Histone Deacetylase 1 Inhibition by Peptides Containing a DNA Damage-Induced, Nonenzymatic, Histone Covalent Modification.

Treatment of HeLa cells with the DNA damaging agent, bleomycin (BLM), results in the formation of a nonenzymatic 5-methylene-2-pyrrolone histone covalent modification on lysine residues (KMP). KMP is much more electrophilic than other N-acyllysine covalent modifications and post-translational modifications, including N-acetyllysine (KAc). Using histone peptides containing KMP, we show that this modification inhibits the class I histone deacetylase, HDAC1, by reacting with a conserved cysteine (C261) located near the active site. HDAC1 is inhibited by histone peptides whose corresponding N-acetylated sequences are known deacetylation substrates, but not one containing a scrambled sequence. The HDAC1 inhibitor, trichostatin A, competes with covalent modification by the KMP-containing peptides. HDAC1 is also covalently modified by a KMP-containing peptide in a complex milieu. These data indicate that peptides containing KMP are recognized by HDAC1 and are bound in the active site. The effects on HDAC1 indicate that KMP formation in cells may contribute to the biological effects of DNA damaging agents, such as BLM, that form this nonenzymatic covalent modification.

Covalent Modification of Bromodomain Proteins by Peptides Containing a DNA Damage-Induced, Histone Post-Translational Modification.

An electrophilic 5-methylene-2-pyrrolone modification (KMP ) is produced at lysine residues of histone proteins in nucleosome core particles upon reaction with a commonly formed DNA lesion (C4-AP). The nonenzymatic KMP modification is also generated in the histones of HeLa cells treated with the antitumor agent, bleomycin that oxidizes DNA and forms C4-AP. This nonenzymatic covalent histone modification has the same charge as the N-acetyllysine (KAc ) modification but is more electrophilic. In this study we show that KMP -containing histone peptides are recognized by, and covalently modify bromodomain proteins that are KAc readers. Distinct selectivity preferences for covalent bromodomain modification are observed following incubation with KMP -containing peptides of different sequence. MS/MS analysis of 3 covalently modified bromodomain proteins confirmed that Cys adduction was selective. The modified Cys was not always proximal to the KAc binding site, indicating that KMP -containing peptide interaction with bromodomain protein is distinct from the former. Analysis of protein adduction yields as a function of bromodomain pH at which the protein charge is zero (pI) or cysteine solvent accessible surface area are also consistent with non-promiscuous interaction between the proteins and electrophilic peptides. These data suggest that intracellular formation of KMP could affect cellular function and viability by modifying proteins that regulate genetic expression.

Intracellular Formation of a DNA Damage-Induced, Histone Post-Translational Modification Following Bleomycin Treatment.

Evaluating the significance of various forms of DNA damage is complicated by discoveries that some lesions inactivate repair enzymes or produce more deleterious forms of damage. Histone lysines within nucleosomes react with the commonly produced C4'-oxidized abasic site (C4-AP) to concomitantly yield an electrophilic modification (KMP) on lysine and DNA strand scission. We developed a chemoproteomic approach to identify KMP in HeLa cells. More than 60 000 KMP-modified histones are produced per cell. Using LC-MS/MS, we detected KMP at 17 of the 57 lysine residues distributed throughout the four core histone proteins. Therefore, KMP constitutes a DNA damage-induced, nonenzymatic histone post-translational modification. KMP formation suggests that downstream processes resulting from DNA damage could have ramifications on cells.

Synthesis of 5-Methylene-2-pyrrolones.

A facile, one-pot synthetic method for the synthesis of 5-methylene-2-pyrrolones (5MPs) from inexpensive furfuryl acetate is described. Bromine oxidation and trapping of the in situ generated 1,4-dicarbonyl compound by a primary amine provided the corresponding 5MPs in 50-69% yield.

Genetically Encoded 2-Aryl-5-carboxytetrazoles for Site-Selective Protein Photo-Cross-Linking.

The genetically encoded photo-cross-linkers promise to offer a temporally controlled tool to map transient and dynamic protein-protein interaction complexes in living cells. Here we report the synthesis of a panel of 2-aryl-5-carboxytetrazole-lysine analogs (ACTKs) and their site-specific incorporation into proteins via amber codon suppression in Escherichia coli and mammalian cells. Among five ACTKs investigated, N-methylpyrroletetrazole-lysine (mPyTK) was found to give robust and site-selective photo-cross-linking reactivity in E. coli when placed at an appropriate site at the protein interaction interface. A comparison study indicated that mPyTK exhibits higher photo-cross-linking efficiency than a diazirine-based photo-cross-linker, AbK, when placed at the same location of the interaction interface in vitro. When mPyTK was introduced into the adapter protein Grb2, it enabled the photocapture of EGFR in a stimulus-dependent manner. The design of mPyTK along with the identification of its cognate aminoacyl-tRNA synthetase makes it possible to map transient protein-protein interactions and their interfaces in living cells.

Probing Enhanced Double-Strand Break Formation at Abasic Sites within Clustered Lesions in Nucleosome Core Particles.

DNA is rapidly cleaved under mild alkaline conditions at apyrimidinic/apurinic sites, but the half-life is several weeks in phosphate buffer (pH 7.5). However, abasic sites are ∼100-fold more reactive within nucleosome core particles (NCPs). Histone proteins catalyze the strand scission, and at superhelical location 1.5, the histone H4 tail is largely responsible for the accelerated cleavage. The rate constant for strand scission at an abasic site is enhanced further in a nucleosome core particle when it is part of a bistranded lesion containing a proximal strand break. Cleavage of this form results in a highly deleterious double-strand break. This acceleration is dependent upon the position of the abasic lesion in the NCP and its structure. The enhancement in cleavage rate at an apurinic/apyrimidinic site rapidly drops off as the distance between the strand break and abasic site increases and is negligible once the two forms of damage are separated by 7 bp. However, the enhancement of the rate of double-strand break formation increases when the size of the gap is increased from one to two nucleotides. In contrast, the cleavage rate enhancement at 2-deoxyribonolactone within bistranded lesions is more modest, and it is similar in free DNA and nucleosome core particles. We postulate that the enhanced rate of double-strand break formation at bistranded lesions containing apurinic/apyrimidinic sites within nucleosome core particles is a general phenomenon and is due to increased DNA flexibility.