Stepwise assembly of chromatin during DNA replication in vitro.

A cell free system that supports replication-dependent chromatin assembly has been used to determine the mechanism of histone deposition during DNA replication. CAF-I, a human cell nuclear factor, promotes chromatin assembly on replicating SV40 DNA in the presence of a crude cytosol replication extract. Biochemical fractionation of the cytosol extract has allowed separation of the chromatin assembly reaction into two steps. During the first step, CAF-I targets the deposition of newly synthesized histones H3 and H4 to the replicating DNA. This reaction is dependent upon and coupled with DNA replication, and utilizes the newly synthesized forms of histones H3 and H4, which unlike bulk histone found in chromatin, do not bind to DNA by themselves. The H3/H4-replicated DNA complex is a stable intermediate which exhibits a micrococcal nuclease resistant structure and can be isolated by sucrose gradient sedimentation. In the second step, this replicated precursor is converted to mature chromatin by the addition of histones H2A and H2B in a reaction that can occur after DNA replication. The requirement for CAF-I in at least the first step of the reaction suggests a level of cellular control for this fundamental process.     

Conformational DNA transition in the in vitro torsionally strained chicken beta-globin 5'' region.

A sequence of 86 bp within the 5' region of the adult chicken beta-globin gene was found to undergo a DNA conformational transition at elevated levels of negative superhelical stress (- sigma = 0.068). In vitro chemical DNA modification studies which detect purine hyperreactivity (HR) to the alkylating agent diethyl pyrocarbonate (DEP) have identified this 86 bp long DEP-HR element. The DEP-HR element is composed of small, tandem segments with imperfect purine-pyrimidine alternations. Methylation of cytosines within GCGC sequences of the DEP-HR element facilitates this structural change. The binding of a monoclonal anti-Z-DNA antibody to the element has been revealed by chemical footprinting with DEP. These data suggest that the DEP-HR sequence can undergo a conformational transition to Z-DNA. It is unknown whether the conformational flexibility observed here occurs in vivo.     

Studies on DNA Topoisomerase activity during in vitro chromatin assembly

The in vitro assembly of chromatin, promoted by the Xenopus cell-free extract (S-150), can be inhibited by oxolinic acid and to a lesser extent by nalidixic acid. Both of these antibiotics have been shown to block the activity of the specialized type 11 Topoisomerase, bacterial DNA Gyrase. Oxolinic acid induces a DNA cleavage by Micrococcal Nuclease at specific sequences in the multiple cloning vector pGEM-4. Nalidixic acid does not inhibit DNA supercoiling, but does diminish the extent of chromatin formation achieved by the S-150 on circular DNA templates. The Topoisomerase I inhibitor, berenil, does not inhibit extensive chromatin assembly, although it aloes diminish the level of supercoiling. Taken together, these results suggest that both topoisomerases play a role in the assembly process. Topoisomerase I may catalyze both the introduction of unconstrained supercoils into relaxed DNA and the formation of monosomes, while Topoisomerase 11 may promote extended chromatin assembly.     

Cell cycle control of higher-order chromatin assembly around naked DNA in vitro.

We have developed an in vitro system in which higher-order chromatin structures are assembled around naked DNAs in a cell cycle-dependent manner. Membrane-free soluble extracts specific to interphase and mitotic states were prepared from Xenopus eggs. When high molecular weight DNA is incubated with interphase extracts, fluffy chromatin-like structures are assembled. In contrast, mitotic extracts produce highly condensed chromosome-like structures. Immunofluorescence studies show that a monoclonal antibody MPM-2, which recognizes a class of mitosis-specific phosphoproteins, stains the "core" or "axis" of condensed mitotic chromatin but not interphase chromatin. By adding mitotic extracts, interphase chromatin structures are synchronously converted into the condensed state. The increasingly condensed state of chromatin correlates with the appearance and structural rearrangements of the MPM-2-stained structures. These results suggest that mitosis-specific phosphoproteins recognized by MPM-2 may be directly involved in the assembly of the chromosome scaffold-like structures and chromatin condensation. Although both extracts promote nucleosome assembly at the same rate, topoisomerase II (topo II) activity is four to five times higher in mitotic extracts compared with interphase extracts. The addition of a topo II inhibitor VM-26 into mitotic assembly mixtures disturbs the organization of the MPM-2-stained structures and affects the final stage of chromatin condensation. This in vitro system should be useful for identifying cis- and trans-acting elements responsible for higher-order chromatin assembly and its structural changes in the cell cycle.     

Novobiocin inhibits passive chromatin assembly in vitro.

Novobiocin, an inhibitor of prokaryotic DNA gyrase and eukaryotic type II topoisomerase enzymes, interferes with in vitro chromatin assembly using purified histones, DNA and nucleoplasmin. The target of inhibition is not topoisomerase II; this energy-independent assembly system lacks any ATP and Mg2+-dependent type II topoisomerase or gyrase activities. Rather, novobiocin interacts with histones, disrupting histone-histone associations required for octamer formation, and causing histones to precipitate from both nucleoplasmin-histone and histone-DNA complexes. Thus, novobiocin is able to generate 'dynamic' chromatin in vitro in the absence of ATP and Mg2+ by removing histones from previously assembled static chromatin, so that the DNA supercoils, previously constrained by conventional nucleosomes, become susceptible to removal by topoisomerase I.     

Hyperacetylated histones facilitate chromatin assembly in vitro.

We have examined the effect of histone acetylation on the in vitro assembly of nucleosomes with DNA and purified histones at physiological ionic strength in the presence of polyglutamic acid. We have found that hyperacetylated histones assemble nucleosomes with greater efficiency, and to a greater extent, than either control or hypoacetylated histones. Assembly reactions were performed over a range of histone to DNA ratios (0.25 to 3.0, w/w) and polyglutamic acid to histone ratios (0 to 1.6, w/w). Although polyglutamic acid may act as a sink to prevent nonspecific histone-DNA interactions, our data suggest that the polyanion primarily facilitates the assembly of nucleosomes by organizing histones into a form that is amenable to deposition.     

Perturbation of chromatin structure in the region of the adult beta-globin gene in chicken erythrocyte chromatin

An EcoRI chromatin fragment containing the adult beta-globin gene and flanking sequences, isolated from chicken erythrocyte nuclei, sediments at a reduced rate relative to bulk chromatin fragments of the same size. We show that the specific retardation cannot be reversed by adding extra linker histones to native chromatin. When the chromatin fragments are unfolded either by removing linker histones or lowering the ionic strength, the difference between globin and bulk chromatin fragments is no longer seen. The refolded chromatin obtained by restoring the linker histones to the depleted chromatin, however, exhibits the original sedimentation difference. This difference is therefore due to a special property of the histone octamers on the active gene that determines the extent of its folding into higher-order structure. That it is not due to the differential binding of linker histones in vitro is shown by measurements of the protein to DNA ratios using CsCl density-gradients. Both before and after selective removal of the linker histones, the globin gene fragment and bulk chromatin fragments exhibit only a marginal difference in buoyant density. In addition, we show that cleavage of the EcoRI fragment by digestion at the 5' and 3' nuclease hypersensitive sites flanking the globin gene liberates a fragment from between these sites that sediments normally. We conclude that the hypersensitive sites per se are responsible for the reduction in sedimentation rate. The non-nucleosomal DNA segments appear to be too long to be incorporated into the chromatin solenoid and thus create spacers between separate solenoidal elements in the chromatin, which can account for its hydrodynamic behaviour.     

Immunological characterization of chromatin assembly factor I, a human cell factor required for chromatin assembly during DNA replication in vitro

Chromatin assembly factor I (CAF-I) is a multisubunit protein complex purified from the nuclei of human cells and required for chromatin assembly during DNA replication in vitro. Purified CAF-I promotes chromatin assembly in a reaction that is dependent upon, and coupled with, DNA replication and is therefore likely to reflect events that occur during S phase in vivo. In order to investigate the regulation and mechanism of CAF-I and the replication-dependent chromatin assembly process, we have used the purified protein to raise monoclonal antibodies. In this report we describe the characterization of a panel of monoclonal antibodies which recognize different subunits of the CAF-I complex. We use immunoprecipitation analysis to show that CAF-I exists as a multiprotein complex in vivo and that some of the polypeptides are phosphorylated. In addition, immunocytochemistry demonstrates that CAF-I is localized to the nucleus of human cells. Finally, monoclonal antibodies directed against the individual subunits of CAF-I immunodeplete chromatin assembly activity from nuclear extracts, confirming that CAF-I is a multisubunit protein required for chromatin assembly in vitro.     

WD repeats of the p48 subunit of chicken chromatin assembly factor-1 required for in vitro interaction with chicken histone deacetylase-2.

Chromatin assembly factor-1 (CAF-1) is essential for chromatin assembly in eukaryotes, and comprises three subunits of 150 kDa (p150), 60 kDa (p60), and 48 kDa (p48). We cloned and sequenced cDNA encoding the small subunit of the chicken CAF-1, chCAF-1p48. It consists of 425 amino acid residues including a putative initiation Met, possesses seven WD repeat motifs, and contains only one amino acid change relative to the human and mouse CAF-1p48s. The immunoprecipitation experiment followed by Western blotting revealed that chCAF-1p48 interacts with chicken histone deacetylases (chHDAC-1 and -2) in vivo. The glutathione S-transferase pulldown affinity assay revealed the in vitro interaction of chCAF-1p48 with chHDAC-1, -2, and -3. We showed that the p48 subunit tightly binds to two regions of chHDAC-2, located between amino acid residues 82-180 and 245-314, respectively. We also established that two N-terminal, two C-terminal, or one N-terminal and one C-terminal WD repeat motif of chCAF-1p48 are required for this interaction, using deletion mutants of the respective regions. These results suggest that chCAF-1p48 is involved in many aspects of DNA-utilizing processes, through alterations in the chromatin structure based on both the acetylation and deacetylation of core histones.     

Chromatin assembly on replicating DNA in vitro.

Replicating single-stranded DNA is preferentially assembled into chromatin in Xenopus egg extracts relative to non-replicating double-stranded DNA. We have examined the molecular basis of this phenomenon. Single-stranded DNA itself is not a favored template for nucleosome assembly in comparison to double-stranded DNA. Complementary strand synthesis is required for the rapid assembly of nucleosomes. We present evidence that the assembly of chromatin on replicating DNA is a two step phenomenon. The first step involves the replication of DNA and the assembly of an intermediate structure, the second step involves the sequestration of histones H2A/H2B onto DNA. Histones H2A/H2B are preferentially sequestered onto replicated DNA in comparison to non-replicated DNA incubated in the extract.     

Distribution of nucleosomes on reconstituted chromatin from cloned mouse beta-globin DNA

Relative abundance of nucleosomes on reconstituted chromatin was estimated with cloned mouse beta-globin gene DNA. Mononucleosomal DNA was isolated from reconstituted chromatin after digestion with micrococcal nuclease, nick-translated and used as a probe for blot hybridization. DNA fragments of restriction nuclease-digested globin DNA were transferred to DBM-paper and hybridized with mononucleosomal [32P] DNA probe. The results showed non-random distribution of nucleosomes.     

Multistep chromatin assembly on supercoiled plasmid DNA by nucleosome assembly protein-1 and ATP-utilizing chromatin assembly and remodeling factor

We examine in vitro nucleosome assembly by nucleosome assembly protein-1 (NAP-1) and ATP-utilizing chromatin assembly and remodeling factor (ACF). In contrast to previous studies that used relaxed, circular plasmids as templates, we have found that negatively supercoiled templates reveal the distinct roles of NAP-1 and ACF in histone deposition and the formation of an ordered nucleosomal array. NAP-1 can efficiently deposit histones onto supercoiled plasmids. Furthermore, NAP-1 exhibits a greater affinity for histones H2A-H2B than does naked DNA, but in the presence of H3-H4, H2A-H2B are transferred from NAP-1 to the plasmid templates. These observations underscore the importance of a high affinity between H2A-H2B and NAP-1 for ordered transfer of core histones onto DNA. In addition, recombinant ACF composed of imitation switch and Acf1 can extend closely packed nucleosomes, which suggests that recombinant ACF can mobilize nucleosomes. In the assembly reaction with a supercoiled template, ACF need not be added simultaneously with NAP-1. Regularly spaced nucleosomes are generated even when recombinant ACF is added after core histones are transferred completely onto the DNA. Atomic force microscopy, however, suggests that NAP-1 alone fails to accomplish the formation of fine nucleosomal core particles, which are only formed in the presence of ACF. These results suggest a model for the ordered deposition of histones and the arrangement of nucleosomes during chromatin assembly in vivo.     

Requirement of DNA topoisomerases for in vitro chromatin assembly by 3T6 mouse cell extracts

Nuclear extracts of 3T6 mouse cells were able to assemble in vitro minichromosomes which displayed a 150-bp periodicity. Activities of both DNA topoisomerases I and II were detected in these extracts. When a supercoiled pUC DNA was added, it was first relaxed in less than 3 min, then slowly supercoiled again in 1-4 h. Both reactions occurred either in the absence or the presence of added Mg2+ and/or ATP, they were not blocked by DNA topoisomerase II inhibitors and they were inhibited by an antiserum against DNA topoisomerase I and by camptothecin. These findings led us to propose that, under our in vitro assay conditions, chromatin assembly is mainly carried out by a DNA topoisomerase I.     

Postreplicative chromatin assembly by Drosophila and human chromatin assembly factor 1.

To study the relationship between DNA replication and chromatin assembly, we have purified a factor termed Drosophila chromatin assembly factor 1 (dCAF-1) to approximately 50% homogeneity from a nuclear extract derived from embryos. dCAF-1 appears to consist of four polypeptides with molecular masses of 180, 105, 75, and 55 kDa. dCAF-1 preferentially mediates chromatin assembly of newly replicated DNA relative to unreplicated DNA during T-antigen-dependent simian virus 40 DNA replication in vitro, as seen with human CAF-1. Analysis of the mechanism of DNA replication-coupled chromatin assembly revealed that both dCAF-1 and human CAF-1 mediate chromatin assembly preferentially with previously yet newly replicated DNA relative to unreplicated DNA. Moreover, the preferential assembly of the postreplicative DNA was observed at 30 min after inhibition of DNA replication by aphidicolin, but this effect slowly diminished until it was no longer apparent at 120 min after inhibition of replication. These findings suggest that the coupling between DNA replication and chromatin assembly may not necessarily involve a direct interaction between the replication and assembly factors at a replication fork.