Chromatin structure plays a fundamental role in the regulation of nuclear processes such as DNA transcription, replication, recombination, and repair. Despite considerable efforts during three decades, the structure of the 30-nm chromatin fiber remains controversial. To define fiber dimensions accurately, we have produced very long and regularly folded 30-nm fibers from in vitro reconstituted nucleosome arrays containing the linker histone and with increasing nucleosome repeat lengths (10 to 70 bp of linker DNA). EM measurements show that the dimensions of these fully folded fibers do not increase linearly with increasing linker length, a finding that is inconsistent with two-start helix models. Instead, we find that there are two distinct classes of fiber structure, both with unexpectedly high nucleosome density: arrays with 10 to 40 bp of linker DNA all produce fibers with a diameter of 33 nm and 11 nucleosomes per 11 nm, whereas arrays with 50 to 70 bp of linker DNA all produce 44-nm-wide fibers with 15 nucleosomes per 11 nm. Using the physical constraints imposed by these measurements, we have built a model in which tight nucleosome packing is achieved through the interdigitation of nucleosomes from adjacent helical gyres. Importantly, the model closely matches raw image projections of folded chromatin arrays recorded in the solution state by using electron cryo-microscopy.chromatin structure ͉ electron microscopy ͉ linker histone ͉ reconstitution E ukaryotic chromosomes have a compact structure in which linear nucleosome arrays are first folded into a fiber of around 30-nm diameter (1, 2). The fundamental repeating unit of chromatin, the nucleosome core particle, organizes 147 bp of DNA in 1.7 left-handed superhelical turns around an octamer of the four core histones (H2A, H2B, H3, and H4) (3-5). Linker histone (H1͞H5) binding organizes an additional 20 bp of DNA to complete the nucleosome containing 167 bp of DNA (6, 7). Such binding determines the geometry of the DNA entering and exiting the nucleosome core particle (8). In nucleosome arrays, adjacent nucleosomes are separated by linker DNA, varying in length between 0 and 80 bp in a tissue-and species-specific manner (9, 10). In vitro, linear nucleosome arrays fold into the ''30-nm'' fiber upon increasing ionic strength (11) in a process that depends on both the integrity of the core histone N-terminal tails (12, 13) and the presence of the linker histone (14,15).During the past three decades evidence from EM (14-23), x-ray and neutron scattering (24-27), electric and photochemical dichroism (28-31), sedimentation analysis (32-35), nuclease digestion (6, 9, 36), and x-ray crystallography (4, 5, 37, 38) has led to the proposal of a number of different models for the 30-nm fiber. These models fall into two main classes: the one-start helix or solenoid models, and the two-start helix models. The solenoid models are comprised of simple one-start helices in which successive nucleosomes are adjacent in the filament and connected by linker DNA that bends into t...
The mechanisms by which chromatin structure decompacts to permit access to DNA are largely unknown. Here, using a model nucleosome array system reconstituted from recombinant histone octamers we have defined the relative contribution of the individual histone octamer N-terminal tails as well as the effect of a targeted histone tail acetylation on the compaction state of thè 30nm' chromatin fibre. This study goes beyond previous studies as it is based on a nucleosome array that is very long (61 nucleosomes) and contains stoichiometric concentrations of bound linker histone, which is essential for the formation of the `30nm' chromatin fibre. We find that compaction is regulated in two steps: Introduction of H4 acetylated to 30% on K16 inhibits compaction to a greater degree than deletion of the H4 N-terminal tail. Further decompaction is achieved by removal of the linker histone.
SUMMARY A complete, 52-protein, 2.5 million Dalton, Mediator-RNA polymerase II pre-initiation complex (Med-PIC) was assembled and analyzed by cryo-electron microscopy and by chemical cross-linking and mass spectrometry. The resulting complete Med-PIC structure reveals two components of functional significance, absent from previous structures, a protein kinase complex and the Mediator-activator interaction region. It thereby shows how the kinase and its target, the C-terminal domain of the polymerase, control Med-PIC interaction and transcription.
Human killer cell immunoglobulin-like receptors (KIRs) are distinguished by expansion of activating KIR2DS, whose ligands and functions remain poorly understood. The oldest, most prevalent KIR2DS is KIR2DS4, which is represented by a variable balance between “full-length” and “deleted” forms. We find that full-length 2DS4 is a human histocompatibility leukocyte antigen (HLA) class I receptor that binds specifically to subsets of C1+ and C2+ HLA-C and to HLA-A*11, whereas deleted 2DS4 is nonfunctional. Activation of 2DS4+ NKL cells was achieved with A*1102 as ligand, which differs from A*1101 by unique substitution of lysine 19 for glutamate, but not with A*1101 or HLA-C. Distinguishing KIR2DS4 from other KIR2DS is the proline–valine motif at positions 71–72, which is shared with KIR3DL2 and was introduced by gene conversion before separation of the human and chimpanzee lineages. Site-directed swap mutagenesis shows that these two residues are largely responsible for the unique HLA class I specificity of KIR2DS4. Determination of the crystallographic structure of KIR2DS4 shows two major differences from KIR2DL: displacement of contact loop L2 and altered bonding potential because of the substitutions at positions 71 and 72. Correlation between the worldwide distributions of functional KIR2DS4 and HLA-A*11 points to the physiological importance of their mutual interaction.
Chemical cross-linking mass spectrometry identifies interacting surfaces within a protein assembly through labeling with bifunctional reagents and identifying the covalently modified peptides. These yield distance constraints that provide a powerful means to model the three-dimensional structure of the assembly. Bioinformatic analysis of crosslinked data resulting from large protein assemblies is challenging because each cross-linked product contains two covalently linked peptides, each of which must be correctly identified from a complex matrix of potential confounders.Protein Prospector addresses these issues through a complementary mass modification strategy in which each peptide is searched and identified separately. We demonstrate this strategy with an analysis of RNA polymerase II. False discovery rates (FDRs) are assessed via comparison of cross-linking data to crystal structure, as well as by using a decoy database strategy. Parameters that are most useful for positive identification of cross-linked spectra are explored. We find that fragmentation spectra generally contain more product ions from one of the two peptides constituting the cross-link. Hence, metrics reflecting the quality of the spectral match to the less confident peptide provide the most discriminatory power between correct and incorrect matches. A support vector machine model was built to further improve classification of cross-linked peptide hits. Furthermore, the frequency with which peptides cross-linked via common acylating reagents fragment to produce diagnostic, cross-linkerspecific ions is assessed.The threshold for successful identification of the cross-linked peptide product depends upon the complexity of the sample under investigation. Protein Prospector, by focusing the reliability assessment on the least confident peptide, is better able to control the FDR for results as larger complexes and databases are ana- Most proteins are organized into stable assemblies that communicate among themselves through transient proteinprotein interaction networks to catalyze cellular phenomena. Chemical cross-linking mass spectrometry directly measures protein-protein interactions by using bifunctional cross-linking reagents to covalently link surfaces of interacting partners (1-3). Following proteolysis, mass spectrometry is used to identify the covalently linked peptides and modified residues. This information, taken together with the geometry of the cross-linking reagent, provides distance constraints that are reflective of the three-dimensional structure of the protein complex. Cross-linking-derived distance constraints provide a powerful means by which to integrate atomic resolution structures of individual protein subunits or subassemblies with low-resolution electron-microscopy-derived structures, as well as to clarify molecular details that are unresolved in electron density maps. For instance, this approach has recently been applied to modeling the RNA Pol II preinitiation complex (4), several chromatin remodeling complexes (5, 6), th...
The 21-subunit Mediator complex transduces regulatory information from enhancers to promoters, and performs an essential role in the initiation of transcription in all eukaryotes. Structural information on two-thirds of the complex has been limited to coarse subunit mapping onto 2-D images from electron micrographs. We have performed chemical cross-linking and mass spectrometry, and combined the results with information from X-ray crystallography, homology modeling, and cryo-electron microscopy by an integrative modeling approach to determine a 3-D model of the entire Mediator complex. The approach is validated by the use of X-ray crystal structures as internal controls and by consistency with previous results from electron microscopy and yeast two-hybrid screens. The model shows the locations and orientations of all Mediator subunits, as well as subunit interfaces and some secondary structural elements. Segments of 20–40 amino acid residues are placed with an average precision of 20 Å. The model reveals roles of individual subunits in the organization of the complex.DOI: http://dx.doi.org/10.7554/eLife.08719.001
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