Refine
Year of publication
- 2020 (4) (remove)
Document Type
- Doctoral Thesis (4)
Language
- English (4)
Has Fulltext
- yes (4)
Is part of the Bibliography
- no (4)
Keywords
- Antigen carrier (1)
- Binding Kinetics (1)
- Binding kinetic (1)
- DDR (1)
- Flavin homeostasis (1)
- Kinase inhibitors (1)
- Protein Kinase (1)
- p38 (1)
Institute
The p38α mitogen-activated protein kinase (MAPK) is activated through stress stimuli such as heat shock or hypoxia. In the nucleus, p38α modulates the activity of other kinases and transcription factors, a process that regulates the expression of specific target genes, most importantly pro-inflammatory cytokines. Dysregulation of p38α therefore plays a major role in the development of inflammatory diseases such as rheumatoid arthritis. Despite many years of intensive research, no p38 small-molecule inhibitors have been approved yet. Several inhibitor design strategies have been reported, leading to >100-fold selective compounds for α/β over the γ and δ isoforms. Achieving such a selectivity among the two structurally most related α and β isoforms, however, remains a challenging task. Targeting an inactive DFG-out conformation offers another strategy for the development of potent kinase inhibitors (type-II), exemplified by the BCR/ABL-inhibitor Imatinib. Achieving selectivity with type-II binders is challenging, because many kinases can adopt an inactive DFG-out conformation. This is exemplified by the p38 type-II inhibitor BIRB-796, which exhibits picomolar on-target affinity but only a poor kinome-wide selectivity. A potent and selective type-II chemical probe for p38α/β was still lacking at the start of this thesis.
The promising hit VPC-00628, was chosen for a combinatorial synthetic approach to develop a type-II chemical probe. The studies covered the optimization of the hinge-binding head group, the hydrophobic region I and the DFG-out deep pocket of the lead compound VPC-00628. Selectivity for the p38α and p38β isoforms was monitored during the optimization process, which identified several inhibitors with favorable isoform selectivity, providing valuable insights into the potential of isoform-selective inhibitor design for p38. A potent and highly selective p38 MAPK probe (SR-318) was discovered, which showed IC50 values in the low nanomolar range in HEK293T cells. An unusual P-loop conformation induced upon binding of SR-318 to p38α contributed most likely to the impressive selectivity profile within the kinome that surpassed both the parent compound and BIRB-796. A negative control compound, SR-321, was developed, to distinguish between on-target effects and non-specific effects due to cross-reactivity with other cellular proteins. Studies of the metabolic stability in human liver microsomes revealed a high stability of the compounds, with only a small amount of metabolites formed over several hours. Compound SR-318 also exhibited a good in vitro efficacy, quantitatively reducing the LPS-stimulated TNF-α release in whole blood. Taken together, SR-318 is a highly potent and selective type-II p38α/β chemical probe, which will help to gain a better understanding of the catalytic and non-catalytic functions of these key signaling kinases in physiology and pathology.
The next studies focused on the exploration of the highly dynamic allosteric back pocket of p38 MAPK, and allosteric BIRB-796 derived compounds for targeting the αC- and DFG-out pockets were synthesized. Kinase activities of allosteric pyrazole-urea fragments were analyzed against a comprehensive set of 47 diverse kinases by differential scanning fluorimetry (DSF), revealing that BIRB-796 off-targets remain a problem when targeting this back-pocket binding motif. Revisiting the recently published compound MCP-081, which combines the allosteric part of BIRB-796 with the active-site directed part of VPC-00628, showed that it displays a clean selectivity profile in our kinase panel. Because the potency of MCP-081 was slightly reduced compared with VPC-00628 and the allosteric tert-butyl pyrazole moiety seemed suboptimal, a set of VPC-00628 derivatives for targeting the αC-out pocket region was synthesized. Through structure-guided extension of the terminal amide of VPC-00628 toward this allosteric site, the potent and selective compound SR-43 was developed, which showed excellent cellular activity on p38 MAPK in NanoBRETTM assays (IC50 [p38α/β] = 14.0 ± 0.1/ 16.8 ± 0.1 nM). SR-43 showed a dose-dependent inhibition of activating phosphorylation of p38 in HCT-15 cells as well as inhibition of phosphorylation of p38 downstream substrates MK2 and Hsp27. In addition, SR-43 induced an anti-inflammatory response by blocking TNF-α release in whole blood and displayed a high metabolic stability. Selectivity profiling of SR-43 revealed a narrow selectivity for additional targets such as the discoidin domain receptor kinases (DDR1/2). DDR kinases play a central role in fibrotic disorders, such as renal and pulmonale fibrosis, atherosclerosis and different forms of cancer. Since selective and potent inhibitors for these important therapeutic targets are largely lacking and the existing inhibitors are of low scaffold diversity, the next study focused on the optimization of SR-43 toward DDR1/2 kinase inhibition. The synthetic work covered the optimization of the hinge-binding head group and the allosteric part of SR-43 toward DDR1/2 kinase inhibition. These studies provided novel insights into the P-loop folding process of p38 MAPK and how targeting of non-conserved amino acids affects inhibitor selectivity. Importantly, they led to the development of a selective dual DDR/p38 inhibitor probe, SR-302, with picomolar affinity for DDR2. SR-302 was efficient in vitro and showed a destabilizing effect on the surface adhesion protein E-cadherin in epithelial cells. In summary, SR-302 and its negative control SR-301 provide a valuable tool set for studying the phenotypic effects of DDR1/2 signaling, e.g., in cancer cell lines.
Guanosine triphosphate (GTP) cyclohydrolase I (GCH1) catalyzes the conversion of GTP to dihydroneopterin triphosphate (H2NTP), the initiating step in the biosynthesis of tetrahydrobiopterin (BH4). Besides other roles, BH4 functions as cofactor in neurotransmitter biosynthesis. The BH4 biosynthetic pathway and GCH1 have been identified as promising targets to treat pain disorders in patients. The function of mammalian GCH1s is regulated by a metabolic sensing mechanism involving a regulator protein, GCH1 feedback regulatory protein (GFRP). GFRP binds to GCH1 to form inhibited or activated complexes dependent on availability of cofactor ligands, BH4 and phenylalanine, respectively. We determined high-resolution structures of human GCH1−GFRP complexes by cryoelectron microscopy (cryo-EM). Cryo-EM revealed structural flexibility of specific and relevant surface lining loops, which previously was not detected by X-ray crystallography due to crystal packing effects. Further, we studied allosteric regulation of isolated GCH1 by X-ray crystallography. Using the combined structural information, we are able to obtain a comprehensive picture of the mechanism of allosteric regulation. Local rearrangements in the allosteric pocket upon BH4 binding result in drastic changes in the quaternary structure of the enzyme, leading to a more compact, tense form of the inhibited protein, and translocate to the active site, leading to an open, more flexible structure of its surroundings. Inhibition of the enzymatic activity is not a result of hindrance of substrate binding, but rather a consequence of accelerated substrate binding kinetics as shown by saturation transfer difference NMR (STD-NMR) and site-directed mutagenesis. We propose a dissociation rate controlled mechanism of allosteric, noncompetitive inhibition.
The dodecin of Mycobacterium tuberculosis : biological function and biotechnical applications
(2020)
Biological Function of Bacterial Dodecins
In this thesis, the dodecins of Mycobacterium tuberculosis (MtDod), Streptomyces coelicolor (ScDod) and Streptomyces davaonensis (SdDod) were studied. Kinetic measurements of the flavin binding of MtDod revealed that the dodecin binding pocket is filled in two distinct steps, for which a kinetic model then was established and verified by experimental data. The analysis with the two-step model showed that the unique binding pocket of dodecins allows them to bind excessive amounts of flavins, while at low flavin concentrations, flavin is released and only weakly bound. This function of flavin buffering prevents accumulation of free oxidised flavins and therefore helps to keep the redox balance of the cell and prevents potential cell damage caused by excessive free flavins. To further gain insights into the role of bacterial dodecins, the effect of knocking out the dodecin encoding gene in S. davaonensis was analysed. The knockout strain showed increased concentrations of various stress related metabolites, indicating that without dodecin the cellular balance is disrupted, which supports the role of dodecins as a flavin homeostasis factor.
With a self-designed affinity measurement method based on the temperature dependent dissociation of the dodecin:flavin complex, which allowed parallel screening of multiple conditions, it was shown that MtDod, ScDod and SdDod have much higher affinities towards FMN and FAD under acidic conditions. Under these conditions, the three dodecins might function as a FMN storage. M. tuberculosis encounters multiple acidic environments during its infection cycle of humans and can adopt a state of dormancy. During recovery from the dormant state, a flavin storage might be beneficial. For some Streptomyces species it was reported that the formed spores are slightly acidic and therefore ScDod and SdDod could function as flavin storages for the spores. Further details on the flavin binding mechanism of MtDod were revealed by a mutagenesis study, identifying the importance of a histidine residue at the fourth position of the protein sequence for flavin binding, but contrary to expectations, this residue seems only to be partly involved in the pH related affinity shift.
The data, reported in this thesis, demonstrates that bacterial dodecins likely function as flavin homeostasis factors, which allow overall higher flavin pools in the cell without disrupting the cellular balance. Further, the reported acid-dependent increase in binding affinity suggests that under certain conditions bacterial dodecins can also function as a flavin storage system.
Application of the Dodecin of M. tuberculosis
In this thesis, the stability of MtDod, ScDod SdDod and HsDod was analysed to find a suitable dodecin for the use as a carrier/scaffold. Therefore, a method to easily measure the stability of dodecins was designed, which measures the ability of the dodecamer to rebind flavins after a heating phase with stepwise increasing temperatures. Using this assay and testing the stability against detergents by SDS PAGE, showed that the dodecamer of MtDod possesses an excellent stability against a vast array of conditions, like temperatures above 95 °C, low pH and about 2% SDS. By solving the crystal structure of ScDod and SdDod, the latter forming a less stable dodecamer, combined with a mutagenesis study, the importance of a specific salt bridge for dodecamer stability was revealed and might be helpful to find further highly stable dodecins.
In addition to the intrinsic high stability of the MtDod dodecamer, also the robustness of the fold was tested by creating diverse MtDod fusion constructs and producing them in Escherichia coli. Here it was shown that MtDod easily tolerates the attachment of proteins up to 4-times of its own size and that both termini can be modified without affecting the dodecamer noticeably. Further, it was shown that MtDod and many MtDod fusion constructs could be purified in high yields via a protocol based on the removal of E. coli proteins through heat denaturation and subsequent centrifugation. In a case study, by fusing diverse antigens from mostly human proteins to MtDod and using these constructs to produce antibodies in rabbits, it was demonstrated that MtDod is immunogenic and presents the attached antigens to the immune system.
The here reported properties of MtDod and to a lesser degree of other bacterial dodecins, show that bacterial dodecins are a valuable addition to the pool of scaffold and carrier proteins and have great potential as antigen carriers.
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.