Histone tails modification sites

Fig. 1. Nucleosome structure and histone tail modification sites. (See Color Insert.)...

Histone phosphorylation is a common posttranslational modification fond in histones, primarily on the N-terminal tails. Phosphorylation sites include serine and threonine residues, tyrosine phosphorylation has not been observed so far. Some phosphorylation events occur locally whereas others occur globally throughout all chromosomes during specific events like mitosis. Histone phosphorylation is catalyzed by kinases. Removal of the phosphoryl groups is catalyzed by phosphatases. 

As described above, histones are much more than passive structural players within chromatin. Dynamic post-translational modifications of these proteins confer specialized chemical proprieties to chromatin of both informational and structural nature with important functional implications. The highly conserved sites for acetylation, methylation, phosphorylation, ADP-ribosylation, and ubiquitination events on histone tails appear to orchestrate functional activities that range from transcriptional activation and repression to DNA repair and recombination. 

Histone acetylation was one of the first posttranslational histone proteins to be described and demonstrated to function in the regulation of transcriptional activation (Braunstein et al., 1993). To date, this modification of histone is the one best characterized (Workman and Kingston, 1998). Acetylation of a lysine residue on a histone tail can neutralize the positive charge, thus weakening the interaction of the nucleosome with the DNA backbone. This then allows for the remodeling of the nucleosome so that the transcriptional machinery, as well as other proteins, can gain access to previously restricted sites within the DNA... 

Fig. 6. Post-translational modifications of core and linker histones. The sites of acetylation, phosphorylation, poly-ADP ribosylation, methylation, and ubiquitination are incficated by numbers that correspond to the amino acid position from the N-termini of the molecules. The nomenclature of histone HI variants is as in Fig. 3. The length of C- and N-terminal tails is in relative scale between core histones to illustrate primary structural differences between these proteins.

Fig. 1. Histone modifications on the nucleosome core particle. The nucleosome core particle showing 6 of the 8 core histone N-terminal tail domains and 2 C-terminal tails. Sites of post-translational modification are indicated by coloured symbols that are defined in the key (lower left) acK = acetyl lysine, meR = methyl arginine, mcK = methyl lysine, PS = phosphoryl serine, and uK = ubiquitinated lysine. Residue numbers are shown for each modification. Note that H3 lysine 9 can be either acetylated or methylated. The C-terminal tail domains of one H2A molecule and one H2B molecule are shown (dashed lines) with sites of ubiquitination at H2A lysine 119 (most common in mammals) and H2B lysine 123 (most common in yeast). Modifications are shown on only one of the two copies of histones H3 and H4 and only one tail is shown for H2A and H2B. Sites marked by green arrows are susceptible to cutting by trypsin in intact nucleosomes. Note that the cartoon is a compendium of data from various organisms, some of which may lack particular modifications e.g., there is no H3meK9 in S. cerevisiae. (From Ref [7].)...

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