The impact of the HIRA histone chaperone upon global nucleosome architecture

HIRA is an evolutionarily conserved histone chaperone that mediates replication-independent nucleosome assembly and is important for a variety of processes such as cell cycle progression, development, and senescence. Here we have used a chromatin sequencing approach to determine the genome-wide contribution of HIRA to nucleosome organization in Schizosaccharomyces pombe. Cells lacking HIRA experience a global reduction in nucleosome occupancy at gene sequences, consistent with the proposed role for HIRA in chromatin reassembly behind elongating RNA polymerase II. In addition, we find that at its target promoters, HIRA commonly maintains the full occupancy of the ?1 nucleosome. HIRA does not affect global chromatin structure at replication origins or in rDNA repeats but is required for nucleosome occupancy in silent regions of the genome. Nucleosome organization associated with the heterochromatic (dg-dh) repeats located at the centromere is perturbed by loss of HIRA function and furthermore HIRA is required for normal nucleosome occupancy at Tf2 LTR retrotransposons. Overall, our data indicate that HIRA plays an important role in maintaining nucleosome architecture at both euchromatic and heterochromatic loci.     

Distinct roles for histone chaperones in the deposition of Htz1 in chromatin

Histone variant Htz1 substitution for H2A plays important roles in diverse DNA transactions. Histone chaperones Chz1 and Nap1 (nucleosome assembly protein 1) are important for the deposition Htz1 into nucleosomes. In literatures, it was suggested that Chz1 is a Htz1–H2B-specific chaperone, and it is relatively unstructured in solution but it becomes structured in complex with the Htz1–H2B histone dimer. Nap1 (nucleosome assembly protein 1) can bind (H3–H4)₂ tetramers, H2A–H2B dimers and Htz1–H2B dimers. Nap1 can bind H2A–H2B dimer in the cytoplasm and shuttles the dimer into the nucleus. Moreover, Nap1 functions in nucleosome assembly by competitively interacting with non-nucleosomal histone–DNA. However, the exact roles of these chaperones in assembling Htz1-containing nucleosome remain largely unknown. In this paper, we revealed that Chz1 does not show a physical interaction with chromatin. In contrast, Nap1 binds exactly at the genomic DNA that contains Htz1. Nap1 and Htz1 show a preferential interaction with AG-rich DNA sequences. Deletion of chz1 results in a significantly decreased binding of Htz1 in chromatin, whereas deletion of nap1 dramatically increases the association of Htz1 with chromatin. Furthermore, genome-wide nucleosome-mapping analysis revealed that nucleosome occupancy for Htz1p-bound genes decreases upon deleting htz1 or chz1, suggesting that Htz1 is required for nucleosome structure at the specific genome loci. All together, these results define the distinct roles for histone chaperones Chz1 and Nap1 to regulate Htz1 incorporation into chromatin.     

The role of DNA methylation,nucleosome occupancy and histone modifications in paramutation

Paramutation is the transfer of epigenetic information between alleles that leads to a heritable change in expression of one of these alleles. Paramutation at the tissue‐specifically expressed maize (Zea mays) b1 locus involves the low‐expressing B′ and high‐expressing B‐I allele. Combined in the same nucleus, B′ heritably changes B‐I into B′. A hepta‐repeat located 100‐kb upstream of the b1 coding region is required for paramutation and for high b1 expression. The role of epigenetic modifications in paramutation is currently not well understood. In this study, we show that the B′ hepta‐repeat is DNA‐hypermethylated in all tissues analyzed. Importantly, combining B′ and B‐I in one nucleus results in de novo methylation of the B‐I repeats early in plant development. These findings indicate a role for hepta‐repeat DNA methylation in the establishment and maintenance of the silenced B′ state. In contrast, nucleosome occupancy, H3 acetylation, and H3K9 and H3K27 methylation are mainly involved in tissue‐specific regulation of the hepta‐repeat. Nucleosome depletion and H3 acetylation are tissue‐specifically regulated at the B‐I hepta‐repeat and associated with enhancement of b1 expression. H3K9 and H3K27 methylation are tissue‐specifically localized at the B′ hepta‐repeat and reinforce the silenced B′ chromatin state. The B′ coding region is H3K27 dimethylated in all tissues analyzed, indicating a role in the maintenance of the silenced B′ state. Taken together, these findings provide insight into the mechanisms underlying paramutation and tissue‐specific regulation of b1 at the level of chromatin structure.     

DAXX adds a de novo H3.3K9me3 deposition pathway to the histone chaperone network

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Structural evidence for Nap1‐dependent H2A–H2B deposition and nucleosome assembly

Nap1 is a histone chaperone involved in the nuclear import of H2A–H2B and nucleosome assembly. Here, we report the crystal structure of Nap1 bound to H2A–H2B together with in vitro and in vivo functional studies that elucidate the principles underlying Nap1‐mediated H2A–H2B chaperoning and nucleosome assembly. A Nap1 dimer provides an acidic binding surface and asymmetrically engages a single H2A–H2B heterodimer. Oligomerization of the Nap1–H2A–H2B complex results in burial of surfaces required for deposition of H2A–H2B into nucleosomes. Chromatin immunoprecipitation‐exonuclease (ChIP‐exo) analysis shows that Nap1 is required for H2A–H2B deposition across the genome. Mutants that interfere with Nap1 oligomerization exhibit severe nucleosome assembly defects showing that oligomerization is essential for the chaperone function. These findings establish the molecular basis for Nap1‐mediated H2A–H2B deposition and nucleosome assembly.     

The H3 chaperone function of NASP is conserved in Arabidopsis

Histones are abundant cellular proteins but, if not incorporated into chromatin, they are usually bound by histone chaperones. Here, we identify Arabidopsis NASP as a chaperone for histones H3.1 and H3.3. NASP interacts in vitro with monomeric H3.1 and H3.3 as well as with histone H3.1–H4 and H3.3–H4 dimers. However, NASP does not bind to monomeric H4. NASP shifts the equilibrium between histone dimers and tetramers towards tetramers but does not interact with tetramers in vitro. Arabidopsis NASP promotes [H3–H4]₂ tetrasome formation, possibly by providing preassembled histone tetramers. However, NASP does not promote disassembly of in vitro preassembled tetrasomes. In contrast to its mammalian homolog, Arabidopsis NASP is a predominantly nuclear protein. In vivo, NASP binds mainly monomeric H3.1 and H3.3. Pulldown experiments indicated that NASP may also interact with the histone chaperone MSI1 and a HSC70 heat shock protein.     

The impact of the HIRA histone chaperone upon global nucleosome architecture

HIRA is an evolutionarily conserved histone chaperone that mediates replication-independent nucleosome assembly and is important for a variety of processes such as cell cycle progression, development, and senescence. Here we have used a chromatin sequencing approach to determine the genome-wide contribution of HIRA to nucleosome organization in Schizosaccharomyces pombe. Cells lacking HIRA experience a global reduction in nucleosome occupancy at gene sequences, consistent with the proposed role for HIRA in chromatin reassembly behind elongating RNA polymerase II. In addition, we find that at its target promoters, HIRA commonly maintains the full occupancy of the −1 nucleosome. HIRA does not affect global chromatin structure at replication origins or in rDNA repeats but is required for nucleosome occupancy in silent regions of the genome. Nucleosome organization associated with the heterochromatic (dg-dh) repeats located at the centromere is perturbed by loss of HIRA function and furthermore HIRA is required for normal nucleosome occupancy at Tf2 LTR retrotransposons. Overall, our data indicate that HIRA plays an important role in maintaining nucleosome architecture at both euchromatic and heterochromatic loci.     

Distinct roles of the histone chaperones NAP1 and NRP and the chromatin‐remodeling factor INO80 in somatic homologous recombination in Arabidopsis thaliana

Homologous recombination (HR) of nuclear DNA occurs within the context of a highly complex chromatin structure. Despite extensive studies of HR in diverse organisms, mechanisms regulating HR within the chromatin context remain poorly elucidated. Here we investigate the role and interplay of the histone chaperones NUCLEOSOME ASSEMBLY PROTEIN1 (NAP1) and NAP1‐RELATED PROTEIN (NRP) and the ATP‐dependent chromatin‐remodeling factor INOSITOL AUXOTROPHY80 (INO80) in regulating somatic HR in Arabidopsis thaliana. We show that simultaneous knockout of the four AtNAP1 genes and the two NRP genes in the sextuple mutant m123456‐1 barely affects normal plant growth and development. Interestingly, compared with the respective AtNAP1 (m123‐1 and m1234‐1) or NRP (m56‐1) loss‐of‐function mutants, the sextuple mutant m123456‐1 displays an enhanced plant hypersensitivity to UV or bleomycin treatments. Using HR reporter constructs, we show that AtNAP1 and NRP act in parallel to synergistically promote somatic HR. Distinctively, the AtINO80 loss‐of‐function mutation (atino80‐5) is epistatic to m56‐1 in plant phenotype and telomere length but hypostatic to m56‐1 in HR determinacy. Further analyses show that expression of HR machinery genes and phosphorylation of H2A.X (γ‐H2A.X) are not impaired in the mutants. Collectively, our study indicates that NRP and AtNAP1 synergistically promote HR upstream of AtINO80‐mediated chromatin remodeling after the formation of γ‐H2A.X foci during DNA damage repair.     

The H3 histone chaperone NASPSIM3 escorts CenH3 in Arabidopsis

Centromeres define the chromosomal position where kinetochores form to link the chromosome to microtubules during mitosis and meiosis. Centromere identity is determined by incorporation of a specific histone H3 variant termed CenH3. As for other histones, escort and deposition of CenH3 must be ensured by histone chaperones, which handle the non‐nucleosomal CenH3 pool and replenish CenH3 chromatin in dividing cells. Here, we show that the Arabidopsis orthologue of the mammalian NUCLEAR AUTOANTIGENIC SPERM PROTEIN (NASP) and Schizosaccharomyces pombe histone chaperone Sim3 is a soluble nuclear protein that binds the histone variant CenH3 and affects its abundance at the centromeres. NASP^SIM3 is co‐expressed with Arabidopsis CenH3 in dividing cells and binds directly to both the N‐terminal tail and the histone fold domain of non‐nucleosomal CenH3. Reduced NASP^SIM3 expression negatively affects CenH3 deposition, identifying NASP^SIM3 as a CenH3 histone chaperone.     

Human testis–specific Y-encoded protein-like protein 5 is a histone H3/H4-specific chaperone that facilitates histone deposition in vitro

DNA and core histones are hierarchically packaged into a complex organization called chromatin. The nucleosome assembly protein (NAP) family of histone chaperones is involved in the deposition of histone complexes H2A/H2B and H3/H4 onto DNA and prevents nonspecific aggregation of histones. Testis-specific Y-encoded protein (TSPY)–like protein 5 (TSPYL5) is a member of the TSPY-like protein family, which has been previously reported to interact with ubiquitin-specific protease USP7 and regulate cell proliferation and is thus implicated in various cancers, but its interaction with chromatin has not been investigated. In this study, we characterized the chromatin association of TSPYL5 and found that it preferentially binds histone H3/H4 via its C-terminal NAP-like domain both in vitro and ex vivo. We identified the critical residues involved in the TSPYL5–H3/H4 interaction and further quantified the binding affinity of TSPYL5 toward H3/H4 using biolayer interferometry. We then determined the binding stoichiometry of the TSPYL5–H3/H4 complex in vitro using a chemical cross-linking assay and size-exclusion chromatography coupled with multiangle laser light scattering. Our results indicate that a TSPYL5 dimer binds to either two histone H3/H4 dimers or a single tetramer. We further demonstrated that TSPYL5 has a specific affinity toward longer DNA fragments and that the same histone-binding residues are also critically involved in its DNA binding. Finally, employing histone deposition and supercoiling assays, we confirmed that TSPYL5 is a histone chaperone responsible for histone H3/H4 deposition and nucleosome assembly. We conclude that TSPYL5 is likely a new member of the NAP histone chaperone family.     

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.     

dBigH1, a second histone H1 in Drosophila,and the consequences for histone fold nomenclature

Recently, Pérez-Montero and colleagues (Developmental cell, 26: 578–590, 2013) described the occurrence of a new histone H1 variant (dBigH1) in Drosophila. The presence of unusual acidic amino acid patches at the N-terminal end of dBigH1 is in contrast to the arginine patches that exist at the N- and C-terminal domains of other histone H1-related proteins found in the sperm of some organisms. This departure from the strictly lysine-rich composition of the somatic histone H1 raises a question about the true definition of its protein members. Their minimal essential requirements appear to be the presence of a lysine- and alanine–rich, intrinsically disordered C-terminal domain, with a highly helicogenic potential upon binding to the linker DNA regions of chromatin. In metazoans, specific targeting of these regions is further achieved by a linker histone fold domain (LHFD), distinctively different from the characteristic core histone fold domain (CHFD) of the nucleosome core histones.     

dBigH1, a second histone H1 in Drosophila,and the consequences for histone fold nomenclature

Recently, Pérez-Montero and colleagues (Developmental cell, 26: 578–590, 2013) described the occurrence of a new histone H1 variant (dBigH1) in Drosophila. The presence of unusual acidic amino acid patches at the N-terminal end of dBigH1 is in contrast to the arginine patches that exist at the N- and C-terminal domains of other histone H1-related proteins found in the sperm of some organisms. This departure from the strictly lysine-rich composition of the somatic histone H1 raises a question about the true definition of its protein members. Their minimal essential requirements appear to be the presence of a lysine- and alanine–rich, intrinsically disordered C-terminal domain, with a highly helicogenic potential upon binding to the linker DNA regions of chromatin. In metazoans, specific targeting of these regions is further achieved by a linker histone fold domain (LHFD), distinctively different from the characteristic core histone fold domain (CHFD) of the nucleosome core histones.     

FACT is recruited to the +1 nucleosome of transcribed genes and spreads in a Chd1-dependent manner

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