Chromatin Remodelling of the Cardiac Beta-myosin Heavy Chain Gene

Overview

Journal Biochem J

Specialty Biochemistry

Date 1998 Apr 18

PMID 9480903

Citations 1

Authors

W Y Huang

C C Liew

Affiliations

Soon will be listed here.

Abstract

To investigate the role of chromatin structure in cardiac gene expression, we used the DNase I and micrococcal nuclease to probe the chromatin structure of the hamster cardiac beta-MyHC gene. Two cardiac-specific DNase I hypersensitive sites (DHS) were identified, one of which was mapped to the -2.3 kb (beta-2.3 kb) region and the other to the proximal promoter region of the beta-MyHC gene. The two sites were readily detectable using nuclei from neonatal hamster heart; however, the proximal promoter site disappeared when adult hamster heart nuclei were used, and the -2.3 kb site decreased in intensity. We were able to demonstrate the gradual disappearance of this proximal promoter DHS by comparing heart nuclei isolated from animals at late-gestation and 1-day-old stages. Furthermore, injecting thyroid hormone caused the disappearance of the proximal promoter DHS in late gestational fetal ventricular nuclei. Digestion of nuclei from various tissues by micrococcal nuclease revealed that the beta-MyHC gene proximal promoter exists in an array of three specifically-positioned nucleosomes only in fetal heart chromatin. The beta-MyHC gene proximal promoter is DNase I hypersensitive within one of the nucleosomal particles. Our data suggest that chromatin structure may participate actively in cardiac gene expression.

Citing Articles

Cardiac myosin heavy chain gene regulation by thyroid hormone involves altered histone modifications.

Haddad F, Jiang W, Bodell P, Qin A, Baldwin K Am J Physiol Heart Circ Physiol. 2010; 299(6):H1968-80.

PMID: 20833952 PMC: 3006294. DOI: 10.1152/ajpheart.00644.2010.

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