Histone octamer function in vivo: mutations in the dimer-tetramer interfaces disrupt both gene activation and repression.

Within the core histone octamer each histone H4 interacts with each H2A-H2B dimer subunit through two binding surfaces. Tyrosines play a central role in these interactions with H4 tyrosines 72 and 88 contacting one H2A-H2B dimer subunit, and tyrosine 98 contacting the other. To investigate the roles of these interactions in vivo, we made site-directed amino acid substitutions at each of these tyrosine residues. Elimination of either set of interactions is lethal, suggesting that binding of the tetramer to both dimers is essential. Temperature-sensitive mutants were obtained through single amino acid substitutions at each of the tyrosines. The mutants show both strong positive and negative effects on transcription. Positive effects include Spt- and Sin-phenotypes resulting from mutations at each of the three tyrosines. One allele has a strong negative effect on the expression of genes essential for the G1 cell cycle transition. At restrictive temperature, mutant cells fail to express the CLN1, CLN2, SWI4 and SWI6 genes, and have reduced levels of CLN3 mRNA. These results demonstrate the critical role of histone dimer-tetramer interactions in vivo, and define their essential role in the expression of genes regulating G1 cell cycle progression.

An asymmetric model for the nucleosome: a binding site for linker histones inside the DNA gyres.

Histone-DNA contacts within a nucleosome influence the function of trans-acting factors and the molecular machines required to activate the transcription process. The internal architecture of a positioned nucleosome has now been probed with the use of photoactivatable cross-linking reagents to determine the placement of histones along the DNA molecule. A model for the nucleosome is proposed in which the winged-helix domain of the linker histone is asymmetrically located inside the gyres of DNA that also wrap around the core histones. This domain extends the path of the protein superhelix to one side of the core particle.

Amino acid substitutions in the structured domains of histones H3 and H4 partially relieve the requirement of the yeast SWI/SNF complex for transcription.

Transcription of many yeast genes requires the SWI/SNF regulatory complex. Prior studies show that reduced transcription of the HO gene in swi and snf mutants is partially relieved by mutations in the SIN1 and SIN2 genes. Here we show that SIN2 is identical to HHT1, one of the two genes coding for histone H3, and that mutations in either can result in a Sin- phenotype. These mutations are partially dominant to wild type and cause amino acid substitutions in three conserved positions in the structured domain of histone H3. We have also identified partially dominant sin mutations that affect two conserved positions in the histone-fold domain of histone H4. Three sin mutations affect surface residues proposed to interact with DNA and may reduce affinity of DNA for the histone octamer. Two sin mutations affect residues at or near interfaces between (H2A-H2B) dimer and (H3-H4)2 tetramer subunits of the histone octamer and may affect nucleosome stability or conformation. The ability of mutations affecting the structure of the histone octamer to relieve the need for SWI and SNF products supports the proposal that the SWI/SNF complex stimulates transcription by altering chromatin structure and can account for the apparent conservation of SWI and SNF proteins in eukaryotes other than yeast.

The histone fold: a ubiquitous architectural motif utilized in DNA compaction and protein dimerization.

The histones of all eukaryotes show only a low degree of primary structure homology, but our earlier crystallographic results defined a three-dimensional structural motif, the histone fold, common to all core histones. We now examine the specific architectural patterns within the fold and analyze the nature of the amino acid residues within its functional segments. The histone fold emerges as a fundamental protein dimerization motif while the differentiations of the tips of the histone dimers appear to provide the rules of core octamer assembly and the basis for nucleosome regulation. We present evidence for the occurrence of the fold from archaebacteria to mammals and propose the use of this structural motif to define a distinct family of proteins, the histone fold superfamily. It appears that evolution has conserved the conformation of the fold even through variations in primary structure and among proteins with various functional roles.

A variety of DNA-binding and multimeric proteins contain the histone fold motif.

The histone fold motif has previously been identified as a structural feature common to all four core histones and is involved in both histone-histone and histone-DNA interactions. Through the use of a novel motif searching method, a group of proteins containing the histone fold motif has been established. The proteins in this group are involved in a wide variety of functions related mostly to DNA metabolism. Most of these proteins engage in protein-protein or protein-DNA interactions, as do their core histone counterparts. Among these, CCAAT-specific transcription factor CBF and its yeast homologue HAP are two examples of multimeric complexes with different component subunits that contain the histone fold motif. The histone fold proteins are distantly related, with a relatively small degree of absolute sequence similarity. It is proposed that these proteins may share a similar three-dimensional conformation despite the lack of significant sequence similarity.

Glycera dibranchiata hemoglobin. X-ray structure of carbonmonoxide hemoglobin at 1.5 A resolution.

The structure of carbonmonoxide Glycera hemoglobin has been determined to 1.5 A resolution by X-ray diffraction. The model, including ordered solvent, has been refined by the method of restrained least-squares to an R-value of 0.146. The positions of 1104 protein atoms and the oxygens of 155 water molecules have been determined with an estimated r.m.s. error of 0.10 to 0.13 A. The r.m.s. errors in protein geometry are 0.027 A for bond distances, 0.038 A for angle distances and 0.012 A for deviations of planar groups from their least-squares planes. The iron lies exactly in the plane of the heme nitrogens and the heme is very slightly domed toward the proximal side. The carbon-oxygen bond in the carbon monoxide ligand is bent 7.9 degrees away from the normal to the plane of the heme nitrogens. The ligand is in close contact with, and slightly removed from the heme normal by distal residues Leu 58(E7) and Val62(E11). Comparison of the CO structure with the 1.5 A deoxy structure shows that the majority of the rather small structural changes occurring upon ligation are mediated by movement of the heme due to shortening of the five iron to nitrogen bonds. There is very little empty space inside the molecule, and no direct channel from the solvent into the heme pocket; however, rotation of the side-chain of the distal leucine residue Leu 58(E6) could provide a ligand pathway.

The octameric histone core of the nucleosome. Structural issues resolved.

The crystal structure of the histone octamer has now been determined at 3.1 A resolution and refined to a crystallographic R value of 25.5%. The overall shape of the structure is significantly different from that originally reported by Burlingame et al. and its length is now in agreement with that observed by Klug et al. in their low-resolution studies. The experimental intensity data used in constructing the new electron density map were the same as those used by Burlingame et al. for the original electron density map. In addition, the methods used in producing the new density map were also the same as those for the original map. The only difference between the two calculations was the selection of the heavy-atom location. The large change seen in the structural image (110 A x 70 A x 70 A versus 55 A x 70 A x 70 A) was due to a relatively small change (2.27 A shift) of the heavy-atom site. The fact that the shape and size of the original structure were incorrect is surprising and unusual, since the electron density map that produced the original model was clear for most parts of the structure; one could easily see the well-formed right-handed helices of the H2A and H2B molecules, and the ordered parts of the H2A and H2B molecules could be easily traced from end to end. A comparison of the two maps shows that the original image was derived from two fused copies of the correct structure rotated by +/- 120 degrees from its true location along a rotation axis parallel to the z-axis and the image seen was a partial (about 19.5%) overlap of two molecules. An explanation is given as to how such a small shift of the heavy-atom position could create such a double image in the unit cell, and how the original electron density map could be converted to the new map by a phase modification in the Fourier synthesis. This study resolves the differences between the analyses of the shape and size of the histone octamer structure.

Topography of the histone octamer surface: repeating structural motifs utilized in the docking of nucleosomal DNA.

The histone octamer core of the nucleosome is a protein superhelix of four spirally arrayed histone dimers. The cylindrical face of this superhelix is marked by intradimer and interdimer pseudodyad axes, which derive from the nature of the histone fold. The histone fold appears as the result of a tandem, parallel duplication of the "helix-strand-helix" motif. This motif, by its occurrence in the four dimers, gives rise to repetitive structural elements--i.e., the "parallel beta bridges" and the "paired ends of helix I" motifs. A preponderance of positive charges on the surface of the octamer appears as a left-handed spiral situated at the expected path of the DNA. We have matched a subset of DNA pseudodyads with the octamer pseudodyads and thus have built a model of the nucleosome. In it, the two DNA strands coincide with the path of the histone-positive charges, and the central 12 turns of the double helix contact the surface of the octamer at the repetitive structural motifs. The properties of these complementary contacts appear to explain the preference of histones for double-helical DNA and to suggest a possible basis for allosteric regulation of nucleosome function.

The nucleosomal core histone octamer at 3.1 A resolution: a tripartite protein assembly and a left-handed superhelix.

The structure of the octameric histone core of the nucleosome has been determined by x-ray crystallography to a resolution of 3.1 A. The histone octamer is a tripartite assembly in which a centrally located (H3-H4)2 tetramer is flanked by two H2A-H2B dimers. It has a complex outer surface; depending on the perspective, the structure appears as a wedge or as a flat disk. The disk represents the planar projection of a left-handed proteinaceous superhelix with approximately 28 A pitch. The diameter of the particle is 65 A and the length is 60 A at its maximum and approximately 10 A at its minimum extension; these dimensions are in agreement with those reported earlier by Klug et al. [Klug, A., Rhodes, D., Smith, J., Finch, J. T. & Thomas, J. O. (1980) Nature (London) 287, 509-516]. The folded histone chains are elongated rather than globular and are assembled in a characteristic "handshake" motif. The individual polypeptides share a common central structural element of the helix-loop-helix type, which we name the histone fold.

Glycera dibranchiata hemoglobin. Structure and refinement at 1.5 A resolution.

The coelomic cells of the common marine bloodworm Glycera dibranchiata contain several hemoglobin monomers and polydisperse polymers. We present the refined structure of one of the Glycera monomers at 1.5 A resolution. The molecular model for protein and ordered solvent for the deoxy form of the Glycera monomer has been refined to a crystallographic R-factor of 12.7% against an X-ray diffraction dataset at 1.5 A resolution. The positions of 1095 protein atoms have been determined with a maximum root-mean-square (r.m.s.) error of 0.13 A, and the r.m.s. deviation from ideal bond lengths is 0.015 A and from ideal bond angles is 1.0 degree. The r.m.s. deviation of planar groups from their least-squares planes is 0.007 A, and the r.m.s. deviation for torsion angles is 1.2 degrees for peptide groups and 16.8 degrees for side-chains. A total of 153 water molecules has been located, and they have been refined to a final average occupancy of 0.80. Multiple conformations have been found for five side-chains, and a change has been suggested for the sequence at five residues. The heme group is present in the "reverse" orientation that differs only in the positions of the vinyl beta-carbons from the "normal" orientation. The doming of the heme towards the proximal side, and the bond distances and angles of the heme and proximal histidine are typical of most deoxy globin structures. The substitution of leucine for the distal histidine residue (E7) creates an unusually hydrophobic heme pocket.