Core histones H2B and H4 are mobilized during infection with herpes simplex virus 1

The infecting genomes of herpes simplex virus 1 (HSV-1) are assembled into unstable nucleosomes soon after nuclear entry. The source of the histones that bind to these genomes has yet to be addressed. However, infection inhibits histone synthesis. The histones that bind to HSV-1 genomes are therefore most likely those previously bound in cellular chromatin. In order for preexisting cellular histones to associate with HSV-1 genomes, however, they must first disassociate from cellular chromatin. Consistently, we have shown that linker histones are mobilized during HSV-1 infection. Chromatinization of HSV-1 genomes would also require the association of core histones. We therefore evaluated the mobility of the core histones H2B and H4 as measures of the mobilization of H2A-H2B dimers and the more stable H3-H4 core tetramer. H2B and H4 were mobilized during infection. Their mobilization increased the levels of H2B and H4 in the free pools and decreased the rate of H2B fast chromatin exchange. The histones in the free pools would then be available to bind to HSV-1 genomes. The mobilization of H2B occurred independently from HSV-1 protein expression or DNA replication although expression of HSV-1 immediate-early (IE) or early (E) proteins enhanced it. The mobilization of core histones H2B and H4 supports a model in which the histones that associate with HSV-1 genomes are those that were previously bound in cellular chromatin. Moreover, this mobilization is consistent with the assembly of H2A-H2B and H3-H4 dimers into unstable nucleosomes with HSV-1 genomes.     

Linker histones are mobilized during infection with herpes simplex virus type 1

Histones interact with herpes simplex virus type 1 (HSV-1) genomes and localize to replication compartments early during infections. However, HSV-1 genomes do not interact with histones in virions and are deposited in nuclear domains devoid of histones. Moreover, late viral replication compartments are also devoid of histones. The processes whereby histones come to interact with HSV-1 genomes, to be later displaced, remain unknown. However, they would involve the early movement of histones to the domains containing HSV-1 genomes and the later movement away from them. Histones unbind from chromatin, diffuse through the nucleoplasm, and rebind at different sites. Such mobility is upregulated by, for example, phosphorylation or acetylation. We evaluated whether HSV-1 infection modulates histone mobility, using fluorescence recovery after photobleaching. All somatic H1 variants were mobilized to different degrees. H1.2, the most mobilized, was mobilized at 4 h and further so at 7 h after infection, resulting in increases in its "free" pools. H1.2 was mobilized to a "basal" degree under conditions of little to no HSV-1 protein expression. This basal mobilization required nuclear native HSV-1 genomes but was independent of HSV-1 proteins and most likely due to cellular responses. Mobilization above this basal degree, and increases in H1.2 free pools, however, depended on immediate-early or early HSV-1 proteins, but not on HSV-1 genome replication or late proteins. Linker histone mobilization is a novel consequence of cell-virus interactions, which is consistent with the dynamic interactions between histones and HSV-1 genomes during lytic infection; it may also participate in the regulation of viral gene expression.     

Histone H3.1 and H3.3 complexes mediate nucleosome assembly pathways dependent or independent of DNA synthesis

Deposition of the major histone H3 (H3.1) is coupled to DNA synthesis during DNA replication and possibly DNA repair, whereas histone variant H3.3 serves as the replacement variant for the DNA-synthesis-independent deposition pathway. To address how histones H3.1 and H3.3 are deposited into chromatin through distinct pathways, we have purified deposition machineries for these histones. The H3.1 and H3.3 complexes contain distinct histone chaperones, CAF-1 and HIRA, that we show are necessary to mediate DNA-synthesis-dependent and -independent nucleosome assembly, respectively. Notably, these complexes possess one molecule each of H3.1/H3.3 and H4, suggesting that histones H3 and H4 exist as dimeric units that are important intermediates in nucleosome formation. This finding provides new insights into possible mechanisms for maintenance of epigenetic information after chromatin duplication.     

A novel histone exchange factor, protein phosphatase 2Cgamma, mediates the exchange and dephosphorylation of H2A-H2B

In eukaryotic nuclei, DNA is wrapped around a protein octamer composed of the core histones H2A, H2B, H3, and H4, forming nucleosomes as the fundamental units of chromatin. The modification and deposition of specific histone variants play key roles in chromatin function. In this study, we established an in vitro system based on permeabilized cells that allows the assembly and exchange of histones in situ. H2A and H2B, each tagged with green fluorescent protein (GFP), are incorporated into euchromatin by exchange independently of DNA replication, and H3.1-GFP is assembled into replicated chromatin, as found in living cells. By purifying the cellular factors that assist in the incorporation of H2A-H2B, we identified protein phosphatase (PP) 2C gamma subtype (PP2Cgamma/PPM1G) as a histone chaperone that binds to and dephosphorylates H2A-H2B. The disruption of PP2Cgamma in chicken DT40 cells increased the sensitivity to caffeine, a reagent that disturbs DNA replication and damage checkpoints, suggesting the involvement of PP2Cgamma-mediated histone dephosphorylation and exchange in damage response or checkpoint recovery in higher eukaryotes.     

Human histone acetyltransferase 1 protein preferentially acetylates H4 histone molecules in H3.1-H4 over H3.3-H4

In mammalian cells, canonical histone H3 (H3.1) and H3 variant (H3.3) differ by five amino acids and are assembled, along with histone H4, into nucleosomes via distinct nucleosome assembly pathways. H3.1-H4 molecules are assembled by histone chaperone CAF-1 in a replication-coupled process, whereas H3.3-H4 are assembled via HIRA in a replication-independent pathway. Newly synthesized histone H4 is acetylated at lysine 5 and 12 (H4K5,12) by histone acetyltransferase 1 (HAT1). However, it remains unclear whether HAT1 and H4K5,12ac differentially regulate these two nucleosome assembly processes. Here, we show that HAT1 binds and acetylates H4 in H3.1-H4 molecules preferentially over H4 in H3.3-H4. Depletion of Hat1, the catalytic subunit of HAT1 complex, results in reduced H3.1 occupancy at H3.1-enriched genes and reduced association of Importin 4 with H3.1, but not H3.3. Finally, depletion of Hat1 or CAF-1p150 leads to changes in expression of a H3.1-enriched gene. These results indicate that HAT1 differentially impacts nucleosome assembly of H3.1-H4 and H3.3-H4.     

Temporal dynamics of cytomegalovirus chromatin assembly in productively infected human cells

The genomes of herpesviruses, including human cytomegalovirus (CMV), are double-stranded DNA molecules maintained as episomes during infection. The viral DNA lacks histones when encapsidated in the virion. However, it has been found histone associated inside infected cells, implying unidentified chromatin assembly mechanisms. Our results indicate that components of the host cell nucleosome deposition machinery target intranuclear CMV DNA, resulting in stepwise viral-chromatin assembly. CMV genomes undergo limited histone association and nucleosome assembly as early as 30 min after infection via DNA replication-independent mechanisms. Low average viral-genome chromatinization is maintained throughout the early stages of infection. The late phase of infection is characterized by a striking increase in average histone occupancy coupled with the process of viral-DNA replication. While the initial chromatinization affected all analyzed parts of the CMV chromosome, a subset of viral genomic regions, including the major immediate-early promoter, proved to be largely resistant to replication-dependent histone deposition. Finally, our results predict the likely requirement for an unanticipated chromatin disassembly process that enables packaging of histone-free DNA into progeny capsids.     

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.     

技术与方法体外组装含有组蛋白变体H2A.Z及H3.3的核小体

核小体是构成真核生物染色质的基本结构单位,组蛋白变体H2A.Z及H3.3对染色质结构及基因转录过程发挥着重要的调控作用。体内研究核小体及染色质结构受到诸多因素限制,体外重构含有H2A.Z及H3.3的核小体结构是研究与组蛋白变体相关基因表达调控的重要方法之一。实验表达纯化了6种组蛋白,在复性的过程中装配了含有H2A.Z和H3.3的组蛋白八聚体。基于DNA序列10bp周期性及序列模体设计了3条易于形成核小体的DNA序列,通过PCR大量扩增的方法,回收了标记Cy3荧光分子的目的DNA序列。采用盐透析法体外组装了含有H2A.Z和H3.3的核小体结构,利用荧光标记、EB染色及考马斯亮蓝染色检测了含有组蛋白变体的核小体形成效率及形成过程的吉布斯自由能变化。结果发现,设计的3条DNA序列可以有效地组装形成含有组蛋白电梯的核小体结构,而且随着组蛋白八聚体与DNA比例的增加,核小体的形成效率显著提高;采用Cy3荧光标记可以灵敏且定量地计算组装过程的吉布斯自由能。该方法的建立对研究组蛋白变体相关的结构生物学及转录调控等具有一定的意义。     

Codanin-1, mutated in the anaemic disease CDAI, regulates Asf1 function in S-phase histone supply

Efficient supply of new histones during DNA replication is critical to restore chromatin organization and maintain genome function. The histone chaperone anti-silencing function 1 (Asf1) serves a key function in providing H3.1-H4 to CAF-1 for replication-coupled nucleosome assembly. We identify Codanin-1 as a novel interaction partner of Asf1 regulating S-phase histone supply. Mutations in Codanin-1 can cause congenital dyserythropoietic anaemia type I (CDAI), characterized by chromatin abnormalities in bone marrow erythroblasts. Codanin-1 is part of a cytosolic Asf1-H3.1-H4-Importin-4 complex and binds directly to Asf1 via a conserved B-domain, implying a mutually exclusive interaction with the chaperones CAF-1 and HIRA. Codanin-1 depletion accelerates the rate of DNA replication and increases the level of chromatin-bound Asf1, suggesting that Codanin-1 guards a limiting step in chromatin replication. Consistently, ectopic Codanin-1 expression arrests S-phase progression by sequestering Asf1 in the cytoplasm, blocking histone delivery. We propose that Codanin-1 acts as a negative regulator of Asf1 function in chromatin assembly. This function is compromised by two CDAI mutations that impair complex formation with Asf1, providing insight into the molecular basis for CDAI disease.     

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 fate of parental nucleosomes during SV40 DNA replication.

The fate of parental nucleosomes during the replication of chromatin templates was studied using a modification of the cell-free SV40 DNA replication system. Plasmid DNA molecules containing the SV40 origin were assembled into chromatin with purified core histones and fractionated assembly factors derived from HeLa cells. When these templates were replicated in vitro, the resulting progeny retained a nucleosomal organization. To determine whether the nucleosomes associated with the progeny molecules resulted from displacement of parental histones during replication followed by reassembly, the replication reactions were performed in the presence of control templates. It was observed that the progeny genomes resulting from the replication of chromatin templates retained a nucleosomal structure, whereas the progeny of the control DNA molecules were not assembled into chromatin. Additional experiments, involving direct addition of histones to the replication reaction mixtures, confirmed that the control templates were not sequestered in some form which made them unavailable for nucleosome assembly. Thus, our data demonstrate that parental nucleosomes remain associated with the replicating molecules and are transferred to the progeny molecules without displacement into solution. We propose a simple model in which nucleosomes ahead of the fork are transferred intact to the newly synthesized daughter duplexes.     

Influence of histone acetylation on the solubility, H1 content and DNase I sensitivity of newly assembled chromatin.

In a previous report [Annunziato, A.T. and Seale, R.L. (1983) J. Biol. Chem. 258:12675] a novel intermediate in chromatin assembly was described (detected by labeling new DNA in the presence of the deacetylase inhibitor sodium butyrate), which retained approximately 50% of the heightened sensitivity of newly replicated chromatin to DNaseI. It is now reported that nucleosomes replicated in butyrate are considerably more soluble in the presence of magnesium, relative to chromatin replicated under control conditions, and that this heightened magnesium-solubility is reflected in a concomitant increase in the preferential solubility of nucleosomes containing newly synthesized core histones. This differential solubility was accompanied by a 5- to 6-fold depletion of histone H1, and was completely abolished by the selective removal of H1 from isolated nuclei. The removal of H1 also markedly reduced the preferential DNaseI sensitivity of chromatin replicated in butyrate. Further, when mononucleosomes of control and (acetylated) nascent chromatin were compared, no differences in DNaseI sensitivity were detected. These results provide evidence that the interactions between newly assembled nucleosomes and histone H1 are altered when histone deacetylation is inhibited during chromatin replication, and suggest a mechanism for the control of H1 deposition during nucleosome assembly in vivo.     

Chromatin assembly during DNA replication in somatic cells.

Newly replicated DNA is assembled into chromatin through two principle pathways. Firstly, parental nucleosomes segregate to replicated DNA, and are transferred directly to one of the two daughter strands during replication fork passage. Secondly, chromatin assembly factors mediate de-novo assembly of nucleosomes on replicating DNA using newly synthesized and acetylated histone proteins. In somatic cells, chromatin assembly factor 1 (CAF-1) appears to be a key player in assembling new nucleosomes during DNA replication. It provides a molecular connection between newly synthesized histones and components of the DNA replication machinery during the S phase of the cell division cycle.