Co-existence of two different types of soluble histone complexes in nuclei of Xenopus laevis oocytes

The nuclear pool of soluble histones in Xenopus laevis oocytes is organized into two major types of acidic histone complexes separable by sucrose density gradient centrifugation. One type of complex sediments at 5 S (Mr approximately 120,000), is isoelectric at pH 4.6, and contains histones H3 and/or H4 tightly bound to one polypeptide of a pair of very acidic polypeptides, designated N1 and N2 (Kleinschmidt, J. A., and Franke, W. W. (1982) Cell 29, 799-809). This complex can be selectively immunoprecipitated by guinea pig antibodies against purified protein N1/N2. In contrast, a larger complex of 7 S contains four histones and nucleoplasmin (the purified protein exists as a pentamer of a polypeptide of Mr approximately 30,000), is isoelectric over the pH range of 5-7, and can be immunoprecipitated by nucleoplasmin antibodies. Its relative molecular weight of 130,000-170,000, as determined by gel filtration, sucrose density gradient centrifugation, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the cross-linked complexes, excludes the association of a histone octamer with nucleoplasmin. In addition to histones H2A and H2B, two histones (designated H3 and H4) which are similar in their electrophoretic mobilities to histones H3 and H4 but have lower isoelectric pH values are enriched in immuno-precipitates obtained with nucleoplasmin antibodies. Cross-linking of complexes present in intact nuclei, using 1% formaldehyde at near-physiological ionic strength and pH, indicates the coexistence of these two soluble histone complexes in the living cell. In chromatin assembly experiments using SV 40 DNA, both histone fractions are able to transfer histones to DNA, resulting in an increase of DNA superhelicity and the formation of beaded nucleoprotein complexes of nucleosome-like morphology. The common principle governing both types of complexes, i.e. the association of one or two histone molecules with a karyophilic large acidic histone-binding protein is emphasized. We discuss the possible role of these complexes in storing histones utilized in chromatin assembly during early amphibian embryogenesis as well as the possible existence of similar complexes, albeit at lower concentrations, in somatic cells.     

The histone H3/H4.N1 complex supplemented with histone H2A-H2B dimers and DNA topoisomerase I forms nucleosomes on circular DNA under physiological conditions

We have fractionated the whole cell extract of Xenopus oocytes (oocyte S-150) and isolated the endogenous components required for DNA supercoiling and nucleosome formation. Histone H2B and the three oocyte-specific H2A proteins were purified as free histones. Histones H3 and H4 were purified 100-fold in a complex with the acidic protein N1. In the presence of DNA topoisomerase I or II, histone H3/H4.N1 complexes supercoil DNA in a reaction that is inhibited by Mg2+, and this inhibition is relieved by NTPs. The supercoiling reaction induced by H3/H4.N1 complexes is enhanced by free histone H2A-H2B dimers, which by themselves do not supercoil DNA. Nuclease digestions and protein analyses indicate that H3/H4.N1 complexes form subnucleosomal particles containing histones H3 and H4. Nucleosomes containing 146-base pair DNA and the four histones are formed when histones H2A and H2B complement the reaction.     

Supercoiling energy and nucleosome formation: the role of the arginine-rich histone kernel.

We have formed complexes of relaxed closed circular Col E1 DNA with various combinations of histones, and examined the effects of treating the complexes with nicking-closing enzyme. Germond et al (1) have shown that when a mixture of the four core histones of the nucleosome (HIA, H2B, H3 and H4) is used in such an experiment, the subsequently isolated DNA is supercoiled. We find that the arginine-rich histone pair, H3 and H4, is sufficient to induce the supercoiling observed in this experiment. Both H3 and H4 are required, and in the absence of either, no other histones are effective. H3 and and H4 are as efficient, per unit weight, as a mixture of the four histones in inducing supercoils. We also show that there is a large difference between the DNA bending energy needed to form a nucleosome and that needed to form one turn of normal superhelical DNA. These two processes are energetically quite distinct and probably separable. We estimate the free energy of interaction between DNA-bound histone pairs, and find that one or two such interactions would generate enough energy to fold the DNA into a nucleosome.     

Two complexes that contain histones are required for nucleosome assembly in vitro: role of nucleoplasmin and N1 in Xenopus egg extracts

The composition and function of histone storage complexes of Xenopus eggs have been investigated using monoclonal antibodies. We show that core histones are contained in two distinct complexes: H2A and H2B are associated with nucleoplasmin, and H3 and H4 are associated with nuclear protein N1. Immunodepletion analyses demonstrate that both complexes are required for nucleosome core assembly by extracts in vitro, the product being a simple sum of the histones from each complex. In addition, the majority of the stored H2A is shown to be an unusual form that migrates close to the position of H3 by SDS-polyacrylamide gel electrophoresis and resembles a variant synthesized in a cell-cycle-independent manner in mammalian cells.     

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.     

H1 histone, polylysine and spermine facilitate nucleosome assembly in vitro

Nucleosome formation has been studied in a system containing relaxed Col E1 DNA, core histones and an extract of Drosophila embryos. The formation of nucleosomes was established by the introduction of supercoils into DNA. The degree of DNA supercoiling was shown to be higher if nucleosomes were assembled in the presence of the H1 histone, polylysine (Mr 20 000) or spermine. These agents do not stimulate relaxation and are the more effective the earlier they are added to the reaction. Thus, the H1 histone, polylysine and spermine facilitate nucleosome assembly in vitro.     

Archaeal histone tetramerization determines DNA affinity and the direction of DNA supercoiling

DNA binding and the topology of DNA have been determined in complexes formed by >20 archaeal histone variants and archaeal histone dimer fusions with residue replacements at sites responsible for histone fold dimer:dimer interactions. Almost all of these variants have decreased affinity for DNA. They have also lost the flexibility of the wild type archaeal histones to wrap DNA into a negative or positive supercoil depending on the salt environment; they wrap DNA into positive supercoils under all salt conditions. The histone folds of the archaeal histones, HMfA and HMfB, from Methanothermus fervidus are almost identical, but (HMfA)(2) and (HMfB)(2) homodimers assemble into tetramers with sequence-dependent differences in DNA affinity. By construction and mutagenesis of HMfA+HMfB and HMfB+HMfA histone dimer fusions, the structure formed at the histone dimer:dimer interface within an archaeal histone tetramer has been shown to determine this difference in DNA affinity. Therefore, by regulating the assembly of different archaeal histone dimers into tetramers that have different sequence affinities, the assembly of archaeal histone-DNA complexes could be localized and used to regulate gene expression.     

Conserved eukaryotic histone-fold residues substituted into an archaeal histone increase DNA affinity but reduce complex flexibility

Although the archaeal and eukaryotic nucleosome core histones evolved from a common ancestor, conserved lysine residues are present at DNA-binding locations in all four eukaryotic histones that are not present in the archaeal histones. Introduction of lysine residues at the corresponding locations into an archaeal histone, HMfB, generated a variant with increased affinity for DNA that formed more compact complexes with DNA. However, these complexes no longer facilitated the circularization of short DNA molecules and had lost the flexibility to wrap DNA alternatively in either a negative or positive supercoil.     

Assembly of nucleosomes: the reaction involving X. laevis nucleoplasmin

We analyze the nucleosome core assembly reaction which is mediated in vitro by a protein previously purified from Xenopus laevis eggs, now named nucleoplasmin in reference to its occurrence in the soluble phase of the nucleus of a wide range of vertebrate cell types. Nucleoplasmin is present in solution as a pentamer. We use nuclease digestion analysis to show that the protein assembles bona fide nucleosome cores in vitro from purified histones and DNA. Nucleoplasmin itself binds neither to DNA nor to the nucleoprotein particles which it assembles in vitro. However, it interacts with histones in vitro in such a way that histones no longer adhere to negatively charged surfaces. We have found no evidence for sterically specific interactions with particular histones. The initial rate of the nucleosome core assembly reaction mediated by purified nucleoplasmin in vitro is essentially identical with the rate of the nucleosome assembly reaction which occurs in the cell-free extracts of Xenopus eggs from which nucleoplasmin was purified. This rate is sufficient to account for the rate of nucleosome assembly required during the early development of Xenopus embryos.     

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.     

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.     

Assembly and properties of chromatin containing histone H1

The Xenopus oocyte supernatant (oocyte S-150) forms chromatin in a reaction that is affected by temperature and by the concentration of ATP and Mg. Under optimal conditions at 27 degrees C, relaxed DNA plasmids are efficiently assembled into supercoiled minichromosomes with the endogenous histones H3, H4, H2A and H2B. This assembly reaction is a gradual process that takes four to six hours for completion. Micrococcal nuclease digestions of the chromatin assembled under these conditions generate an extended series of DNA fragments that are, on average, multiples of 180 base-pairs. We have examined the effect of histone H1 in this system. Exogenous histone H1, when added at a molar ratio of H1 to nucleosome of 1:1 to 5:1, causes an increase in the micrococcal nuclease resistance of the chromatin without causing chromatin aggregation under these experimental conditions. Furthermore, the periodically arranged nucleosomes display longer internucleosome distances, and the average length of the nucleosome repeat is a function of the amount of histone H1 added, when this histone is present at the onset of the assembly process. In contrast, no major change in the length of the nucleosome repeat is observed when histone H1 is added at the end of the chromatin assembly process. Protein analyses of the purified minichromosomes show that histone H1 is incorporated in the chromatin that is assembled in the S-150 supplemented with histone H1. The amount of histone H1 bound to chromatin is a function of the total amount of histone H1 added. We define here the parameters that generate histone H1-containing chromatin with native nucleosome repeats from 160 to 220 base-pairs, and we discuss the implications of these studies.     

The crystal structure of nucleoplasmin-core: implications for histone binding and nucleosome assembly.

The efficient assembly of histone complexes and nucleosomes requires the participation of molecular chaperones. Currently, there is a paucity of data on their mechanism of action. We now present the structure of an N-terminal domain of nucleoplasmin (Np-core) at 2.3 A resolution. The Np-core monomer is an eight-stranded beta barrel that fits snugly within a stable pentamer. In the crystal, two pentamers associate to form a decamer. We show that both Np and Np-core are competent to assemble large complexes that contain the four core histones. Further experiments and modeling suggest that these complexes each contain five histone octamers which dock to a central Np decamer. This work has important ramifications for models of histone storage, sperm chromatin decondensation, and nucleosome assembly.     

Association of nucleosome core particle DNA with different histone oligomers. Transfer of histones between DNA-(H2A,H2B) and DNA-(H3,H4) complexes

In non-denaturing low ionic strength gels, the titration of core DNA with H2A,H2B produces five well-defined bands. Quantitative densitometry and cross-linking experiments indicate that these bands are due to the successive binding of H2A,H2B dimers to core DNA. Only two bands are obtained with DNA-(H3,H4) samples. The slower of these bands is broad and presumably corresponds to two complexes containing one and two H3,H4 tetramers, respectively. In gels of higher ionic strength, DNA-(H2A,H2B) samples produce an ill-defined band, suggesting that the lifetime of the complexes containing H2A,H2B is relatively short. However, the low intensity of the free DNA band observed in these gels indicates that most of the DNA is associated with H2A,H2B. In agreement with this, our results obtained using different techniques (sedimentation, cross-linking, trypsin and nuclease digestions, and thermal denaturation) demonstrate that the association of H2A,H2B with core DNA occurs in free solution in both the absence and presence of NaCl (0.1 to 0.2 M). The low mobilities of DNA-(H2A,H2B) complexes, together with sedimentation and DNase I digestion results, indicate that the DNA in these complexes is not folded into the compact structure found in the core particle. Furthermore, non-denaturing gels have been used to study the dynamic properties of DNA-(H2A,H2B) and DNA-(H3,H4) complexes in 0.2 M-NaCl. Our results show that: (1) H2A,H2B and H3,H4 can associate, respectively, with DNA-(H3,H4) and DNA-(H2A,H2B) to produce complexes containing the four core histones; (2) DNA-(H2A,H2B) and DNA-(H3,H4) are able to transfer histones to free core DNA; (3) an exchange of histone pairs takes place between DNA-(H2A,H2B) and DNA-(H3,H4) and produces complexes with the same histone composition as that of the normal nucleosome core particle; and (4) although both histone pairs can exchange, histones H2A,H2B show a higher tendency than H3,H4 to migrate from one incomplete core particle to another. The complexes produced in these reactions have the same compact structure as reconstituted core particles containing the four core histones. Our kinetic results are consistent with a reaction mechanism in which the transfer of histones involves direct contacts between the reacting complexes. The possible participation of these spontaneous reactions on the mechanism of nucleosome assembly is discussed.     

In vivo study of the nucleosome assembly functions of ASF1 histone chaperones in human cells

Histone chaperones have been implicated in nucleosome assembly and disassembly as well as histone modification. ASF1 is a highly conserved histone H3/H4 chaperone that synergizes in vitro with two other histone chaperones, chromatin assembly factor 1 (CAF-1) and histone repression A factor (HIRA), in DNA synthesis-coupled and DNA synthesis-independent nucleosome assembly. Here, we identify mutants of histones H3.1 and H3.3 that are unable to interact with human ASF1A and ASF1B isoforms but that are still competent to bind CAF-1 and HIRA, respectively. We show that these mutant histones are inefficiently deposited into chromatin in vivo. Furthermore, we found that both ASF1A and ASF1B participate in the DNA synthesis-independent deposition of H3.3 in HeLa cells, thus highlighting an unexpected role for ASF1B in this pathway. This pathway does not require interaction of ASF1 with HIRA. We provide the first direct determination that ASF1A and ASF1B play a role in the efficiency of nucleosome assembly in vivo in human cells.     

H3.H4 tetramer directs DNA and core histone octamer assembly in the nucleosome core particle.

The way in which histones interact with DNA during in vitro assembly of nucleohistone has been examined. Chicken erythrocyte core histones H2A, H2B, H3, and H4 and lambdaDNA in 2 M NaCl were allowed to interact by stepwise decrease in the salt concentration. Binding, although weak, was first observed at 1.4 M NaCl and was essentially completed at 0.6 M NaCl. Analysis of the DNA-bound histones revealed that each of the histones in the pairs H2A,H2B and H3,H4 was always present in equimolar amounts and that the relative proportion of each pair was constant between 1.4 and 0.8 M NaCl. Evidence is presented suggesting that binding occurred via complexes of the four histones, the nature of which is likely to reflect the equilibrium among the octamer and its products of dissociation (Ruiz-Carrillo, A., & Jorcano, J.L. (1979) Biochemistry (preceding paper in this issue)). The presence of complexes of the four core histones is, however not required for the correct assembly of the nucleosome core particle. Nucleohistones obtained by adding at progressively lower ionic strengths the dimer H2A.H2B to the H3.H4-DNA complex (split reconstitutions) had the same characteristics as those assembled with the core histone complexes.     

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.     

ATP dependent histone phosphorylation and nucleosome assembly in a human cell free extract.

Physiologically spaced nucleosome formation in HeLa cell extracts is ATP dependent. ATP hydrolysis is required for chromatin assembly on both linear and covalently closed circular DNA. The link between the phosphorylation state of histones and nucleosome formation has been examined and we demonstrate that in the absence of histone phosphorylation no stable and regularly spaced nucleosomes are formed. Phosphorylated H3 stabilizes the nucleosome core; while phosphorylation of histone H2a is necessary to increase the linker length between nucleosomes from 0 to approximately 45 bp. Histone H1 alone, whether phosphorylated or unphosphorylated, does not increase the nucleosome repeat length in the absence of core histone phosphorylation. Phosphorylations of H1 and H3 correlate with condensation of chromatin. Maximum ATP hydrolysis which is necessary to increase the periodicity of nucleosomes from approximately 150 to approximately 185 bp, not only inhibits H1 and H3 phosphorylation but facilitates their dephosphorylation.