Nuclear assembly of purified Crythecodinium cohnii chromosomes in cell—free extracts of Xenopus laevis eggs

Incubation of dinoflagellate Crythecodinium cohnii chromosomes in cytoplasmic extracts of unfertilized Xenopus laevis eggs resulted in chromosomes decondensation and recondensation,nuclear envelope assembly,and nuclear reconstitution.Dinoflagellate Crythecodinium cohnii is a kind of primitive eukaryote which possesses numerous permanently condensed chromosomes and discontinuous double-layered nuclear membrane throughout the cell cycle.The assembled nuclei,being surrounded by a continuous double membrane containing nuclear pores and the uniformly dispersed chromatin fibers are morphologically distinguishable from that of Dinoflagellate Crythecodinium cohnii.However,incubation of dinoflagellate Cyrthecodinium cohnii chromosomes in the extracts from dinoflagellate Crythecodinium cohnii cells does not induce nuclear reconstitution.     

The NH2 tail of the novel histone variant H2BFWT exhibits properties distinct from conventional H2B with respect to the assembly of mitotic chromosomes

We have studied the functional and structural properties of nucleosomes reconstituted with H2BFWT, a recently identified putative histone variant of the H2B family with totally unknown function. We show that H2BFWT can replace the conventional histone H2B in the nucleosome. The presence of H2BFWT did not affect the overall structure of the nucleosome, and the H2BFWT nucleosomes exhibited the same stability as conventional nucleosomes. SWI/SNF was able to efficiently remodel and mobilize the H2BFWT nucleosomes. Importantly, H2BFWT, in contrast to conventional H2B, was unable to recruit chromosome condensation factors and to participate in the assembly of mitotic chromosomes. This was determined by the highly divergent (compared to conventional H2B) NH2 tail of H2BFWT. These data, in combination with the observations that H2BFWT was found by others in the sperm nuclei and appeared to be associated with the telomeric chromatin, suggest that H2BFWT could act as a specific epigenetic marker.     

Nucleosome destabilization in the epigenetic regulation of gene expression

Assembly, mobilization and disassembly of nucleosomes can influence the regulation of gene expression and other processes that act on eukaryotic DNA. Distinct nucleosome-assembly pathways deposit dimeric subunits behind the replication fork or at sites of active processes that mobilize pre-existing nucleosomes. Replication-coupled nucleosome assembly appears to be the default process that maintains silent chromatin, counteracted by active processes that destabilize nucleosomes. Nucleosome stability is regulated by the combined effects of nucleosome-positioning sequences, histone chaperones, ATP-dependent nucleosome remodellers, post-translational modifications and histone variants. Recent studies suggest that histone turnover helps to maintain continuous access to sequence-specific DNA-binding proteins that regulate epigenetic inheritance, providing a dynamic alternative to histone-marking models for the propagation of active chromatin.     

Dispersive segregation of nucleosomes during replication of simian virus 40 chromosomes

The distribution of preformed ("old") histone octamers between the two arms of DNA replication forks was analyzed in simian virus 40(SV40)-infected cells following treatment with cycloheximide to prevent nucleosome assembly from nascent histones. Viral chromatin synthesized in the presence of cycloheximide was shown to be deficient in nucleosomes. Replicating SV40 DNA (wild-type 800 and capsid assembly mutant, tsB11) was radiolabeled in either intact cells or nuclear extracts supplemented with cytosol. Nascent nucleosomal monomers were then released by extensive digestion of isolated nuclei, nuclear extracts or isolated viral chromosomes with micrococcal nuclease. The labeled nucleosomal DNA was purified and found to hybridize to both strands of SV40 DNA restriction fragments taken from each side of the origin of DNA replication, whereas Okazaki fragments hybridized only to the strand representing the retrograde DNA template. In addition, isolated, replicating SV40 chromosomes were digested with two strand-specific exonucleases that excised nascent DNA from either the forward or the retrograde side of replication forks. Pretreatment of cells with cycloheximide did not result in an excess of prenucleosomal DNA on either side of replication forks, but did increase the amount of internucleosomal DNA. These data are consistent with a dispersive model for nucleosome segregation in which "old" histone octamers are distributed to both arms of DNA replication forks.     

Core histone N-termini play an essential role in mitotic chromosome condensation

We have studied the role of core histone tails in the assembly of mitotic chromosomes using Xenopus egg extracts. Incubation of sperm nuclei in the extracts led to the formation of mitotic chromosomes, a process we found to be correlated with phosphorylation of the N-terminal tail of histone H3 at Ser10. When the extracts were supplemented with H1-depleted oligosomes, they were not able to assemble chromosomes. Selective elimination of oligosome histone tails by trypsin digestion resulted in a dramatic decrease in their ability to inhibit chromosome condensation. The chromosome assembly was also inhibited by each of the histone tails with differing efficiency. In addition, we found that nucleosomes were recruiting through the flexible histone tails some chromosome assembly factors, different from topoisomerase II and 13S condensin. These findings demonstrate that histone tails play an essential role in chromosome assembly. We also present evidence that the nucleosomes, through physical association, were able to deplete the extracts from the kinase phosphorylating histone H3 at Ser10, suggesting that this kinase could be important for chromosome condensation.     

Fractionation of nucleosomes by salt elution from micrococcal nuclease- digested nuclei

The solubilization of nucleosomes and histone H1 with increasing concentrations of NaCl has been investigated in rat liver nuclei that had been digested with micrococcal nuclease under conditions that did not substantially alter morphological properties with respect to differences in the extent of chromatin condensation. The pattern of nucleosome and H1 solubilization was gradual and noncoordinate and at least three different types of nucleosome packing interactions could be distinguished from the pattern. A class of nucleosomes containing 13-- 17% of the DNA and comprising the chromatin structures most available for micrococcal nuclease attack was eluted by 0.2 M NaCl. This fraction was solubilized with an acid-soluble protein of apparent molecular weight of 20,000 daltons and no histone H1. It differed from the nucleosomes released at higher NaCl concentrations in content of nonhistone chromosomal proteins. 40--60% of the nucleosomes were released by 0.3 M NaCl with 30% of the total nuclear histone H1 bound. The remaining nucleosomes and H1 were solublized by 0.4 M or 0.6 M NaCl. H1 was not nucleosome bound at these ionic strengths, and these fractions contained, respectively, 1.5 and 1.8 times more H1 per nucleosome than the population released by 0.3 M NaCl. These fractions contained the DNA least available for micrococcal nuclease attach. The strikingly different macromolecular composition, availability for nuclease digestion, and strength of the packing interactions of the nucleosomes released by 0.2 M NaCl suggest that this population is involved in a special function.     

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.     

Nucleosome assembly protein 1 exchanges histone H2A-H2B dimers and assists nucleosome sliding

Eukaryotic chromatin is highly dynamic and turns over rapidly even in the absence of DNA replication. Here we show that the acidic histone chaperone nucleosome assembly protein 1 (NAP-1) from yeast reversibly removes and replaces histone protein dimer H2A-H2B or histone variant dimers from assembled nucleosomes, resulting in active histone exchange. Transient removal of H2A-H2B dimers facilitates nucleosome sliding along the DNA to a thermodynamically favorable position. Histone exchange as well as nucleosome sliding is independent of ATP and relies on the presence of the C-terminal acidic domain of yeast NAP-1, even though this region is not required for histone binding and chromatin assembly. Our results suggest a novel role for NAP-1 (and perhaps other acidic histone chaperones) in mediating chromatin fluidity by incorporating histone variants and assisting nucleosome sliding. NAP-1 may function either untargeted (if acting alone) or may be targeted to specific regions within the genome through interactions with additional factors.     

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.     

Dimerization of the CENP‐A assembly factor HJURP is required for centromeric nucleosome deposition

The epigenetic mark of the centromere is thought to be a unique centromeric nucleosome that contains the histone H3 variant, centromere protein‐A (CENP‐A). The deposition of new centromeric nucleosomes requires the CENP‐A‐specific chromatin assembly factor HJURP (Holliday junction recognition protein). Crystallographic and biochemical data demonstrate that the Scm3‐like domain of HJURP binds a single CENP‐A–histone H4 heterodimer. However, several lines of evidence suggest that HJURP forms an octameric CENP‐A nucleosome. How an octameric CENP‐A nucleosome forms from individual CENP‐A/histone H4 heterodimers is unknown. Here, we show that HJURP forms a homodimer through its C‐terminal domain that includes the second HJURP_C domain. HJURP exists as a dimer in the soluble preassembly complex and at chromatin when new CENP‐A is deposited. Dimerization of HJURP is essential for the deposition of new CENP‐A nucleosomes. The recruitment of HJURP to centromeres occurs independent of dimerization and CENP‐A binding. These data provide a mechanism whereby the CENP‐A pre‐nucleosomal complex achieves assembly of the octameric CENP‐A nucleosome through the dimerization of the CENP‐A chaperone HJURP.     

体外装配核小体过程组蛋白浓度依赖的动力学模型

为探索组蛋白浓度对核小体体外装配的影响,本研究表达纯化了4种组蛋白,通过控制实验反应体系中组蛋白的浓度,利用盐透析法在体外装配了核小体,检测分析了组蛋白浓度与核小体组装效率的关系。以此实验数据为基础,提出了核小体组装过程组蛋白浓度依赖性的动力学模型。实验结果发现,反应体系中组蛋白浓度与核小体生成量呈典型的线性关系。依据动力学理论模型,进行线性回归拟合,回归系数达到0.963;经计算601 DNA序列组装核小体的反应速率常数k为1.49×10^-5mL·h·μg^-1。CS1序列验证动力学模型的线性回归相关系数为0.989,反应速率常数为1.52×10^-5mL·h·μg^-1。该实验方法及动力学模型中反应速率常数k可用于评价相同长度的DNA序列组装核小体的能力、组蛋白与其突变体以及组蛋白变体之间形成核小体结构能力的差异。该动力学模型的建立为理解核小体装配、核小体定位、染色质结构等相关问题提供了理论指导。     

A nucleosome assembly factor is a constituent of simian virus 40 minichromosomes.

Using in vitro replication assays, we compared native with salt-treated simian virus 40 minichromosomes isolated from infected cell nuclei. Minichromosomes from both preparations contain the full complement of nucleosomes, but salt treatment removes histone H1 and a fraction of nonhistone chromatin proteins. Both types of minichromosomes served well as templates for in vitro replication, but the structures of the replication products were strikingly different. Replicated salt-treated minichromosomes contained, on average, about half the normal number of nucleosomes as previously shown (T. Krude and R. Knippers, Mol. Cell. Biol. 11:6257-6267, 1991). In contrast, the replicated untreated minichromosomes were found to be densely packed with nucleosomes, indicating that an assembly of new nucleosomes occurred during in vitro replication. Biochemical and immunological data showed that the fraction of nonhistone chromatin proteins associated with native minichromosomes includes a nucleosome assembly activity that appears to be closely related to chromatin assembly factor I (S. Smith and B. W. Stillman, Cell 58:15-25, 1989). Furthermore, this minichromosome-bound nucleosome assembly factor is able to exert its activity in trans to replicating protein-free competitor DNA. Thus, native chromatin itself contains the activities required for an ordered assembly of nucleosomes during the replication process.     

Human CAF-1-dependent nucleosome assembly in a defined system

Replication-coupled nucleosome assembly is a critical step in packaging newly synthesized DNA into chromatin. Previous studies have defined the importance of the histone chaperones CAF-1 and ASF1A, the replicative clamp PCNA, and the clamp loader RFC for the assembly of nucleosomes during DNA replication. Despite significant progress in the field, replication-coupled nucleosome assembly is not well understood. One of the complications in elucidating the mechanisms of replication-coupled nucleosome assembly is the lack of a defined system that faithfully recapitulates this important biological process in vitro. We describe here a defined system that assembles nucleosomal arrays in a manner dependent on the presence of CAF-1, ASF1A-H3-H4, H2A-H2B, PCNA, RFC, NAP1L1, ATP, and strand breaks. The loss of CAF-1 p48 subunit causes a strong defect in packaging DNA into nucleosomes by this system. We also show that the defined system forms nucleosomes on nascent DNA synthesized by the replicative polymerase δ. Thus, the developed system reproduces several key features of replication-coupled nucleosome assembly.     

Nuclear reassembly in vitro is independent of nucleosome/chromatin assembly

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Histone-DNA binding free energy cannot be measured in dilution-driven dissociation experiments

Despite decades of study on nucleosomes, there has been no experimental determination of the free energy of association between histones and DNA. Instead, only the relative free energy of association of the histone octamer for differing DNA sequences has been available. Recently, a method was developed based on quantitative analysis of nucleosome dissociation in dilution experiments that provides a simple practical measure of nucleosome stability. Solution conditions were found in which nucleosome dissociation driven by dilution fit well to a simple model involving a noncooperative nucleosome assembly/disassembly equilibrium, suggesting that this approach might allow absolute equilibrium affinity of the histone octamer for DNA to be measured. Here, we show that the nucleosome assembly/disassembly process is not strictly reversible in these solution conditions, implying that equilibrium affinities cannot be obtained from these measurements. Increases in [NaCl] or temperature, commonly employed to suppress kinetic bottlenecks in nucleosome assembly, lead to cooperative behavior that cannot be interpreted with the simple assembly/disassembly equilibrium model. We conclude that the dilution experiments provide useful measures of kinetic but not equilibrium stability. Kinetic stability is of practical importance: it may govern nucleosome function in vivo, and it may (but need not) parallel absolute thermodynamic stability.     

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.