The core histones are essential components of the nucleosome that act as global negative regulators of DNA-mediated reactions including transcription, DNA replication and DNA repair. Modified residues in the N-terminal tails are well characterized in transcription, but not in DNA replication and DNA repair. In addition, roles of residues in the core globular domains are not yet well characterized in any DNA-mediated reactions. To comprehensively understand the functional surface(s) of a core histone, we constructed 320 yeast mutant strains, each of which has a point mutation in a core histone, and identified 42 residues responsible for the suppressor of Ty (Spt -) phenotypes, and 8, 30 and 61 residues for sensitivities to 6-azauracil (6AU), hydroxyurea (HU) and methyl-methanesulfonate (MMS), respectively. In addition to residues that affect one specific assay, residues involved in multiple reactions were found, and surprisingly, about half of them were clustered at either the nucleosome entry site, the surface required for nucleosome-nucleosome interactions in crystal packing or their surroundings. This comprehensive mutation approach was proved to be powerful for identification of the functional surfaces of a core histone in a variety of DNA-mediated reactions and could be an effective strategy for characterizing other evolutionarily conserved hub-like factors for which surface structural information is available.
CIA (CCG1-interacting factor A)/ASF1, which is the most conserved histone chaperone among the eukaryotes, was genetically identified as a factor for an anti-silencing function (Asf1) by yeast genetic screening. Shortly after that, the CIA-histone-H3-H4 complex was isolated from Drosophila as a histone chaperone CAF-1 stimulator. Human CIA-I/II (ASF1a/b) was identified as a histone chaperone that interacts with the bromodomain-an acetylated-histone-recognizing domain-of CCG1, in the general transcription initiation factor TFIID. Intensive studies have revealed that CIA/ASF1 mediates nucleosome assembly by forming a complex with another histone chaperone in human cells and yeast, and is involved in DNA replication, transcription, DNA repair and silencing/anti-silencing in yeast. CIA/ASF1 was shown as a major storage chaperone for soluble histones in proliferating human cells. Despite all these biochemical and biological functional analyses, the structure-function relationship of the nucleosome assembly/disassembly activity of CIA/ASF1 has remained elusive. Here we report the crystal structure, at 2.7 A resolution, of CIA-I in complex with histones H3 and H4. The structure shows the histone H3-H4 dimer's mutually exclusive interactions with another histone H3-H4 dimer and CIA-I. The carboxy-terminal beta-strand of histone H4 changes its partner from the beta-strand in histone H2A to that of CIA-I through large conformational change. In vitro functional analysis demonstrated that CIA-I has a histone H3-H4 tetramer-disrupting activity. Mutants with weak histone H3-H4 dimer binding activity showed critical functional effects on cellular processes related to transcription. The histone H3-H4 tetramer-disrupting activity of CIA/ASF1 and the crystal structure of the CIA/ASF1-histone-H3-H4 dimer complex should give insights into mechanisms of both nucleosome assembly/disassembly and nucleosome semi-conservative replication.
for the first time. These observations lead to a mechanism of RapAmediated RNAP recycling, including the RapA-facilitated release of sequestered RNAP from DNA template and the σ70-dependent removal of RapA from the RapA•CORE complex for transcription reinitiation. The derived mechanism of RapA provides a framework for further structural and biochemical investigations on, for example, how and where RNAP becomes sequestered in the PTC, the exact composition of the PTC, the DNA translocase activity of RapA and its precise mechanism, and additional factors that may contribute to the destabilization of the PTC.
Eukaryotic DNA is packaged into chromatin by histone proteins, which assemble the DNA into an organized, higher-order structure. The precise organization of chromatin is essential for faithful execution of DNA-mediated reactions such as transcription, DNA replication, DNA repair and DNA recombination. The organization of chromatin is considered to be regulated by a variety of post-translational modifications of histones, such as acetylation, methylation, phosphorylation, ubiquitination, SUMOylation and poly-ADP-ribosylation. The relationship between histone acetylation and gene expression was first observed in 1964. Since then, a great deal of evidence has accumulated showing that not only transcription but other DNA-mediated reactions also are regulated by histone acetylation. With regard to the putative mechanism(s) by which histone acetylation regulates the flow of genetic information, site-specific modification and recognition of acetylated histone/DNA complexes have been postulated. Elucidation of the downstream effects of histone modification, as well as the identification, isolation and characterization of the relevant factors involved, have aided in our understanding of the mechanisms of regulation of DNA activity by histones. Currently, state-of-the-art technologies that enable genome-wide analysis are allowing insight into a critical and interesting question in eukaryotic transcription: are the principles that govern transcription of individual gene loci applicable to the genome as a whole? Here, we review the recent progress on histone modifications, with an emphasis on the role of histone acetylation in gene expression.
The attachment of sister kinetochores to microtubules from opposite spindle poles is essential for faithful chromosome segregation. Kinetochore assembly requires centromere‐specific nucleosomes containing the histone H3 variant CenH3. However, the functional roles of the canonical histones (H2A, H2B, H3, and H4) in chromosome segregation remain elusive. Using a library of histone point mutants in Saccharomyces cerevisiae, 24 histone residues that conferred sensitivity to the microtubule‐depolymerizing drugs thiabendazole (TBZ) and benomyl were identified. Twenty‐three of these mutations were clustered at three spatially separated nucleosomal regions designated TBS‐I, ‐II, and ‐III (TBZ/benomyl‐sensitive regions I–III). Elevation of mono‐polar attachment induced by prior nocodazole treatment was observed in H2A‐I112A (TBS‐I), H2A‐E57A (TBS‐II), and H4‐L97A (TBS‐III) cells. Severe impairment of the centromere localization of Sgo1, a key modulator of chromosome bi‐orientation, occurred in H2A‐I112A and H2A‐E57A cells. In addition, the pericentromeric localization of Htz1, the histone H2A variant, was impaired in H4‐L97A cells. These results suggest that the spatially separated nucleosomal regions, TBS‐I and ‐II, are necessary for Sgo1‐mediated chromosome bi‐orientation and that TBS‐III is required for Htz1 function.
Nucleosomes around the promoter region are disassembled for transcription in response to various signals, such as acetylation and methylation of histones. Although the interactions between histone-acetylation-recognizing bromodomains and factors involved in nucleosome disassembly have been reported, no structural basis connecting histone modifications and nucleosome disassembly has been obtained. Here, we determined at 3.3 Å resolution the crystal structure of histone chaperone cell cycle gene 1 (CCG1) interacting factor A/antisilencing function 1 (CIA/ASF1) in complex with the double bromodomain in the CCG1/TAF1/TAF(II)250 subunit of transcription factor IID. Structural, biochemical, and biological studies suggested that interaction between double bromodomain and CIA/ASF1 is required for their colocalization, histone eviction, and pol II entry at active promoter regions. Furthermore, the present crystal structure has characteristics that can connect histone acetylation and CIA/ASF1-mediated histone eviction. These findings suggest that the molecular complex between CIA/ASF1 and the double bromodomain plays a key role in site-specific histone eviction at active promoter regions. The model we propose here is the initial structure-based model of the biological signaling from histone modifications to structural change of the nucleosome (hi-MOST model).chromatin | transcription | transcription factor IID | x-ray crystallography
A rapid increase in research on the relationship between histone modifications and their subsequent reactions in the nucleus has revealed that the histone modification system is complex, and robust against point mutations. The prevailing theoretical framework (the histone code hypothesis) is inadequate to explain either the complexity or robustness, making the formulation of a new theoretical framework both necessary and desirable. Here, we develop a model of the regulatory network of histone modifications in which we encode histone modifications as nodes and regulatory interactions between histone modifications as links. This network has scale-free properties and subnetworks with a pseudo-mirror symmetry structure, which supports the robustness of the histone modification network. In addition, we show that the unstructured tail regions of histones are suitable for the acquisition of this scale-free property. Our model and related insights provide the first framework for an overall architecture of a histone modification network system, particularly with regard to the structural and functional roles of the unstructured histone tail region. In general, the post-translational "modification webs" of natively unfolded regions (proteins) may function as signal routers for the robust processing of the large amounts of signaling information.
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