Volker Badock

Affinity Map of Bromodomain Protein 4 (BRD4) Interactions with the Histone H4 Tail and the Small Molecule Inhibitor JQ1

Background: BRD4 is a reader of acetylated histones. Results: Mutational analysis of BRD4 BD1 allowed the identification of three groups with different binding profiles. Conclusion: Pro-82, Leu-94, Asp-145, and Ile-146 have a differentiated role in acetyl-lysine and inhibitor interaction. Significance: Identification of residues essential for BRD4 function will guide the design of novel inhibitors. Bromodomain protein 4 (BRD4) is a member of the bromodomain and extra-terminal domain (BET) protein family. It binds to acetylated histone tails via its tandem bromodomains BD1 and BD2 and forms a complex with the positive transcription elongation factor b, which controls phosphorylation of RNA polymerase II, ultimately leading to stimulation of transcription elongation. An essential role of BRD4 in cell proliferation and cancer growth has been reported in several recent studies. We analyzed the binding of BRD4 BD1 and BD2 to different partners and showed that the strongest interactions took place with di- and tetra-acetylated peptides derived from the histone 4 N-terminal tail. We also found that several histone 4 residues neighboring the acetylated lysines significantly influenced binding. We generated 10 different BRD4 BD1 mutants and analyzed their affinities to acetylated histone tails and to the BET inhibitor JQ1 using several complementary biochemical and biophysical methods. The impact of these mutations was confirmed in a cellular environment. Altogether, the results show that Trp-81, Tyr-97, Asn-140, and Met-149 play similarly important roles in the recognition of acetylated histones and JQ1. Pro-82, Leu-94, Asp-145, and Ile-146 have a more differentiated role, suggesting that different kinds of interactions take place and that resistance mutations compatible with BRD4 function are possible. Our study extends the knowledge on the contribution of individual BRD4 amino acids to histone and JQ1 binding and may help in the design of new BET antagonists with improved pharmacological properties.

Structural analysis of human KDM5B guides histone demethylase inhibitor development.

Members of the KDM5 (also known as JARID1) family are 2-oxoglutarate- and Fe(2+)-dependent oxygenases that act as histone H3K4 demethylases, thereby regulating cell proliferation and stem cell self-renewal and differentiation. Here we report crystal structures of the catalytic core of the human KDM5B enzyme in complex with three inhibitor chemotypes. These scaffolds exploit several aspects of the KDM5 active site, and their selectivity profiles reflect their hybrid features with respect to the KDM4 and KDM6 families. Whereas GSK-J1, a previously identified KDM6 inhibitor, showed about sevenfold less inhibitory activity toward KDM5B than toward KDM6 proteins, KDM5-C49 displayed 25-100-fold selectivity between KDM5B and KDM6B. The cell-permeable derivative KDM5-C70 had an antiproliferative effect in myeloma cells, leading to genome-wide elevation of H3K4me3 levels. The selective inhibitor GSK467 exploited unique binding modes, but it lacked cellular potency in the myeloma system. Taken together, these structural leads deliver multiple starting points for further rational and selective inhibitor design.

Discovery and Characterization of a Highly Potent and Selective Aminopyrazoline-Based in Vivo Probe (BAY-598) for the Protein Lysine Methyltransferase SMYD2

Protein lysine methyltransferases have recently emerged as a new target class for the development of inhibitors that modulate gene transcription or signaling pathways. SET and MYND domain containing protein 2 (SMYD2) is a catalytic SET domain containing methyltransferase reported to monomethylate lysine residues on histone and nonhistone proteins. Although several studies have uncovered an important role of SMYD2 in promoting cancer by protein methylation, the biology of SMYD2 is far from being fully understood. Utilization of highly potent and selective chemical probes for target validation has emerged as a concept which circumvents possible limitations of knockdown experiments and, in particular, could result in an improved exploration of drug targets with a complex underlying biology. Here, we report the development of a potent, selective, and cell-active, substrate-competitive inhibitor of SMYD2, which is the first reported inhibitor suitable for in vivo target validation studies in rodents.

ATAD2 is an epigenetic reader of newly synthesized histone marks during DNA replication.

ATAD2 (ATPase family AAA domain-containing protein 2) is a chromatin regulator harboring an AAA+ ATPase domain and a bromodomain, previously proposed to function as an oncogenic transcription co-factor. Here we suggest that ATAD2 is also required for DNA replication. ATAD2 is co-expressed with genes involved in DNA replication in various cancer types and predominantly expressed in S phase cells where it localized on nascent chromatin (replication sites). Our extensive biochemical and cellular analyses revealed that ATAD2 is recruited to replication sites through a direct interaction with di-acetylated histone H4 at K5 and K12, indicative of newly synthesized histones during replication-coupled chromatin reassembly. Similar to ATAD2-depletion, ectopic expression of ATAD2 mutants that are deficient in binding to these di-acetylation marks resulted in reduced DNA replication and impaired loading of PCNA onto chromatin, suggesting relevance of ATAD2 in DNA replication. Taken together, our data show a novel function of ATAD2 in cancer and for the first time identify a reader of newly synthesized histone di-acetylation-marks during replication.

Isoform-Selective ATAD2 Chemical Probe with Novel Chemical Structure and Unusual Mode of Action

ATAD2 (ANCCA) is an epigenetic regulator and transcriptional cofactor, whose overexpression has been linked to the progress of various cancer types. Here, we report a DNA-encoded library screen leading to the discovery of BAY-850, a potent and isoform selective inhibitor that specifically induces ATAD2 bromodomain dimerization and prevents interactions with acetylated histones in vitro, as well as with chromatin in cells. These features qualify BAY-850 as a chemical probe to explore ATAD2 biology.

Crystallization and molecular‐replacement solution of a diagnostic fluorescent dye in complex with a specific Fab fragment

Tetrasulfocyanine (TSC) has been described as a fluorescent probe for tumour imaging. The complex of TSC and the Fab antibody fragment MOR03268 has been crystallized in three different crystal forms. MOR03268 was identified from the HuCAL GOLD library and further optimized to bind TSC with high affinity (Kd = 0.6 nM). For two of the three crystal forms (forms 1 and 2), data sets could be collected to 2.8 and 2.85 A resolution, respectively. Form 1 belongs to space group I222, with unit-cell parameters a = 72, b = 99, c = 154 A. Form 2 belongs to space group P4(3)2(1)2, with unit-cell parameters a = b = 77, c = 379 A. Form 3 only diffracted to 8 A and was not analyzed further. Molecular-replacement solutions for forms 1 and 2 were found and rebuilding and refinement is in progress. Form 1 contains one Fab molecule per asymmetric unit, while form 2 harbours two. Judging from the green colour of the crystals, both forms contain the Fab molecule bound to the green TSC dye and in both the hydrolysis-sensitive dye molecule is protected from degradation for several weeks to months. The structures should reveal the molecular basis of the high-affinity recognition of TSC by the Fab molecule MOR03268.

Abstract 5239: Probing the cancer epigenome: empowering target validation by open innovation

Low reproducibility of published target validation studies as well as the frequent failure of genetic knock-down effects to phenocopy those of small molecule inhibitors have been recognized as road blocks for cancer drug discovery. Academic and industrial institutions have started to address these issues by providing access to high quality small molecular probes for novel targets of interest. Here we discuss probe discovery challenges and quality criteria based on the generation of three novel inhibitors for epigenetic targets. ATAD2 (ATPase family AAA-domain containing protein 2) is an epigenetic regulator that binds to chromatin through its bromodomain (BD). ATAD2 has been proposed to act as a co-factor for oncogenic transcription factors such as ERα and Myc. A more thorough validation of ATAD2 as a therapeutic target has been hampered by the lack of appropriate ATAD2 inhibitors. Here we disclose a structurally unprecedented series of ATAD2 BD inhibitors identified from a DNA-encoded library screen. Optimization delivered BAY-850, a highly potent and exceptionally selective ATAD2 BD inhibitor, which fully recapitulates effects seen by genetic mutagenesis studies in a cellular assay. The three BD and PHD-finger (BRPF) family members are found in histone acetyltransferase complexes. Whereas bromodomain inhibitors with dual activity against BRPF1 and 2 have been described before, we now disclose BAY-299, the first nanomolar inhibitor of the BRPF2 BD with high selectivity against its paralogs. Isoform selectivity was confirmed in cellular protein-protein interaction assays and rationalized based on X-Ray structures. BAY-598, a highly selective, cellularly active and orally bioavailable inhibitor of the protein lysine methyl transferase SMYD2, had been disclosed previously (Stresemann et al., AACR 2015). Development of BAY-598 allowed the identification of new methylation targets of SMYD2 as well as a proposed role of SMYD2 in pancreatic cancer. These results support further development of small molecule inhibitors as research tools to probe the functional role of novel epigenetic targets and underscore the power of open innovation for advancing our understanding of cancer target biology. Citation Format: Ingo V. Hartung, Cheryl Arrowsmith, Volker Badock, Naomi Barak, Markus Berger, Peter J. Brown, Clara D. Christ, Erik Eggert, Ursula Egner, Oleg Fedorov, Amaury E. Fernandez-Montalvan, Matyas Gorjanacz, Andrea Haegebarth, Bernard Haendler, Roman C. Hillig, Simon H. Holton, Kilian V. Huber, Seong J. Koo, Antonius ter Laak, Susanne Mueller, Anke Mueller-Fahrnow, Cora Scholten, Stephan Siegel, Timo Stellfeld, Detlef Stoeckigt, Carlo Stresemann, Masoud Vedadi, Joerg Weiske, Hilmar Weinmann. Probing the cancer epigenome: empowering target validation by open innovation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5239. doi:10.1158/1538-7445.AM2017-5239

Abstract 5084: Potent and isoform-selective ATAD2 bromodomain inhibitor with unprecedented chemical structure and mode of action

ATAD2 (ATPase family AAA-domain containing protein 2, also called ANCCA) is an epigenetic regulator that binds to chromatin through its bromodomain (BD), a motif specialized for acetyl-lysine recognition. ATAD2 directly associates with multiple transcription factors such as ERα, AR, E2F, and Myc; hence, ATAD2 has been proposed to act as a co-factor for oncogenic transcription factors. Furthermore, we have recently reported a novel role for ATAD2 during DNA replication, uncovering interactions between ATAD2 and histone acetylation marks on newly synthesized histone H4. High expression of ATAD2 strongly correlates with poor patient prognosis in multiple tumor types, including gastric, endometrial, hepatocellular, ovarian, breast and lung cancers. However, the exact function of ATAD2 in these tumor types remains unclear. A more thorough validation of ATAD2 as a therapeutic target is hampered by the lack of isoform-selective, potent and cellularly active ATAD2 inhibitors. A systematic assessment of crystal structures of BD-containing protein family predicted that development of selective inhibitors of ATAD2 would be challenging. In line with this prediction, only limited progress in developing lead compounds targeting ATAD2 has been reported so far. A few notable exceptions relied on fragments as starting points, however, their weak potency, insufficient selectivity against other BDs, permeability limitations or modest cellular activity have curbed their further development towards drug candidates. Here we embarked on a novel strategy to identify ATAD2 inhibitors: 11 different DNA-encoded libraries adding up to 67 billion unique encoded compounds were combined and incubated with ATAD2 BD followed by two rounds of affinity-mediated selection. This approach provided with several series of binders, for which specific target engagement of their SMOL moiety upon off-DNA synthesis was confirmed in biochemical and biophysical assays. Several rounds of potency optimization led to the identification of BAY-850, a highly potent and ATAD2 (isoform A) mono-selective inhibitor, which holds an amine substituted 3-(2-furyl)benzamide core. This compound shows - as revealed by size exclusion chromatography and native mass spectrometry - a novel mode of action for a BD inhibitor based on specific target dimerization. In a cellular fluorescence recovery after photobleaching (FRAP) assay BAY-850 displaced wild-type ATAD2 from the chromatin to the same extent as the genetic mutagenesis of ATAD2 BD. In contrast, chemically very similar inactive control compounds showed no major effects on ATAD2 association with the chromatin. These results qualify BAY-850 as the first biologically active ATAD2 isoform A-specific chemical probe, which will enable further elucidation of the cancer biology of this intriguing protein. Citation Format: Amaury E. Fernandez-Montalvan, Markus Berger, Benno Kuropka, Seong Joo Koo, Volker Badock, Joerg Weiske, Simon J. Holton, Apirat Chaikuad, Laura Diaz-Saez, James Bennett, Oleg Federov, Kilian Huber, Paolo Centrella, Matthew A. Clark, Christoph E. Dumelin, Eric A. Sigel, Holly S. Soutter, Dawn M. Troast, Ying Zhang, John W. Cuozzo, Anthony D. Keefe, Didier Roche, Vincent Rodeschini, Jan Hubner, Hilmar Weinmann, Ingo V. Hartung, Matyas Gorjanacz. Potent and isoform-selective ATAD2 bromodomain inhibitor with unprecedented chemical structure and mode of action [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5084. doi:10.1158/1538-7445.AM2017-5084

Abstract 2829: Discovery and in vitro and in vivo characterization of aminopyrazoline-based SMYD2 inhibitors

SMYD2 (SET and MYND domain-containing protein 2) is a protein lysine methyltransferase (PKMT) which was initially described as a histone H3K36 and H3K4 methyltransferase involved in transcriptional regulation. SMYD2 has recently been reported to methylate and regulate several non-histone cancer relevant proteins such as p53, retinoblastoma protein (Rb) and the estrogen receptor alpha. Given the reports that overexpression of SMYD2 is linked to poor prognosis in certain cancers, SMYD2 is proposed to be an oncogene and an attractive cancer drug target. Here we report the discovery of a novel potent and selective SMYD2 inhibitor, SMYD2-BAY-01, by high throughput screening and extensive biophysical validation. The co-crystal structure revealed that SMYD2-BAY-01 binds to the substrate binding site and occupies the hydrophobic pocket for lysine binding using an unprecedented hydrogen bond pattern. The competitive behavior of the inhibitor in biochemical assays is consistent with the binding mode observed in the crystal structure. Further optimization generated SMYD2-BAY-02, which shows improved low nanomolar potency and is selective against kinases and other PKMTs. Furthermore, SMYD2-BAY-02 specifically inhibits SMYD2 methylation activity in a cellular assay with similar potency and reduces methylation of the tumor suppressor protein p53. Based on promising in vitro and in vivo DMPK data, SMYD2-BAY-02 was further characterized in vivo for SMYD2-specific methylation inhibition. In vivo activity could be shown upon in vivo administration at doses as low as 30 mg/kg p.o. in a SMYD2 overexpressing esophageal squamous cell carcinoma model. In summary, SMYD2-BAY-02 is a promising selective and potent SMYD2 inhibitor in vitro and in vivo and may represent a new treatment option for cancers overexpressing SMYD2. Citation Format: Carlo Stresemann, Ingo Hartung, Timo Stellfeld, Naomi Barak, Jeffrey Mowat, Clara Christ, Antonius ter Laak, Silke Koehr, Jorg Weiske, Roman Hillig, Volker Badock, Detlef Stoeckigt, Karl Ziegelbauer, Hilmar Weinmann, Volker Gekeler. Discovery and in vitro and in vivo characterization of aminopyrazoline-based SMYD2 inhibitors. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2829. doi:10.1158/1538-7445.AM2015-2829