Transcription activator Chromatin structure

Enzyme activity ascribed to corepressors, which is the removal of acetyl groups from lysine residues of histone tails. Thereby the assembly of nucleosomes is maintained, which leads to a dense, transcriptional inactive chromatin structure. 

One possible function for H3.3 and some of the other replacement variants is to maintain the integrity of chromatin structure by replacing histones that are damaged or lost during normal cellular metabolism. Ahmad and Henikoff [104] suggested that replication independent incorporation of H3.3 could provide a mechanism to switch patterns of histone modification by removing H3 molecules that may be irreversibly modified by methylation. They also suggested that H3.3 could serve as a mark of transcriptionally active chromatin. One complication for... 

H3 replacement variants are also present in plants [108] and Tetrahymena [109]. Phylogenetic analyses indicates that these H3 replacement variants arose independently of animal H3.3 [109]. Like H3.3, the plant H3 replacement variant also appears to be preferentially deposited into transcriptionally active chromatin [110]. The H3 replacement variant in Tetrahymena, hv2, is found only in the transcriptionally active macronucleus [49]. In contrast to H3.3, the amino acid differences between hv2 and the replication dependent H3 of Tetrahymena do not appear to be essential for replication independent incorporation into chromatin [111]. In this case constitutive expression appears to be the dominant factor that can drive replication independent deposition of hv2 or an H3 variant that is normally replication dependent. This difference between hv2 and H3.3 is not necessarily surprising because hv2 appears to have arisen independently of H3.3 and does not have the structural features characteristic of H3.3 [109]. 

Boffa, L.C., Walker, J., Chen, T.A., Sterner, R., Mariani, M.R., and Allfrey, V.G. (1990) Factors effecting nucleosome structure in transcriptionally active chromatin. Histone acetylation, nascent RNA and inhibitors of RNA synthesis. Eur. J. Biochem. 194, 811-823. 

The family of HDAC enzymes has been named after their first substrate identified, i.e., the nuclear histone proteins. Histone proteins (H2A, H2B, H3 and H4) form an octamer complex, around which the DNA helix is wrapped in order to establish a condensed chromatin structure. The acetylation status of histones is in a dynamic equilibrium governed by histone acetyl transferases (HATs), which acetylate and HDACs which are responsible for the deacetylation of histone tails (Fig. 1). Inhibition of the HDAC enzyme promotes the acetylation of nucleosome histone tails, favoring a more transcriptionally competent chromatin structure, which in turn leads to altered expression of genes involved in cellular processes such as cell prohferation, apoptosis and differentiation. Inhibition of HDAC activity results in the activation of only a limited set of pre-programmed genes microarray experiments have shown that 2% of all genes are activated by structmally different HDAC inhibitors [1-5]. In recent years, a growing number of additional nonhistone HDAC substrates have been identified, which will be discussed in more detail below. 

Transcriptionally Active Chromatin Is Structurally Distinct from Inactive Chromatin... 

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. 

Hypoacetylated, transcriptionally inactive chromatin assumes a more condensed structure and is more resistant to DNase I than hyperacetylated, transcriptionally active chromatin. 

The right folding of chromatin renders many of the sites on DNA inaccessible to the proteins that must be assembled to form an active transcription complex. Chromatin structure decreases the amount of DNA available to nonchromatin proteins. Remodeling of chromatin makes some of these sites accessible. 

An additional important observation on the )3-globin locus related to a different type of chromatin structure alteration observed in vivo a change in the covalent modification status of histone tails within a domain of transcriptionally active chromatin. To better illuminate the significance of this finding, we must briefly review the biochemistry of such modifications. As mentioned earlier, in 1964 it was discovered that particular lysine residues in the NH2-terminal tails of the core histones are reversibly covalently modified by acetylation ... 

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