Literature DB >> 11259307

DNA folding: structural and mechanical properties of the two-angle model for chromatin.

H Schiessel1, W M Gelbart, R Bruinsma.   

Abstract

We present a theoretical analysis of the structural and mechanical properties of the 30-nm chromatin fiber. Our study is based on the two-angle model introduced by Woodcock et al. (Woodcock, C. L., S. A. Grigoryev, R. A. Horowitz, and N. Whitaker. 1993. Proc. Natl. Acad. Sci. USA. 90:9021-9025) that describes the chromatin fiber geometry in terms of the entry-exit angle of the nucleosomal DNA and the rotational setting of the neighboring nucleosomes with respect to each other. We analytically explore the different structures that arise from this building principle, and demonstrate that the geometry with the highest density is close to the one found in native chromatin fibers under physiological conditions. On the basis of this model we calculate mechanical properties of the fiber under stretching. We obtain expressions for the stress-strain characteristics that show good agreement with the results of recent stretching experiments (Cui, Y., and C. Bustamante. 2000. Proc. Natl. Acad. Sci. USA. 97:127-132) and computer simulations (Katritch, V., C. Bustamante, and W. K. Olson. 2000. J. Mol. Biol. 295:29-40), and which provide simple physical insights into correlations between the structural and elastic properties of chromatin.

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Year:  2001        PMID: 11259307      PMCID: PMC1301383          DOI: 10.1016/S0006-3495(01)76164-4

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  30 in total

1.  Self-assembly in vivo.

Authors:  S Fraden; R D Kamien
Journal:  Biophys J       Date:  2000-05       Impact factor: 4.033

2.  Chiral discotic columnar germs of nucleosome core particles.

Authors:  F Livolant; A Leforestier
Journal:  Biophys J       Date:  2000-05       Impact factor: 4.033

3.  Pulling a single chromatin fiber reveals the forces that maintain its higher-order structure.

Authors:  Y Cui; C Bustamante
Journal:  Proc Natl Acad Sci U S A       Date:  2000-01-04       Impact factor: 11.205

4.  Pulling chromatin fibers: computer simulations of direct physical micromanipulations.

Authors:  V Katritch; C Bustamante; W K Olson
Journal:  J Mol Biol       Date:  2000-01-07       Impact factor: 5.469

5.  Solenoidal model for superstructure in chromatin.

Authors:  J T Finch; A Klug
Journal:  Proc Natl Acad Sci U S A       Date:  1976-06       Impact factor: 11.205

6.  Dinucleosomes show compaction by ionic strength, consistent with bending of linker DNA.

Authors:  P J Butler; J O Thomas
Journal:  J Mol Biol       Date:  1998-08-21       Impact factor: 5.469

7.  Nucleosomes, linker DNA, and linker histone form a unique structural motif that directs the higher-order folding and compaction of chromatin.

Authors:  J Bednar; R A Horowitz; S A Grigoryev; L M Carruthers; J C Hansen; A J Koster; C L Woodcock
Journal:  Proc Natl Acad Sci U S A       Date:  1998-11-24       Impact factor: 11.205

8.  Structure of the 300A chromatin filament: X-ray diffraction from oriented samples.

Authors:  J Widom; A Klug
Journal:  Cell       Date:  1985-11       Impact factor: 41.582

9.  Physicochemical studies of the folding of the 100 A nucleosome filament into the 300 A filament. Cation dependence.

Authors:  J Widom
Journal:  J Mol Biol       Date:  1986-08-05       Impact factor: 5.469

10.  Involvement of histone H1 in the organization of the nucleosome and of the salt-dependent superstructures of chromatin.

Authors:  F Thoma; T Koller; A Klug
Journal:  J Cell Biol       Date:  1979-11       Impact factor: 10.539
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  42 in total

1.  Internucleosomal interactions mediated by histone tails allow distant communication in chromatin.

Authors:  Olga I Kulaeva; Guohui Zheng; Yury S Polikanov; Andrew V Colasanti; Nicolas Clauvelin; Swagatam Mukhopadhyay; Anirvan M Sengupta; Vasily M Studitsky; Wilma K Olson
Journal:  J Biol Chem       Date:  2012-04-19       Impact factor: 5.157

2.  The effect of linker histone's nucleosome binding affinity on chromatin unfolding mechanisms.

Authors:  Rosana Collepardo-Guevara; Tamar Schlick
Journal:  Biophys J       Date:  2011-10-05       Impact factor: 4.033

3.  Exploring the conformational space of chromatin fibers and their stability by numerical dynamic phase diagrams.

Authors:  René Stehr; Robert Schöpflin; Ramona Ettig; Nick Kepper; Karsten Rippe; Gero Wedemann
Journal:  Biophys J       Date:  2010-03-17       Impact factor: 4.033

4.  Histone depletion facilitates chromatin loops on the kilobasepair scale.

Authors:  Philipp M Diesinger; Susanne Kunkel; Jörg Langowski; Dieter W Heermann
Journal:  Biophys J       Date:  2010-11-03       Impact factor: 4.033

5.  Local geometry and elasticity in compact chromatin structure.

Authors:  Elena F Koslover; Colin J Fuller; Aaron F Straight; Andrew J Spakowitz
Journal:  Biophys J       Date:  2010-12-15       Impact factor: 4.033

6.  Electrostatic mechanism of nucleosomal array folding revealed by computer simulation.

Authors:  Jian Sun; Qing Zhang; Tamar Schlick
Journal:  Proc Natl Acad Sci U S A       Date:  2005-05-26       Impact factor: 11.205

7.  Flexible histone tails in a new mesoscopic oligonucleosome model.

Authors:  Gaurav Arya; Qing Zhang; Tamar Schlick
Journal:  Biophys J       Date:  2006-04-07       Impact factor: 4.033

8.  Role of histone tails in chromatin folding revealed by a mesoscopic oligonucleosome model.

Authors:  Gaurav Arya; Tamar Schlick
Journal:  Proc Natl Acad Sci U S A       Date:  2006-10-23       Impact factor: 11.205

9.  Nucleosome geometry and internucleosomal interactions control the chromatin fiber conformation.

Authors:  Nick Kepper; Dietrich Foethke; Rene Stehr; Gero Wedemann; Karsten Rippe
Journal:  Biophys J       Date:  2008-01-22       Impact factor: 4.033

10.  The influence of the cylindrical shape of the nucleosomes and H1 defects on properties of chromatin.

Authors:  Philipp M Diesinger; Dieter W Heermann
Journal:  Biophys J       Date:  2008-01-30       Impact factor: 4.033
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