Directed Modulation of Protein Kinase C Isozyme Selectivity with Bisubstrate‐Based Inhibitors

Kinases present an attractive target for drug development, since they are involved in vital cellular processes and are implicated in a variety of diseases, such as cancer and diabetes. However, obtaining selectivity for a specific kinase over others is difficult since many current kinase inhibitors exclusively target the highly conserved kinase ATP binding domain. Previously, a microarray‐based strategy to discover so‐called bisubstrate‐based inhibitors that target the more specific peptide binding groove in addition to the ATP binding site was described. One attractive feature of this strategy is the opportunity to tune the selectivity of these inhibitors by systematically varying components. In an extension to this previous work, this study explores the potential of this guided selectivity modulation, leading to a series of inhibitors with different selectivity profiles against highly homologous protein kinase C (PKC) isozymes. Of the inhibitors studied, most exhibited improved potency and selectivity compared with their constituent parts. Furthermore, the selectivity was found to be tunable either through modification of the pseudosubstrate peptide (peptide binding groove) or the ATP‐competitive part (ATP binding site). In a number of cases, the selectivity of the construct could be predicted from the initial peptide substrate profiling experiment. Since this strategy is applicable to all kinase sets, it could be used to rapidly develop uniquely selective inhibitors.     

Bisubstrate Inhibitors of Protein Kinases: from Principle to Practical Applications

Bisubstrate inhibitors consist of two conjugated fragments, each targeted to a different binding site of a bisubstrate enzyme. The design of bisubstrate inhibitors presupposes the formation of the ternary complex in the course of the catalyzed reaction. The principle advantage of bisubstrate inhibitors is their ability to generate more interactions with the target enzyme that could result in improved affinity and selectivity of the conjugates, when compared with single‐site inhibitors. Among phosphotransferases, the approach was first successfully used for adenylate kinase in 1973. Since then, several types of bisubstrate inhibitors have been developed for protein kinases, including conjugates of peptides with nucleotides, adenosine derivatives and potent ATP‐competitive inhibitors. Earlier bisubstrate inhibitors had pharmacokinetic qualities that were unsuitable for cellular experiments and hence were mostly used for in vitro studies. The recently constructed conjugates of adenosine derivatives and D ‐arginine‐rich peptides (ARCs) possess high kinase affinity, high biological and chemical stability and good cell plasma membrane penetrative properties that enable their application in the regulation of cellular protein phosphorylation balances in cell and tissue experiments.     

Discovery of Non‐ATP‐Competitive Inhibitors of Polo‐like Kinase 1

Polo‐like kinase 1 (Plk1) is an evolutionarily conserved serine/threonine kinase, and its N‐terminal kinase domain (KD) controls cell signaling through phosphorylation. Inhibitors of Plk1 are potential anticancer drugs. Most known Plk1 KD inhibitors are ATP‐competitive compounds, which may suffer from low selectivity. In this study we discovered novel non‐ATP‐competitive Plk1 KD inhibitors by virtual screening and experimental studies. Potential binding sites in Plk1 KD were identified by using the protein binding site detection program Cavity. The identified site was subjected to molecular‐docking‐based virtual screening. The activities of top‐ranking compounds were evaluated by in vitro enzyme assay with full‐length Plk1 and direct binding assay with Plk1 KD. Several compounds showed inhibitory activity, and the most potent was found to be 3‐((2‐oxo‐2‐(thiophen‐2‐yl)ethyl)thio)‐6‐(pyridin‐3‐ylmethyl)‐1,2,4‐triazin‐5(4H)‐one (compound 4 ) with an IC₅₀ value of 13.1±1.7 μm . Our work provides new insight into the design of kinase inhibitors that target non‐ATP binding sites.     

Structural Investigation of the Binding of 5‐Substituted Swainsonine Analogues to Golgi α‐Mannosidase II

Golgi α‐mannosidase II (GMII) is a key enzyme in the N‐glycosylation pathway and is a potential target for cancer chemotherapy. The natural product swainsonine is a potent inhibitor of GMII. In this paper we characterize the binding of 5α‐substituted swainsonine analogues to the soluble catalytic domain of Drosophila GMII by X‐ray crystallography. These inhibitors enjoy an advantage over previously reported GMII inhibitors in that they did not significantly decrease the inhibitory potential of the swainsonine head‐group. The phenyl groups of these analogues occupy a portion of the binding site not previously seen to be populated with either substrate analogues or other inhibitors and they form novel hydrophobic interactions. They displace a well‐organized water cluster, but the presence of a C(10) carbonyl allows the reestablishment of important hydrogen bonds. Already approximately tenfold more active against the Golgi enzyme than the lysosomal enzyme, these inhibitors offer the potential of being extended into the N‐acetylglucosamine binding site of GMII for the creation of even more potent and selective GMII inhibitors.     

para‐Substituted 2‐Phenyl‐3,4‐dihydroquinazolin‐4‐ones As Potent and Selective Tankyrase Inhibitors

Human tankyrases are attractive drug targets, especially for the treatment of cancer. We identified a set of highly potent tankyrase inhibitors based on a 2‐phenyl‐3,4‐dihydroquinazolin‐4‐one scaffold. Substitutions at the para position of the scaffold′s phenyl group were evaluated as a strategy to increase potency and improve selectivity. The best compounds displayed single‐digit nanomolar potencies, and profiling against several human diphtheria‐toxin‐like ADP‐ribosyltransferases revealed that a subset of these compounds are highly selective tankyrase inhibitors. The compounds also effectively inhibit Wnt signaling in HEK293 cells. The binding mode of all inhibitors was studied by protein X‐ray crystallography. This allowed us to establish a structural basis for the development of highly potent and selective tankyrase inhibitors based on the 2‐phenyl‐3,4‐dihydroquinazolin‐4‐one scaffold and outline a rational approach to the modification of other inhibitor scaffolds that bind to the nicotinamide site of the catalytic domain.     

DXP Synthase‐Catalyzed C?N Bond Formation: Nitroso Substrate Specificity Studies Guide Selective Inhibitor Design

1‐Deoxy‐D ‐xylulose 5‐phosphate (DXP) synthase catalyzes the first step in the nonmammalian isoprenoid biosynthetic pathway to form DXP from pyruvate and D ‐glyceraldehyde 3‐phosphate (D ‐GAP) in a thiamin diphosphate‐dependent manner. Its unique structure and mechanism distinguish DXP synthase from its homologues and suggest that it should be pursued as an anti‐infective drug target. However, few reports describe any development of selective inhibitors of this enzyme. Here, we reveal that DXP synthase catalyzes C? N bond formation and exploit aromatic nitroso substrates as active site probes. Substrate specificity studies reveal a high affinity of DXP synthase for aromatic nitroso substrates compared to the related ThDP‐dependent enzyme pyruvate dehydrogenase (PDH). Results from inhibition and mutagenesis studies indicate that nitroso substrates bind to E. coli DXP synthase in a manner distinct from that of D ‐GAP. Our results suggest that the incorporation of aryl acceptor substrate mimics into unnatural bisubstrate analogues will impart selectivity to DXP synthase inhibitors. As a proof of concept, we show selective inhibition of DXP synthase by benzylacetylphosphonate (BnAP).     

Alzheimer’s Disease: Identification and Development of β‐Secretase (BACE‐1) Binding Fragments and Inhibitors by Dynamic Ligation Screening (DLS)

The application of dynamic ligation screening (DLS), a methodology for fragment‐based drug discovery (FBDD), to the aspartic protease β‐secretase (BACE‐1) is reported. For this purpose, three new fluorescence resonance energy transfer (FRET) substrates were designed and synthesized. Their kinetic parameters (V_max, K_M, and k_cat) were determined and compared with a commercial substrate. Secondly, a peptide aldehyde was designed as a chemically reactive inhibitor (CRI) based on the Swedish mutation substrate sequence. Incubation of this CRI with the protease, a FRET substrate, and one amine per well taken from an amine library, which was assembled by a maximum common substructure (MCS) approach, revealed the fragment 3‐(3‐aminophenyl)‐2H‐chromen‐2‐one ( 1 ) to be a competitive BACE‐1 inhibitor that enhanced the activity of the CRI. Irreversibly formed fragment combination products of 1 with the initial peptide sequence were active and confirmed the targeting of the active site through the ethane‐1,2‐diamine isostere. Finally, structure‐assisted combination of fragment 1 with secondary fragments that target the S1 site in hit optimization yielded novel, entirely fragment‐based BACE‐1 inhibitors with up to 30‐fold improved binding affinity. Interactions with the protein were explained by molecular modeling studies, which indicate that the new fragment combinations interact with the catalytic aspartic acid dyad, as well as with the adjacent binding sites required for potency.     

MAO Inhibitory Activity of 2‐Arylbenzofurans versus 3‐Arylcoumarins: Synthesis,in vitro Study,and Docking Calculations

Monoamine oxidase (MAO) is an important drug target for the treatment of neurological disorders. Several 3‐arylcoumarin derivatives were previously described as interesting selective MAO‐B inhibitors. Preserving the trans‐stilbene structure, a series of 2‐arylbenzofuran and corresponding 3‐arylcoumarin derivatives were synthesized and evaluated as inhibitors of both MAO isoforms, MAO‐A and MAO‐B. In general, both types of derivatives were found to be selective MAO‐B inhibitors, with IC₅₀ values in the nano‐ to micromolar range. 5‐Nitro‐2‐(4‐methoxyphenyl)benzofuran ( 8 ) is the most active compound of the benzofuran series, presenting MAO‐B selectivity and reversible inhibition (IC₅₀=140 nM ). 3‐(4′‐Methoxyphenyl)‐6‐nitrocoumarin ( 15 ), with the same substitution pattern as that of compound 8 , was found to be the most active MAO‐B inhibitor of the coumarin series (IC₅₀=3 nM ). However, 3‐phenylcoumarin 14 showed activity in the same range (IC₅₀=6 nM ), is reversible, and also severalfold more selective than compound 15 . Docking experiments for the most active compounds into the MAO‐B and MAO‐A binding pockets highlighted different interactions between the derivative classes (2‐arylbenzofurans and 3‐arylcoumarins), and provided new information about the enzyme–inhibitor interaction and the potential therapeutic application of these scaffolds.     

Small‐Molecule Inhibitors That Target Protein–Protein Interactions in the RAD51 Family of Recombinases

The development of small molecules that inhibit protein–protein interactions continues to be a challenge in chemical biology and drug discovery. Herein we report the development of indole‐based fragments that bind in a shallow surface pocket of a humanised surrogate of RAD51. RAD51 is an ATP‐dependent recombinase that plays a key role in the repair of double‐strand DNA breaks. It both self‐associates, forming filament structures with DNA, and interacts with the BRCA2 protein through a common “FxxA” tetrapeptide motif. We elaborated previously identified fragment hits that target the FxxA motif site and developed small‐molecule inhibitors that are approximately 500‐fold more potent than the initial fragments. The lead compounds were shown to compete with the BRCA2‐derived Ac‐FHTA‐NH₂ peptide and the self‐association peptide of RAD51, but they had no effect on ATP binding. This study is the first reported elaboration of small‐molecular‐weight fragments against this challenging target.     

α‐Keto Phenylamides as P1′‐Extended Proteasome Inhibitors

The major challenge for proteasome inhibitor design lies in achieving high selectivity for, and activity against, the target, which requires specific interactions with the active site. Novel ligands aim to overcome off‐target‐related side effects such as peripheral neuropathy, which is frequently observed in cancer patients treated with the FDA‐approved proteasome inhibitors bortezomib ( 1 ) or carfilzomib ( 2 ). A systematic comparison of electrophilic headgroups recently identified the class of α‐keto amides as promising for next generation drug development. On the basis of crystallographic knowledge, we were able to develop a structure–activity relationship (SAR)‐based approach for rational ligand design using an electronic parameter (Hammett’s σ) and in silico molecular modeling. This resulted in the tripeptidic α‐keto phenylamide BSc4999 [(S)‐3‐(benzyloxycarbonyl‐(S)‐leucyl‐(S)‐leucylamino)‐5‐methyl‐2‐oxo‐N‐(2,4‐dimethylphenyl)hexanamide, 6 a ], a highly potent (IC₅₀=38 nM ), cell‐permeable, and slowly reversible covalent inhibitor which targets both the primed and non‐primed sites of the proteasome’s substrate binding channel as a special criterion for selectivity. The improved inhibition potency and selectivity of this new α‐keto phenylamide makes it a promising candidate for targeting a wider range of tumor subtypes than commercially available proteasome inhibitors and presents a new candidate for future studies.     

Understanding Kinase Selectivity Through Energetic Analysis of Binding Site Waters

Kinases remain an important drug target class within the pharmaceutical industry; however, the rational design of kinase inhibitors is plagued by the complexity of gaining selectivity for a small number of proteins within a family of more than 500 related enzymes. Herein we show how a computational method for identifying the location and thermodynamic properties of water molecules within a protein binding site can yield insight into previously inexplicable selectivity and structure–activity relationships. Four kinase systems (Src family, Abl/c‐Kit, Syk/ZAP‐70, and CDK2/4) were investigated, and differences in predicted water molecule locations and energetics were able to explain the experimentally observed binding selectivity profiles. The successful predictions across the range of kinases studied here suggest that this methodology could be generally applicable for predicting selectivity profiles in related targets.     

Inhibition of Eimeria tenella CDK‐Related Kinase 2: From Target Identification to Lead Compounds

Apicomplexan parasites encompass several human‐ and animal‐pathogenic protozoans such as Plasmodium falciparum, Toxoplasma gondii, and Eimeria tenella. E. tenella causes coccidiosis, a disease that afflicts chickens, leading to tremendous economic losses to the global poultry industry. The considerable increase in drug resistance makes it necessary to develop new therapeutic strategies against this parasite. Cyclin‐dependent kinases (CDKs) are key molecules in cell‐cycle regulation and are therefore prominent target proteins in parasitic diseases. Bioinformatics analysis revealed four potential CDK‐like proteins, of which one—E. tenella CDK‐related kinase 2 (EtCRK2)—has already been characterized by gene cloning and expression. 1 By using the CDK‐specific inhibitor flavopiridol in EtCRK2 enzyme assays and schizont maturation assays (SMA), we could chemically validate CDK‐like proteins as potential drug targets. An X‐ray crystal structure of human CDK2 (HsCDK2) served as a template to build protein models of EtCRK2 by comparative homology modeling. Structural differences in the ATP binding site between EtCRK2 and HsCDK2, as well as chicken CDK3, were addressed for the optimization of selective ATP‐competitive inhibitors. Virtual screening and “wet‐bench” high‐throughput screening campaigns on large compound libraries resulted in an initial set of hit compounds. These compounds were further analyzed and characterized, leading to a set of four promising lead compounds for development as EtCRK2 inhibitors.     

Monitoring Binding of HIV‐1 Capsid Assembly Inhibitors Using 19F Ligand‐and 15N Protein‐Based NMR and X‐ray Crystallography: Early Hit Validation of a Benzodiazepine Series

The emergence of resistance to existing classes of antiretroviral drugs underlines the need to find novel human immunodeficiency virus (HIV)‐1 targets for drug discovery. The viral capsid protein (CA) represents one such potential target. Recently, a series of benzodiazepine inhibitors was identified via high‐throughput screening using an in vitro capsid assembly assay (CAA). Here, we demonstrate how a combination of NMR and X‐ray co‐crystallography allowed for the rapid characterization of the early hits from this inhibitor series. Ligand‐based ¹⁹F NMR was used to confirm inhibitor binding specificity and reversibility as well as to identify the N‐terminal domain of the capsid (CA_NTD) as its molecular target. Protein‐based NMR (¹H and ¹⁵N chemical shift perturbation analysis) identified key residues within the CA_NTD involved in inhibitor binding, while X‐ray co‐crystallography confirmed the inhibitor binding site and its binding mode. Based on these results, two conformationally restricted cyclic inhibitors were designed to further validate the possible binding modes. These studies were crucial to early hit confirmation and subsequent lead optimization.     

Matrix Metalloproteinase Inhibition by Heterotrimeric Triple‐Helical Peptide Transition State Analogues

Matrix metalloproteinases (MMPs) have been implicated in numerous pathologies. An overall lack of selectivity has rendered active‐site‐targeted MMP inhibitors problematic. The present study describes MMP inhibitors that function by binding both secondary binding sites (exosites) and the active site. Heterotrimeric triple‐helical peptide transition‐state analogue inhibitors (THPIs) were assembled utilizing click chemistry. Three different heterotrimers were constructed, allowing for the inhibitory phosphinate moiety to be present uniquely in the leading, middle, or trailing strand of the triple helix. All heterotrimeric constructs had sufficient thermally stability to warrant analysis as inhibitors. The heterotrimeric THPIs were effective against MMP‐13 and MT1‐MMP, with K_i values spanning 100–400 nM . Unlike homotrimeric THPIs, the heterotrimeric THPIs offered complete selectivity between MT1‐MMP and MMP‐1. Exosite‐based approaches such as this provide inhibitors with desired MMP selectivities.     

From Type I to Type II: Design,Synthesis, and Characterization of Potent Pyrazin‐2‐ones as DFG‐Out Inhibitors of PDGFRβ

Reversible protein kinase inhibitors that bind in the ATP cleft can be classified as type I or type II binders. Of these, type I inhibitors address the active form, whereas type II inhibitors typically lock the kinase in an inactive form. At the molecular level, the conformation of the flexible activation loop holding the key DFG motif controls access to the ATP site, thereby determining an active or inactive kinase state. Accordingly, type I and type II kinase inhibitors bind to so‐called DFG‐in or DFG‐out conformations, respectively. Based on our former study on highly selective platelet‐derived growth factor receptor β (PDGFRβ) pyrazin‐2‐one type I inhibitors, we expanded this scaffold toward the deep pocket, yielding the highly potent and effective type II inhibitor 5 (4‐[(4‐methylpiperazin‐1‐yl)methyl]‐N‐[3‐[[6‐oxo‐5‐(3,4,5‐trimethoxyphenyl)‐1H‐pyrazin‐3‐yl]methyl]phenyl]benzamide). In vitro characterization, including selectivity panel data from activity‐based assays (300 kinases) and affinity‐based assays (97 kinases) of these PDGFRβ type I ( 1 ; 5‐(4‐hydroxy‐3‐methoxy‐phenyl)‐3‐(3,4,5‐trimethoxyphenyl)‐1H‐pyrazin‐2‐one) and II ( 5 ) inhibitors showing the same pyrazin‐2‐one chemotype are compared. Implications are discussed regarding the data for selectivity and efficacy of type I and type II ligands.     

Inhibitors of Cyclin-Dependent Kinases: Types and Their Mechanism of Action

Recent studies on cyclin-dependent kinase (CDK) inhibitors have revealed that small molecule drugs have become very attractive for the treatment of cancer and neurodegenerative disorders. Most CDK inhibitors have been developed to target the ATP binding pocket. However, CDK kinases possess a very similar catalytic domain and three-dimensional structure. These features make it difficult to achieve required selectivity. Therefore, inhibitors which bind outside the ATP binding site present a great interest in the biomedical field, both from the fundamental point of view and for the wide range of their potential applications. This review tries to explain whether the ATP competitive inhibitors are still an option for future research, and highlights alternative approaches to discover more selective and potent small molecule inhibitors.     

Biological Evaluation and X‐ray Co‐crystal Structures of Cyclohexylpyrrolidine Ligands for Trypanothione Reductase,an Enzyme from the Redox Metabolism of Trypanosoma

The tropical diseases human African trypanosomiasis, Chagas disease, and the various forms of leishmaniasis are caused by parasites of the family of trypanosomatids. These protozoa possess a unique redox metabolism based on trypanothione and trypanothione reductase (TR), making TR a promising drug target. We report the optimization of properties and potency of cyclohexylpyrrolidine inhibitors of TR by structure‐based design. The best inhibitors were freely soluble and showed competitive inhibition constants (K_i) against Trypanosoma (T.) brucei TR and T. cruzi TR and in vitro activities (half‐maximal inhibitory concentration, IC₅₀) against these parasites in the low micromolar range, with high selectivity against human glutathione reductase. X‐ray co‐crystal structures confirmed the binding of the ligands to the hydrophobic wall of the “mepacrine binding site” with the new, solubility‐providing vectors oriented toward the surface of the large active site.     

Binding to Large Enzyme Pockets: Small‐Molecule Inhibitors of Trypanothione Reductase

The causative agents of the parasitic disease human African trypanosomiasis belong to the family of trypanosomatids. These parasitic protozoa exhibit a unique thiol redox metabolism that is based on the flavoenzyme trypanothione reductase (TR). TR was identified as a potential drug target and features a large active site that allows a multitude of possible ligand orientations, which renders rational structure‐based inhibitor design highly challenging. Herein we describe the synthesis, binding properties, and kinetic analysis of a new series of small‐molecule inhibitors of TR. The conjunction of biological activities, mutation studies, and virtual ligand docking simulations led to the prediction of a binding mode that was confirmed by crystal structure analysis. The crystal structures revealed that the ligands bind to the hydrophobic wall of the so‐called “mepacrine binding site”. The binding conformation and potency of the inhibitors varied for TR from Trypanosoma brucei and T. cruzi.