Mechanism of histone lysine methyl transfer revealed by the structure of SET7/9-AdoMet

The methylation of lysine residues of histones plays a pivotal role in the regulation of chromatin structure and gene expression. Here, we report two crystal structures of SET7/9, a histone methyltransferase (HMTase) that transfers methyl groups to Lys4 of histone H3, in complex with S-adenosyl-L-methionine (AdoMet) determined at 1.7 and 2.3 A resolution. The structures reveal an active site consisting of: (i) a binding pocket between the SET domain and a c-SET helix where an AdoMet molecule in an unusual conformation binds; (ii) a narrow substrate-specific channel that only unmethylated lysine residues can access; and (iii) a catalytic tyrosine residue. The methyl group of AdoMet is directed to the narrow channel where a substrate lysine enters from the opposite side. We demonstrate that SET7/9 can transfer two but not three methyl groups to unmodified Lys4 of H3 without substrate dissociation. The unusual features of the SET domain-containing HMTase discriminate between the un- and methylated lysine substrate, and the methylation sites for the histone H3 tail.     

赖氨酸特异性组蛋白去甲基化酶1作用机制及其生物学功能的研究进展

与其他化学修饰,如乙酰化、磷酸化、泛素化等相似,组蛋白赖氨酸甲基化是一个可以逆转的组蛋白修饰,是一个动态调节的过程。赖氨酸特异性组蛋白去甲基化酶1（lysine specific demethylase 1,LSD1）是一个黄素腺嘌呤二核苷酸（flavin adenine dinulcleotide,FAD）依赖性胺氧化酶,它能够特异性脱去H3K4和H3K9位点上的单甲基化和二甲基化的甲基基团。LSD1参与调控核受体介导的基因转录,并分别维持染色质的活性和非活性状态,被誉为细胞深处的基因＂开关＂。LSD1的功能失衡可引发多种重要生命现象的改变。主要综述LSD1的结构、作用机制及其在肿瘤发生、胚胎发育、体细胞重编程的调控、细胞分裂和造血等过程中生物学功能的研究新进展。     

A Novel Mammalian Flavin-dependent Histone Demethylase

Methylation of Lys residues on histone proteins is a well known and extensively characterized epigenetic mark. The recent discovery of lysine-specific demethylase 1 (LSD1) demonstrated that lysine methylation can be dynamically controlled. Among the histone demethylases so far identified, LSD1 has the unique feature of functioning through a flavin-dependent amine oxidation reaction. Data base analysis reveals that mammalian genomes contain a gene (AOF1, for amine-oxidase flavin-containing domain 1) that is homologous to the LSD1-coding gene. Here, we demonstrate that the protein encoded by AOF1 represents a second mammalian flavin-dependent histone demethylase, named LSD2. The new demethylase is strictly specific for mono- and dimethylated Lys⁴ of histone H3, recognizes a long stretch of the H3 N-terminal tail, senses the presence of additional epigenetic marks on the histone substrate, and is covalently inhibited by tranylcypromine. As opposed to LSD1, LSD2 does not form a biochemically stable complex with the C-terminal domain of the corepressor protein CoREST. Furthermore, LSD2 contains a CW-type zinc finger motif with potential zinc-binding sites that are not present in LSD1. We conclude that mammalian LSD2 represents a new flavin-dependent H3-Lys⁴ demethylase that features substrate specificity properties highly similar to those of LSD1 but is very likely to be part of chromatin-remodeling complexes that are distinct from those involving LSD1.     

Structure of the conserved core of the yeast Dot1p, a nucleosomal histone H3 lysine 79 methyltransferase

Methylation of Lys79 on histone H3 by Dot1p is important for gene silencing. The elongated structure of the conserved core of yeast Dot1p contains an N-terminal helical domain and a seven-stranded catalytic domain that harbors the binding site for the methyl-donor and an active site pocket sided with conserved hydrophobic residues. The S-adenosyl-L-homocysteine exhibits an extended conformation distinct from the folded conformation observed in structures of SET domain histone lysine methyltransferases. A catalytic asparagine (Asn479), located at the bottom of the active site pocket, suggests a mechanism similar to that employed for amino methylation in DNA and protein glutamine methylation. The acidic, concave cleft between the two domains contains two basic residue binding pockets that could accommodate the outwardly protruding basic side chains around Lys79 of histone H3 on the disk-like nucleosome surface. Biochemical studies suggest that recombinant Dot1 proteins are active on recombinant nucleosomes, free of any modifications.     

Three-dimensional structures of fibrillar Sm proteins: Hfq and other Sm-like proteins

SET domain lysine methyltransferases are known to catalyze site and state-specific methylation of lysine residues in histones that is fundamental in epigenetic regulation of gene activation and silencing in eukaryotic organisms. Here we report the three-dimensional solution structure of the SET domain histone lysine methyltransferase (vSET) from Paramecium bursaria chlorella virus 1 bound to cofactor S-adenosyl-L-homocysteine and a histone H3 peptide containing mono-methylated lysine 27. The dimeric structure, mimicking an enzyme/cofactor/substrate complex, yields the structural basis of the substrate specificity and methylation multiplicity of the enzyme. Our results from mutagenesis and enzyme kinetics analyses argue that a general base mechanism is less likely for lysine methylation by SET domains; and that the only invariant active site residue tyrosine 105 in vSET facilitates methyl transfer from cofactor to the substrate lysine by aligning intermolecular interactions in the lysine access channel of the enzyme.     

组蛋白去甲基化酶LSD1及其生物学功能

赖氨酸特异性组蛋白去甲基化酶1(Lysine specific demethylase 1, LSD1) 的发现, 表明组蛋白的甲基化修饰是一个动态可调节的过程。结构分析显示, LSD1 是一个黄素腺嘌呤二核苷酸(Flavin adenine dinulcleotide, FAD) 依赖性胺氧化酶, 它能够特异性脱去单甲基化和二甲基化组蛋白H3第4位赖氨酸(H3K4) 和H3K9 位点上的甲基基团。功能研究显示, LSD1 定位于细胞核内, 调控着基因转录的激活和抑制, 被誉为细胞深处的基因“开关”, 在胚胎发育和肿瘤发生过程中起着重要的作用。文章主要综述了LSD1 的结构、作用机制及其调控作用研究的新进展。     

Human histone demethylase LSD1 reads the histone code

Human histone demethylase LSD1 is a flavin-dependent amine oxidase that catalyzes the specific removal of methyl groups from mono- and dimethylated Lys4 of histone H3. The N-terminal tail of H3 is subject to various covalent modifications, and a fundamental question in LSD1 biology is how these epigenetic marks affect the demethylase activity. We show that LSD1 does not have a strong preference for mono- or dimethylated Lys4 of H3. Substrate recognition is not confined to the residues neighboring Lys4, but it requires a sufficiently long peptide segment consisting of the N-terminal 20 amino acids of H3. Electrostatic interactions are an important factor in protein-substrate recognition, as indicated by the high sensitivity of Km to ionic strength. We have probed LSD1 for its ability to demethylate Lys4 in presence of a second modification on the same peptide substrate. Methylation of Lys9 does not affect enzyme catalysis. Conversely, Lys9 acetylation causes an almost 6-fold increase in the Km value, whereas phosphorylation of Ser10 totally abolishes activity. LSD1 is inhibited by a demethylated peptide with an inhibition constant of 1.8 microM, suggesting that LSD1 can bind to H3 independently of Lys4 methylation. LSD1 is a chromatin-modifying enzyme, which is able to read different epigenetic marks on the histone N-terminal tail and can serve as a docking module for the stabilization of the associated corepressor complex(es) on chromatin.     

Histone demethylation catalysed by LSD1 is a flavin-dependent oxidative process

Lysine-specific histone demethylase 1 (LSD1) is a very recently discovered enzyme which specifically removes methyl groups from Lys4 of histone 3. We have addressed the functional properties of the protein demonstrating that histone demethylation involves the flavin-catalysed oxidation of the methylated lysine. The nature of the substrate that acts as the electron acceptor required to complete the catalytic cycle was investigated. LSD1 converts oxygen to hydrogen peroxide although this reactivity is not as pronounced as that of other flavin-dependent oxidases. Our findings raise the possibility that in vivo LSD1 might not necessarily function as an oxidase, but it might use alternative electron acceptors.     

Structural Insights into Estrogen Receptor α Methylation by Histone Methyltransferase SMYD2, a Cellular Event Implicated in Estrogen Signaling Regulation

Estrogen receptor (ER) signaling plays a pivotal role in many developmental processes and has been implicated in numerous diseases including cancers. We recently showed that direct ERα methylation by the multi-specificity histone lysine methyltransferase SMYD2 regulates estrogen signaling through repressing ERα-dependent transactivation. However, the mechanism controlling the specificity of the SMYD2–ERα interaction and the structural basis of SMYD2 substrate binding diversity are unknown. Here we present the crystal structure of SMYD2 in complex with a target lysine (Lys266)-containing ERα peptide. The structure reveals that ERα binds SMYD2 in a U-shaped conformation with the binding specificity determined mainly by residues C-terminal to the target lysine. The structure also reveals numerous intrapeptide contacts that ensure shape complementarity between the substrate and the active site of the enzyme, thereby likely serving as an additional structural determinant of substrate specificity. In addition, comparison of the SMYD2–ERα and SMYD2–p53 structures provides the first structural insight into the diverse nature of SMYD2 substrate recognition and suggests that the broad specificity of SMYD2 is achieved by multiple molecular mechanisms such as distinct peptide binding modes and the intrinsic dynamics of peptide ligands. Strikingly, a novel potentially SMYD2-specific polyethylene glycol binding site is identified in the CTD domain, implicating possible functions in extended substrate binding or protein–protein interactions. Our study thus provides the structural basis for the SMYD2-mediated ERα methylation, and the resulting knowledge of SMYD2 substrate specificity and target binding diversity could have important implications in selective drug design against a wide range of ERα-related diseases.     

SET domain proteins in plant development

Post-translational methylation of lysine residues on histone tails is an epigenetic modification crucial for regulation of chromatin structure and gene expression in eukaryotes. The majority of the histone lysine methyltransferases (HKMTases) conferring such modifications are proteins with a conserved SET domain responsible for the enzymatic activity. The SET domain proteins in the model plant Arabidopsis thaliana can be assigned to evolutionarily conserved classes with different specificities allowing for different outcomes on chromatin structure. Here we review the present knowledge of the biochemical and biological functions of plant SET domain proteins in developmental processes. This article is part of a Special Issue entitled: Epigenetic control of cellular and developmental processes in plants.