Histone H4

About: Histone H4 is a research topic. Over the lifetime, 2620 publications have been published within this topic receiving 190568 citations. The topic is also known as: Histone_H4 & IPR001951.

The language of covalent histone modifications.

Abstract: Histone proteins and the nucleosomes they form with DNA are the fundamental building blocks of eukaryotic chromatin. A diverse array of post-translational modifications that often occur on tail domains of these proteins has been well documented. Although the function of these highly conserved modifications has remained elusive, converging biochemical and genetic evidence suggests functions in several chromatin-based processes. We propose that distinct histone modifications, on one or more tails, act sequentially or in combination to form a 'histone code' that is, read by other proteins to bring about distinct downstream events.

Crystal structure of the nucleosome core particle at 2.8 Å resolution

Abstract: The X-ray crystal structure of the nucleosome core particle of chromatin shows in atomic detail how the histone protein octamer is assembled and how 146 base pairs of DNA are organized into a superhelix around it. Both histone/histone and histone/DNA interactions depend on the histone fold domains and additional, well ordered structure elements extending from this motif. Histone amino-terminal tails pass over and between the gyres of the DNA superhelix to contact neighbouring particles. The lack of uniformity between multiple histone/DNA-binding sites causes the DNA to deviate from ideal superhelix geometry.

Transcriptional silencing and longevity protein Sir2 is an NAD-dependent histone deacetylase

Abstract: Yeast Sir2 is a heterochromatin component that silences transcription at silent mating loci, telomeres and the ribosomal DNA, and that also suppresses recombination in the rDNA and extends replicative life span. Mutational studies indicate that lysine 16 in the amino-terminal tail of histone H4 and lysines 9, 14 and 18 in H3 are critically important in silencing, whereas lysines 5, 8 and 12 of H4 have more redundant functions. Lysines 9 and 14 of histone H3 and lysines 5, 8 and 16 of H4 are acetylated in active chromatin and hypoacetylated in silenced chromatin, and overexpression of Sir2 promotes global deacetylation of histones, indicating that Sir2 may be a histone deacetylase. Deacetylation of lysine 16 of H4 is necessary for binding the silencing protein, Sir3. Here we show that yeast and mouse Sir2 proteins are nicotinamide adenine dinucleotide (NAD)-dependent histone deacetylases, which deacetylate lysines 9 and 14 of H3 and specifically lysine 16 of H4. Our analysis of two SIR2 mutations supports the idea that this deacetylase activity accounts for silencing, recombination suppression and extension of life span in vivo. These findings provide a molecular framework of NAD-dependent histone deacetylation that connects metabolism, genomic silencing and ageing in yeast and, perhaps, in higher eukaryotes.

Histone H4-K16 Acetylation Controls Chromatin Structure and Protein Interactions

Abstract: Acetylation of histone H4 on lysine 16 (H4-K16Ac) is a prevalent and reversible posttranslational chromatin modification in eukaryotes. To characterize the structural and functional role of this mark, we used a native chemical ligation strategy to generate histone H4 that was homogeneously acetylated at K16. The incorporation of this modified histone into nucleosomal arrays inhibits the formation of compact 30-nanometer-like fibers and impedes the ability of chromatin to form cross-fiber interactions. H4-K16Ac also inhibits the ability of the adenosine triphosphate-utilizing chromatin assembly and remodeling enzyme ACF to mobilize a mononucleosome, indicating that this single histone modification modulates both higher order chromatin structure and functional interactions between a nonhistone protein and the chromatin fiber.

Histone acetylation and transcriptional regulatory mechanisms

Abstract: More than 30 years ago, Vincent Allfrey proposed that histone acetylation was associated with transcriptional activity in eukaryotic cells (Allfrey et al. 1964; Pogo et al. 1966). Subsequently, acetylated core histones were shown to preferentially associate with transcriptionally active chromatin (Sealy and Chalkley 1978; Vidali et al. 1978; Hebbes et al. 1988). Acetylation occurs at lysine residues on the amino-terminal tails of the histones, thereby neutralizing the positive charge of the histone tails and decreasing their affinity for DNA (Hong et al. 1993). As a consequence, histone acetylation alters nucleosomal conformation (Norton et al. 1989), which can increase the accessibility of transcriptional regulatory proteins to chromatin templates (Lee et al. 1993; Vettese-Dadey et al. 1996). Taken together, these observations suggested how histone acetylation could result in increased transcriptional activity in vivo. However, there was essentially no information about the cause and effect relationship between histone acetylation and transcriptional activity or about the underlying molecular mechanisms. A mechanistic and physiologically relevant connection between histone acetylation and transcriptional regulation was initially provided by two independent lines of evidence. First, yeast cells unable to acetylate the histone H4 tail because of mutations of the target lysine residues show altered patterns of transcription (Durrin et al. 1991). However, these mutations broadly affect chromatin structure in vivo, and hence are likely to influence other molecular processes involving DNA (e.g., DNA replication and repair, recombination, chromosome segregation). Second, treatment of mammalian cells with potent inhibitors of histone deacetylase activity such as trapoxin or trichostatin A resulted in increased expression of a variety of genes (Yoshida et al. 1995). However, these drugs might inhibit other cellular targets, and they affect a variety of cellular processes, including cell proliferation, apoptosis, differentiation, and DNA synthesis. Although these observations were suggestive, understanding of the relationship between chromatin structure and transcription regulation was hampered significantly by a lack of knowledge about the enzymes that acetylate and deacetylate histones. In the past 2 years, our understanding of the causal relationship between histone acetylation and gene expression has been enhanced dramatically by the identification of proteins with intrinsic histone acetylase and deacetylase activity (Brownell et al. 1996; for recent reviews, see Grunstein 1997; Pazin and Kadonaga 1997; Wade et al. 1997). Of particular significance, some of these enzymes had been identified previously as components of the RNA polymerase II (Pol II) transcription machinery itself, proteins that associate with transcriptional regulatory factors, or proteins that positively or negatively affect transcription in vivo. These discoveries have led to a major paradigm shift. It is now clear that chromatin structure and modification can not be viewed as a process that is independent of transcriptional initiation, that is, chromatin is not simply a structure that serves to compact DNA in the nucleus and provide a relatively passive substrate for the action of transcription factors. Instead, histone acetylases and deacetylases provide a critical link between chromatin structure and transcriptional output, and this link is now accessible to experimental intervention. This review will focus on molecular mechanisms by which histone acetylation affects transcriptional activity in living cells.