Refine
Document Type
- Article (2)
- Doctoral Thesis (1)
- Preprint (1)
Language
- English (4)
Has Fulltext
- yes (4)
Is part of the Bibliography
- no (4)
Keywords
- BET inhibitor (1)
- Binding Kinetics (1)
- E3 Ligase (1)
- HDAC inhibitor (1)
- IAP (1)
- NanoBRET (1)
- PROTAC (1)
- Protein Kinase (1)
- Ubiquitin (1)
- combined therapy (1)
Institute
A toolbox for the generation of chemical probes for Baculovirus IAP Repeat containing proteins
(2022)
E3 ligases constitute a large and diverse family of proteins that play a central role in regulating protein homeostasis by recruiting substrate proteins via recruitment domains to the proteasomal degradation machinery. Small molecules can either inhibit, modulate or hijack E3 function. The latter class of small molecules led to the development of selective protein degraders, such as PROTACs (PROteolysis TArgeting Chimeras), that recruit protein targets to the ubiquitin system leading to a new class of pharmacologically active drugs and to new therapeutic options. Recent efforts have focused on the E3 family of Baculovirus IAP Repeat (BIR) domains that comprise a structurally conserved but diverse 70 amino acid long protein interaction domain. In the human proteome, 16 BIR domains have been identified, among them promising drug targets such as the Inhibitors of Apoptosis (IAP) family, that typically contain three BIR domains (BIR1, BIR2, and BIR3). To date, this target area lacks assay tools that would allow comprehensive evaluation of inhibitor selectivity. As a consequence, the selectivity of current BIR domain targeting inhibitors is unknown. To this end, we developed assays that allow determination of inhibitor selectivity in vitro as well as in cellulo. Using this toolbox, we have characterized available BIR domain inhibitors. The characterized chemical starting points and selectivity data will be the basis for the generation of new chemical probes for IAP proteins with well-characterized mode of action and provide the basis for future drug discovery efforts and the development of PROTACs and molecular glues.
Salt-inducible kinases (SIKs) are key metabolic regulators. Imbalance of SIK function is associated with the development of diverse cancers, including breast, gastric and ovarian cancer. Chemical tools to clarify the roles of SIK in different diseases are, however, sparse and are generally characterized by poor kinome-wide selectivity. Here, we have adapted the pyrido[2,3-d]pyrimidin-7-one-based PAK inhibitor G-5555 for the targeting of SIK, by exploiting differences in the back-pocket region of these kinases. Optimization was supported by high-resolution crystal structures of G-5555 bound to the known off-targets MST3 and MST4, leading to a chemical probe, MRIA9, with dual SIK/PAK activity and excellent selectivity over other kinases. Furthermore, we show that MRIA9 sensitizes ovarian cancer cells to treatment with the mitotic agent paclitaxel, confirming earlier data from genetic knockdown studies and suggesting a combination therapy with SIK inhibitors and paclitaxel for the treatment of paclitaxel-resistant ovarian cancer.
Human protein kinases play essential roles in cellular signaling pathways and - if deregulated - are linked to a large diversity of diseases such as cancer and inflammation or to metabolic diseases. Because of their key role in disease development or progression, kinases have developed into major drug targets resulting in the approval of 52 kinase inhibitors by the Food and Drug Administration (FDA) so far.
Within the drug discovery process, the affinity of the inhibitors is the parameter that is used most often to predict the later efficacy in humans. However, the kinetics of binding have recently emerged as an important but largely neglected factor of kinase inhibitor efficacy. To efficiently suppress a signaling pathway, the targeted kinase needs to be continuously inhibited. Thus, it has been hypothesized that fast binding on-rates and slow off-rates would be the preferred property of an efficacious inhibitor. Despite optimizing the potency of kinase inhibitors, in the past decade optimization of kinetic selectivity has therefore gained interest as a molecule cannot be active unless it is bound, as Paul Ehrlich once stated. There is increasing evidence of correlations between prolonged drug-target residence time and increased drug efficacy, and that inhibitor selectivity in cellular contexts can be modulated by altered residence times. In order to contribute to the understanding of the effect of long residence times on cellular targets we initiated two projects.
The first of these projects is related to the STE20 kinase Serine/threonine kinase 10 (STK10) and its close relative STE20 like kinase (SLK) which have been reported to be frequent off-targets for kinase inhibitors used in the clinics. Also, an inhibition of STK10 and SLK has been linked to a common side-effect of severe skin rash developed upon treatment with the EGFR inhibitor erlotinib, but not gefitinib and the severity of this rash correlated with the treatment outcome, which fits the known biology of STK10 and SLK to be regulators of lymphocyte migration and PLK kinases. However, there are yet no explanations why these two proteins show such high hit-rates across the kinome among the kinase inhibitors. Using structural analysis, we identified the flexibility of STK10 to be the main reason for this hit-rate. The observed strong in vitro potencies did however not translate to the cellular system which is why we investigated the inhibitors residence time on STK10. We found the same flexibility to be the main reason for slow residence times among several inhibitors. We observed large rearrangements in the hydrophobic backpocket of STK10 including the αC, the P-loop enclosing the inhibitor like a lid and strong π-π-stackings to be the main reasons for prolonged residence times on STK10. Interestingly, we observed an increased residence time for erlotinib, which showed skin-related side-effects, giving rise whether the binding kinetics should be investigated for weak cellular off-target effects in future drug discovery efforts.
In the second project we initiated, we illuminate a structural mechanism that allows kinetic selection between two closely related kinases, focal adhesion kinase (FAK) and proline-rich tyrosine kinase 2 (PYK2). Using an inhibitor series designed to probe the mechanism, residence times measured in vitro and in cells showed a strong correlation. Crystal structures and mutagenesis identified hydrophobic interactions with L567, adjacent to the DFG-motif, as being crucial to kinetic selectivity of FAK over PYK2. This specific interaction was observed only when the DFG-motif was stabilized into a helical conformation upon ligand binding to FAK. The interplay between the protein structural mobility and ligand-induced effect was found to be the key regulator of kinetic inhibitor selectivity for FAK over PYK2.
These two projects showed that the parameter residence time should be considered for different problems among the drug discovery process. First, in an open in vivo system not only the potency of a drug alone, but as well its residence time might be of importance. Here we showed that the weak cellular potency translated to prolonged residence times for several inhibitors in cells and established a link between the phenotypic outcome of skin rash after erlotinib treatment and the residence time of this inhibitor on STK10 in cells. On the other hand, medicinal chemistry efforts should consider structure kinetic relationships (SKR) in the optimization process and aim to understand the molecular basis for prolonged target residence times. Here, we showed that a hydrophobic interaction that is enforced upon inhibitor binding is crucial for an unusual helical DFG conformation which arrests the inhibitor and prolongs its residence time providing the molecular basis for understanding the kinetic selectivity of two closely related protein kinases. Establishing the SKRs will help medicinal chemists to kinetically optimize their drug candidates to select a suitable molecule to proceed into further optimization programs. Hence, the projects showed that the target residence time parameter needs to be considered both as a molecular optimization parameter to improve compound potency and binding behavior as well as a parameter to be understood for proceeding to the open system of in vivo models to later modulate the in vivo efficacy of protein kinase targeting drugs.
Characterization of a dual BET/HDAC inhibitor for treatment of pancreatic ductal adenocarcinoma
(2020)
Pancreatic ductal adenocarcinoma (PDAC) is resistant to virtually all chemo‐ and targeted therapeutic approaches. Epigenetic regulators represent a novel class of drug targets. Among them, BET and HDAC proteins are central regulators of chromatin structure and transcription, and preclinical evidence suggests effectiveness of combined BET and HDAC inhibition in PDAC. Here, we describe that TW9, a newly generated adduct of the BET inhibitor (+)‐JQ1 and class I HDAC inhibitor CI994, is a potent dual inhibitor simultaneously targeting BET and HDAC proteins. TW9 has a similar affinity to BRD4 bromodomains as (+)‐JQ1 and shares a conserved binding mode, but is significantly more active in inhibiting HDAC1 compared to the parental HDAC inhibitor CI994. TW9 was more potent in inhibiting tumor cell proliferation compared to (+)‐JQ1, CI994 alone or combined treatment of both inhibitors. Sequential administration of gemcitabine and TW9 showed additional synergistic antitumor effects. Microarray analysis revealed that dysregulation of a FOSL1‐directed transcriptional program contributed to the antitumor effects of TW9. Our results demonstrate the potential of a dual chromatin‐targeting strategy in the treatment of PDAC and provide a rationale for further development of multitarget inhibitors.