Protein lysine methyltransferases G9a and GLP modulate the transcriptional repression of a variety of genes via dimethylation of Lys9 on histone H3 (H3K9me2) as well as dimethylation of non-histone targets. Here we report the discovery of UNC0638, an inhibitor of G9a and GLP with excellent potency and selectivity over a wide range of epigenetic and non-epigenetic targets. UNC0638 treatment of a variety of cell lines resulted in lower global H3K9me2 levels, equivalent to levels observed for small hairpin RNA knockdown of G9a and GLP with the functional potency of UNC0638 being well separated from its toxicity. UNC0638 markedly reduced the clonogenicity of MCF7 cells, reduced the abundance of H3K9me2 marks at promoters of known G9a-regulated endogenous genes and disproportionately affected several genomic loci encoding microRNAs. In mouse embryonic stem cells, UNC0638 reactivated G9a-silenced genes and a retroviral reporter gene in a concentration-dependent manner without promoting differentiation.
The 3D structures of human therapeutic targets are enabling for drug discovery. However, their purification and crystallization remain rate determining. In individual cases, ligands have been used to increase the success rate of protein purification and crystallization, but the broad applicability of this approach is unknown. We implemented two screening platforms, based on either fluorimetry or static light scattering, to measure the increase in protein thermal stability upon binding of a ligand without the need to monitor enzyme activity. In total, 221 different proteins from humans and human parasites were screened against one or both of two sorts of small-molecule libraries. The first library comprised different salts, pH conditions, and commonly found small molecules and was applicable to all proteins. The second comprised compounds specific for protein families of particular interest (e.g., protein kinases). In 20 cases, including nine unique human protein kinases, a small molecule was identified that stabilized the proteins and promoted structure determination. The methods are cost-effective, can be implemented in any laboratory, promise to increase the success rates of purifying and crystallizing human proteins significantly, and identify new ligands for these proteins.chemical biology ͉ crystallography ͉ human S tructural, functional, and chemical genomics (proteomics) are disciplines that aim to determine the biochemical, cellular, and physiological functions of proteins on a genome scale. Many of the central, important experimental approaches that are involved, such as protein-based screens for small-molecule inhibitors, depend on the availability of purified and active proteins. To meet this demand, many large projects are devoted to developing methods to generate large numbers of purified proteins. However, the task is proving challenging: on average, for proteins from prokaryotes, only 50-70% of soluble proteins and 30% of membrane proteins can be readily expressed in recombinant form, and only 30-50% of these expressed proteins can be purified to homogeneity (1, 2). The success rates for human proteins are predicted to be significantly lower.To improve the general rates of protein purification, efforts have focused largely on alterations of the recombinant host, the expression conditions, changes of the construct encoding the protein, and the purification conditions. It is also known that the expression and purification of a protein can be improved significantly by the addition of a specific ligand, which serves to stabilize the protein, thereby reducing its propensity to unfold, aggregate, or succumb to proteolysis. This parameter has not been studied systematically, although in individual cases the addition of a specific ligand has had dramatic effects. For example, the recombinant expression of the guinea pig and human forms of the enzyme 11-hydroxysteroid dehydrogenase-1 in bacteria was increased dramatically by the addition of an inhibitor of the enzyme to the growing cells (3) Wu, K. L. Kav...
The eight mammalian Cbx proteins are chromodomain-containing proteins involved in regulation of heterochromatin, gene expression, and developmental programs. They are evolutionarily related to the Drosophila HP1 (dHP1) and Pc (dPc) proteins that are key components of chromatin-associated complexes capable of recognizing repressive marks such as trimethylated Lys-9 and Lys-27, respectively, on histone H3. However, the binding specificity and function of the human homologs, Cbx1–8, remain unclear. To this end we employed structural, biophysical, and mutagenic approaches to characterize the molecular determinants of sequence contextual methyllysine binding to human Cbx1–8 proteins. Although all three human HP1 homologs (Cbx1, -3, -5) replicate the structural and binding features of their dHP counterparts, the five Pc homologs (Cbx2, -4, -6, -7, -8) bind with lower affinity to H3K9me3 or H3K27me3 peptides and are unable to distinguish between these two marks. Additionally, peptide permutation arrays revealed a greater sequence tolerance within the Pc family and suggest alternative nonhistone sequences as potential binding targets for this class of chromodomains. Our structures explain the divergence of peptide binding selectivity in the Pc subfamily and highlight previously unrecognized features of the chromodomain that influence binding and specificity.
SAR exploration of the 2,4-diamino-6,7-dimethoxyquinazoline template led to the discovery of 8 (UNC0224) as a potent and selective G9a inhibitor. A high resolution X-ray crystal structure of the G9a-8 complex, the first co-crystal structure of G9a with a small molecule inhibitor, was obtained. The co-crystal structure validated our binding hypothesis and will enable structure-based design of novel inhibitors. 8 is a useful tool for investigating the biology of G9a and its roles in chromatin remodeling.Multicellular organisms have evolved elaborate mechanisms to enable differential and celltype specific expression of genes. Epigenetics refers to these heritable changes in how the genome is accessed in different cell-types and during development and differentiation. This capability permits specialization of function between cells even though each cell contains the same genome. Over the last decade, the cellular machinery that creates these heritable changes has been the subject of intense scientific investigation as there is no area of biology or for that matter no area of human health, where epigenetics may not play a fundamental role. 1 The template upon which the epigenome is written is chromatin -the complex of histone proteins, RNA and DNA that efficiently package the genome in an appropriately accessible state within each cell. The state of chromatin, and therefore access to the genetic code, is mainly regulated by covalent and reversible PTMs to histone proteins and DNA, and the recognition of these marks by other proteins and protein complexes. The PTMs of histones and DNA include: histone lysine methylation, arginine methylation, lysine acetylation, sumoylation, † The coordinates and structure factors of UNC0224 co-crystallized with G9a have been deposited in the Protein Data Bank (www.pdb.org, PDB code 3K5K). ubiquitination, glycosylation and phosphorylation, and DNA methylation. 2 Given the wide-spread importance of chromatin regulation to cell biology, the enzymes that produce these modifications (the 'writers'), the proteins that recognize them (the 'readers'), and the enzymes that remove them (the 'erasers') are critical targets for manipulation in order to further understand the histone code 3, 4 and its role in human disease. Indeed, small molecule histone de-acetylase inhibitors5 and DNA methyltransferase inhibitors6 have already proven useful in the treatment of cancer.Histone lysine methylation refers to covalent methylation of histone lysine tails to produce mono-,di-, or trimethylated states. Among a myriad of PTMs, histone lysine methylation catalyzed by histone lysine methyltransferases (HMTs) has received great attention because of its essential function in many biological processes including gene expression and transcriptional regulation, heterochromatin formation, and X-chromosome inactivation. 7 It is therefore considered to be one of the most significant PTMs of histones. Since the first HMT was characterized in 20008, more than 50 human histone methyltransferases have been ...
In the ubiquitin-proteasome system (UPS), E2 enzymes mediate the conjugation of ubiquitin to substrates and thereby control protein stability and interactions. The E2 enzyme hCdc34 catalyzes the ubiquitination of hundreds of proteins in conjunction with the cullin-RING (CRL) superfamily of E3 enzymes. We identified a small molecule termed CC0651 that selectively inhibits hCdc34. Structure determination revealed that CC0651 inserts into a cryptic binding pocket on hCdc34 distant from the catalytic site, causing subtle but wholesale displacement of E2 secondary structural elements. CC0651 analogs inhibited proliferation of human cancer cell lines and caused accumulation of the SCF(Skp2) substrate p27(Kip1). CC0651 does not affect hCdc34 interactions with E1 or E3 enzymes or the formation of the ubiquitin thioester but instead interferes with the discharge of ubiquitin to acceptor lysine residues. E2 enzymes are thus susceptible to noncatalytic site inhibition and may represent a viable class of drug target in the UPS.
Protein lysine methyltransferase G9a, which catalyzes methylation of lysine 9 of histone H3 (H3K9) and lysine 373 (K373) of p53, is over expressed in human cancers. Genetic knockdown of G9a inhibits cancer cell growth and the di-methylation of p53 K373 results in the inactivation of p53. Initial SAR exploration of the 2,4-diamino-6,7-dimethoxyquinazoline template represented by 3a (BIX01294), a selective small molecule inhibitor of G9a and GLP, led to the discovery of 10 (UNC0224) as a potent G9a inhibitor with excellent selectivity. A high resolution X-ray crystal structure of the G9a-10 complex, the first co-crystal structure of G9a with a small molecule inhibitor, was obtained. Based on the structural insights revealed by this co-crystal structure, optimization of the 7-dimethylaminopropoxy side chain of 10 resulted in the discovery of 29 (UNC0321) (Morrison K i = 63 pM), which is the first G9a inhibitor with picomolar potency and the most potent G9a inhibitor to date.
PRMT3, a protein arginine methyltransferase, has been shown to influence ribosomal biosynthesis by catalyzing the dimethylation of the 40S ribosomal protein S2. Although PRMT3 has been reported to be a cytosolic protein, it has been shown to methylate histone H4 peptide (H4 1-24) in vitro. Here, we report the identification of a PRMT3 inhibitor (1-(benzo[d][1,2,3]thiadiazol-6-yl)-3-(2-cyclohexenylethyl)urea; compound 1) with IC50 value of 2.5 μM by screening a library of 16,000 compounds using H4 (1-24) peptide as a substrate. The crystal structure of PRMT3 in complex with compound 1 as well as kinetic analysis reveals an allosteric mechanism of inhibition. Mutating PRMT3 residues within the allosteric site or using compound 1 analogs that disrupt interactions with allosteric site residues both abrogated binding and inhibitory activity. These data demonstrate an allosteric mechanism for inhibition of protein arginine methyltransferases, an emerging class of therapeutic targets.
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