Binding of Chromatin-Modifying Activities to Phosphorylated Histone H2A at DNA Damage Sites
Yeast histone H2A is phosphorylated on Ser129 upon DNA damage, an event required for efficient repair. We show that phosphorylation occurs rapidly over a large region around DNA double-strand breaks (DSBs). Histone H4 acetylation is also important for DSB repair, and we found that the NuA4 HAT complex associates specifically with phospho-H2A peptides. A single NuA4 subunit, Arp4, is responsible for the interaction. The NuA4 complex is recruited to a DSB concomitantly with the appearance of H2A P-Ser129 and Arp4 is important for this binding. Arp4 is also a subunit of the Ino80 and Swr1 chromatin remodeling complexes, which also interact with H2A P-Ser129 and are recruited to DSBs. This association again requires Arp4 but also prior NuA4 recruitment and action. Thus, phosphorylation of H2A at DNA damage sites creates a mark recognized by different chromatin modifiers. This interaction leads to stepwise chromatin reconfiguration, allowing efficient DNA repair.
Eaf1 (for Esa1-associated factor 1) and Eaf2 have been identified as stable subunits of NuA4, a yeast histone H4/H2A acetyltransferase complex implicated in gene regulation and DNA repair. While both SWI3-ADA2-N-CoR-TF IIIB domain-containing proteins are required for normal cell cycle progression, their depletion does not affect the global Esa1-dependent acetylation of histones. In contrast to all other subunits, Eaf1 is found exclusively associated with the NuA4 complex in vivo. It serves as a platform that coordinates the assembly of functional groups of subunits into the native NuA4 complex. Eaf1 shows structural similarities with human p400/Domino, a subunit of the NuA4-related TIP60 complex. On the other hand, p400 also possesses an SWI2/SNF2 family ATPase domain that is absent from the yeast NuA4 complex. This domain is highly related to the yeast Swr1 protein, which is responsible for the incorporation of histone variant H2AZ in chromatin. Since all of the components of the TIP60 complex are homologous to SWR1 or NuA4 subunits, we proposed that the human complex corresponds to a physical merge of two yeast complexes. Chromatin is a very dynamic structure, and it plays an intricate regulatory role in DNA replication, transcription, and repair. Two major types of activities regulating chromatin structure and function have been studied extensively over the past few years and have been functionally linked together in diverse nuclear processes (65). ATP-dependent chromatin-remodeling complexes of the SWI2/SNF2 family disrupt DNAhistone contacts within nucleosomes, increasing DNA accessibility and nucleosome mobility (25). Histone-modifying complexes target specific residues on histones for acetylation, methylation, phosphorylation, and ubiquitinylation. These modifications can affect the level of DNA compaction but also serve as markers identifying the chromatin state of specific genomic loci. Different histone modifications influence each other and create a specific local signature that can be recognized by protein domains present in various regulators, e.g., bromodomains for acetylated lysines and chromodomains for methylated lysines. These posttranslational modifications are reversible and highly dynamic during cell growth (36). Diverse ATP-dependent remodelers and histone modifiers have been shown to be recruited to specific loci through direct interactions with DNA-bound factors. For example, histone acetyltransferase (HAT) and histone deacetylase (HDAC) complexes are recruited to specific promoter regions by transcriptional activators or repressors (61). The local incorporation of specific histone variants is an additional mechanism that regulates chromatin function. Activities responsible for these incorporations recently have been identified, and a specific class of ATP-dependent remodelers has been implicated in this process (31,40).Nucleosome acetyltransferase of H4 (NuA4) is a multisubunit HAT complex that is highly conserved in eukaryotes and plays important roles in transcription and DNA repair (2...
Structural and functional analyses of nucleosomes containing histone variant H2A.Z have drawn a lot of interest over the past few years. Important work in budding yeast has shown that H2A.Z (Htz1)-containing nucleosomes are specifically located on the promoter regions of genes, creating a specific chromatin structure that is poised for disassembly during transcription activation. The SWR1 complex is responsible for incorporation of Htz1 into nucleosomes through ATP-dependent exchange of canonical H2A-H2B dimers for Htz1-H2B dimers. Interestingly, the yeast SWR1 complex is functionally linked to the NuA4 acetyltransferase complex in vivo. NuA4 and SWR1 are physically associated in higher eukaryotes as they are homologous to the TIP60/p400 complex, which encompasses both histone acetyltransferase (Tip60) and histone exchange (p400/Domino) activities. Here we present work investigating the impact of NuA4-dependent acetylation on SWR1-driven incorporation of H2A.Z into chromatin. Using in vitro histone exchange assays with native chromatin, we demonstrate that prior chromatin acetylation by NuA4 greatly stimulates the exchange of H2A for H2A.Z. Interestingly, we find that acetylation of H2A or H4 N-terminal tails by NuA4 can independently stimulate SWR1 activity. Accordingly, we demonstrate that mutations of H4 or H2A N-terminal lysine residues have similar effects on H2A.Z incorporation in vivo, and cells carrying mutations in both tails are nonviable. Finally, depletion experiments indicate that the bromodomain-containing protein Bdf1 is important for NuA4-dependent stimulation of SWR1. These results provide important mechanistic insight into the functional cross-talk between chromatin acetylation and ATP-dependent exchange of histone H2A variants.Genetic information within the eukaryotic cell nucleus is organized in a highly conserved structural polymer, chromatin, which supports and controls crucial functions of the genome. Chromatin remodeling and post-translational modifications of histones are critical processes regulating genome expression and maintenance by controlling access to DNA and signaling local regions for specific molecular interactions (1, 2). Incorporation of different histone variants in specific chromosomal regions is also known to be associated with important biological processes controlling gene expression and genome integrity (3).A specific histone variant, H2A.Z, has been the focus of intense research over the past few years (4 -6). Delineation of its impact on nucleosome structure and stability and on gene expression has turned into a long-heated debate involving apparently contradicting experimental data. However, recent findings led to an emerging model that could partly reconcile these contradictions (7). Genome-wide analyses of H2A.Z localization in eukaryotes indicate that it is preferentially found on gene promoter/regulatory regions within nucleosomes flanking more accessible DNA sequences (8 -14). Importantly, H2A.Z is found within the promoters of inactive or weakly transcribed ge...
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