Histone acetylation increases chromatin accessibility-Reference-Cited by-同舟云学术

Histone acetylation increases chromatin accessibility

Published:2005-12-15 Issue:24 Volume:118 Page:5825-5834
ISSN:1477-9137
Container-title:Journal of Cell Science
language:en
Short-container-title:

Author:

Görisch Sabine M.¹,Wachsmuth Malte²,Tóth Katalin Fejes²,Lichter Peter¹,Rippe Karsten²

Affiliation:

1. Division of Molecular Genetics, Deutsches Krebsforschungszentrum, Im Neuenheimer Feld 280, 69120 Heidelberg, Germany

2. Molecular Biophysics Group, Kirchhoff-Institut für Physik, Im Neuenheimer Feld 227, 69120 Heidelberg, Germany

Abstract

In eukaryotes, the interaction of DNA with proteins and supramolecular complexes involved in gene expression is controlled by the dynamic organization of chromatin inasmuch as it defines the DNA accessibility. Here, the nuclear distribution of microinjected fluorescein-labeled dextrans of 42 kDa to 2.5 MDa molecular mass was used to characterize the chromatin accessibility in dependence on histone acetylation. Measurements of the fluorescein-dextran sizes were combined with an image correlation spectroscopy analysis, and three different interphase chromatin condensation states with apparent pore sizes of 16-20 nm, 36-56 nm and 60-100 nm were identified. A reversible change of the chromatin conformation to a uniform 60-100 nm pore size distribution was observed upon increased histone acetylation. This result identifies histone acetylation as a central factor in the dynamic regulation of chromatin accessibility during interphase. In mitotic chromosomes, the chromatin exclusion limit was 10-20 nm and independent of the histone acetylation state.

Publisher

The Company of Biologists

Subject

Cell Biology

Link

http://journals.biologists.com/jcs/article-pdf/118/24/5825/1523093/5825.pdf

Reference62 articles.

1. Agalioti, T., Chen, G. and Thanos, D. (2002). Deciphering the transcriptional histone acetylation code for a human gene. Cell111, 381-392.

2. Bellard, M., Kuo, M. T., Dretzen, G. and Chambon, P. (1980). Differential nuclease sensitivity of the ovalbumin and beta-globin chromatin regions in erythrocytes and oviduct cells of laying hen. Nucleic Acids Res.8, 2737-2750.

3. Belmont, A. S. and Bruce, K. (1994). Visualization of G1 chromosomes: a folded, twisted, supercoiled chromonema model of interphase chromatid structure. J. Cell Biol.127, 287-302.

4. Chen, D., Dundr, M., Wang, C., Leung, A., Lamond, A., Misteli, T. and Huang, S. (2005). Condensed mitotic chromatin is accessible to transcription factors and chromatin structural proteins. J. Cell Biol.168, 41-54.

5. Chen, L. and Widom, J. (2004). Molecular basis of transcriptional silencing in budding yeast. Biochem. Cell Biol.82, 413-418.

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