Rice HMGB1 protein recognizes DNA structures and bends DNA efficiently

We analyzed the DNA-binding and DNA-bending properties of recombinant HMGB1 proteins based on a rice HMGB1 cDNA. Electrophoretic mobility shift assay demonstrated that rice HMGB1 can bind synthetic four-way junction (4H) DNA and DNA minicircles efficiently but the binding to 4H can be completed out by HMGA and histone H1. Conformational changes were detected by circular dichroism analysis with 4H DNA bound to various concentrations of HMGB1 or its truncated forms. T4 ligase-mediated circularization assays with short DNA fragments of 123 bp showed that the protein is capable of increasing DNA flexibility. The 123-bp DNA formed closed circular monomers efficiently in its presence, similar to that in an earlier study on maize HMG. Additionally, our results show for the first time that the basic N-terminal domain enhances the affinity of the plant HMGB1 protein for 4H DNA, while the acidic C-terminal domain has the converse effects.     

HMG-D and histone H1 alter the local accessibility of nucleosomal DNA

There is evidence that HMGB proteins facilitate, while linker histones inhibit chromatin remodelling, respectively. We have examined the effects of HMG-D and histone H1/H5 on accessibility of nucleosomal DNA. Using the 601.2 nucleosome positioning sequence designed by Widom and colleagues we assembled nucleosomes in vitro and probed DNA accessibility with restriction enzymes in the presence or absence of HMG-D and histone H1/H5. For HMG-D our results show increased digestion at two spatially adjacent sites, the dyad and one terminus of nucleosomal DNA. Elsewhere varying degrees of protection from digestion were observed. The C-terminal acidic tail of HMG-D is essential for this pattern of accessibility. Neither the HMG domain by itself nor in combination with the adjacent basic region is sufficient. Histone H1/H5 binding produces two sites of increased digestion on opposite faces of the nucleosome and decreased digestion at all other sites. Our results provide the first evidence of local changes in the accessibility of nucleosomal DNA upon separate interaction with two linker binding proteins.     

Nonhistone nuclear high mobility group proteins 14 and 17 stabilize nucleosome core particles

Nucleosome core particles form well defined complexes with the nuclear nonhistone proteins HMG 14 or 17. The binding of HMG 14 or 17 to nucleosomes results in greater stability of the nucleosomal DNA as shown by circular dichroism and thermal denaturation. Under appropriate conditions the binding is cooperative, and cooperativity is ionic strength dependent. The specificity and cooperative transitions of high mobility group (HMG) binding are preserved in 1 M urea. Specificity is lost in 4 M urea. Thermal denaturation and circular dichroism show a dramatic reversal of the effects of urea on nucleosomes when HMG 14 or 17 is bound, indicating stabilization of the nucleosome by HMG proteins. Complexes formed between reconstructed nucleosomes containing purified inner histones plus poly(dA-dT) and HMG 14 or 17 demonstrate that the HMG binding site requires only DNA and histones. Electron microscopy reveals no major structural alterations in the nucleosome upon binding of HMG 14 or 17. Cross-linking the nucleosome extensively with formaldehyde under cooperative HMG binding conditions does not prevent the ionic strength-dependent shift to noncooperative binding. This suggests mechanisms other than internal nucleosome conformational changes may be involved in cooperative HMG binding.     

Binding of non-histone chromosomal protein HMG1 to histone H3 in nucleosomes detected by photochemical cross-linking

The interaction of non-histone chromosomal protein HMG1 with core histones in nucleosomes was studied via reconstitution and photochemical cross-linking. The results obtained indicated that photoaffinity-labeled HMG1 interacted in nucleosomes with histone H3. Similar experiments with peptides derived from HMG1 by V8 protease digestion allowed to identify N-terminal domain of HMG1 (peptide V3) as a binding region for histone H3 in nucleosomes.     

Studies on protein organization of nucleosomes using cross-linking

When chromosomal proteins in chromatin or in mononucleosomes were extensively cross-linked with an imido ester, the H1-containing nonameric histone complex was revealed. In this complex, histone H1 is connected with the octamer of core histones. The cross-linking of H1 to the octamer is realized preferentially through H2a and H3 histones. Some HMG (high mobility group) proteins located presumably in the linker regions of a nucleosome fiber also take part in the formation of dimers, possibly with the histones of a nucleosomal core. The results suggest mutual interactions between some linker-associated proteins and intranucleosomal histones. Experiments involving extensive cross-linking of proteins in the purified mononucleosome subfractions demonstrated differences in the organization of core histones between complete nucleosomes and nucleosomes lacking H1.Abbreviations HMG proteins high mobility group proteins - DMA dimethyladipimidate dihydrochloride - DMP dimethyl-3,3-dithio-bis-propionimidate dihydrochloride     

Structural dynamics of nucleosome core particle: comparison with nucleosomes containing histone variants

The present study provides insights on the dominant mechanisms of motions of the nucleosome core particle and the changes in its functional dynamics in response to histone variants. Comparative analysis of the global dynamics of nucleosomes with native and variant H2A histones, using normal mode analysis revealed that the dynamics of the nucleosome is highly symmetric, and its interaction with the nucleosomal DNA plays a vital role in its regulation. The collective dynamics of nucleosomes are predicted to be dominated by two types of large-scale motions: (1) a global stretching-compression of nucleosome along the dyad axis by which the nucleosome undergoes a breathing motion with a massive distortion of nucleosomal DNA, modulated by histone-DNA interactions; and (2) the flipping (or bending) of both the sides of the nucleosome in an out-of-plane fashion with respect to the dyad axis, originated by the highly dynamic N-termini of H3 and (H2A.Z-H2B) dimer in agreement with the experimentally observed perturbed dynamics of the particular N-terminus under physiological conditions. In general, the nucleosomes with variant histones exhibit higher mobilities and weaker correlations between internal motions compared to the nucleosome containing ordinary histones. The differences are more pronounced at the L1 and L2 loops of the respective monomers H2B and H2A, and at the N-termini of the monomers H3 and H4, all of which closely interact with the wrapping DNA.     

The in vitro reconstitution of nucleosome and its binding patterns with HMG1／2 and HMG14／17 proteins

Using atomic force microscopy (AFM), the dynamic process of the in vitro nucleosome reconstitution followed by slow dilution from high salt to low salt was visualized. Data showed that the histone octamers were dissociatedfrom DNA at 1M NaC1. When the salt concentration was slowly reduced to 650 mM and 300 mM, the core histones bound to the naked DNA gradually. Once the salt concentration was reduced to 50 mM the classic “beads-on-a-string“ structure was clearly visualized. Furthermore, using the technique of the in vitro reconstitution of nucleosome,the mono- and di- nucleosomes were assembled in vitro with both HS2core (-10681 to -10970 bp) and NCR2 (-372to -194 bp) DNA sequences in the 5‘flanking sequence of human b-globin gene. Data revealed that HMG 1/2 and HMG 14/17 proteins binding to both DNA sequences are changeable following the assembly and disassembly of nucleosomes. We suggest that the changeable binding patterns of HMG 14/17 and HMG1/2 proteins with these regulatory elements may be critical in the process of nucleosome assembly, recruitment of chromatin-modifying activities, and the regulation of human b-globin gene expression.     

Interaction of wheat high-mobility-group proteins with four-way-junction DNA and characterization of the structure and expression of HMGA gene

Plant high-mobility-group (HMG) chromosomal proteins are the most abundant and ubiquitous nonhistone proteins found in the nuclei of higher eukaryotes. There are only two families of HMG proteins, namely, HMGA and HMGB in plants. The cDNA encoding wheat HMGa protein was isolated and characterized. Wheat HMGA cDNA encodes a protein of 189 amino acid residues. At its N terminus, there is a histone H1-like structure, which is a common feature of plant HMGA proteins, followed by four AT-hook motifs. Polymerase chain reaction results show that the gene contains a single intron of 134 bp. All four AT-hook motifs are encoded by the second exon. Northern blot results show that the expression of HMGA gene is much higher in organs undergoing active cell proliferation. Gel retardation analysis show that wheat HMGa, b, c and histone H1 bind to four-way-junction DNA with high binding affinity, but affinity is dramatically reduced with increasing Mg(2+) and Na(+) ion concentration. Competition binding studies show that proteins share overlapping binding sites on four-way-junction DNA. HMGd does not bind to four-way-junction DNA.     

The interaction of HMGB1 and linker histones occurs through their acidic and basic tails

H1 and HMGB1 bind to linker DNA in chromatin, in the vicinity of the nucleosome dyad. They appear to have opposing effects on the nucleosome, H1 stabilising it by "sealing" two turns of DNA around the octamer, and HMGB1 destabilising it, probably by bending the adjacent DNA. Their presence in chromatin might be mutually exclusive. Displacement/replacement of one by the other as a result of their highly dynamic binding in vivo might, in principle, involve interactions between them. Chemical cross-linking and gel-filtration show that a 1:1 linker histone/HMGB1 complex is formed, which persists at physiological ionic strength, and that complex formation requires the acidic tail of HMGB1. NMR spectroscopy shows that the linker histone binds, predominantly through its basic C-terminal domain, to the acidic tail of HMGB1, thereby disrupting the interaction of the tail with the DNA-binding faces of the HMG boxes. A potential consequence of this interaction is enhanced DNA binding by HMGB1, and concomitantly lowered affinity of H1 for DNA. In a chromatin context, this might facilitate displacement of H1 by HMGB1.     

Histone H2A ubiquitination does not preclude histone H1 binding, but it facilitates its association with the nucleosome

Histone H2A ubiquitination is a bulky posttranslational modification that occurs at the vicinity of the binding site for linker histones in the nucleosome. Therefore, we took several experimental approaches to investigate the role of ubiquitinated H2A (uH2A) in the binding of linker histones. Our results showed that uH2A was present in situ in histone H1-containing nucleosomes. Notably in vitro experiments using nucleosomes reconstituted onto 167-bp random sequence and 208-bp (5 S rRNA gene) DNA fragments showed that ubiquitination of H2A did not prevent binding of histone H1 but it rather enhanced the binding of this histone to the nucleosome. We also showed that ubiquitination of H2A did not affect the positioning of the histone octamer in the nucleosome in either the absence or the presence of linker histones.     

Primary organization of nucleosomes. Interaction of non-histone high mobility group proteins 14 and 17 with nucleosomes, as revealed by DNA-protein crosslinking and immunoaffinity isolation

The binding sites for histones and high mobility group proteins (HMG) 14 and 17 have been located on DNA in the nucleosomal cores and H1/H5-containing nucleosomes. The nucleosomes were specifically associated with two molecules of the non-histone proteins HMG 14 and/or HMG 17 when followed by DNA-protein crosslinking and immunoaffinity isolation of the crosslinked HMG-DNA complexes. HMGs 14 and 17 were shown to be crosslinked in a similar manner to each core DNA strand at four sites: to both 3' and 5' DNA ends and also at distances of about 25 and 125 nucleotides from the 5' termini of the DNA. These sites are designated as HMG(143), (0), (25) and (125). The site HMG(125) is located at the place where no significant histone-DNA crosslinking was observed. The HMG(125) and HMG(25) sites lie opposite one another on the complementary DNA strands across the minor DNA groove and are placed, similarly to histones, on the inner side of the DNA superhelix in the nucleosome. The crosslinking of HMG 17 to the 3' ends of the DNA is much weaker than that of HMG 14. These data indicate that each of two molecules of HMG 14 and/or HMG 17 is bound to the double-stranded core DNA at two discrete sites: to the 3' and 5' ends of the DNA and at a distance of 20 to 25 base-pairs from each DNA terminus inside the nucleosome on a histone-free DNA region. Binding of HMG 14 or 17 does not induce any detectable rearrangement of histones on DNA and both HMGs seem to choose the same sites for attachment in nucleosomal cores and H1/H5-containing nucleosomes.     

Human centromere protein B induces translational positioning of nucleosomes on alpha-satellite sequences

The human centromere proteins A (CENP-A) and B (CENP-B) are the fundamental centromere components of chromosomes. CENP-A is the centromere-specific histone H3 variant, and CENP-B specifically binds a 17-base pair sequence (the CENP-B box), which appears within every other alpha-satellite DNA repeat. In the present study, we demonstrated centromere-specific nucleosome formation in vitro with recombinant proteins, including histones H2A, H2B, H4, CENP-A, and the DNA-binding domain of CENP-B. The CENP-A nucleosome wraps 147 base pairs of the alpha-satellite sequence within its nucleosome core particle, like the canonical H3 nucleosome. Surprisingly, CENP-B binds to nucleosomal DNA when the CENP-B box is wrapped within the nucleosome core particle and induces translational positioning of the nucleosome without affecting its rotational setting. This CENP-B-induced translational positioning only occurs when the CENP-B box sequence is settled in the proper rotational setting with respect to the histone octamer surface. Therefore, CENP-B may be a determinant for translational positioning of the centromere-specific nucleosomes through its binding to the nucleosomal CENP-B box.     

Different mechanism for in vitro formation of nucleosome core particles

The interaction of different histone oligomers with nucleosomes has been investigated by using nondenaturing gel electrophoresis. In the presence of 0.2 M NaCl, the addition of the pairs H2A,H2B or H3,H4 or the four core histones to nucleosome core particles produces a decrease in the intensity of the core particle band and the appearance of aggregated material at the top of the gel, indicating that all these histone oligomers are able to associate with nucleosomes. Equivalent results were obtained by using oligonucleosome core particles. Additional electrophoretic results, together with second-dimension analysis of histone composition and fluorescence and solubility studies, indicate that H2A,H2B, H3,H4, and the four core histones can migrate spontaneously from the aggregated nucleosomes containing excess histones to free core DNA. In all cases the estimated yield of histone transfer is very high. Furthermore, the results obtained from electron microscopy, solubility, and supercoiling assays demonstrate the transfer of excess histones from oligonucleosomes to free circular DNA. However, the extent of solubilization obtained in this case is lower than that observed with core DNA as histone acceptor. Our results demonstrate that nucleosome core particles can be formed in 0.2 M NaCl by the following mechanisms: (1) transfer of excess core histones from oligonucleosomes of free DNA, (2) transfer to excess H2A,H2B and H3,H4 associated separately with oligonucleosomes to free DNA, (3) transfer to excess H2A,H2B initially associated with oligonucleosomes to DNA, followed by the reaction of the resulting DNA-(H2A,H2B) complex with oligonucleosomes containing excess H3,H4, and (4) a two-step transfer reaction similar to that indicated in (3), in which excess histones H3,H4 are transferred to DNA before the reaction with oligonucleosomes containing excess H2A,H2B. The possible biological implications of these spontaneous reactions are discussed in the context of the present knowledge of the nucleosome function.     

Rat liver HMG1: a physiological nucleosome assembly factor.

Incubation of rat liver single-stranded DNA-binding protein HMG1 with the four core histones at 0.15 M NaCl favors histone association primarily into tetramers and, to a lesser extent, into octamers. The assembly of pre-formed histone-HMG1 complexes with DNA yields nucleosome-like subunits which satisfy most of the criteria defining native core particles: (i) the circular DNA extracted from the complexes is supercoiled indicating that the initially relaxed DNA acquired superhelical turns during complex formation in the presence of topoisomerase I; (ii) the digestion of the complexes with micrococcal nuclease yields a DNA fragment of approximately 140 bp in length; (iii) electron microscopy of the reconstituted complexes shows a beaded structure with the DNA wrapped around the histone cores, leading to a reduction in the contour length of the genome compared with free DNA. Moreover, in the presence of HMG1, nucleosome assembly occurs rapidly at 0.15 M NaCl. Therefore, in addition to its DNA-binding properties, HMG1 mediates the assembly of nucleosomes in vitro under conditions of physiological ionic strength. The possible involvement of these properties in the DNA replication process is discussed.     

Interaction of non-histone proteins HMG1 and HMG2 with core histones in nucleosomes and core particles revealed by chemical cross-linking

Chemical cross-linking was used to study the interaction of the non-histone chromosomal proteins HMG1 and HMG2 with core histones in H1,H5-depleted nucleosomes or core particles. Cross-linking with a 'zero-length' cross-linker 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide and with a longer (cleavable) cross-linker dimethyl-3,3'-dithiobispropionimidate revealed an interaction of HMG1 and HMG2 with (or proximity to) core histones in both types of particles. These results indicated that the presence of the 40-50-base-pairs-long segment of the 'linker' DNA in nucleosomes was not necessary for the establishment of mutual contacts of HMG1 and HMG2 proteins with core histones. Possible implications of the interaction of HMG1 and HMG2 proteins with histones for the structure and functioning of chromatin are discussed.