Methylated lysine 9 on the histone 3 (H3) tail recruits heterochromatin protein 1 from Drosophila (dHP1) via its chromodomain and results in gene silencing. The dHP1 chromodomain binds H3 K9Me3 with an aromatic cage surrounding the trimethyllysine. The sequence selectivity of binding comes from insertion of the histone tail between two β-strands of the chromodomain to form a three-stranded β-sheet. Herein, we investigated the sequence selectivity provided by the β-sheet interactions and how those interactions compare to other model systems. Residue Thr6 of the histone tail forms cross-strand interactions with Ala25 and Asp62 of the chromodomain. Each of these three residues was substituted for amino acids known to have high β-sheet propensities and/or to form favorable side chain–side chain (SC–SC) interactions in β-sheets, including hydrophobic, H-bonding, and aromatic interactions. We found that about 50% of the chromodomain mutants resulted in equal or tighter binding to the histone tail and about 25% of the histone tail mutants provided tighter binding compared to that of the native histone tail sequence. These studies provide novel insights into the sequence selectivity of the dHP1 chromodomain for the histone tail and relates the information gleaned from model systems and statistical studies to β-sheet-mediated protein–protein interactions. Moreover, this work suggests that the development of designer histone–chromodomain pairs for chemical biology applications is feasible.

The Jumonji C domain-containing histone demethylases (JmjC-HDMs) are α-ketoglutarate (αKG)-dependent, O2-activating, non-heme iron enzymes that play an important role in epigenetics. Reported herein is a detailed kinetic analysis of three JmjC-HDMs, including the cancer-relevant JMJD2C, that was achieved by employing three enzyme activity assays. A continuous O2 consumption assay reveals that HDMs have low affinities for O2, suggesting that these enzymes can act as oxygen sensors in vivo. An interesting case of αKG substrate inhibition was found, and the kinetic data suggest that αKG inhibits JMJD2C competitively with respect to O2. JMJD2C displays an optimal activity in vitro at αKG concentrations similar to those found in cancer cells, with implications for the regulation of histone demethylation activity in cancer versus normal cells.

Trimethyllysine 72 (Tml72) of yeast iso-1-cytochrome c lies across the surface of the heme crevice loop (Ω-loop D, residues 70–85) like a brace. Lys72 is oriented similarly in horse cytochrome c (Cytc). To determine whether this residue affects the dynamics of opening the heme crevice loop, we have studied the effect of a Tml72 to Ala substitution on the formation of the His79–heme alkaline conformer near neutral pH using a variant of iso-1-Cytc including K72A and K79H mutations. Guanidine hydrochloride denaturation shows that the Tml72 to Ala substitution within error does not affect the global stability of the protein. The effect of the Tml72 to Ala substitution on the thermodynamics of the His79–heme alkaline transition is also small. However, pH-jump kinetic studies of the His79–heme alkaline transition show that both the forward and backward rates of conformational change are increased by the Tml72 to Ala substitution. The barrier for opening the heme crevice is reduced by 0.5 kcal/mol and for closing the heme crevice by 0.3 kcal/mol. The ability of Tml72 to modulate the heme crevice dynamics may indicate a crucial role in regulating function, such as in the peroxidase activity seen in the early stages of apoptosis.