furthermore, CpG methylation affects neither basal nor vitamin D-enhanced OC promoter activity in transient expression experiments. Together, our results indicate that DNA methylation may contribute indirectly to OC transcriptional control in osteoblasts by maintaining a highly condensed and repressed chromatin structure.

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