A pH-dependent interaction between histones H2A and H2B involving secondary and tertiary folding

Investigating the stability of dengue virus envelope protein dimer using well-tempered metadynamics simulations

We explored the stability of the dengue virus envelope (E) protein dimer since it is widely assumed that the E protein dimer is stabilized by drug ligands or antibodies in an acidic environment, neutralizing the virus's ability to fuse with human cells. During this process, a large conformational change of the E protein dimer is required. We performed Molecular Dynamics simulations to mimic the conformational change and stability of the dimer in neutral and acidic conditions with the well-tempered metadynamics method. Furthermore, as a few neutralizing antibodies discovered from dengue patients were reported, we used the same simulation method to examine the influence of a selected antibody on the dimer stability in both neutral and acidic conditions. We also investigated the antibody's influence on a point-mutated E protein that had been reported to interrupt the protein-antibody interaction and result in more than 95% loss of the antibody's binding ability. Our simulation results are highly consistent with the experimental conclusion that binding of the antibody to the E protein dimer neutralizes the virus, especially in a low pH condition, while the mutation of W101A or N153A significantly reduces the antibody's ability in stabilizing the E protein dimer. We demonstrate that well-tempered metadynamics can be used to accurately explore the antibody's interaction on large protein complexes such as the E protein dimer, and the computational approach in this work is promising in future antibody development.

Unspinning chromatin: Revealing the dynamic nucleosome landscape by NMR

NMR is an essential technique for obtaining information at atomic resolution on the structure, motions and interactions of biomolecules. Here, we review the contribution of NMR to our understanding of the fundamental unit of chromatin: the nucleosome. Nucleosomes compact the genome by wrapping the DNA around a protein core, the histone octamer, thereby protecting genomic integrity. Crucially, the imposed barrier also allows strict regulation of gene expression, DNA replication and DNA repair processes through an intricate system of histone and DNA modifications and a wide range of interactions between nucleosomes and chromatin factors. In this review, we describe how NMR has contributed to deciphering the molecular basis of nucleosome function. Starting from pioneering studies in the 1960s using natural abundance NMR studies, we focus on the progress in sample preparation and NMR methodology that has allowed high-resolution studies on the nucleosome and its subunits. We summarize the results and approaches of state-of-the-art NMR studies on nucleosomal DNA, histone complexes, nucleosomes and nucleosomal arrays. These studies highlight the particular strength of NMR in studying nucleosome dynamics and nucleosome-protein interactions. Finally, we look ahead to exciting new possibilities that will be afforded by on-going developments in solution and solid-state NMR. By increasing both the depth and breadth of nucleosome NMR studies, it will be possible to offer a unique perspective on the dynamic landscape of nucleosomes and its interacting proteins.

The divergence, actions, roles, and relatives of sodium-coupled bicarbonate transporters

The mammalian Slc4 (Solute carrier 4) family of transporters is a functionally diverse group of 10 multi-spanning membrane proteins that includes three Cl-HCO3 exchangers (AE1-3), five Na(+)-coupled HCO3(-) transporters (NCBTs), and two other unusual members (AE4, BTR1). In this review, we mainly focus on the five mammalian NCBTs-NBCe1, NBCe2, NBCn1, NDCBE, and NBCn2. Each plays a specialized role in maintaining intracellular pH and, by contributing to the movement of HCO3(-) across epithelia, in maintaining whole-body pH and otherwise contributing to epithelial transport. Disruptions involving NCBT genes are linked to blindness, deafness, proximal renal tubular acidosis, mental retardation, and epilepsy. We also review AE1-3, AE4, and BTR1, addressing their relevance to the study of NCBTs. This review draws together recent advances in our understanding of the phylogenetic origins and physiological relevance of NCBTs and their progenitors. Underlying these advances is progress in such diverse disciplines as physiology, molecular biology, genetics, immunocytochemistry, proteomics, and structural biology. This review highlights the key similarities and differences between individual NCBTs and the genes that encode them and also clarifies the sometimes confusing NCBT nomenclature.

Conformations and flexibilities of histones and high mobility group (HMG) proteins in chromatin structure and function

The packaging of the enormous lengths of eukaryotic DNA into the different conformational states of chromosomes is controlled very largely by an equal total mass of the histones, H1, H2A, H2B, H3 and H4. Histone sequences, sequence conservations, postsynthetic chemical modifications and studies of histone conformations and interactions show clearly that histones are multi-domain proteins. The N-terminal domains of all histones and the C-terminal domains of H1, H2A and H2B are flexible random coils, while the C-terminal regions of H3 and H4 and the central regions of H1, H2A and H2B are structured. Histones H3 and H4 are essential for nucleosome structure and interact with DNA to give the nucleus of the nucleosome structure, which is completed by interactions of the conserved structured regions of (H2A, H2B) dimers and H1. The flexible domains of all the histones are very basic and contain all the sites of reversible chemical modifications: acetylation of lysines in the core histones and phosphorylation of serines and threonines in histone H1. Strict correlations have been observed (i) between acetylation and DNA processing and (ii) between H1 phosphorylation and chromosome condensation. In addition to histone acetylation, active chromatin is also associated with high mobility group (HMG) proteins 14 and 17. These proteins are completely flexible under all solution conditions and their native structures must be imposed by their binding sites in active chromatin. The function of flexibility in these chromosomal proteins is not understood but is probably related to the enormous lengths of DNA which have to be controlled in the structures and function of chromosomes.

Distinct importin recognition properties of histones and chromatin assembly factors

Synthesis of the protein components of nuclear chromatin occurs in the cytoplasm, necessitating specific import into the nucleus. Here, we report the binding affinities of the nuclear localisation sequence (NLS)-binding importin subunits for a range of histones and chromatin assembly factors. The results suggest that import of histones to the nucleus may be mediated predominantly by importin beta1, whereas the import of the other components probably relies on the conventional alpha/beta1 import pathway. Differences in recognition by importin beta1 were observed between histone H2A and the variant H2AZ, as well as between histone H3/4 with or without acetylation. The results imply that different histone variants may possess distinct nuclear import properties, with acetylation possibly playing an inhibitory role through NLS masking.

The histone fold: evolutionary questions

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Compactness of protein molten globules: temperature-induced structural changes of the apomyoglobin folding intermediate

Apomyoglobin undergoes a two-step unfolding transition when the pH is lowered from 6 to 2. The partly folded intermediate (I) state at pH 4 and low ionic strength has properties of a molten globule. We have studied structural features of this state, its compactness, content of secondary structure, and specific packing of aromatic side chains, using dynamic light scattering, and small-angle X-ray scattering and far- and near-ultraviolet circular dichroism spectroscopy. Particular attention was paid to temperature-dependent structural changes. The results are discussed with reference to the native-like (N) state and the highly unfolded (U) state. It turned out that the I-state is most compact near 30 degrees C, having a Stokes radius 20% larger and a radius of gyration 30% larger than those of the N-state. Both cooling and heating relative to 30 degrees C led to an expansion of the molecule, but the structural changes at low and high temperatures were of a different kind. At temperatures above 40 degrees C non co-operative melting of structural elements was observed, while the secondary structure was essentially retained on cooling. The results are discussed in context with theoretical predictions of the compactness and the stability of apomyoglobin by Alonso et al. [Alonso, D. O. V., Dill, K. A., and Stigter, D. (1991) Biopolymers 31:1631-1649]. Comparing the I-state of apomyoglobin with the molten globules of alpha-lactalbumin and cytochrome c, we found that the compactness of the molten globule states of the three proteins decreases in the order alpha-lactalbumin > apocytochrome c > apomyoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)

Rearrangement of the histone H2A C-terminal domain in the nucleosome

Using zero-length covalent protein-DNA crosslinking, we have mapped the histone-DNA contacts in nucleosome core particles from which the C- and N-terminal domains of histone H2A were selectively trimmed by trypsin or clostripain. We found that the flexible trypsin-sensitive C-terminal domain of histone H2A contacts the dyad axis, whereas its globular domain contacts the end of DNA in the nucleosome core particle. The appearance of the histone H2A contact at the dyad axis occurs only in the absence of linker DNA and does not depend on the absence of linker histones. Our results show the ability of the histone H2A C-terminal domain to rearrange. This rearrangement might play a biological role in nucleosome disassembly and reassembly and the retention of the H2A-H2B dimer (or the whole octamer) during the passing of polymerases through the nucleosome.

Sequence differences between histones of procyclic Trypanosoma brucei brucei and higher eukaryotes

Four histones, a, b, c, d from procyclic Trypanosoma brucei brucei, which show similarities with the amino acid composition of the core histones H3, H2A, H2B and H4, were isolated and cleaved with Endoproteinase Glu-C. The fragments were separated by FPLC reversed phase chromatography and a subset of the fragments (a5, a9, b6, c8, d3, d9, d11) was subjected to sequence analysis. A 54-71% identity was found in the sequences of the fragment c8 and the C-terminal half of H2B and of three fragments of protein d covering the N-terminal half as well as the C-terminal region of H4. The amino acid sequence of the fragment a9 showed a 57 and 54% identity with H3 sequences of Saccharomyces cerevisiae and Xenopus laevis. Neither the a5 nor the b6 sequence could be aligned with histone sequences of other eukaryotes. The significant differences of 21-48% between the T.b. brucei histone sequences and those of calf thymus histones, which are more pronounced than the differences of Tetrahymena pyriformis and the higher eukaryote, resulted partially from replacements of amino acids with different properties and indicate specific patterns of histone-histone and/or histone-DNA contact sites in the nucleosome of T.b. brucei. These differences, together with the lack of a functional histone H1, may be sufficient to explain the lack of a salt-dependent formation of the nucleosome filament into the 30 nm fibre, which reflects alternative methods of organizing and processing the genetic information in the nucleus of the protozoan parasite and which may be of chemotherapeutic significance.

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.

A NMR study of mobility in the histone octamer

The histone octamer from chicken erythrocytes was studied in 2 M NaCl using 500 mHz 1H NMR spectroscopy. We compared the spectrum of control octamers with that of octamers isolated from trypsinized nucleosome core particles. We observe that the sharp resonances found in the spectrum of the native octamer disappear completely after trypsinization. Therefore, within the time frame of the NMR experiment, all of the mobile amino acid residues in the histone octamer are found in the well defined trypsin sensitive domains. These results indicate that there is a very clear structural demarcation between the random coil N- and C-terminal tails and the globular domains of the histones.

Spectropolarimetric analysis of the core histone octamer and its subunits

The secondary structure of the calf thymus core histone octamer, (H2A-H2B-H3-H4)2, and its two physiological subunits, the H2A-H2B dimer and (H3-H4)2 tetramer, was analyzed by ORD spectropolarimetry as a function of temperature and solvent ionic strength within the ranges of these experimental parameters where assembly of the core histone octamer exhibits pronounced sensitivity. While the secondary structure of the dimer is relatively stable from 0.1 to 2.0 M NaCl, the secondary structure of the tetramer exhibits complex changes over this range of NaCl concentrations. Both complexes exhibit only modest responses to temperature changes. ORD spectra of very high and very low concentrations of stoichiometric mixtures of the core histones revealed no evidence of changes in the ordered structure of the histones as a result of the octamer assembly process at NaCl concentrations above 0.67 M, nor were time-dependent changes detected in the secondary structure of tetramer dissolved in low ionic strength solvent. The secondary structure of the chicken erythrocyte octamer dissolved in high concentrations of ammonium sulfate, including those of our crystallization conditions, was found to be essentially unchanged from that in 2 M NaCl when examined by both ORD and CD spectropolarimetry. The two well-defined cleaved products of the H2A-H2B dimer, cH2A-H2B and cH2A-cH2B, exhibited reduced amounts of ordered structure; in the case of the doubly cleaved moiety cH2A-cH2B, the reductions were so pronounced as to suggest marked structural rearrangements.

H2A.X. a histone isoprotein with a conserved C-terminal sequence, is encoded by a novel mRNA with both DNA replication type and polyA 3' processing signals

A full length cDNA clone that directs the in vitro synthesis of human histone H2A isoprotein H2A.X has been isolated and sequenced. H2A.X contains 142 amino acid residues, 13 more than human H2A.1. The sequence of the first 120 residues of H2A.X is almost identical to that of human H2A.1. The sequence of the carboxy-terminal 22 residues of H2A.X is unrelated to any known sequence in vertebrate histone H2A; however, it contains a sequence homologous with those of several lower eukaryotes. This homology centers on the carboxy-terminal tetrapeptide which in H2A.X is SerGlnGluTyr. Homologous sequences are found in H2As of three types of yeasts, in Tetrahymena and Drosophila. Seven of the nine carboxy-terminal amino acids of H2A.X are identical with those of S. cerevisiae H2A.1. It is suggested that this H2A carboxy-terminal motif may be present in all eukaryotes. The H2A.X cDNA is 1585 bases long followed by a polyA tail. There are 73 nucleotides in the 5' UTR, 432 in the coding region, and 1080 in the 3' UTR. Even though H2A.X is considered a basal histone, being synthesized in G1 as well as in S-phase, and its mRNA contains polyA addition motifs and a polyA tail, its mRNA also contains the conserved stem-loop and U7 binding sequences involved in the processing and stability of replication type histone mRNAs. Two forms of H2A.X mRNA, consistent with the two sets of processing signals were found in proliferating cell cultures. One, about 1600 bases long, contains polyA; the other, about 575 bases long, lacks polyA. The short form behaves as a replication type histone mRNA, decreasing in amount when cell cultures are incubated with inhibitors of DNA synthesis, while the longer behaves as a basal type histone mRNA.

Structural differences between histone H1 molecules from sea urchin (Strongylocentrotus intermedius) sperm and calf thymus: hydrodynamic and c.d. studies

Comparative sedimentation, diffusion and circular dichroism (c.d.) measurements have been performed on two histones H1 from sperm of the sea urchin Strongylocentrotus intermedius (H1S) and from calf thymus (H1T), at a high salt concentration of M NaCl. Both the Stokes radius and the frictional ratio derived from the hydrodynamic parameters were found to be somewhat smaller for H1S than the corresponding values for H1T. In view of the considerably higher molar mass of H1S compared with that of H1T, this result indicates that H+S in 2 M NaCl has a more compact conformation than H1T, probably due to a higher degree of secondary structure in the flanking domains of H1S. The c.d. measurements likewise show that H1S has a higher content of ordered structures than H1T. Model considerations indicate that the C-terminal tail of H1S is the main candidate for accommodation of these additional secondary structure regions.

Amino acid sequences that determine the nuclear localization of yeast histone 2B

Histone-beta-galactosidase protein fusions were used to identify the domain of yeast histone 2B, which targets this protein to the nucleus. Amino acids 28 to 33 in H2B were required for nuclear localization of such fusion proteins and thus constitute a nuclear localization sequence. The amino acid sequence in this region (Gly-29 Lys Lys Arg Ser Lys Ala) is similar to the nuclear location signal in simian virus 40 large T antigen (Pro-126 Lys Lys Lys Arg Lys Val) (D. Kalderon, B.L. Roberts, W.D. Richardson, and A.E. Smith, Cell 39:499-509, 1984). A point mutation changing lysine 31 to methionine abolished nuclear localization of an H2B-beta-galactosidase fusion protein containing amino acids 1 to 33 of H2B. However, an H2B-beta-galactosidase fusion protein containing both this point mutation and the H2A interaction domain of H2B was nuclear localized. These results suggest that H2A and H2B may be cotransported to the nucleus as a heterodimer.

Sequence of cDNAs for mammalian H2A.Z, an evolutionarily diverged but highly conserved basal histone H2A isoprotein species

The nucleotide sequences of cDNAs for the evolutionarily diverged but highly conserved basal H2A isoprotein, H2A.Z, have been determined for the rat, cow, and human. As a basal histone, H2A.Z is synthesized throughout the cell cycle at a constant rate, unlinked to DNA replication, and at a much lower rate in quiescent cells. Each of the cDNA isolates encodes the entire H2A.Z polypeptide. The human isolate is about 1.0 kilobases long. It contains a coding region of 387 nucleotides flanked by 106 nucleotides of 5'UTR and 376 nucleotides of 3'UTR, which contains a polyadenylation signal followed by a poly A tail. The bovine and rat cDNAs have 97 and 94% nucleotide positional identity to the human cDNA in the coding region and 98% in the proximal 376 nucleotides of the 3'UTR which includes the polyadenylation signal. A potential stem-forming sequence imbedded in a direct repeat is found centered at 261 nucleotides into the 3'UTR. Each of the cDNA clones could be transcribed and translated in vitro to yield H2A.Z protein. The mammalian H2A.Z cDNA coding sequences are approximately 80% similar to those in chicken and 75% to those in sea urchin.

Amino acid sequences that determine the nuclear localization of yeast histone 2B

Histone-beta-galactosidase protein fusions were used to identify the domain of yeast histone 2B, which targets this protein to the nucleus. Amino acids 28 to 33 in H2B were required for nuclear localization of such fusion proteins and thus constitute a nuclear localization sequence. The amino acid sequence in this region (Gly-29 Lys Lys Arg Ser Lys Ala) is similar to the nuclear location signal in simian virus 40 large T antigen (Pro-126 Lys Lys Lys Arg Lys Val) (D. Kalderon, B.L. Roberts, W.D. Richardson, and A.E. Smith, Cell 39:499-509, 1984). A point mutation changing lysine 31 to methionine abolished nuclear localization of an H2B-beta-galactosidase fusion protein containing amino acids 1 to 33 of H2B. However, an H2B-beta-galactosidase fusion protein containing both this point mutation and the H2A interaction domain of H2B was nuclear localized. These results suggest that H2A and H2B may be cotransported to the nucleus as a heterodimer.

Polyamines permit the preparation of stable Physarum core particles which have a structure similar to those from higher eukaryotes

The inherent instability of Physarum nucleosome core particles prepared by micrococcal nuclease digestion in Na+/Ca2+ buffers can be overcome by the addition of 0.15 mM spermine and 0.5 mM spermidine. Neutron scattering, circular dichroism, nuclease digestion and thermal denaturation studies carried out on these stable monosomes show them to be very similar to those obtained from higher eukaryotes.

The chromatin of sea urchin sperm

Digestion of sea urchin sperm nuclei with micrococcal nuclease yields nucleosomal monomer fragments of 151 and 164 base pairs. Prior trypsin treatment of the sperm chromatin does not alter the size of these monomer DNA fragments despite the fact that the H1 histone is reduced to a limit globular peptide of about 83 residues. Heterologous reconstitution experiments show that this peptide is capable of protecting an extra 22 base pairs beyond the core particle in a chromatosome. Nuclease digestion of reconstitutes from DNA and sperm core histones yields a core monomer of about 141 base pairs. It is concluded that this sperm chromatin contains a chromatosome of 164 bp essentially similar to that observed in the more usual chromatins. Edman degradation of the H1 limit peptide shows its sequence to be closely analogous to the corresponding peptide of calf H1 and chicken H5. Circular dichroism studies of histone H1 from the sperm of three sea urchin species demonstrate the presence of trypsin-sensitive helical regions outside the globular domain that are absent in calf H1 and chicken H5.

DNA topology in a chromatin model system

The synthetic copolypeptide (Lys33, Leu67)100-Orn20, modeled on some general features of the histone sequences, has been found to supercoil the DNA double helix, wrapping it into a micelle, as a result of cohesive interactions between the polypeptide hydrophobic moieties. X-ray low-angle diffraction of complexes between the polypeptide and DNA is characterized by maxima at 50, 32, and 23 A, reminiscent of the chromatin pattern. The existence of a nucleosome-like structure along the DNA is suggested by gel electrophoresis analysis of DNA fragments after micrococcal nuclease digestion, showing the presence of a fragment of about 100 basepairs (bp) long. Topological experiments on the complexes with supercoiled as well as relaxed circular DNA by two-dimensional gel electrophoresis show the presence of left-handed superhelical turns. The results are in agreement with an intrinsic propensity of B-DNA to writhe into left-handed supercoils.

Structuring of H1 histone. Evidence of high-affinity binding sites for phosphate ions

Circular dichroism studies show that low concentrations of phosphate ions induce folding of the H1 histones. Sulfate and perchlorate anions have effects similar to phosphate indicating the presence on H1 histones of binding sites with high affinity for ions with tetrahedral geometry. In fact, the structuring efficiency of different ions, as determined by the midpoint value of the effect/concentration curve, is 0.05 M for NaCl, 0.005 M for NaClO4, 0.001 M for sodium phosphate and 0.0003 M for sodium sulfate on H1 histone from Chaetopterus variopedatus sperm chromatin. Phosphate shows similar folding efficiency also on calf thymus and on sea-urchin sperm H1 histones. The effect of phosphate ions on the H1 molecule is observed also by differential absorption spectroscopy in the region of absorption of amino acid side-chains. Binding studies by gel filtration chromatography on Sephadex columns show that phosphate binding occurs in the presence of structuring concentrations of sodium chloride. About 9 ATP molecules bind to H1 histones derived from non-active cell chromatins while only 3.5 ATP molecules bind to H1 derived from active somatic chromatins. The fluorescence of the tyrosine residues of Chaetopterus sperm H1 is enhanced by chloride ions and heavily quenched by phosphate ions in correlation with structuring of the molecule, demonstrating direct interactions between tyrosine residues and phosphate ions. The defined and limited number of phosphate groups bound per histone molecule, the high affinity of the interaction and the effect on the structure of the histone suggest the participation of phosphate groups in the binding of H1 histones to DNA.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Preparation of chromosomal protein A24 (uH2A) by denaturing gel filtration and preparation of its free nonhistone component ubiquitin by ion-exchange chromatography

Chromosomal protein A24 (uH2A) is unique in that it comprises the nucleosomal core histone H2A in isopeptide linkage with the highly conserved, globular, and stable nonhistone protein ubiquitin. Some 10% of the chromatin complement of H2A is modified in this way and studies to elucidate a role for this modification have concentrated on observations requiring no purification of A24 due to the difficulty in isolating the protein in large and pure quantities. We describe a method for isolating A24 by chromatography on Pharmacia G-100 gel filtration medium under urea denaturing conditions. A24 prepared by this method is structurally intact and is available in the quantities required for studies of the behavior and influence of the protein on histone-histone, histone-DNA, and enzymatic interactions. In conjunction with this method we describe a procedure for the isolation of large quantities of free ubiquitin of far greater purity than previously reported.

Involvement of the histidine residues in the pH-induced conformational change of histone H5

Comparative studies on the conformational stability of histones H1 and H5 have been carried out by monitoring the pH-induced conformational transitions of the proteins by CD and 1H NMR spectroscopies. The transition point of H1 agrees with the pKa of the carboxyl groups of the acidic residues. In contrast, the transition of H5 is associated with the ionization of the histidine residues which exist exclusively in H5, as well as the deionization of the acidic residues. These observations, combined with the result of the deuterium exchange rates of the histidine C-2 protons, led us to conclude that His-25 and His-62, which are buried in the globular domain, play an important role in the conformational stability of histone H5.

Preparations of homeostatic thymus hormone consist predominantly of histones 2A and 2B and suggest additional histone functions

The two major constituents in preparations of the homeostatic thymus hormone (HTH) were purified. Amino acid sequence analysis showed that the components (HTH alpha and HTH beta) are identical to histones H2A and H2B, suggesting the possibility that histones might have hitherto unrecognized occurrence and functions. If the HTH activities are not ascribed to the two histones in the preparation, they could only be derived from minor constituents present in minimal amounts. Therefore, the histone structures were scrutinized for properties of relevance in relation to hormone activities and for similarities with thymic hormones. Similarities between COOH-terminal regions of histones H2A, H2B, and H3 were noticed, as well as some similarities between NH2-terminal regions of histones and parts of recognized thymus hormones and related proteins. Potential signals, resembling cleavage sites in prohormones, are present in the histone structures, and further correlations with recently discovered ubiquitin functions may explain molecular mechanisms for actions of the HTH preparations. None of the observations is significant by itself, but the combined results suggest the hypothesis of different relationships and functions, including hormone-like activities, for some histones.

Accessibility of tyrosyl residues altered by formation of the histone 2A/2B complex

The availability of tyrosyl residues to surface iodination was analyzed for histone 2A (H2A), histone 2B (H2B), and the H2A/H2B complex. When H2A is free in solution (200 mM NaCl, pH 7.4) tyrosine-39 and one or both tyrosines-50 and -57 were readily iodinated. Tyrosines-83 and -121 of H2B were iodinated, both when the histone was free in solution and when it was associated with H2A, while tyrosines-37, -40, and -42 of H2B were not iodinated under either condition. When H2A and H2B were associated or covalently cross-linked, all tyrosyl residues of H2A were unavailable for iodination. We also found that the iodination of nondenatured H2A and H2B did not inhibit formation of the H2A/H2B complex. These results indicate that the amino-terminal regions of the hydrophobic portions of H2A and H2B undergo significant conformational changes upon formation of the H2A/H2B complex. These conformational shifts occur in the same region of the H2A/H2B complex that contains a contact site between H2A and H2B in the nucleosome, thus indicating an involvement of this region in chromatin assembly.

Contact site of histones 2A and 2B in chromatin and in solution

Irradiation of isolated nuclei or of a complex of histones 2A (H2A) and 2B (H2B) with ultraviolet light produces a covalent cross-link between H2A and H2B. Sequence analysis of the peptides isolated from the H2A-H2B dimer formed in solution and in nuclei demonstrated that both dimers are produced through the covalent linkage of Tyr-40 of H2B and Pro-26 of H2A. Tyrosyl residues proximal to Tyr-40 did not produce a cross-link with H2A, thereby indicating that strict conformational parameters are required for production of the H2A-H2B cross-link. We conclude that the precise juxtaposition of Tyr-40 of H2B and Pro-26 of H2A in this region of the H2A/H2B contact site is not altered upon interaction of these histones with H3 and H4 (tetramer), DNA, or other chromosomal components during nucleosome assembly.

Laser Raman spectra of calf thymus chromatin and its constituents

Extensive Raman measurements have been made on calf thymus chromatin, core chromatin, the (H3,H4)/DNA complex, and isolated DNA. The results indicate that the alpha-helical content of the nucleosomal histones gradually increases as they form the heterocomplexes that lead to the formation of the octameric nucleosome core. The secondary structure of the latter is not modified as it binds to DNA. The spectra indicate that the DNA essentially retains its B conformation in nucleosomes, although slight changes probably occur in the ribose-phosphate backbone. No specific interactions between the nucleosomal histones and DNA can be established from the spectra, but histone H1 possibly interacts selectively with the thymine bases.

Antigenic structure of histone H2B

Antigenic determinants of histone H2B were localized using a series of 23 overlapping fragments of H2B obtained either by chemical and enzymatic cleavage of the histone or by solid-phase peptide synthesis. The ability of peptides to bind H2B antibodies was measured in an enzyme-linked immunosorbent assay, using antisera directed against calf thymus and chicken erythrocyte H2B as well as four anti H2B monoclonal antibodies obtained from autoimmune mice. Seven antigenic determinants were localized in the H2B molecule in the vicinity of residues 1-11, 6-18, 15-25, 26-35, 50-65, 94-113 and 114-125. Two of these determinants (residues 6-18 and 26-35) were revealed only through the binding properties of antibodies isolated from autoimmune mice. The usual correlation between hydrophilicity and antigenicity was found to hold for four of the epitopes, and the N- and C-termini of H2B were both antigenically active.

Differential dissociation of histone tails from core chromatin

The dissociation of the trypsin-sensitive basic tails of the core histones in core chromatin has been followed as a function of [NaCl] using proton NMR spectroscopy. The tails dissociate in a highly cooperative all or none manner over the salt concentration range 0.2-0.6 M, that is, below the salt concentration required to dissociate the complete molecule. Assuming that each basic tail dissociates independently, the total number of salt linkages involved in binding the tails to DNA is 103. This equals the number of basic side chains in the tails of an octamer. The standard free energy of dissociation, delta G degree, in 1 M NaCl at 297 K is 3.6 kcal/mol. Temperature had no effect on the extent of dissociation up to 45 degrees C. However, between 45 and 65 degrees C, where the premelting transition in the core chromatin occurs, the tails dissociated completely. Dissociation of the tails was associated with a conformational transition in the DNA consistent with loss of supercoiling. From this, and the results of a previous study, it can be shown that the structured, trypsin-resistant domain of each core histone octamer makes 100 salt linkages to DNA. Thus, in 10 mM salt, each core octamer makes a total of 203 salt linkages to DNA.

Conformation and domain structure of the non-histone chromosomal proteins HMG 1 and 2. Domain interactions

The sequence of the 224 residues of HMG 1 suggests it consists of three domains. We have previously proposed [Cary et al. (1980 Eur. J. Biochem. 131, 367-374] that the A and B domains can fold autonomously and that there is also a small N domain. Several proteases are now found to cut at the end of the B domain (at or close to residue 184). It is shown that the A + B-domain fragment also folds and probably contains all the helix of intact HMG 1. The stability of the B domain is enhanced by the presence of the A domain. The acidic C domain undergoes a coil----helix transition on lowering the pH. Several peptides have been prepared by cleavage at tryptophan. Peptide 57--C-terminus contains complete B and C domains but does not fold. In the absence of the A domain the C domain is thus able to destabilise the B domain. It is concluded that the stability of the B domain in HMG 1 is due to interaction with the A domain and the C domain has a separate function from the other domains.

The structure of the histone dimer H2A-H2B studied by spectroscopy

The spatial organization of the histone dimer (H2A-H2B) in 0.1-1.0 M NaCl is characterized by the inclusion of 38% of the residues in alpha-helical segments, an average fluorescence quantum yield of 0.085 +/- 0.003, a red shift of absorption (lambda max = 278 +/- 0.5 nm) and fluorescent spectra (lambda max = 304.4 +/- 0.3 nm) as compared to the respective spectra of free tyrosine. The changing of position lambda max of tyrosine fluorescence of histones during denaturation has been shown. The dimer (H2A-H2B) exhibited a conformational change in a transition centred at about 0.5 M NaCl. The dimer denaturation takes place at higher urea concentrations as the ionic strength of the medium increases. The quenching of tyrosine fluorescence of the histone dimer (H2A-H2B) was performed using the ions I-, Cs+ and acrylamide. It has been shown that, at a concentration of NaCl over 0.5 M, dimer compactization takes place, as well as the screening of some part of tyrosyls for te against the quenching effect of Cs+. Our experiments made it possible to identify three zones in the composition of the histone dimer (H2A-H2B) and determine the number (ni) and fluorescence quantum yields (qi) of tyrosyls included in the following specific zones: zone I, n1 = 2, q1 = 0.136; zone II, n2 = 3; q2 = 0.08; zone III, n3 = 3; q3 = 0.055.

Neutron scattering studies of the H2a-H2b and (H3-H4)2 histone complexes

Neutron scattering experiments have shown that both the (H3-H4)2 and H2a-H2b histone complexes are quite asymmetric in solution. The (H3-H4)2 tetramer is an oblate or flattened structure, with a radius of gyration almost as large as that of the core octamer. If the tetramer is primarily globular, it must have an axial ratio of about 1:5. It is more likely, however, that this asymmetry results in part from N-terminal arms that extend outward approximately within the major plane of the particle. If this is the case, less asymmetric models for the globular part of the tetramer, including a dislocated disk of the type proposed by Klug et al. (23), can be made consistent with the scattering data. The H2a-H2b dimer, on the other hand, is an elongated structure. The low resolution data are in good agreement with those calculated for a cylindrical model 64 X 27 A, but other elongated models fit those data almost as well, including one that approximates free N-terminal arms at each end. Free arms are not necessary, but they must extend from the ends if they exist. A contrast matching experiment done with 50% deuterated H2b and undeuterated H2a in the reconstituted dimer showed that these two histones must each be rather elongated within the complex and are not just confined to one end. The amount of scattering contrast between the undeuterated and 50% deuterated histones was sufficient to suggest further experiments using complexes reconstituted from mixtures of undeuterated and partially deuterated histones which will help elucidate their arrangement within the histone complexes and within the octamer core of the nucleosome core particle.

Codon-level analysis of histone primary sequence: evidence of a repeat tetrapeptide origin and later inclusion of transcribed sequence

This work is directed to the question of protein sequence conservation. By reference to the genetic code the aminoacyl sequence of histones H2A, H4, H3, H2B and H1 (fragment) were rewritten as the codon sequences. The N-terminal regions were set aside on the grounds of different composition and sequence. The remainder of the molecule could be referred to simple repeat-tetrapeptide proteins by codon composition (high Gxy, low xGy content) and by sequence. Random segments of three to six residues occur characterized by composition and sequence as originating from the complimentary DNA strand, i.e. as codon "transcript". Ancestral features are probably best seen in H3, point mutations appear to be more extensive in H2B and H1. Segments in reverse order in H2A and in "transcript" in H4 distinguish these two from the other three histones. There is a tenuous possibility the N-terminals also originated as repeat-tetrapeptide now intensively modified. At codon-level the 50S ribosomal protein (L7/L12) of E. coli has features in common with histones (including a palindrome-containing N-terminal). It has the composition and sequence of a well-conserved tetrapeptide-repeat strand (statistical support). If interpretations made here are substantially correct, the 50S r-protein illustrates a significant stage in evolution of histone codon strands.

Studies of the histidine residues of human and bovine glycoprotein hormones by nuclear magnetic resonance

Titration curves of the histidine residues in lutropin, thyrotropin, follitropin and chorionic gonadotropin have been assigned using imidazole C-2 proton nuclear magnetic resonance spectra and their estimated pK values determined. Spectra of reassociated hormone preparations, in which one or the other of their two subunits (alpha or beta) have had their accessible histidines exchanged with deuterium, permitted assignment of C-2 resonance to specific residues. Similar titration curves were found for residues which are conserved from one hormone to another. However, these conserved histidines do not have identical pK values, indicating that differences in the conformation or microenvironment around these residues occur in these hormones. Changes in some pK values also occur as a function of subunit association. The most dramatic change seen in all cases is the exposure to solvent of histidine alpha-83; in isolated alpha subunits this residue is unavailable for titration over a wide pH range. This change appears to be a general consequence of the association of the two subunits in any of these hormones. The data show that all histidines in the intact hormones are accessible to the environment, including those proposed to be in domains involved in subunit-subunit interaction.

Conformation and domain structure of the non-histone chromosomal proteins, HMG 1 and 2. Isolation of two folded fragments from HMG 1 and 2

Proteins HMG 1 and 2 have been digested with trypsin and two major products, stable to further digestion between 8 min and 2 h, have been purified (peptides A and B). Peptide B from HMG 1 has been identified as residues 12-75 and peptide A as residues 94/96-169 by amino acid analyses and Edman degradations. Peptide B spontaneously folds with the formation of 51% helix and exhibits the majority of the perturbed NMR resonances characteristic of folded intact HMG 1. Peptide B is stably folded in the presence of 150 mM NaCl between pH 3 and 10, like intact HMG 1. Peptide A forms 30% alpha-helix and also exhibits tertiary folding but is denatured by pH 10. The 11 N-terminal residues removed by trypsin contain both sites of post-synthetic acetylation (residues 2 and 11), a situation very similar to that found with core histones. It is proposed that HMG 1 and 2 consist of four structural domains, viz: (a) residues 1-11, (b) residues 12 to approximately 75, (c) residues 94-169 and (d) the very acidic region beyond residue 169. The instability of peptide A may mean that it is not a truly independent domain. No structural similarities to histone H1 are therefore observed in HMG 1 and 2.

Two new low-molecular-weight acidic proteins from calf thymus nuclei that resemble HMG (high-mobility-group) proteins 14 and 17

Two new, closely similar, acidic proteins were extracted and purified from calf thymus and designated AP-X and AP-Y (acidic proteins X and Y). They contain about 33% acidic residues, mostly non-amidated, and 20% lysine, but no arginine, tyrosine, histidine or tryptophan. There is a single phenylalanine residue in a molecular weight of approx. 5000. Circular dichroism and proton nuclear magnetic resonance show that they do not take up secondary or tertiary structure in free solution, as expected from the low content of hydrophobic amino acids. They appear structurally related to the high-mobility-group proteins HMG 14 and 17. Controlled extraction experiments indicate that proteins AP-X and AP-Y are at least partially located in the calf thymus nucleus.

Effect of acetylation on the binding of N-terminal peptides of histone H4 to DNA

The trypsin-sensitive N-terminal domain of histone H4 (residues 1-19) contains four acetylation sites at residues 5, 8, 12 and 16 and may play a separate role in chromatin structure from the remainder of the H4 chain. High-resolution proton NMR has been used to probe the DNA-binding of this H4 domain using the peptides (4-17), (1-23) and (1-37). Binding strength is in the order (1-37) greater than (1-23) greater than (4-17) but is weak even for (1-37). The observed weak binding correlates with arginine rather than lysine content and marked changes in the glycine resonance indicate the involvement of the peptide backbone in binding. When peptides (1-23) and (4-17) are fully acetylated with acetic anhydride, this weak binding is totally abolished. Circular dichroism indicates that neither acetylated nor unacetylated peptides take up any secondary structure. The results are consistent with the view that acetylation of H4 in vivo lifts the N-terminal domain off the DNA and thereby promulgates a major structural change in the chromatin.

Precise elimination of the N-terminal domain of histone H1

The proteinase from mouse submaxillary gland was used to cleave total calf thymus histone H1 between residues 32 and 33. The C-terminal peptide, comprising residues 33 to the C-terminus, was purified and identified by amino acids analysis and Edman degradation. Spectroscopic characterization by n.m.r. for tertiary structure and by c.d. for secondary structure shows the globular domain of the parent histone H1 to be preserved intact in the peptide. It has therefore lost only the N-terminal domain and is a fragment of histone H1 comprising the globular plus C-terminal domains only. Precise elimination of only the N-terminal domain makes the fragment suitable for testing domain function in histone H1.

UV differential study of the histones H2A-H2B-H3-H4 octamer

The individual calf thymus histones H2A, H2B, H3 and H4, the dimer H2A-H2B, the tetramer (H3-H4)2 and the octamer (H2A-H2B-H3-H4)2 were studied by differential UV absorption i.e. observing absorption shifts of tyrosyl residues due to thermal perturbations. The histone octamer was studied in 2 M NaCl pH 7.5 a condition under which it is stable, as demonstrated by Eickbush and Moudrianakis [18]. In addition these authors suggested that the interactions which maintain the four histones as an octamer involve the weak association of one (H3-H4)2 tetramer with two H2A-H2B dimers and might be due essentially to histidine-lysine or histidine-tyrosine hydrogen bonds. We performed the study of the octamer by UV differential absorption using the tyrosyl residues as a natural probe to follow their interaction with different residues in their neighbourhood. The main result obtained shows that the tetramer (H3-H4)2 has all its tyrosyl residues exposed to the solvent whereas the octamer has no tyrosine exposed, suggesting that with this polymer no DNA-tyrosine interactions could take place.

Proteolytic digestion studies of chromatin core-histone structure. Identification of limit peptides from histone H2B

Trypsin digestion of chicken erythrocyte chromatin results in a well-defined set of limit peptides derived from the core histones (P1-P5). Two peptides running in sodium dodecyl sulphate gel electrophoresis at the positions of P2 and P3 have been identified as histone H2B residues 21-125 and 24-125. No C-terminal residues are therefore lost from histone H2B. The N-terminal sequence removed correlates well with that having low sequence conservation and not with that showing the greatest basicity. The same correlation was reported previously by us for histone H2A.