Quantitative analysis of CBP- and P300-induced histone acetylations in vivo using native chromatin

In vivo, histone tails are involved in numerous interactions, including those with DNA, adjacent histones, and other, nonhistone proteins. The amino termini are also the substrates for a number of enzymes, including histone acetyltransferases (HATs), histone deacetylases, and histone methyltransferases. Traditional biochemical approaches defining the substrate specificity profiles of HATs have been performed using purified histone tails, recombinant histones, or purified mononucleosomes as substrates. It is clear that the in vivo presentation of the substrate cannot be accurately represented by using these in vitro approaches. Because of the difficulty in translating in vitro results into in vivo situations, we developed a novel single-cell HAT assay that provides quantitative measurements of endogenous HAT activity. The HAT assay is performed under in vivo conditions by using the native chromatin structure as the physiological substrate. The assay combines the spatial resolving power of laser scanning confocal microscopy with simple statistical analyses to characterize CREB binding protein (CBP)- and P300-induced changes in global histone acetylation levels at specific lysine residues. Here we show that CBP and P300 exhibit unique substrate specificity profiles, consistent with the developmental and functional differences between the two HATs.     

Histone modifying enzymes: structures, mechanisms, and specificities

Histone modifying enzymes catalyze the addition or removal of an array of covalent modifications in histone and non-histone proteins. Within the context of chromatin, these modifications regulate gene expression as well as other genomic functions and have been implicated in establishing and maintaining a heritable epigenetic code that contributes to defining cell identity and fate. Biochemical and structural characterization of histone modifying enzymes has yielded important insights into their respective catalytic mechanisms, substrate specificities, and regulation. In this review, we summarize recent advances in understanding these enzymes, highlighting studies of the histone acetyltransferases (HATs) p300 (also now known as KAT3B) and Rtt109 (KAT11) and the histone lysine demethylases (HDMs) LSD1 (KDM1) and JMJD2A (KDM4A), present overriding themes that derive from these studies, and pose remaining questions concerning their regulatory roles in mediating DNA transactions.     

A novel non-SET domain multi-subunit methyltransferase required for sequential nucleosomal histone H3 methylation by the mixed lineage leukemia protein-1 (MLL1) core complex

Gene expression within the context of eukaryotic chromatin is regulated by enzymes that catalyze histone lysine methylation. Histone lysine methyltransferases that have been identified to date possess the evolutionarily conserved SET or Dot1-like domains. We previously reported the identification of a new multi-subunit histone H3 lysine 4 methyltransferase lacking homology to the SET or Dot1 family of histone lysine methyltransferases. This enzymatic activity requires a complex that includes WRAD (WDR5, RbBP5, Ash2L, and DPY-30), a complex that is part of the MLL1 (mixed lineage leukemia protein-1) core complex but that also exists independently of MLL1 in the cell. Here, we report that the minimal complex required for WRAD enzymatic activity includes WDR5, RbBP5, and Ash2L and that DPY-30, although not required for enzymatic activity, increases the histone substrate specificity of the WRAD complex. We also show that WRAD requires zinc for catalytic activity, displays Michaelis-Menten kinetics, and is inhibited by S-adenosyl-homocysteine. In addition, we demonstrate that WRAD preferentially methylates lysine 4 of histone H3 within the context of the H3/H4 tetramer but does not methylate nucleosomal histone H3 on its own. In contrast, we find that MLL1 and WRAD are required for nucleosomal histone H3 methylation, and we provide evidence suggesting that each plays distinct structural and catalytic roles in the recognition and methylation of a nucleosome substrate. Our results indicate that WRAD is a new H3K4 methyltransferase with functions that include regulating the substrate and product specificities of the MLL1 core complex.     

MassSQUIRM

In eukaryotes, DNA is wrapped around proteins called histones and is condensed into chromatin. Post-translational modification of histones can result in changes in gene expression. One of the most well-studied histone modifications is the methylation of lysine 4 on histone H3 (H3K4). This residue can be mono-, di- or tri-methylated and these varying methylation states have been associated with different levels of gene expression. Understanding exactly what the purpose of these methylation states is, in terms of gene expression, has been a topic of much research in recent years. Enzymes that can add (methyltransferases) and remove (demethylases) these modifications are of particular interest. The first demethylase discovered, LSD1, is the most well-classified and has been implicated in contributing to human cancers and to DNA damage response pathways. Currently, there are limited methods for accurately studying the activity of demethylases in vitro or in vivo. In this work, we present MassSQUIRM (mass spectrometric quantitation using isotopic reductive methylation), a quantitative method for studying the activity of demethylases capable of removing mono- and di-methyl marks from lysine residues. We focus specifically on LSD1 due to its potential as a prime therapeutic target for human disease. This quantitative approach will enable better characterization of the activity of LSD1 and other chromatin modifying enzymes in vitro, in vivo or in response to inhibitors.     

Chromatin-associated protein kinases specific for acidic proteins

Protein kinases (EC 2.7.1.37) were eluted by 0.4 NaCl from chromatin of several mammalian cell typs. The enzymes were partially purified by ion-exchange chromatography, DNA-cellulose columns and sucrose gradient centrifugation. At least five different enzymes could be distinguished by their biochemical properties and their substrate specificities. Three of the enzyme activities tested phosphorylate different sets of histones, while two enzymes phosphorylate acidic nonhistone chromatin proteins or artificial substrates like casein and phosvitin. The two nonhistone protein kinases have slightly different pH and salt optima. They sediment through sucrose gradients with approx. 4 S and approx. 8 S, respectively. These enzymes are further characterized by their different substrate specificity, since they phosphorylate different, though partially overlapping sets of nonhistone chromatin proteins. Enzymes with these properties were deteced in chromatin from mouse ascites cells, bovine lymphocytes, African green monkey kidney cells and a human SV40 transformed cell line.     

Structure of histone acetyltransferases

Histone acetyltranferase (HAT) enzymes are the catalytic subunits of multisubunit protein complexes that acetylate specific lysine residues on the N-terminal regions of the histone components of chromatin to promote gene activation. These enzymes, which now include more than 20 members, fall into distinct families that generally have high sequence similarity and related substrate specificity within families, but have divergent sequence and substrate specificity between families. Significant insights into the mode of catalysis and histone substrate binding have been provided by the structure determination of the divergent HAT enzymes Hat1, Gcn5/PCAF and Esa1. A comparison of these structures reveals a structurally conserved central core domain that mediates extensive interactions with the acetyl-coenzyme A cofactor, and structurally divergent N and C-terminal domains. A correlation of these structures with other studies reveals that the core domain plays a particularly important role in histone substrate catalysis and that the N and C-terminal domains play important roles in histone substrate binding. These correlations imply a related mode of catalysis and histone substrate binding by a diverse group of HAT enzymes.     

Chemical probes for histone-modifying enzymes

The histone-modifying enzymes that catalyze reversible lysine acetylation and methylation are central to the epigenetic regulation of chromatin remodeling. From the early discovery of histone deacetylase inhibitors to the more recent identification of histone demethylase blockers, chemical approaches offer increasingly sophisticated tools for the investigation of the structure and function of these lysine-modifying enzymes. This review summarizes progress to date on compounds identified from screens or by design that can modulate the activity of classical histone deacetylases, sirtuins, histone acetyltransferases, histone methyltransferases and histone demethylases. We highlight applications of compounds to mechanistic and functional studies involving these enzymes and discuss future challenges regarding target specificity and general utility.     

Chlorambucil-sensitive and -resistant lymphoid cells display different responses to the histone deacetylase inhibitor, sodium butyrate

Clinical chemoresistance is a frequent complication of alkylating agent treatment of malignant tumours. Chromatin remodelling using histone deacetylase inhibitors (e.g., sodium butyrate, NaBu) may increase target cell chemosensitivity. Apoptotic responses and expression of chromatin modifying enzymes in lymphoid cell lines, LP-1 and NCI-H929, to chlorambucil (CLB) and/or NaBu were examined in this study. NaBu augmented the apoptotic response in CLB-resistant LP-1 cells but antagonised it in CLB-sensitive NCI-H929 cells. CLB increased expression of methyltransferase I and histone acetyltransferase I in both cell lines while NaBu had only small effect. CLB-induced increased gene expression was attenuated by NaBu in CLB-sensitive NCI-H929 cells but not in resistant LP-1 cells. These results suggest that chromatin modifying agents may have differential effects on cells depending on their chemosensitivity.     

MassSQUIRM: An assay for quantitative measurement of lysine demethylase activity

In eukaryotes, DNA is wrapped around proteins called histones and is condensed into chromatin. Post-translational modification of histones can result in changes in gene expression. One of the most well-studied histone modifications is the methylation of lysine 4 on histone H3 (H3K4). This residue can be mono-, di- or tri-methylated and these varying methylation states have been associated with different levels of gene expression. Understanding exactly what the purpose of these methylation states is, in terms of gene expression, has been a topic of much research in recent years. Enzymes that can add (methyltransferases) and remove (demethylases) these modifications are of particular interest. The first demethylase discovered, LSD1, is the most well-classified and has been implicated in contributing to human cancers and to DNA damage response pathways. Currently, there are limited methods for accurately studying the activity of demethylases in vitro or in vivo. In this work, we present MassSQUIRM (mass spectrometric quantitation using isotopic reductive methylation), a quantitative method for studying the activity of demethylases capable of removing mono- and di-methyl marks from lysine residues. We focus specifically on LSD1 due to its potential as a prime therapeutic target for human disease. This quantitative approach will enable better characterization of the activity of LSD1 and other chromatin modifying enzymes in vitro, in vivo or in response to inhibitors.Key words: LSD1, lysine demethylase, mass spectrometry, reductive methylation, monoamine oxidase (MAO) inhibitors     

An H3 histone-specific kinase isolated from bovine thymus chromatin.

A substantial portion of the histone phosphorylating activity of bovine thymus chromatin can be isolated by extraction in 0.2 M NaCl. The specificity of this extract for either free histones or washed chromatin substrates was compared. The salt-extracted kinase enzymes favor H2b as the major acceptor when whole free histone is the substrate and H3 when the substrate is intact chromatin. The H3 kinase activity of bovine thymus tissue has been purified free from other detectable histone kinase activities by ammonium sulfate fractionation and is highly specific for H3 histone when assayed either with chromatin or isolated whole histone. The activity is cAMP-independent. Tryptic peptide mapping of the labeled H3 histone reveals a single site of phosphorylation. This site appears to be identical with the major site of metaphase-associated H3 phosphorylation in hepatoma tissue culture cells. No corresponding H3 phosphorylation has been detected in thymus tissue in vivo.