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

The compaction level of arrays of nucleosomes may be understood in terms of the balance between the self-repulsion of DNA (principally linker DNA) and countering factors including the ionic strength and composition of the medium, the highly basic N termini of the core histones, and linker histones. However, the structural principles that come into play during the transition from a loose chain of nucleosomes to a compact 30-nm chromatin fiber have been difficult to establish, and the arrangement of nucleosomes and linker DNA in condensed chromatin fibers has never been fully resolved. Based on images of the solution conformation of native chromatin and fully defined chromatin arrays obtained by electron cryomicroscopy, we report a linker histone-dependent architectural motif beyond the level of the nucleosome core particle that takes the form of a stem-like organization of the entering and exiting linker DNA segments. DNA completes approximately 1.7 turns on the histone octamer in the presence and absence of linker histone. When linker histone is present, the two linker DNA segments become juxtaposed approximately 8 nm from the nucleosome center and remain apposed for 3-5 nm before diverging. We propose that this stem motif directs the arrangement of nucleosomes and linker DNA within the chromatin fiber, establishing a unique three-dimensional zigzag folding pattern that is conserved during compaction. Such an arrangement with peripherally arranged nucleosomes and internal linker DNA segments is fully consistent with observations in intact nuclei and also allows dramatic changes in compaction level to occur without a concomitant change in topology.

[1]  A. Wolffe The transcription of chromatin templates. , 1994, Current opinion in genetics & development.

[2]  V. Ramakrishnan,et al.  Chromatin higher-order structure studied by neutron scattering and scanning transmission electron microscopy. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[3]  Alan P. Wolffe,et al.  Transcription: In tune with the histones , 1994, Cell.

[4]  J. Dubochet,et al.  DNA at the entry-exit of the nucleosome observed by cryoelectron microscopy. , 1995, Journal of structural biology.

[5]  R. Kingston,et al.  Repression and activation by multiprotein complexes that alter chromatin structure. , 1996, Genes & development.

[6]  C. Woodcock,et al.  Electron microscopy of chromatin. , 1997, Methods.

[7]  D. Z. Staynov,et al.  Possible nucleosome arrangements in the higher-order structure of chromatin , 1983 .

[8]  G. Felsenfeld,et al.  Chromatin as an essential part of the transcriptional mechanim , 1992, Nature.

[9]  J. Widom,et al.  A relationship between the helical twist of DNA and the ordered positioning of nucleosomes in all eukaryotic cells. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[10]  A Klug,et al.  Involvement of histone H1 in the organization of the nucleosome and of the salt-dependent superstructures of chromatin , 1979, The Journal of cell biology.

[11]  Butler Pj A defined structure of the 30 nm chromatin fibre which accommodates different nucleosomal repeat lengths. , 1984 .

[12]  J. Hansen,et al.  Reversible oligonucleosome self-association: dependence on divalent cations and core histone tail domains. , 1996, Biochemistry.

[13]  F. Crick Linking numbers and nucleosomes. , 1976, Proceedings of the National Academy of Sciences of the United States of America.

[14]  A. Wolffe,et al.  What do linker histones do in chromatin? , 1997, BioEssays : news and reviews in molecular, cellular and developmental biology.

[15]  D A Agard,et al.  The three-dimensional architecture of chromatin in situ: electron tomography reveals fibers composed of a continuously variable zig-zag nucleosomal ribbon , 1994, The Journal of cell biology.

[16]  B D Athey,et al.  Chromatin fibers are left-handed double helices with diameter and mass per unit length that depend on linker length. , 1986, Biophysical journal.

[17]  A. Wolffe,et al.  Nucleosome positioning and modification: chromatin structures that potentiate transcription. , 1994, Trends in biochemical sciences.

[18]  J. Dubochet,et al.  Chromatin conformation and salt-induced compaction: three-dimensional structural information from cryoelectron microscopy , 1995, The Journal of cell biology.

[19]  Andrzej Stasiak,et al.  Determination of the DNA helical repeat by cryo-electron microscopy , 1994, Nature Structural Biology.

[20]  R. Simpson Structure of the chromatosome, a chromatin particle containing 160 base pairs of DNA and all the histones. , 1978, Biochemistry.

[21]  H. Weintraub Assembly and propagation of repressed and derepressed chromosomal states , 1985, Cell.

[22]  F. Vella Chromatin structure and function: by A Wolffe. pp 213. Academic Press, London and San Diego. 1992. £14.95 , 1994 .

[23]  J. B. Rattner,et al.  The higher-order structure of chromatin: evidence for a helical ribbon arrangement , 1984, The Journal of cell biology.

[24]  J. Lepault,et al.  Electron cryo‐microscopy of vitrified biological specimens: towards high spatial and temporal resolution , 1994, Biology of the cell.

[25]  D A Agard,et al.  Automated microscopy for electron tomography. , 1992, Ultramicroscopy.

[26]  J. Ausió,et al.  Role of the histone "tails" in the folding of oligonucleosomes depleted of histone H1. , 1992, The Journal of biological chemistry.

[27]  D. Bates,et al.  Histones H1 and H5: one or two molecules per nucleosome? , 1981, Nucleic acids research.

[28]  J. Hansen,et al.  The nucleosomal array: structure/function relationships. , 1996, Critical reviews in eukaryotic gene expression.

[29]  B. Turner,et al.  Histone acetylation and control of gene expression. , 1991, Journal of cell science.

[30]  V. Ramakrishnan,et al.  Linker histone-dependent DNA structure in linear mononucleosomes. , 1996, Journal of molecular biology.

[31]  A. Prunell A topological approach to nucleosome structure and dynamics: the linking number paradox and other issues. , 1998, Biophysical journal.

[32]  F. Thoma,et al.  Involvement of the globular domain of histone H1 in the higher order structures of chromatin. , 1984, Journal of molecular biology.

[33]  P. Chambon,et al.  Folding of the DNA double helix in chromatin-like structures from simian virus 40. , 1975, Proceedings of the National Academy of Sciences of the United States of America.

[34]  V. Ramakrishnan,et al.  Histone H1 is located in the interior of the chromatin 30-nm filament , 1994, Nature.

[35]  T. Richmond,et al.  Crystal structure of the nucleosome core particle at 2.8 Å resolution , 1997, Nature.

[36]  J. Hansen,et al.  Core Histone Tail Domains Mediate Oligonucleosome Folding and Nucleosomal DNA Organization through Distinct Molecular Mechanisms (*) , 1995, The Journal of Biological Chemistry.

[37]  C. Woodcock,et al.  Chromatin organization re-viewed. , 1995, Trends in cell biology.

[38]  T. Kimura,et al.  Electrostatic mechanism of chromatin folding. , 1990, Journal of molecular biology.

[39]  B. Nordén,et al.  Reinterpretation of linear dichroism of chromatin supports a perpendicular linker orientation in the folded state. , 1990, Journal of biomolecular structure & dynamics.

[40]  K. V. van Holde,et al.  Homogeneous reconstituted oligonucleosomes, evidence for salt-dependent folding in the absence of histone H1. , 1989, Biochemistry.

[41]  A J Koster,et al.  Automated electron microscope tomography of frozen-hydrated chromatin: the irregular three-dimensional zigzag architecture persists in compact, isolated fibers. , 1997, Journal of structural biology.

[42]  S. Grigoryev,et al.  A chromatin folding model that incorporates linker variability generates fibers resembling the native structures. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[43]  J. Widom Physicochemical studies of the folding of the 100 A nucleosome filament into the 300 A filament. Cation dependence. , 1986, Journal of molecular biology.

[44]  G. Arents,et al.  Topography of the histone octamer surface: repeating structural motifs utilized in the docking of nucleosomal DNA. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[45]  C. Crane-Robinson Where is the globular domain of linker histone located on the nucleosome? , 1997, Trends in biochemical sciences.

[46]  J. Workman,et al.  Multiple functions of nucleosomes and regulatory factors in transcription. , 1993, Trends in biochemical sciences.

[47]  K. V. van Holde,et al.  Chromatin fiber structure: morphology, molecular determinants, structural transitions. , 1998, Biophysical journal.

[48]  K. V. van Holde,et al.  Chromatin Higher Order Structure: Chasing a Mirage?(*) , 1995, The Journal of Biological Chemistry.

[49]  E. Bradbury,et al.  Linker histones H1 and H5 prevent the mobility of positioned nucleosomes. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[50]  E. Bradbury,et al.  Chromatosome positioning on assembled long chromatin. Linker histones affect nucleosome placement on 5 S rDNA. , 1991, Journal of molecular biology.

[51]  J. Bednar,et al.  Linker histones stabilize the intrinsic salt-dependent folding of nucleosomal arrays: mechanistic ramifications for higher-order chromatin folding. , 1998, Biochemistry.

[52]  S. Elgin,et al.  Position effect variegation in Drosophila is associated with an altered chromatin structure. , 1995, Genes & development.

[53]  J. Hansen,et al.  Hybrid trypsinized nucleosomal arrays: identification of multiple functional roles of the H2A/H2B and H3/H4 N-termini in chromatin fiber compaction. , 1997, Biochemistry.

[54]  J. Hansen,et al.  Formation and stability of higher order chromatin structures. Contributions of the histone octamer. , 1994, Journal of Biological Chemistry.

[55]  K. V. van Holde,et al.  Three-dimensional structure of extended chromatin fibers as revealed by tapping-mode scanning force microscopy. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[56]  James Allan,et al.  Roles of H1 domains in determining higher order chromatin structure and H1 location. , 1986, Journal of molecular biology.

[57]  J. Allan,et al.  Participation of core histone "tails" in the stabilization of the chromatin solenoid , 1982, The Journal of cell biology.

[58]  F. Thoma,et al.  Chromatin reconstituted from tandemly repeated cloned DNA fragments and core histones: A model system for study of higher order structure , 1985, Cell.

[59]  J. Widom,et al.  Toward a unified model of chromatin folding. , 1989, Annual review of biophysics and biophysical chemistry.

[60]  E. Bradbury,et al.  Deposition of histone H1 onto reconstituted nucleosome arrays inhibits both initiation and elongation of transcripts by T7 RNA polymerase. , 1995, Nucleic acids research.

[61]  K. Holde The omnipotent nucleosome , 1993, Nature.

[62]  Claudio Nicolini,et al.  Chromatin Structure and Function , 1979, NATO Advanced Study Institutes Series.

[63]  H. Zentgraf,et al.  Biochemical and ultrastructural analysis of SV40 chromatin. , 1978, Cold Spring Harbor symposia on quantitative biology.

[64]  J. Dubochet,et al.  Cryo-electron microscopy of vitrified specimens , 1988, Quarterly Reviews of Biophysics.