Evidence for the formation of nucleosome-like histone complexes on single-stranded DNA.

Using histones reconstituted with RNA and DNA celluloses, we have shown elsewhere that histones elute identically with salt from single- and double-stranded DNA, but differently from RNA (Palter and Alberts, 1979). In this paper we characterize further the suspected specific binding interactions between histones and single-stranded DNA. Nuclease digestion of complexes of histone reconstituted with single-stranded DNA generates only a small yield of discrete (approximately 9S) particles. We can, however, efficiently obtain such 9S "nucleosome-like" complexes when nuclease treatment is avoided and histones are reconstituted directly with short single-stranded DNA pieces. Strikingly, these 9S subunits contain an equimolar composition of the four nucleosomal histones. When these subunits are visualized in the electron microscope, they appear as globular particles which are morphologically indistinguishable from normal mononucleosomes. Based on their sedimentation properties, histone-to-DNA ratio, histone composition and particle diameter, we conclude that they represent an octamer of the four histones (containing two molecules of each histone) associated with single-stranded DNA. These data, viewed in the context of other information concerning chromatin, suggest that nucleosome cores may become transiently bound to single strands of DNA as DNA and RNA polymerases pass.     

Binding of linker histones to the core nucleosome

Binding of chicken erythrocyte linker histones H1/H5 to the core nucleosome has been studied. Histones H1/H5 bind very efficiently to the isolated core nucleosome in vitro. The binding of linker histones to the core nucleosome is associated with aggregation of the particles. Approximately one molecule of linker histone binds per core nucleosome in the aggregates, irrespective of the concentration of the linker histones and the salt used. Histone H5 shows greater binding affinity to the core nucleosome as compared to H1. The carboxyl-terminal fragment of the linker histones binds strongly to the core nucleosome while the binding of the central globular domain is weak. Each core nucleosome is capable of binding two molecules of carboxyl-terminal fragment of linker histone. The core nucleosome containing one molecule of carboxyl-terminal fragment of linker histone requires higher salt concentration for aggregation while the core nucleosome containing two molecules of carboxyl-terminal fragment of linker histone can self-associate even at lower salt concentrations. On the basis of these results we are proposing a novel mechanism for the condensation of chromatin by linker histones and other related phenomena.     

Interaction of maize chromatin-associated HMG proteins with mononucleosomes: role of core and linker histones

Two groups of plant chromatin-associated high mobility group (HMG) proteins, namely the HMGA family, typically containing four A/T-hook DNA-binding motifs, and the HMGB family, containing a single HMG-box DNA-binding domain, have been identified. We have examined the interaction of recombinant maize HMGA and five different HMGB proteins with mononucleosomes (containing approx. 165 bp of DNA) purified from micrococcal nuclease-digested maize chromatin. The HMGB proteins interacted with the nucleosomes independent of the presence of the linker histone H1, while the binding of HMGA in the presence of H1 differed from that observed in the absence of H1. HMGA and the HMGB proteins bound H1-containing nucleosome particles with similar affinity. The plant HMG proteins could also bind nucleosomes that were briefly treated with trypsin (removing the N-terminal domains of the core histones), suggesting that the histone N-termini are dispensable for HMG protein binding. In the presence of untreated nucleosomes and trypsinised nucleosomes, HMGB1 could be chemically crosslinked with a core histone, which indicates that the trypsin-resistant part of the histones within the nucleosome is the main interaction partner of HMGB1 rather than the histone N-termini. In conclusion, these results indicate that specific nucleosome binding of the plant HMGB proteins requires simultaneous DNA and histone contacts.     

Symmetrical modification within a nucleosome is not required globally for histone lysine methylation

Two copies of each core histone exist in every nucleosome; however, it is not known whether both histones within a nucleosome are required to be symmetrically methylated at the same lysine residues. We report that for most lysine methylation states, wild-type histones paired with mutant, unmethylatable histones in mononucleosomes have comparable methylation levels to bulk histones. Our results indicate that symmetrical histone methylation is not required on a global scale. However, wild-type H4 histones paired with unmethylatable H4K20R histones showed reduced levels of H4K20me2 and H4K20me3, suggesting that some fractions of these modifications might exist symmetrically, and enzymes mediating these modifications might, to some extent, favour nucleosome substrates with premethylated H4K20.     

Acetylation of histone H3 lysine 56 regulates replication-coupled nucleosome assembly

Chromatin assembly factor 1 (CAF-1) and Rtt106 participate in the deposition of newly synthesized histones onto replicating DNA to form nucleosomes. This process is critical for the maintenance of genome stability and inheritance of functionally specialized chromatin structures in proliferating cells. However, the molecular functions of the acetylation of newly synthesized histones in this DNA replication-coupled nucleosome assembly pathway remain enigmatic. Here we show that histone H3 acetylated at lysine 56 (H3K56Ac) is incorporated onto replicating DNA and, by increasing the binding affinity of CAF-1 and Rtt106 for histone H3, H3K56Ac enhances the ability of these histone chaperones to assemble DNA into nucleosomes. Genetic analysis indicates that H3K56Ac acts in a nonredundant manner with the acetylation of the N-terminal residues of H3 and H4 in nucleosome assembly. These results reveal a mechanism by which H3K56Ac regulates replication-coupled nucleosome assembly mediated by CAF-1 and Rtt106.     

Remodeling of nucleosome-dimer particles with yIsw2 promotes their association with ALL-1 SET domain in vitro

Functioning of histone lysine methyltransferases (HKMTs) involves interactions of their catalytic domain "SET" with the N-termini of histone H3. However, these interactions are restricted in canonical nucleosomes due to the limited accessibility of H3 termini. Here we investigated whether nucleosome remodeling with the yeast Isw2 affects nucleosome affinity to the SET domain of ALL-1 HKMT. Reconstitution of mononucleosomes by salt dilutions also produces some nucleosome-dimer particles (self-associated mononucleosomes, described by: Tatchell and van Holde (1977) Biochemistry, 16, 5295-5303). The GST-tagged SET-domain polypeptide of ALL-1 was assayed for binding to assembled mononucleosomes and nucleosome-dimer particles, either intact or remodeled with purified yeast Isw2. Remodeling of mononucleosomes does not noticeably affect their affinity to SET domain; however, yIsw2 remodeling of nucleosome-dimer particles facilitated their association with GST-SET polypeptide. Therefore, it is conceivable that nucleosome interactions in trans could be implicated in the maintenance of chromatin methylation patterns in vivo.     

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.     

Nucleosome-interacting proteins regulated by DNA and histone methylation

Modifications on histones or on DNA recruit proteins that regulate chromatin function. Here, we use nucleosomes methylated on DNA and on histone H3 in an affinity assay, in conjunction with a SILAC-based proteomic analysis, to identify "crosstalk" between these two distinct classes of modification. Our analysis reveals proteins whose binding to nucleosomes is regulated by methylation of CpGs, H3K4, H3K9, and H3K27 or a combination thereof. We identify the origin recognition complex (ORC), including LRWD1 as a subunit, to be a methylation-sensitive nucleosome interactor that is recruited cooperatively by DNA and histone methylation. Other interactors, such as the lysine demethylase Fbxl11/KDM2A, recognize nucleosomes methylated on histones, but their recruitment is disrupted by DNA methylation. These data establish SILAC nucleosome affinity purifications (SNAP) as a tool for studying the dynamics between different chromatin modifications and provide a modification binding "profile" for proteins regulated by DNA and histone methylation.     

The interaction of histone H5 and its globular domain with core particles, depleted chromatosomes, polynucleosomes, and a DNA decamer

Certain features of linker histone behavior were analyzed using a precipitation and a nitrocellulose filter binding assay. Chromatosomes, depleted of the linker histones, present one unique binding site to the globular domain of histone H5 (GH5) which involves the two 10-base pair DNA ends of the chromatosome. Additional binding to lower affinity sites is intrinsically different and results in aggregation as does all binding to core particles. These findings, as well as the binding study on a synthetic DNA decamer, lend support to earlier hypotheses of more than one DNA binding site on the globular domain. Our studies provide a deeper insight into the long standing question of H5/nucleosome stoichiometry. A salt dependence analysis of GH5 binding to H5-depleted chromatosomes indicates that GH5 displaces a number of ions similar to the total H1 linker histone, suggesting a delocalized binding of the carboxyl- and amino-terminal tails.     

Conformation of reconstituted mononucleosomes and effect of linker histone H1 binding studied by scanning force microscopy

The conformation of mononucleosome complexes reconstituted with recombinant core histones on a 614-basepair-long DNA fragment containing the Xenopus borealis 5S rRNA nucleosome positioning sequence was studied by scanning/atomic force microscopy in the absence or presence of linker histone H1. Imaging without prior fixation was conducted with air-dried samples and with mononucleosomes that were injected directly into the scanning force microscopy fluid cell and visualized in buffer. From a quantitative analysis of approximately 1,700 complexes, the following results were obtained: i), In the absence of H1, a preferred location of the nucleosome at the X. borealis 5S rRNA sequence in the center of the DNA was detected. From the distribution of nucleosome positions, an energy difference of binding to the 5S rRNA sequence of DeltaDeltaG approximately 3 kcal mol(-1) as compared to a random sequence was estimated. Upon addition of H1, a significantly reduced preference of nucleosome binding to this sequence was observed. ii), The measured entry-exit angles of the DNA at the nucleosome in the absence of H1 showed two maxima at 81 +/- 29 degrees and 136 +/- 18 degrees (air-dried samples), and 78 +/- 25 degrees and 137 +/- 25 degrees (samples imaged in buffer solution). In the presence of H1, the species with the smaller entry-exit angle was stabilized, yielding average values of 88 +/- 34 degrees for complexes in air and 85 +/- 10 degrees in buffer solution. iii), The apparent contour length of the nucleosome complexes was shortened by 34 +/- 13 nm as compared to the free DNA due to wrapping of the DNA around the histone octamer complex. Considering an 11 nm diameter of the nucleosome core complex, this corresponds to a total of 145 +/- 34 basepairs that are wound around the nucleosome.     

Fine structure of mononucleosomes derived by bright- and dark-field electron microscopy

Images of intact and disrupted mononucleosomes, obtained by both bright-field (BF) and dark-field (DF) microscopy, were compared and analysed to determine the degree of continuity of morphological structures from the two visualization modes. DF images were about 10–13 % larger than BF images. Unless fixed with glutaraldehyde or stained with uranyl acetate, mononucleosomes may be partly unfolded. The 10.3 ± 1.1 nm diameter glutamate dehydrogenase hexamer, aggregates of histones H2a, H2b, H3 and H4 and naked DNA were used to estimate the contribution of protein and DNA to the images of mononucleosomes. The major contribution to the electron-dense regions of mononucleosomes viewed by the DF process is from histones and not DNA alone. Image analogs and autocorrelation methods were used to solve the three-dimensional organization of the nucleosome images in relation to the eight histones and the DNA. The structure of the mononucleosome which is most consistent with the data is that of a supercoiled nucleoprotein of 1.5 gyrs or greater with 8 roughly evenly spaced globular histone domains, each about 4.2 ± 0.7 nm in diameter, arranged as a pseudo-penta or hexamer as viewed along the central axis of symmetry. The structure is in essential agreement with models specified by Finch & Klug [12], and Trifonov [50].     

Mapping the interaction surface of linker histone H1(0) with the nucleosome of native chromatin in vivo

H1 linker histones stabilize the nucleosome, limit nucleosome mobility and facilitate the condensation of metazoan chromatin. Here, we have combined systematic mutagenesis, measurement of in vivo binding by photobleaching microscopy, and structural modeling to determine the binding geometry of the globular domain of the H1(0) linker histone variant within the nucleosome in unperturbed, native chromatin in vivo. We demonstrate the existence of two distinct DNA-binding sites within the globular domain that are formed by spatial clustering of multiple residues. The globular domain is positioned via interaction of one binding site with the major groove near the nucleosome dyad. The second site interacts with linker DNA adjacent to the nucleosome core. Multiple residues bind cooperatively to form a highly specific chromatosome structure that provides a mechanism by which individual domains of linker histones interact to facilitate chromatin condensation.     

技术与方法体外组装含有组蛋白变体H2A.Z及H3.3的核小体

核小体是构成真核生物染色质的基本结构单位,组蛋白变体H2A.Z及H3.3对染色质结构及基因转录过程发挥着重要的调控作用。体内研究核小体及染色质结构受到诸多因素限制,体外重构含有H2A.Z及H3.3的核小体结构是研究与组蛋白变体相关基因表达调控的重要方法之一。实验表达纯化了6种组蛋白,在复性的过程中装配了含有H2A.Z和H3.3的组蛋白八聚体。基于DNA序列10bp周期性及序列模体设计了3条易于形成核小体的DNA序列,通过PCR大量扩增的方法,回收了标记Cy3荧光分子的目的DNA序列。采用盐透析法体外组装了含有H2A.Z和H3.3的核小体结构,利用荧光标记、EB染色及考马斯亮蓝染色检测了含有组蛋白变体的核小体形成效率及形成过程的吉布斯自由能变化。结果发现,设计的3条DNA序列可以有效地组装形成含有组蛋白电梯的核小体结构,而且随着组蛋白八聚体与DNA比例的增加,核小体的形成效率显著提高;采用Cy3荧光标记可以灵敏且定量地计算组装过程的吉布斯自由能。该方法的建立对研究组蛋白变体相关的结构生物学及转录调控等具有一定的意义。     

Arginine residues involved in strong histone--DNA interactions to fold DNA into the nucleosome core particle.

The numbers of the arginine residues involved in strong histone-DNA interactions to fold DNA into a nucleosome core particle were determined for each of the four core histones, by kinetic studies of chemical modification of the residues in the nucleosome core particle. It was suggested that the arginines in the globular region of H3 histone make major contributions to the strong binding of the octameric histones to the core DNA.     

A thermodynamic model for Nap1-histone interactions

The yeast nucleosome assembly protein 1 (yNap1) plays a role in chromatin maintenance by facilitating histone exchange as well as nucleosome assembly and disassembly. It has been suggested that yNap1 carries out these functions by regulating the concentration of free histones. Therefore, a quantitative understanding of yNap1-histone interactions also provides information on the thermodynamics of chromatin. We have developed quantitative methods to study the affinity of yNap1 for histones. We show that yNap1 binds H2A/H2B and H3/H4 histone complexes with low nm affinity, and that each yNap1 dimer binds two histone fold dimers. The yNap1 tails contribute synergistically to histone binding while the histone tails have a slightly repressive effect on binding. The (H3/H4)(2) tetramer binds DNA with higher affinity than it binds yNap1.     

H1 family histones in the nucleus. Control of binding and localization by the C-terminal domain

H1 histones bind to DNA as they enter and exit the nucleosome. H1 histones have a tripartite structure consisting of a short N-terminal domain, a highly conserved central globular domain, and a lysine-and arginine-rich C-terminal domain. The C-terminal domain comprises approximately half of the total amino acid content of the protein, is essential for the formation of compact chromatin structures, and contains the majority of the amino acid variations that define the individual histone H1 family members. This region contains several cell cycle-regulated phosphorylation sites and is thought to function through a charge-neutralization process, neutralizing the DNA phosphate backbone to allow chromatin compaction. In this study, we use fluorescence microscopy and fluorescence recovery after photobleaching to define the behavior of the individual histone H1 subtypes in vivo. We find that there are dramatic differences in the binding affinity of the individual histone H1 subtypes in vivo and differences in their preference for euchromatin and heterochromatin. Further, we show that subtype-specific properties originate with the C terminus and that the differences in histone H1 binding are not consistent with the relatively small changes in the net charge of the C-terminal domains.     

Energetics and affinity of the histone octamer for defined DNA sequences

Previous studies have compared the relative free energies for histone octamer binding to various DNA sequences; however, no reports of the equilibrium binding affinity of the octamer for unique sequences have been presented. It has been shown that nucleosome core particles (NCPs) dissociate into free DNA and histone octamers (or free histones) on dilution without generation of stable intermediates. Dissociation is reversible, and an equilibrium distribution of NCPs and DNA is rapidly attained. Under low ionic strength conditions (<400 mM NaCl), NCP dissociation obeys the law of mass action, making it possible to calculate apparent equilibrium dissociation constants (K(d)s) for NCPs reconstituted on defined DNA sequences. We have used two DNA sequences that have previously served as model systems for nucleosome reconstitution studies, human alpha-satellite DNA and Lytechinus variegatus 5S DNA, and find that the octamer exhibits K(d)s of 0.03 and 0.06 nM, respectively, for these sequences at 50 mM NaCl. These DNAs form NCPs that are approximately 2 kcal/mol more stable than total NCPs isolated from cellular chromatin. As for mixed-sequence NCPs, increasing ionic strength or temperature promotes dissociation. van't Hoff plots of K(a)s versus temperature reveal that the difference in binding free energy for alpha-satellite and 5S NCPs compared to bulk NCPs is due almost entirely to a more favorable entropic component for NCPs formed on the unique sequences compared to mixed-sequence NCPs. Additionally, we address the contribution of the amino-terminal tail domains of histones H3 and H4 to octamer affinity through the use of recombinant tailless histones.