A histone variant, Htz1p, and a Sir1p-like protein, Esc2p, mediate silencing at HMR

Silencing at HMR requires silencers, and one of the roles of the silencer is to recruit Sir proteins. This work focuses on the function of Sir1p once it is recruited to the silencer. We have generated mutants of Sir1p that are recruited to the silencer but are unable to silence, and we have utilized these mutants to identify four proteins, Sir3p, Sir4p, Esc2p, and Htz1p, that when overexpressed, restored silencing. The isolation of Sir3p and Sir4p validated this screen. Molecular analysis suggested that Esc2p contributed to silencing in a manner similar to Sir1p and probably helped recruit or stabilize the other Sir proteins, while Htz1p present at HMR assembled a specialized chromatin structure necessary for silencing.     

Histone H2A C-terminus regulates chromatin dynamics, remodeling, and histone H1 binding

The tails of histone proteins are central players for all chromatin-mediated processes. Whereas the N-terminal histone tails have been studied extensively, little is known about the function of the H2A C-terminus. Here, we show that the H2A C-terminal tail plays a pivotal role in regulating chromatin structure and dynamics. We find that cells expressing C-terminally truncated H2A show increased stress sensitivity. Moreover, both the complete and the partial deletion of the tail result in increased histone exchange kinetics and nucleosome mobility in vivo and in vitro. Importantly, our experiments reveal that the H2A C-terminus is required for efficient nucleosome translocation by ISWI-type chromatin remodelers and acts as a novel recognition module for linker histone H1. Thus, we suggest that the H2A C-terminal tail has a bipartite function: stabilisation of the nucleosomal core particle, as well as mediation of the protein interactions that control chromatin dynamics and conformation.     

The amino acid sequence of boar H1t, a testis-specific H1 histone variant

H1t is a testis-specific H1 variant found in spermatocytes and spermatids of mammals. The complete amino acid sequence has been determined for H1t isolated from boar testes. The protein is composed of 211 amino acids with the composition 3 aspartic acids, 6 asparagines, 13 threonines, 21 serines, 7 glutamic acids, 7 glutamines, 15 prolines, 14 glycines, 37 alanines, 11 valines, 1 methionine, 3 isoleucines, 14 leucines, 1 tyrosine, 1 phenylalanine, 42 lysines, 15 arginines and a calculated molecular weight of 22,059 disregarding the post-translational acetylation of the amino-terminal alanine. The protein shows typical H1 domains with basic amino- and carboxyl-terminal regions separated by a conserved, presumably globular, core sequence. The core region is very homologous to the highly conserved core sequence found in somatic mammalian H1 histones but does differ from this sequence in 15 places. Accordingly, it may be appropriate to consider H1t as new variant category. The carboxyl-terminal half of H1t is distinguished from the standard somatic family by being somewhat shorter and by the presence of 10 arginine residues. In contrast to many H1 proteins, the carboxyl-terminal region of H1t does not show an obvious pattern of peptide repeats.     

Characterization of a cDNA clone coding for a sea urchin histone H2A variant related to the H2A.F/Z histone protein in vertebrates.

A cDNA clone coding for a sea urchin histone H2A variant has been isolated. The coding region of the clone has been sequenced and the sequence found to be closely related to the H2A.F sequence in chickens. The nucleotide sequence of the sea urchin H2A.F/Z is 74% conserved when compared to chicken H2A.F and 51% conserved compared to sea urchin H2A early and 60% compared to sea urchin H2A late. The nucleotide-derived amino acid comparisons show that H2A.F/Z is 97% homologous with H2A.F in chickens and 57% and 56% homologous when compared to sea urchin H2A early and late respectively. There are between 3-6 copies of the H2A.F/Z sequence in the S. purpuratus genome. The H2A.F/Z gene sequence codes for the previously identified H2A.Z protein. All embryonic stages and adult tissues tested contain mRNA for H2A.F/Z. The mRNA appears in the poly A+ RNA fraction after chromatography over oligo dT cellulose.     

Isolation of the gene for the testis-specific H1 histone variant H1t

H1t is a testis-specific H1 variant found in pachytene spermatocytes and round spermatids of mammals. The H1t gene was isolated from the Sargent-Bonner library of recombinant lambda bacteriophage containing EcoRI fragments of rat liver DNA using a hybridization probe derived from a chicken H1 variant. The rat H1t gene encodes a 207-amino acid protein (ignoring the initiating methionine) that matches perfectly what is known of the sequence and composition of H1t isolated from rat testes. The gene lacks introns and has good matches to all the consensus sequences known to lie upstream from a variety of H1 genes from diverse organisms. It also has the standard downstream palindromic sequence that specifies the 3'-end of most histone messages. Accordingly, the features of the gene or its environs that restrict its expression to a particular phase of spermatogenesis are not yet evident.     

Chz1, a nuclear chaperone for histone H2AZ

The histone variant H2AZ marks nucleosomes flanking the promoters of most genes of budding yeast. The incorporation of H2AZ into chromatin is dependent on the SWR1 complex, which catalyses the replacement of conventional histone H2A with H2AZ. In cells, the pool of unincorporated histone H2AZ has previously been found in association with Nap1, a chaperone for conventional histone H2A-H2B. Here, we report the discovery of Chz1, a histone chaperone that has preference for H2AZ and can also deliver a source of the histone variant for SWR1-dependent histone replacement. Bacterially expressed Chz1 forms a heterotrimer with H2AZ-H2B, stabilizing the association of the histone dimer. We have identified a conserved motif important for histone variant recognition within the H2AZ-interacting domain of Chz1. The presence of this motif in other metazoan proteins suggests that H2AZ-specific chaperones may be widely conserved.     

The histone variant macroH2A1.1 is recruited to DSBs through a mechanism involving PARP1

The repair of DNA double-strand breaks (DSBs) requires remodeling of the local chromatin architecture to allow the repair machinery to access sites of damage. Here, we report that the histone variant macroH2A1.1 is recruited to DSBs. Cells lacking macroH2A1 have defective recruitment of 53BP1, defective activation of chk2 kinase and increased radiosensitivity. Importantly, macroH2A1.1 is not incorporated into nucleosomes at DSBs, but instead associates with the chromatin through a mechanism which requires PARP1 activity. These results reveal an unusual mechanism involving a direct association of macroH2A1.1 with PARylated chromatin which is critical for retaining 53BP1 at sites of damage.     

H2A.Z.2.2 is an alternatively spliced histone H2A.Z variant that causes severe nucleosome destabilization

The histone variant H2A.Z has been implicated in many biological processes, such as gene regulation and genome stability. Here, we present the identification of H2A.Z.2.2 (Z.2.2), a novel alternatively spliced variant of histone H2A.Z and provide a comprehensive characterization of its expression and chromatin incorporation properties. Z.2.2 mRNA is found in all human cell lines and tissues with highest levels in brain. We show the proper splicing and in vivo existence of this variant protein in humans. Furthermore, we demonstrate the binding of Z.2.2 to H2A.Z-specific TIP60 and SRCAP chaperone complexes and its active replication-independent deposition into chromatin. Strikingly, various independent in vivo and in vitro analyses, such as biochemical fractionation, comparative FRAP studies of GFP-tagged H2A variants, size exclusion chromatography and single molecule FRET, in combination with in silico molecular dynamics simulations, consistently demonstrate that Z.2.2 causes major structural changes and significantly destabilizes nucleosomes. Analyses of deletion mutants and chimeric proteins pinpoint this property to its unique C-terminus. Our findings enrich the list of known human variants by an unusual protein belonging to the H2A.Z family that leads to the least stable nucleosome known to date.