Nucleosomes are exposed at the cell surface in apoptosis

Apoptotic cells are considered the source of DNA, histones, and nucleoprotein complexes that drive the production of autoantibodies in systemic lupus erythematosus. However, the role of apoptotic cells in the activation of the immune system is not clear. To explore interactions that may initiate or sustain the production of anti-nuclear autoantibodies, we characterized the binding of a large panel of monoclonal autoantibodies to apoptotic cells. Autoantibodies to DNA, individual core histones, histone-DNA complexes, or the native nucleosome core particle revealed a consistent and specific binding pattern in confocal microscopy. Immunoreactive epitopes were detected in the cytoplasm and accumulated along the surface of the fragmenting nucleus in a caspase-dependent manner. Ag-Ab complexes on nuclear fragments that had emerged from the plasma membrane were accessible to anti-isotype-reactive microparticles. Moreover, autoantibodies specific for the nucleosome core or its molecular components selectively precipitated a complex of core histones and DNA from the cytosol at 4 h after induction of apoptosis. These observations identify distinct steps in the release of nucleosomes from the nucleus and their exposure at the cell surface. Furthermore, the results indicate a direct role for nucleosomes in the execution of apoptosis, clearance of apoptotic cells, and regulation of anti-nuclear autoantibody production.     

Anti-histone antibodies in idiopathic and drug-induced lupus recognize distinct intrahistone regions

We have identified regions within core histones that are antigenic for autoantibodies in systemic lupus erythematosus (SLE) and drug-induced lupus. An immunoblotting technique was used to determine the reactivity of lupus antibodies for intact histones and for trypsin-resistant histone fragments that lack the amino- and carboxyl-terminal amino acids that are normally exposed in native nucleosomes. In SLE, the predominant anti-histone response was restricted to epitopes in the trypsin-sensitive regions. Of 20 SLE sera that had strong antibody activity for multiple intact histones, 17 showed minimal activity with any of the corresponding trypsin-resistant fragments. A markedly different pattern of reactivity was present in sera of patients with procainamide (Pr)-induced lupus in which antibodies to H2A, H2B, and the H2A-H2B complex had strong fragment activity. Interestingly, recognition of trypsin-resistant fragments was also noted in a small number of SLE sera that contained antibodies to the H2A-H2B complex. In contrast to both SLE and Pr-induced lupus, antibodies induced by hydralazine (Hy) reacted primarily with H3 and H4. Furthermore, these antibodies bound equally well to the corresponding trypsin-resistant regions that are thought to be relatively unexposed in native nucleosomes. Thus, the specificities of anti-histone antibodies in SLE, Pr-induced lupus, and Hy-induced lupus are markedly different, but in each disease reactivity appears to be restricted to a limited number of histone determinants. The data raise the possibility that autoantigen in the form of native nucleosomes may be recognized in SLE and possibly in Pr-induced lupus. In contrast, the propensity of Hy to induce autoantibodies to determinants usually not recognized in SLE or Pr-induced lupus may suggest a different immunogenic stimulus in this disease.     

Autoantibody to the nucleosome subunit (H2A-H2B)-DNA is an early and ubiquitous feature of lupus-like conditions

Chromatin, a huge polymer of nucleosomes, has been implicated as an important target of autoantibodies in idiopathic and drug-induced lupus for decades, but the antigenicity of chromatin has only recently been dissected. IgG reactivity with the (H2A-H2B)-DNA complex, a subunit of the nucleosome, is present in the majority of patients with systemic lupus erythematosus, in >90% of patients with lupus induced by procainamide and in individual patients with lupus induced by a variety of other drugs, but is not seen in people taking these medications who are clinically asymptomatic. Anti-[(H2A-H2B)-DNA] accounted for the bulk of the anti-chromatin activity in drug-induced lupus. The earliest detectable autoantibody in lupus-prone mice recognized similar epitopes in the (H2A-H2B)-DNA subnucleosome complex; as the immune response progressed, native DNA and other constituents of chromatin became antigenic. The importance of chromatin-reactive T cells in the anti-[(H2A-H2B)-DNA] response is suggested by the presence of somatic mutations in antibody V_H and V_L regions, their perdominant IgG isotype and the similarity in kinetics of their production to that of conventional T cell dependent antigens. Together with the serologic data from human lupus-like disease, these results are consistent with chromatin being a common stimulant for both B and T cells. While chromatin-reactive antibodies are closely associated with systemic disease and have recently been implicated in glomerulonephritis in SLE, the absence of renal disease in drug-induced lupus indicates that additional abnormalities are required to manifest the serious pathogenic potential of anti-[(H2A-H2B)-DNA] antibodies.Abbreviations APC antigen present cells - DIL drug-induced lupus - ELISA enzyme-linked immunosorbent assay - GBM glomerular basement membrane - [(H2A-H2B)-DNA] an intermolecular complex consisting of DNA and a dimer of histones H2A and H2B - nDNA native (double-stranded) DNA - SLE systemic lupus erythematosus     

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.     

Histones synthesized for use in early development of Xenopus laevis are stored as a complex with antigenic properties similar to those of the octamer core of nucleosomes

Serum of patients with systemic lupus erythematosus (SLE) contains crossreacting autoantibodies which recognize histones in nucleosomes or when they are induced to form octamers in solution in the presence of 2 M NaCl, but not when they are dissociated free in solution at physiological ionic strength. We have found that histones stored in eggs of Xenopus laevis for use in rapid nuclear synthesis during early development react with this antibody. This reaction has been observed by radioimmunoassay, inhibition of chromatin assembly by the extracts in the presence of antibody, and, in a preliminary result, by identification of a histone-antibody complex bound to protein A- sepharose. Further evidence that the extract antigen corresponds to the stored histone pool comes from sedimentation and charge fractionation experiments where the chromatin assembly activity and antigen (measured by radioimmunoassay) were found to cofractionate. BEcause the extract histones are not bound to DNA, our results suggest that they are stored as a soluble complex in a conformation similar or identical to the octameric core of the nucleosome. Our data suggest that the histones in this complex are bound to an anionic factor or factors which presumably replaces the DNA in shielding the positive charges on the histones.     

Mobile histone tails in nucleosomes. Assignments of mobile segments and investigations of their role in chromatin folding

The 13C NMR spectrum of isolated nucleosome core particles contains many sharp resonances, including resonances of alpha- and beta-carbons, indicating that certain terminal segments of histones rich in basic residues are highly mobile (Hilliard, R. R., Jr., Smith, R. M., and Rill, R. L. (1986) J. Biol. Chem. 261, 5992-5998). Specific histone termini can be removed sequentially from nucleosome core particles by mild treatment with alpha-chymotrypsin or chymotrypsin plus trypsin (Rosenberg, N. L., Smith. R. M., and Rill, R. L. (1986) J. Biol. Chem. 261, 12375-12383). Comparisons of the 13C NMR spectra of native and several partially proteolyzed core particles indicated that a minimum of residues 1-20 of H3 and 1-11 and 118-128 of H2a are contained in mobile segments of native cores. H4 did not appear to contribute to the resonances from mobile histone segments, but a possible contribution of H2b residues 1-16 could not be ruled out. The 13C NMR spectra of oligonucleosomes containing and lacking lysine-rich histones (H1, H5) were similar to each other and to that of native nucleosome cores both when the oligonucleosomes were in an extended conformation at low ionic strength and when they were in a more compact conformation at higher ionic strength. This similarity suggests that histones H1 and H5 must be largely immobilized upon chromatin binding and that the segments of core histones that are mobile in isolated nucleosome cores are not strongly bound to adjacent linker regions in intact chromatin, and are not immobilized by compaction to the degree achieved in 50 mM phosphate buffer.     

Primary organization of nucleosomes containing all five histories and DNA 175 and 165 base-pairs long

The sequential arrangement of histones along DNA in nucleosomes containing all five histones and DNA about 165 and 175 base-pairs in length has been determined. The data provide evidence that core histones (H2A, H2B, H3 and H4) are arranged in nucleosomes and nucleosome core particles in a largely similar way with the following differences. (1) On nucleosomal DNA about 175 basepairs long core histones are probably shifted by 20 nucleotides on one DNA strand and by 10 nucleotides on the complementary DNA strand from the 5′ end. On nucleosomal DNA 165 base-pairs long, histones appear to be shifted by 10 nucleotides from the 5′ end of DNA on both the DNA strands. (2) Histone H3 is extended beyond core DNA and is bound to the 3′ end of DNA about 175 nucleotides long. Thus, core histones span the whole length of nucleosomal DNA. (3) Histone H2A seems to be absent from the central region of nucleosomal DNA. These results indicate that during the preparation of core particles, some rearrangement of histones or some of their regions occurs.Histone H1 has been shown to be bound mainly to the ends of nucleosomal DNA and, along the whole DNA length, to the gap regions that are free of core histones.     

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.     

Generation of a third-order folded structure for chromatin

A model for the initiation of the diffuse-condensed transition of chromatin induced by a change in the conformation of lysine-rich histones is proposed. Three levels of folded structures are discussed. The first-order folded structure refers to the structure of the repeat unit of chromatin, which is called the nucleosome. The nucleosome contains a nuclease resistant region in which 140 base pairs of DNA are wrapped around the surface of a histone aggregated of two copies each of the histones H2A, H2B, H3 and H4. This DNA-histone aggregate is called a core particle. The nuclease accessible region of the nucleosome is approximately 60 base pairs of DNA which link the core particle, hence the terminology “linker DNA.” The lysine-rich histones, (Hl, H5), which are more loosely bound than the core histones, are associated with the linker DNA. The second-order folded structure refers to the conformation of a polynucleosome. Based on neutron scattering and quasielastic light scattering studies the second-order folded structure is assumed to be an extended helix in solution with 5–7 nucleosome units per turn. The third-order folded structure is defined as that structure resulting from the first stage in the condensation process induced by a conformational change in the lysine-rich histones. Generation of the third-order folded structure in the proposed model is effected by an increased affinity of the lysine-rich histones for super-helical DNA in the core particles in adjacent turns of the second-order folded structure. Since the lysine-rich histones preferentially bind to A-T rich regions in DNA, the distribution of these regions would determine the third-order folded structure. The net effect of a non-random distribution of A-T rich regions as in the proposed model is the generation of a helix for the third-order folded structure. The assumption of a non-random distribution of A-T rich regions is indirectly supported by proflavine binding studies reported herein and by the existence of repetitive and non-repetitive DNA regions inferred from renaturation studies. One consequence of the proposed mechanism is that the majority of the A-T rich regions are in the interior of the third-order folded structure. Promoter sites of high A-T content would then be inaccessible to polymerases. The proposed model also suggests a role for spacer DNA in the genome. Higher order folded structures must also be present in the final state of condensed chromatin since the three orders of folded structures considered in this communication accounts for only 2% of that required in the diffuse-condensed transition.     

Generation of different nucleosome spacing periodicities in vitro. Possible origin of cell type specificity

We have been able to generate ordered nucleosome arrays that span the physiological range of spacing periodicities, using an in vitro system. Our system (a refinement of the procedure previously developed) uses the synthetic polynucleotide poly[d(A-T)], poly[d(A-T)], core histones, purified H1, and polyglutamic acid, a factor that increases nucleohistone solubility and greatly promotes the formation of ordered nucleosome arrays. This system has three useful features, not found in other chromatin assembly systems. First, it allowed us to examine histones from three different cell types/species (sea urchin sperm, chicken erythrocyte, and HeLa) as homologous or heterologous combinations of core and H1 histones. Second, it allowed us to control the average packing density (core histone to polynucleotide weight ratio) of nucleosomes on the polynucleotide; histone H1 is added in a second distinct step in the procedure to induce nucleosome alignment. Third, it permitted us to study nucleosome array formation in the absence of DNA base sequence effects. We show that the value of the spacing periodicity is controlled by the value of the initial average nucleosome packing density. The full range of physiological periodicities appears to be accessible to arrays generated using chicken erythrocyte (or HeLa) core histones in combination with chicken H5. However, chromatin-like structures cannot be assembled for some nucleosome packing densities in reactions involving some histone types, thus limiting the range of periodicities that can be achieved. For example, H1 histone types differ significantly in their ability to recruit disordered nucleosomes into ordered arrays at low packing densities. Sea urchin sperm H1 is more efficient than chicken H5, which is more efficient than H1 from HeLa or chicken erythrocyte. Sea urchin sperm core histones are more efficient in this respect than the other core histone types used. These findings suggest how different repeat lengths arise in different cell types and species, and provide new insights into the problems of nucleosome linker heterogeneity and how different types of chromatin structures could be generated in the same cell.     

DNase I site mapping and micrococcal nuclease digestion of pachytene chromatin reveal novel structural features

A comparison of the DNase I digestion products of the 32P-5'-end-labeled pachytene nucleosome core particles (containing histones H2A, TH2A, X2, H2B, TH2B, H3, and H4) and liver nucleosome core particles (containing somatic histones H2A, H2B, H3, and H4) revealed that the cleavage sites that are 30, 40, and 110 nucleotides away from the 5'-end are significantly more accessible in the pachytene core particles than in the liver core particles. These cleavage sites correspond to the region wherein H2B interacts with the nucleosome core DNA. These results, therefore, suggest that the histone-DNA interaction at these sites in the pachytene core particles is weaker, possibly because of the presence of the histone variant TH2B interacting at similar topological positions in the nucleosome core as that of its somatic counterpart H2B. Such a loosened structure may also be maintained even in the native pachytene chromatin since micrococcal nuclease digestion of pachytene nuclei resulted in a higher ratio of subnucleosomes (SN4 + SN7) to mononucleosomes than that observed in liver chromatin.     

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.     

Nonrandom assembly of chromatin during hydroxyurea inhibition of DNA synthesis

Incubation of MSB-1 chicken lymphoblastoid cells with hydroxyurea leads to a rapid 25-fold decrease in the incorporation of [3H]thymidine into DNA and a 5-fold decrease [3H]lysine into the nucleosome core histones. I have investigated whether the distortion in the normal proportion of histone-DNA synthesis results in alterations in the nucleosome assembly process and find that neither the stoichiometry of new histone synthesis nor the deposition is appreciably changed during hydroxyurea incubation. Protein cross-linking and micrococcal nuclease digestion show that the histones synthesized during hydroxyurea treatment form octamer structures and are assembled into typical nucleosome particles. Minor nucleosome subpopulations are found which exhibit altered sensitivity to nuclease digestion and which are depleted in new histones H3 and H4. When MSB-1 cells incubated in hydroxyurea are pulsed briefly with density-labeled amino acids and [3H]lysine, the radiolabeled core histone octamers formed are as dense as individual monomer histones. These results suggest that the newly synthesized histone octamers are uniformly dense and do not contain mixtures of new and old histones. Thus, histones synthesized during hydroxyurea incubation are deposited nonrandomly and do not exchange with preexisting histones.     

The organization of histones and DNA in chromatin: Evidence for an arginine-rich histone kernel

We have examined the role played by various histones in the organization of the DNA of the nucleosome, using staphylococcal nuclease as a probe of DNA conformation. When this enzyme attacks chromatin, a series of fragments evenly spaced at 10 base pair intervals is generated, reflecting the histone-DNA interactions within the nucleosome structure. To determine what contribution the various histones make to DNA organization, we have studied the staphylococcal nuclease digestion patterns of complexes of DNA with purified histones.Virtually all possible combinations of homogeneous histones were reconstituted onto DNA. Exhaustive digestion of a complex containing the four histones H2A, H2B, H3, and H4 yields a DNA fragment pattern very similar to that of whole chromatin. The only other combinations of histones capable of inducing chromatin-like DNA organization are H2A/H2B/H4 and those mixtures containing both H3 and H4. From an examination of the kinetics of digestion of H3/H4 reconstitutes, we conclude that although the other histones have a role in DNA organization within the nucleosome, the arginine-rich histone pair, H3/H4, can organize DNA segments the length of the nucleosome core in the absence of all other histones.     

Purification and initial characterization of a protein which facilitates assembly of nucleosome-like structure from mammalian cells

A protein, which facilitates assembly of a nucleosome-like structure in vitro, was previously partially purified from mouse FM3A cells [Ishimi, Y. et al. (1983) J. Biochem. (Tokyo) 94, 735-744]. The protein has been purified to approximately 80% from FM3A cells by using histone-Sepharose column chromatography. It sedimented at 4.6 S and had a molecular mass of 53kDa. A preincubation of core histones with the 53-kDa peptide before DNA addition was necessary for the nucleosome assembly. The 53-kDa peptide bound to core histones and formed a 12-S complex. This complex contained stoichiometrical amounts of the 53-kDa peptide and core histones, and the core histones in this complex were composed of equal amounts of H2A, H2B, H3 and H4 histones. The nucleosomes were assembled by adding pBR322 DNA to the 12-S complex. When mononucleosome DNA and core histones were mixed in the presence of the 53-kDa peptide, formation of a 10.5-S complex was observed. The complex contained DNA and core histones in equal amounts, while no 53-kDa peptide was detected in the complex. From above results it is suggested that the 53-kDa peptide facilitates nucleosome assembly by mediating formation of histone octamer and transferring it to DNA. Rat antibody against the 53-kDa peptide did not bind to nucleoplasmin from Xenopus eggs. The relationship between the 53-kDa peptide and nucleoplasmin is discussed.     

Role of histone tyrosines in nucleosome formation and histone-histone interaction

We have studied the functional properties of iodinated histones. Isolated, denatured histones were iodinated at trace levels and then renatured together with carrier histones and high molecular weight DNA to form nucleohistone. Nucleosomes were prepared from the reconstitute using micrococcal nuclease, and the relative representations of the individual iodinated tyrosines of the histones in the reconstituted nucleosomes were determined. Our principal findings are 1) that denatured histones can be iodinated at any tyrosine without interfering in subsequent nucleosome reconstitution and 2) that the resulting reconstituted nucleosomes nevertheless possess histone cores of altered stability, being either more or less stable depending on the particular tyrosine which is iodinated. We show that tyrosines 37, 40, and 42 of H2B are protected from iodination in intact core particles, as expected since these tyrosines lie within the H2B-H2A binding site. Yet iodination of these tyrosines in denatured H2B does not interfere with nucleosome assembly. However, the histone cores isolated from these reconstituted nucleosomes are of diminished stability as assayed by Sephadex column chromatography in 2 M salt. In contrast, iodination of tyrosines 83 and 121 of H2B, as well as iodination of the tyrosines of H2A, increases the stability of the histone octamer core. Iodination of H4 tyrosine 72 is without effect on histone octamer stability. Tyrosine iodination constitutes a profound amino acid alteration in the context of the absolute evolutionary conservation of most histone tyrosines. For example, all H2Bs sequenced to date, from fungi to mammals, possess tyrosines at positions 37, 40, and 42. Our results suggest that the immutability of these tyrosines reflects some sophisticated function of the nucleosome histone core beyond the assembly and mere maintenance of a compact structure.     

Effect of trypsinization and histone H5 addition on DNA twist and topology in reconstituted minichromosomes.

Free DNA in solution exhibits an untwisting of the double helix with increasing temperature. We have shown previously that when DNA is reconstituted with histones to form nucleosome core particles, both the core DNA and the adjacent linker DNA are constrained from thermal untwisting. The origin of this constraint is unknown. Here we examine the effect of two modifications of nucleosome structure on the constraint against thermal untwisting, and also on DNA topology. In one experiment, we removed the highly positively charged histone amino and carboxy termini by trypsinization. Alternatively, we added histone H5, a histone H1 variant from chick erythrocytes. Neither of these modifications had any major effect on DNA topology or twist in the nucleosome.     

Nucleosome assembly in vitro: separate histone transfer and synergistic interaction of native histone complexes purified from nuclei of Xenopus laevis oocytes.

High speed supernatants of Xenopus laevis oocyte nuclei efficiently assemble DNA into nucleosomes in vitro under physiological salt conditions. The assembly activity cofractionates with two histone complexes composed of the acidic protein N1/N2 in complex with histones H3 and H4, and nucleoplasmin in complex with histones H2B and H2A. Both histone complexes have been purified and their nucleosome assembly activities have been analysed separately and in combination. While the histones from the N1/N2 complexes are efficiently transferred to DNA and induce supercoils into relaxed circular plasmid DNA, the nucleoplasmin complexes show no supercoil induction, but can also transfer their histones to DNA. In combination, the complexes act synergistically in supercoil induction thereby increasing the velocity and the number of supercoils induced. Electron microscopic analysis of the reaction products shows fully packaged nucleoprotein structures with the typical nucleosomal appearance resulting in a compaction ratio of 2.8 under low ionic strength conditions. The high mobility group protein HMG-1, which is also present in the soluble nuclear homogenate from X. laevis oocytes, is not required for nucleosome core assembly. Fractionation experiments show that the synergistic effect in the supercoiling reaction can be exerted by histones H3 and H4 bound to DNA and the nucleoplasmin complexes alone. This indicates that it is not the synchronous action of both complexes which is required for nucleosome assembly, but that their cooperative action can be resolved into two steps: deposition of H3 and H4 from the N1/N2 complexes onto the DNA and completion of nucleosome core formation by addition of H2B and H2A from the nucleoplasmin complexes.     

Liquid-Liquid Phase Separation of Histone Proteins in Cells: Role in Chromatin Organization

Liquid-liquid phase separation (LLPS) of proteins and nucleic acids has emerged as an important phenomenon in membraneless intracellular organization. We demonstrate that the linker histone H1 condenses into liquid-like droplets in the nuclei of HeLa cells. The droplets, observed during the interphase of the cell cycle, are colocalized with DNA-dense regions indicative of heterochromatin. In vitro, H1 readily undergoes LLPS with both DNA and nucleosomes of varying lengths but does not phase separate in the absence of DNA. The nucleosome core particle maintains its structural integrity inside the droplets, as demonstrated by FRET. Unexpectedly, H2A also forms droplets in the presence of DNA and nucleosomes in vitro, whereas the other core histones precipitate. The phase diagram of H1 with nucleosomes is invariant to the nucleosome length at physiological salt concentration, indicating that H1 is capable of partitioning large segments of DNA into liquid-like droplets. Of the proteins tested (H1, core histones, and the heterochromatin protein HP1α), this property is unique to H1. In addition, free nucleotides promote droplet formation of H1 nucleosome in a nucleotide-dependent manner, with droplet formation being most favorable with ATP. Although LLPS of HP1α is known to contribute to the organization of heterochromatin, our results indicate that H1 also plays a role. Based on our study, we propose that H1 and DNA act as scaffolds for phase-separated heterochromatin domains.