Reports

Nucleosome Arrays Reveal the Two-Start Organization of the Chromatin Fiber

Benedetta Dorigo,^1* Thomas Schalch,^1* Alexandra Kulangara,¹ Sylwia Duda,¹ Rasmus R. Schroeder,² Timothy J. Richmond¹

Chromatin folding determines the accessibility of DNA constituting eukaryotic genomes and consequently is profoundly important in the mechanisms of nuclear processes such as gene regulation. Nucleosome arrays compact to form a 30-nanometer chromatin fiber of hitherto disputed structure. Two competing classes of models have been proposed in which nucleosomes are either arranged linearly in a one-start higher order helix or zigzag back and forth in a two-start helix. We analyzed compacted nucleosome arrays stabilized by introduction of disulfide cross-links and show that the chromatin fiber comprises two stacks of nucleosomes in accord with the two-start model.

¹ Eidgenössische Technische Hochschule (ETH) Zürich, Institute for Molecular Biology and Biophysics, ETH–Hönggerberg, CH–8093 Zürich, Switzerland. ² Max Planck Institute for Medical Research, Department of Biomedical Mechanisms, Jahnstrasse 29, 69120 Heidelberg, Germany.

^* These authors contributed equally to this work.

To whom correspondence should be addressed. E-mail: richmond{at}mol.biol.ethz.ch

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A Novel Mechanism of Antagonism between ATP-Dependent Chromatin Remodeling Complexes Regulates RNR3 Expression.

R. S. Tomar, J. N. Psathas, H. Zhang, Z. Zhang, and J. C. Reese (2009)
Mol. Cell. Biol. 29, 3255-3265
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Modeling interactions between adjacent nucleosomes improves genome-wide predictions of nucleosome occupancy.

S. Lubliner and E. Segal (2009)
Bioinformatics 25, i348-i355
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The H4 Tail Domain Participates in Intra- and Internucleosome Interactions with Protein and DNA during Folding and Oligomerization of Nucleosome Arrays.

P.-Y. Kan, T. L. Caterino, and J. J. Hayes (2009)
Mol. Cell. Biol. 29, 538-546
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Three-dimensional localization of CENP-A suggests a complex higher order structure of centromeric chromatin.

O. J. Marshall, A. T. Marshall, and K.H. A. Choo (2008)
J. Cell Biol. 183, 1193-1202
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Analysis of cryo-electron microscopy images does not support the existence of 30-nm chromatin fibers in mitotic chromosomes in situ.

M. Eltsov, K. M. MacLellan, K. Maeshima, A. S. Frangakis, and J. Dubochet (2008)
PNAS 105, 19732-19737
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Nucleosome repeat length and linker histone stoichiometry determine chromatin fiber structure.

A. Routh, S. Sandin, and D. Rhodes (2008)
PNAS 105, 8872-8877
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The Silent Information Regulator 3 Protein, SIR3p, Binds to Chromatin Fibers and Assembles a Hypercondensed Chromatin Architecture in the Presence of Salt.

S. J. McBryant, C. Krause, C. L. Woodcock, and J. C. Hansen (2008)
Mol. Cell. Biol. 28, 3563-3572
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Packaging the Genome: the Structure of Mitotic Chromosomes.

K. Maeshima and M. Eltsov (2008)
J. Biochem. 143, 145-153
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Site-specific Binding Affinities within the H2B Tail Domain Indicate Specific Effects of Lysine Acetylation.

X. Wang and J. J. Hayes (2007)
J. Biol. Chem. 282, 32867-32876
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The H3 Tail Domain Participates in Multiple Interactions during Folding and Self-Association of Nucleosome Arrays.

P.-Y. Kan, X. Lu, J. C. Hansen, and J. J. Hayes (2007)
Mol. Cell. Biol. 27, 2084-2091
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Disulfide cross-linking indicates that FlgM-bound and free {sigma}28 adopt similar conformations.

M. K. Sorenson and S. A. Darst (2006)
PNAS 103, 16722-16727
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Role of histone tails in chromatin folding revealed by a mesoscopic oligonucleosome model.

G. Arya and T. Schlick (2006)
PNAS 103, 16236-16241
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Human ACF1 Alters the Remodeling Strategy of SNF2h.

X. He, H.-Y. Fan, G. J. Narlikar, and R. E. Kingston (2006)
J. Biol. Chem. 281, 28636-28647
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EM measurements define the dimensions of the "30-nm" chromatin fiber: Evidence for a compact, interdigitated structure.

P. J. J. Robinson, L. Fairall, V. A. T. Huynh, and D. Rhodes (2006)
PNAS 103, 6506-6511
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Aspects of large-scale chromatin structures in mouse liver nuclei can be predicted from the DNA sequence.

A. Cioffi, T. J. Fleury, and A. Stein (2006)
Nucleic Acids Res. 34, 1974-1981
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Histone H4-K16 Acetylation Controls Chromatin Structure and Protein Interactions.

M. Shogren-Knaak, H. Ishii, J.-M. Sun, M. J. Pazin, J. R. Davie, and C. L. Peterson (2006)
Science 311, 844-847
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The Core Histone N-terminal Tail Domains Function Independently and Additively during Salt-dependent Oligomerization of Nucleosomal Arrays.

F. Gordon, K. Luger, and J. C. Hansen (2005)
J. Biol. Chem. 280, 33701-33706
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Salt-dependent Intra- and Internucleosomal Interactions of the H3 Tail Domain in a Model Oligonucleosomal Array.

C. Zheng, X. Lu, J. C. Hansen, and J. J. Hayes (2005)
J. Biol. Chem. 280, 33552-33557
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Alteration of the nucleosomal DNA path in the crystal structure of a human nucleosome core particle.

Y. Tsunaka, N. Kajimura, S.-i. Tate, and K. Morikawa (2005)
Nucleic Acids Res. 33, 3424-3434
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Electrostatic mechanism of nucleosomal array folding revealed by computer simulation.

J. Sun, Q. Zhang, and T. Schlick (2005)
PNAS 102, 8180-8185
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Chromatin modifying activity of leukaemia associated fusion proteins.

L. Di Croce (2005)
Hum. Mol. Genet. 14, R77-R84
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