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Histones covalent modification

Histone acetylation is a reversible and covalent modification of histone proteins introduced at the e-amino groups of lysine residues. Histones and DNA form a complex - chromatin - which condenses DNA and controls gene activity. Current models interpret histone acetylation as a means to regulate chromatin activity. [Pg.592]

In the nucleosome, the DNA is supercoiled in a left-handed helix over the surface of the disk-shaped histone octamer (Figure 36-2). The majority of core histone proteins interact with the DNA on the inside of the supercoil without protruding, though the amino terminal tails of all the histones probably protrude outside of this structure and are available for regulatory covalent modifications (see Table 36-1). [Pg.315]

The cis-acting elements that decrease or repress the expression of specific genes have also been identified. Because fewet of these elements have been smdied, it is not possible to fotmulate genetalizations about their mechanism of action—though again, as for gene activation, chromatin level covalent modifications of histones and other proteins by (repressor)-recruited multisubunit corepressors have been imphcated. [Pg.385]

Figure 1 Covalent modifications of DNA and histones play a fundamental role in the regulation of differentiation and development. The writers, readers, and erasers of this dynamic code are potentially amenable to modulation with small molecules. Lysine methylation is a critical posttranslational modification influencing chromatin function (PMT = protein lysine methyltransferase, royal family proteins bind KMe, KDM = lysine demethylase). Figure 1 Covalent modifications of DNA and histones play a fundamental role in the regulation of differentiation and development. The writers, readers, and erasers of this dynamic code are potentially amenable to modulation with small molecules. Lysine methylation is a critical posttranslational modification influencing chromatin function (PMT = protein lysine methyltransferase, royal family proteins bind KMe, KDM = lysine demethylase).
One of the most-studied covalent modifications is the acetylation of the lysine residues of histone tails. The acetylation state of lysines of nucleosomal histones modulates chromatin structure and regulates gene transcriptional activity. The balance of lysine acetylation is controlled by the antagonistic action of two enzyme families histone deacetylases (HDACs) and histone acetyltransferases (HATs). In humans there are essentially three main HDAC subclasses [6]. [Pg.337]

Depletion of histone HI after covalent modification from chromatin is a key step in eukaryotic transcription (Lee et al, 1993 Juan et al, 1994 Rice and Allis, 2001). A comparison of the association of the antibiotic Mg + complexes with the normal and HI depleted chromatin suggests that smaller ligands, like anticancer drugs, have better accessibility for HI depleted chromatin compared to native chromatin. HI depleted chromatin is also more prone to aggregation upon association with the complex I of the antibiotic Mg + complexes. It is also less accessible to micrococcal nuclease. We propose that HI depleted chromatin is a better target of these antibiotics compared to native chromatin. This observation is particularly significant in case of neoplastic cells where most of the cell nuclei are transcriptionally active, and, therefore, contain HI depleted chromatin. [Pg.159]

Epigenetic is a term used to describe a state of gene expression that is mitotically and meiotically inherited without any change in the sequence of DNA. Epigenetic mechanisms are mainly of two classes (1) the DNA may be modified by the covalent attachment of a moiety that is then perpetuated. (2) a self-perpetuating protein state may be established (Zelent et al, 2004). The two most studied epigenetic phenomena are DNA methylation and histone tail modifications (Mai et ai, 2005). [Pg.176]

Zeng L, Zhou MM (2002) Bromodomain an acetyl-lysine binding domain. EEBS letters 513 124-128 Zhang Y, Reinberg D (2001) Transcription regulation by histone methylation interplay between different covalent modifications of the core histone tails. Genes Dev 15 2343-2360... [Pg.370]

Chromatin-modifying complexes are classified into two major groups (1) enzymes that conttol covalent modifications of the amino-terminal tails of histones (acetylation, methylation, phosphorylation, ubiquitinylation) (see Sections 1.3 and... [Pg.375]

The covalent modifications of histone tails such as acetylation, phosphorylation, and ubiquitination have been shown to be reversible. This reversibility help the cells to respond to these regulatory modifications and thereby, influence the gene expression. Methylation of histones however, has been considered to be a relatively stable and irreversible mark on histones. Nevertheless active turnover of methyl groups on histones do exist. One of the possible mechanism of removal of methyl... [Pg.400]

Although the histone fold was first described from the structure of the histone octamer core of the nucleosome [17], the high a-helical content was predicted much earlier [43]. The core histones possess three functional domains (1) the histone fold domain, (2) an N-terminal tail domain, and (3) various accessory helices and less structured regions. The N-terminal tail domains of the core histones are currently the focus of intense research. Covalent modifications of residues in these unstructured domains appear to modify local chromatin structure, either directly or... [Pg.22]

Bhaumik, S.R., Smilh, E. and Shilatifard, A. (2007) Covalent modifications of histones during development and disease pathogenesis. Nature Structural ei Molecular Biology, 14, 1008—1016. [Pg.85]

McKittrick, E., Gafken, P.R., Ahmad, K. and Henikoff, S. (2004) Histone H3.3 is enriched in covalent modifications associated with active chromatin. Proceedings of the National Academy of Sciences of the United States of America, 101, 1525-1530. [Pg.96]

The structural differences between euchromatin and heterochromatin are coor-dinately regulated by reversible covalent modification of the DNA or histones. [Pg.178]

Histones within transcriptionally active chromatin and heterochromatin also differ in their patterns of covalent modification. The core histones of nucleosome particles (H2A, H2B, H3, H4 see Fig. 24-27) are modified by irreversible methylation of Lys residues, phosphorylation of Ser or Thr residues, acetylation (see below), or attachment of ubiquitin (see Fig. 27-41). Each of the core histones has two distinct structural domains. A central domain is involved in histone-histone interaction and the wrapping of DNA around the nucleosome. A second, lysine-rich amino-terminal domain is generally positioned near the exterior of the assembled nucleosome particle the covalent modifications occur at specific residues concentrated in this amino-terminal domain. The patterns of modification have led some researchers to propose the existence of a histone code, in which modification patterns are recognized by enzymes that alter the structure of chromatin. Modifications associated with transcriptional activation would be recognized by enzymes that make the chromatin more accessible to the transcription machinery. [Pg.1102]

In the recent literature, many examples of A/BPs containing benzophenones can be found. A first example concerns the study of HDACs. These enzymes catalyze the hydrolysis of acetylated lysine amine side chains in histones and are thus involved in the regulation of gene expression. There are approximately 20 human HDACs, which are divided into three classes (I, II, and III). Class I and II HDACs are zinc-dependent metallohydrolases that do not form a covalent bond with their substrates during their catalytic process, which is similar to MMPs. It has been found that hydroxamate 65 (SAHA, see Fig. 5) is a potent reversible inhibitor of class I and II HDACs. In 2007, Cravatt and coworkers reported the transformation of SAHA into an A/BP by installment of a benzophenone and an alkyne moiety, which resulted in SAHA-BPyne (66) [73]. They showed that the probe can be used for the covalent modification and enrichment of several class I and class II HDACs from complex proteomes in an activity-dependent manner. In addition, they identified several HDAC-associated proteins, possibly arising from the tight interaction with HDACs. Also, the probe was used to measure differences in HDAC content in human disease models. Later they reported the construction of a library of related probes and studied the differences in HDAC labeling [74], Their most... [Pg.100]

Acetylation is not the only covalent modification of histones. Histones can be methylated, ADP-ribosylated, and phosphorylated. Each of these covalent modifications has been implicated in packaging DNA, in the replication of DNA, and in the regulation of gene transcription. [Pg.166]

AdoMet-Dependent Methyltransferases, Chemistry of DNA, Covalent Modifications of Histone Acetyltransferases, Selective Inhibitors of Post-Translational Modifications to Regulate Protein Eunction... [Pg.475]

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