Asf1 is required for viability and chromatin assembly during DNA replication in vertebrate cells

Asf1 (anti-silencing function 1), a well conserved protein from yeast to humans, acts as a histone chaperone and is predicted to participate in a variety of chromatin-mediated cellular processes. To investigate the physiological role of vertebrate Asf1 in vivo, we generated a conditional Asf1-deficient mutant from chicken DT40 cells. Induction of Asf1 depletion resulted in the accumulation of cells in S phase with decreased DNA replication and increased mitotic aberrancy forming multipolar spindles, leading to cell death. In addition, nascent chromatin in Asf1-depleted cells showed increased nuclease sensitivity, indicating impaired nucleosome assembly during DNA replication. Complementation analyses revealed that the functional domain of Asf1 for cell viability was confined to the N-terminal core domain (amino acids 1-155) that is a binding platform for histones H3/H4, CAF-1p60, and HIRA, whereas Asf1 mutant proteins, abolishing binding abilities with both p60 and HIRA, exhibit no effect on viability. These results together indicate that the vertebrate Asf1 plays a crucial role in replication-coupled chromatin assembly, cell cycle progression, and cellular viability and provide a clue of a possible role in a CAF-1- and HIRA-independent chromatin-modulating process for cell proliferation.     

Histone acetylation reduces H1-mediated nucleosome interactions during chromatin assembly

During chromatin replication and nucleosome assembly, newly synthesized histone H4 is acetylated before it is deposited onto DNA, then deacetylated as assembly proceeds. In a previous study (Perry and Annunziato, Nucleic Acids Res. 17, 4275 [1989]) it was shown that when replication occurs in the presence of sodium butyrate (thereby inhibiting histone deacetylation), nascent chromatin fails to mature fully and instead remains preferentially sensitive to DNaseI, more soluble in magnesium, and depleted of histone H1 (relative to mature chromatin). In the following report the relationships between chromatin replication, histone acetylation, and H1-mediated nucleosome aggregation were further investigated. Chromatin was replicated in the presence or absence of sodium butyrate; isolated nucleosomes were stripped of linker histone, reconstituted with H1, and treated to produce Mg(2+)-soluble and Mg(2+)-insoluble chromatin fractions. Following the removal of H1, all solubility differences between chromatin replicated in sodium butyrate for 30 min (bu-chromatin) and control chromatin were lost. Reconstitution with H1 completely restored the preferential Mg(2+)-solubility of bu-chromatin, demonstrating that a reduced capacity for aggregation/condensation is an inherent feature of acetylated nascent nucleosomes; however, titration with excess H1 caused the solubility differences to be lost again. Moreover, when the core histone N-terminal "tails" (the sites of acetylation) were removed by trypsinization prior to reconstitution, H1 was unable to reestablish the altered solubility of chromatin replicated in butyrate. Thus, the core histone "tails," and the acetylation thereof, not only modulate H1-mediated nucleosome interactions in vitro, but also strongly influence the ability of H1 to differentiate between new and old nucleosomes. The data suggest a possible mechanism for the control of H1 deposition and/or chromatin folding during nucleosome assembly.     

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.     

Histone acetyltransferase 1 is dispensable for replication-coupled chromatin assembly but contributes to recover DNA damages created following replication blockage in vertebrate cells

Histone acetyltransferase 1 (HAT1) is implicated for diacetylation of Lys-5 and Lys-12 of newly synthesized histone H4, the biological significance of which remains unclear. To investigate the in vivo role of HAT1, we generated HAT1-deficient DT40 clone (HAT1(-/-)). HAT1(-/-) cells exhibited greatly reduced diacetylation levels of Lys-5 and Lys-12, and acetylation level of Lys-5 of cytosolic and chromatin histones H4, respectively. The in vitro nucleosome assembly assay and in vivo MNase digestion assay revealed that HAT1 and diacetylation of Lys-5 and Lys-12 of histone H4 are dispensable for replication-coupled chromatin assembly. HAT1(-/-) cells had mild growth defect, conferring sensitivities to methyl methanesulfonate and camptothecin that enforce replication blocks creating DNA double strand breaks. Such heightened sensitivities were associated with prolonged late-S/G2 phase. These results indicate that HAT1 participates in recovering replication block-mediated DNA damages, probably through chromatin modulation based on acetylation of Lys-5 and Lys-12 of histone H4.     

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.     

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.     

A role for chromatin remodellers in replication of damaged DNA

In eukaryotic cells, replication past damaged sites in DNA is regulated by the ubiquitination of proliferating cell nuclear antigen (PCNA). Little is known about how this process is affected by chromatin structure. There are two isoforms of the Remodels the Structure of Chromatin (RSC) remodelling complex in yeast. We show that deletion of RSC2 results in a dramatic reduction in the level of PCNA ubiquitination after DNA-damaging treatments, whereas no such effect was observed after deletion of RSC1. Similarly, depletion of the BAF180 component of the corresponding PBAF (Polybromo BRG1 (Brahma-Related Gene 1) Associated Factor) complex in human cells led to a similar reduction in PCNA ubiquitination. Remarkably, we found that depletion of BAF180 resulted after UV-irradiation, in a reduction not only of ubiquitinated PCNA but also of chromatin-associated unmodified PCNA and Rad18 (the E3 ligase that ubiquitinates PCNA). This was accompanied by a modest decrease in fork progression. We propose a model to account for these findings that postulates an involvement of PBAF in repriming of replication downstream from replication forks blocked at sites of DNA damage. In support of this model, chromatin immunoprecipitation data show that the RSC complex in yeast is present in the vicinity of the replication forks, and by extrapolation, this is also likely to be the case for the PBAF complex in human cells.     

RAD51AP1-deficiency in vertebrate cells impairs DNA replication

RAD51-associated protein 1 (RAD51AP1) is critical for homologous recombination (HR) by interacting with and stimulating the activities of the RAD51 and DMC1 recombinases. In human somatic cells, knockdown of RAD51AP1 results in increased sensitivity to DNA damaging agents and to impaired HR, but the formation of DNA damage-induced RAD51 foci is unaffected. Here, we generated a genetic model system, based on chicken DT40 cells, to assess the phenotype of fully inactivated RAD51AP1 in vertebrate cells. Targeted inactivation of both RAD51AP1 alleles has no effect on either viability or doubling-time in undamaged cells, but leads to increased levels of cytotoxicity after exposure to cisplatin or to ionizing radiation. Interestingly, ectopic expression of GgRAD51AP1, but not of HsRAD51AP1 is able to fully complement in cell survival assays. Notably, in RAD51AP1-deficient DT40 cells the resolution of DNA damage-induced RAD51 foci is greatly slowed down, while their formation is not impaired. We also identify, for the first time, an important role for RAD51AP1 in counteracting both spontaneous and DNA damage-induced replication stress. In human and in chicken cells, RAD51AP1 is required to maintain wild type speed of replication fork progression, and both RAD51AP1-depleted human cells and RAD51AP1-deficient DT40 cells respond to replication stress by a slow-down of replication fork elongation rates. However, increased firing of replication origins occurs in RAD51AP1-/- DT40 cells, likely to ensure the timely duplication of the entire genome. Taken together, our results may explain why RAD51AP1 commonly is overexpressed in tumor cells and tissues, and we speculate that the disruption of RAD51AP1 function could be a promising approach in targeted tumor therapy.     

Requirements for DNA replication preceding cell division in Tetrahymena pyriformis

Populations of Tetrahymena pyriformis were synchronized by 30 min heat shocks at 34 °C separated by 160 min intervals at the normal growth temperature. The cells initiate DNA synthesis immediately after the cellular division, and the S period of the population lasts about 80 min. It was found that DNA replication is a prerequisite for the following synchronous division. Inhibition of the DNA synthesis in early S by starvation of the cells for thymidine prevents the forthcoming division. However, inhibition in the latter half of S does not prevent the subsequent division. Thus the cells have synthesized enough DNA to permit cell division before the end of a normal S period. These results are discussed in relation to the organization of the genome replication in the highly polyploid macronucleus.     

Purification and characterization of CAF-I, a human cell factor required for chromatin assembly during DNA replication in vitro

The purification and characterization of a replication-dependent chromatin assembly factor (CAF-I) from the nuclei of human cells is described. CAF-I is a multisubunit protein that, when added to a crude cytosol replication extract, promotes chromatin assembly on replicating SV40 DNA. Chromatin assembly by CAF-I requires and is coupled with DNA replication. The minichromosomes assembled de novo by CAF-I consist of correctly spaced nucleosomes containing the four core histones H2A, H2B, H3, and H4, which are supplied in a soluble form by the cytosol replication extract. Thus, by several criteria, the CAF-I-dependent chromatin assembly reaction described herein reflects the process of chromatin formation during DNA replication in vivo.     

DNA sequence plays a major role in determining nucleosome positions in yeast CUP1 chromatin.

The role of DNA sequence in determining nucleosome positions in vivo was investigated by comparing the positions adopted by nucleosomes reconstituted on a yeast plasmid in vitro using purified core histones with those in native chromatin containing the same DNA, described previously. Nucleosomes were reconstituted on a 2.5 kilobase pair DNA sequence containing the yeast TRP1ARS1 plasmid with CUP1 as an insert (TAC-DNA). Multiple, alternative, overlapping nucleosome positions were mapped on TAC-DNA. For the 58 positioned nucleosomes identified, the relative positioning strengths and the stabilities to salt and temperature were determined. These positions were, with a few exceptions, identical to those observed in native, remodeled TAC chromatin containing an activated CUP1 gene. Only some of these positions are utilized in native, unremodeled chromatin. These observations suggest that DNA sequence is likely to play a very important role in positioning nucleosomes in vivo. We suggest that events occurring in yeast CUP1 chromatin determine which positions are occupied in vivo and when they are occupied.     

Essential role of MCM proteins in premeiotic DNA replication

A critical event in eukaryotic DNA replication involves association of minichromosome maintenance (MCM2-7) proteins with origins, to form prereplicative complexes (pre-RCs) that are competent for initiation. The ability of mutants defective in MCM2-7 function to complete meiosis had suggested that pre-RC components could be irrelevant to premeiotic S phase. We show here that MCM2-7 proteins bind to chromatin in fission yeast cells preparing for meiosis and during premeiotic S phase in a manner suggesting they in fact are required for DNA replication in the meiotic cycle. This is confirmed by analysis of a degron mcm4 mutant, which cannot carry out premeiotic DNA replication. Later in meiosis, Mcm4 chromatin association is blocked between meiotic nuclear divisions, presumably accounting for the absence of a second round of DNA replication. Together, these results emphasize similarity between replication mechanisms in mitotic and meiotic cell cycles.     

Unequal cell division and chromatin diffrentiation in pollen grain cells

The dynamics of the microtubule (MT) were studied by α-tubulin immunofluorescence methods during the polleng rain ontogeny inTradescantia paludosa. Before the microspore division, interphase nuclei of themicrospore cells were twice displaced from the center to one side (NM-1) and from the side to the center near the inner wall (NM-2). During NM-1, a few MTs appeared around the nucleus, but the movement was not interrupted by colchicine treatment. In NM-2, however, which was essential to the unequal division of microspores, many MTs and MT bundles became organized and shifted in a manner corresponding to the nuclear movement. This movement was inhibited by the colchicine treatment. It was concluded that NM-2 was dependent on the MT cytoskeleton, but NM-1 was independent. Througthout the microspore division, mitotic spindles were organized asymmetrically. From prophase to prometaphase, the spindle began to construct itself in the vegetative pole preceding the generative pole. The half-spindles were asymmetric at the metaphase and the phragmoplast developed curving toward the generative pole at the telophase. No pre-prophase band of MTs was observed throughout the cell cycle. The relationship between the characteristic MT dynamics and the nuclear movement, or unequal cell division, was revealed and is discussed here.     

Unequal cell division and chromatin differentiation in pollen grain cells

Pinus pollen grains, normally developing, were subjected to centrifugal force, low temperature and caffeine solution. In the former two treatments, daughter cells with some abnormal directions of division, abnormal volume and chromatin dispersion were induced in pollen grains treated. Regardless of the direction of division, of the two daughter cells produced by the unequal division, the larger one contained strongly dispersed chromatin and the smaller one weakly dispersed chromatin. In the two daughter cells produced by approximately equal division, the chromatin was dispersed strongly to a similar degree, and by halfway unequal division, chromatin in the larger cell was dispersed strongly and in the smaller one intermediately. Chromatin in bi-nucleate cells induced by caffeine treatment was dispersed strongly to an identical degree. It is suggested that for the occurrence of heteronomous chromatin configuration in natural pollen grains the unequal cell division was indispensable, although the axis of division didn't directly contribute. After both the treatments of centrifugation and low temperature during microspore and embryonal cell divisions, the affected daughter cells divided in terms of the certain fixed axis of division and chromatin dispersion, instead of exhibiting abnormal development.