Christian Stegmann

Discovery of a Potent Class I Protein Arginine Methyltransferase Fragment Inhibitor.

Protein methyltransferases (PMTs) are a promising target class in oncology and other disease areas. They are composed of SET domain methyltransferases and structurally unrelated Rossman-fold enzymes that include protein arginine methyltransferases (PRMTs). In the absence of a well-defined medicinal chemistry tool-kit focused on PMTs, most current inhibitors were identified by screening large and diverse libraries of leadlike molecules. So far, no successful fragment-based approach was reported against this target class. Here, by deconstructing potent PRMT inhibitors, we find that chemical moieties occupying the substrate arginine-binding site can act as efficient fragment inhibitors. Screening a fragment library against PRMT6 produced numerous hits, including a 300 nM inhibitor (ligand efficiency of 0.56) that decreased global histone 3 arginine 2 methylation in cells, and can serve as a warhead for the development of PRMT chemical probes.

Conformational Adaption May Explain the Slow Dissociation Kinetics of Roniciclib (BAY 1000394), a Type I CDK Inhibitor with Kinetic Selectivity for CDK2 and CDK9.

Roniciclib (BAY 1000394) is a type I pan-CDK (cyclin-dependent kinase) inhibitor which has revealed potent efficacy in xenograft cancer models. Here, we show that roniciclib displays prolonged residence times on CDK2 and CDK9, whereas residence times on other CDKs are transient, thus giving rise to a kinetic selectivity of roniciclib. Surprisingly, variation of the substituent at the 5-position of the pyrimidine scaffold results in changes of up to 3 orders of magnitude of the drug-target residence time. CDK2 X-ray cocrystal structures have revealed a DFG-loop adaption for the 5-(trifluoromethyl) substituent, while for hydrogen and bromo substituents the DFG loop remains in its characteristic type I inhibitor position. In tumor cells, the prolonged residence times of roniciclib on CDK2 and CDK9 are reflected in a sustained inhibitory effect on retinoblastoma protein (RB) phosphorylation, indicating that the target residence time on CDK2 may contribute to sustained target engagement and antitumor efficacy.

Abstract 160: High target binding affinity with long lasting cellular target engagement and high dose intermittent schedule of PI3K inhibitor copanlisib contribute to the potent anti-tumor activity and good safety profile

Introduction: Several generations of PI3K inhibitors have been tested in clinic. However, thus far, clinical activity has been moderate. Different from other oral PI3K inhibitors dosed continuously, copanlisib (BAY 80-6946) is an intravenous PI3K inhibitor given intermittently to patients. Copanlisib dosed once weekly demonstrated clinical benefit with an improved safety profile, and therefore challenges the concept of default continuous dosing of PI3K inhibitors. However, it is still unclear if this concept can be generalized and whether ‘micropharmacokinetic parameters’ also contributed to the potent anti-tumor profile of copanlisib. Here, we report the characterization of binding kinetics for copanlisib, as well as the functional consequence in vivo. Methods: A set of PI3K inhibitors were characterized in 1) a kinetic probe competition assay (kPCA); 2) a cellular nanoBRET target engagement assay; 3) a cellular washout study with the assessment on pathway engagement; and 4) in vivo pharmacokinetics analysis. Results: Copanlisib showed nearly diffusion-controlled on- and relatively slow off-rates with kon = 3.45E+7 [M-1*s-1] and koff = 1.67E-3 [s-1] to PI3Kα. Consequently, it exhibited very high affinity to PI3Kα ( Ki ePCA = 9.31E-11[M] and KD kPCA = 4.77E-11 [M]). In a cellular nanoBRET target engagement assay, the apparent half-life (t1/2) of ca. 2 hours greatly surpassed the 6.9 min measured using kPCA. The high affinity to PI3Kα also translated into potent cellular pathway engagement demonstrated by inhibition of p-AKT and p-PRAS40 in the PIK3CAmut KPL4 cell line. In a cellular washout study, p-AKT and p-PRAS40 were assessed till 168 h after incubation with copanlisib for 1 h followed by a washout step. A dose- and time-dependent pathway engagement was observed even at 72 h post washout. This result indicated that in cells, copanlisib engages PI3Kα for an extremely long time, likely due to rebinding effects facilitated by the fast equilibration kinetics of the compound and its micropharmacokinetic properties. Interestingly, in vivo, BAY 80-6946 levels were approximately 100-fold higher in the tumor than in plasma at 48 hours and drug clearance from the tumor occurred more slowly than from plasma. This high and prolonged tumor exposure might be explained, at least in part, by the high expression of PI3Kα and long lasting target occupancy of copanlisib in tumors. Conclusion: Copanlisib demonstrated high affinity to PI3Kα with protracted target engagement at cellular and in vivo levels. This ‘micropharmacokinetic feature’ not only supports intermittent dosing but likely also explains the high exposure in tumors vs plasma, potent anti-tumor activity and good safety profiles. Citation Format: Amaury E. Fernandez-Montalvan, Victoria Georgi, James Vasta, Sarah Glaeske, Vera Puetter, Matthew B. Robers, Ursula Moenning, Andrea Sturz, Julien Lefranc, Karl Ziegelbauer, Michael Brands, Christian Stegmann, William J. Scott, Ningshu Liu. High target binding affinity with long lasting cellular target engagement and high dose intermittent schedule of PI3K inhibitor copanlisib contribute to the potent anti-tumor activity and good safety profile [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 160. doi:10.1158/1538-7445.AM2017-160

Functional and Structural Characterization of Bub3·BubR1 Interactions Required for Spindle Assembly Checkpoint Signaling in Human Cells

The spindle assembly checkpoint (SAC) is an essential safeguarding mechanism devised to ensure equal chromosome distribution in daughter cells upon mitosis. The proteins Bub3 and BubR1 are key components of the mitotic checkpoint complex, an essential part of the molecular machinery on which the SAC relies. In the present work we have performed a detailed functional and biochemical characterization of the interaction between human Bub3 and BubR1 in cells and in vitro. Our results demonstrate that genetic knockdown of Bub3 abrogates the SAC, promotes apoptosis, and inhibits the proliferation of human cancer cells. We also show that the integrity of the human mitotic checkpoint complex depends on the specific recognition between BubR1 and Bub3, for which the BubR1 Gle2 binding sequence motif is essential. This 1:1 binding event is high affinity, enthalpy-driven and with slow dissociation kinetics. The affinity, kinetics, and thermodynamic parameters of the interaction are differentially modulated by small regions in the N and C termini of the Gle2 binding domain sequence, suggesting the existence of “hotspots” for this protein-protein interaction. Furthermore, we show that specific disruption of endogenous BubR1·Bub3 complexes in human cancer cells phenocopies the effects observed in gene targeting experiments. Our work enhances the current understanding of key members of the SAC and paves the road for the pursuit of novel targeted cancer therapies based on SAC inhibition.