The accumulation of unfolded proteins under endoplasmic reticulum (ER) stress leads to the activation of the multidomain protein sensor IRE1α as part of the unfolded protein response (UPR). Clustering of IRE1α lumenal domains in the presence of unfolded proteins promotes kinase trans-autophosphorylation in the cytosol and subsequent RNase domain activation. Interestingly, there is an allosteric relationship between the kinase and RNase domains of IRE1α, which allows ATP-competitive inhibitors to modulate the activity of the RNase domain. Here, we use kinase inhibitors to study how ATP-binding site conformation affects the activity of the RNase domain of IRE1α. We find that diverse ATP-competitive inhibitors of IRE1α promote dimerization and activation of RNase activity despite blocking kinase autophosphorylation. In contrast, a subset of ATP-competitive ligands, which we call KIRAs, allosterically inactivate the RNase domain through the kinase domain by stabilizing monomeric IRE1α. Further insight into how ATP-competitive inhibitors are able to divergently modulate the RNase domain through the kinase domain was gained by obtaining the first structure of apo human IRE1α in the RNase active back-to-back dimer conformation. Comparison of this structure with other existing structures of IRE1α and integration of our extensive structure activity relationship (SAR) data has led us to formulate a model to rationalize how ATP-binding site ligands are able to control the IRE1α oligomeric state and subsequent RNase domain activity.

New therapies are needed for the treatment of toxoplasmosis, which is a disease caused by the protozoan parasite Toxoplasma gondii. To this end, we previously developed a potent and selective inhibitor (compound 1) of Toxoplasma gondii calcium-dependent protein kinase 1 (TgCDPK1) that possesses antitoxoplasmosis activity in vitro and in vivo. Unfortunately, 1 has potent human ether-a-go-go-related gene (hERG) inhibitory activity, associated with long Q–T syndrome, and consequently presents a cardiotoxicity risk. Here, we describe the identification of an optimized TgCDPK1 inhibitor 32, which does not have a hERG liability and possesses a favorable pharmacokinetic profile in small and large animals. 32 is CNS-penetrant and highly effective in acute and latent mouse models of T. gondii infection, significantly reducing the amount of parasite in the brain, spleen, and peritoneal fluid and reducing brain cysts by >85%. These properties make 32 a promising lead for the development of a new antitoxoplasmosis therapy.

•ATP-competitive kinase inhibitors can affect the regulatory interactions of MAPKs•Conformation-selective inhibitors allow differential modulation of MAPK regulation•MAPK regulation is sensitive to the conformation of their ATP-binding sites•A noncatalytic function of Erk2 can be mediated by ATP-competitive inhibitorsMost potent protein kinase inhibitors act by competing with ATP to block the phosphotransferase activity of their targets. However, emerging evidence demonstrates that ATP-competitive inhibitors can affect kinase interactions and functions in ways beyond blocking catalytic activity. Here, we show that stabilizing alternative ATP-binding site conformations of the mitogen-activated protein kinases (MAPKs) p38α and Erk2 with ATP-competitive inhibitors differentially, and in some cases divergently, modulates the abilities of these kinases to interact with upstream activators and deactivating phosphatases. Conformation-selective ligands are also able to modulate Erk2’s ability to allosterically activate the MAPK phosphatase DUSP6, highlighting how ATP-competitive ligands can control noncatalytic kinase functions. Overall, these studies underscore the relationship between the ATP-binding and regulatory sites of MAPKs and provide insight into how ATP-competitive ligands can be designed to confer graded control over protein kinase function.Figure optionsDownload full-size imageDownload high-quality image (141 K)Download as PowerPoint slide

Multidomain protein kinases, central controllers of signal transduction, use regulatory domains to modulate catalytic activity in a complex cellular environment. Additionally, these domains regulate noncatalytic functions, including cellular localization and protein–protein interactions. Src-family kinases (SFKs) are promising therapeutic targets for a number of diseases and are an excellent model for studying the regulation of multidomain kinases. Here, we demonstrate that the regulatory domains of the SFKs Src and Hck are divergently affected by ligands that stabilize two distinct inactive ATP-binding site conformations. Conformation-selective, ATP-competitive inhibitors differentially modulate the ability of the SH3 and SH2 domains of Src and Hck to engage in intermolecular interactions and the ability of the kinase–inhibitor complex to undergo post-translational modification by effector enzymes. This surprising divergence in regulatory domain behavior by two classes of inhibitors that each stabilize inactive ATP-binding site conformations is found to occur through perturbation or stabilization of the αC helix. These studies provide insight into how conformation-selective, ATP-competitive inhibitors can be designed to modulate domain interactions and post-translational modifications distal to the ATP-binding site of kinases.

•Potent pyrazolopyrimidine-based inhibitors of PfCDPK4 have been identified.•High selectivity for PfCDPK4 over human kinases achieved.•Inhibitors of PfCDPK4 are also able to block Plasmodium falciparum exflagellation.•The ATP-binding sites of several parasite kinases have been profiled.•Molecular determinants of selective PfCDPK4 inhibition characterized.Malaria remains a major health concern for a large percentage of the world's population. While great strides have been made in reducing mortality due to malaria, new strategies and therapies are still needed. Therapies that are capable of blocking the transmission of Plasmodium parasites are particularly attractive, but only primaquine accomplishes this, and toxicity issues hamper its widespread use. In this study, we describe a series of pyrazolopyrimidine- and imidazopyrazine-based compounds that are potent inhibitors of PfCDPK4, which is a calcium-activated Plasmodium protein kinase that is essential for exflagellation of male gametocytes. Thus, PfCDPK4 is essential for the sexual development of Plasmodium parasites and their ability to infect mosquitoes. We demonstrate that two structural features in the ATP-binding site of PfCDPK4 can be exploited in order to obtain potent and selective inhibitors of this enzyme. Furthermore, we demonstrate that pyrazolopyrimidine-based inhibitors that are potent inhibitors of the in vitro activity of PfCDPK4 are also able to block Plasmodium falciparum exflagellation with no observable toxicity to human cells. This medicinal chemistry effort serves as a valuable starting point in the development of safe, transmission-blocking agents for the control of malaria.

Src-family kinases (SFKs) make up a family of nine homologous multidomain tyrosine kinases whose misregulation is responsible for human disease (cancer, diabetes, inflammation, etc.). Despite overall sequence homology and identical domain architecture, differences in SH3 and SH2 regulatory domain accessibility and ability to allosterically autoinhibit the ATP-binding site have been observed for the prototypical SFKs Src and Hck. Biochemical and structural studies indicate that the SH2-catalytic domain (SH2-CD) linker, the intramolecular binding epitope for SFK SH3 domains, is responsible for allosterically coupling SH3 domain engagement to autoinhibition of the ATP-binding site through the conformation of the αC helix. As a relatively unconserved region between SFK family members, SH2-CD linker sequence variability across the SFK family is likely a source of nonredundant cellular functions between individual SFKs via its effect on the availability of SH3 and SH2 domains for intermolecular interactions and post-translational modification. Using a combination of SFKs engineered with enhanced or weakened regulatory domain intramolecular interactions and conformation-selective inhibitors that report αC helix conformation, this study explores how SH2-CD sequence heterogeneity affects allosteric coupling across the SFK family by examining Lyn, Fyn1, and Fyn2. Analyses of Fyn1 and Fyn2, isoforms that are identical but for a 50-residue sequence spanning the SH2-CD linker, demonstrate that SH2-CD linker sequence differences can have profound effects on allosteric coupling between otherwise identical kinases. Most notably, a dampened allosteric connection between the SH3 domain and αC helix leads to greater autoinhibitory phosphorylation by Csk, illustrating the complex effects of SH2-CD linker sequence on cellular function.

•Only some protein kinases have been shown to adopt specific inactive conformations•Two residues were found that confer sensitivity to ligands stabilizing the DFG-out inactive form•Kinases in two distinct families were sensitized to these ligands•Structural evidence is given of mutant Erk2 in the DFG-out inactive conformationOnly a small percentage of protein kinases have been shown to adopt a distinct inactive ATP-binding site conformation, called the Asp-Phe-Gly-out (DFG-out) conformation. Given the high degree of homology within this enzyme family, we sought to understand the basis of this disparity on a sequence level. We identified two residue positions that sensitize mitogen-activated protein kinases (MAPKs) to inhibitors that stabilize the DFG-out inactive conformation. After characterizing the structure and dynamics of an inhibitor-sensitive MAPK mutant, we demonstrated the generality of this strategy by sensitizing a kinase (apoptosis signal-regulating kinase 1) not in the MAPK family to several DFG-out stabilizing ligands, using the same residue positions. The use of specific inactive conformations may aid the study of noncatalytic roles of protein kinases, such as binding partner interactions and scaffolding effects.Figure optionsDownload full-size imageDownload high-quality image (305 K)Download as PowerPoint slide

Over the past decade, an increasingly diverse array of potent and selective inhibitors that target the ATP-binding sites of protein kinases have been developed. Many of these inhibitors, like the clinically approved drug imatinib (Gleevec), stabilize a specific catalytically inactive ATP-binding site conformation of their kinases targets. Imatinib is notable in that it is highly selective for its kinase target, Abl, over other closely related tyrosine kinases, such as Src. In addition, imatinib is highly sensitive to the phosphorylation state of Abl’s activation loop, which is believed to be a general characteristic of all inhibitors that stabilize a similar inactive ATP-binding site conformation. In this report, we perform a systematic analysis of a diverse series of ATP-competitive inhibitors that stabilize a similar inactive ATP-binding site conformation as imatinib with the tyrosine kinases Src and Abl. In contrast to imatinib, many of these inhibitors have very similar potencies against Src and Abl. Furthermore, only a subset of this class of inhibitors is sensitive to the phosphorylation state of the activation loop of these kinases. In attempting to explain this observation, we have uncovered an unexpected correlation between Abl’s activation loop and another flexible active site feature, called the phosphate-binding loop (p-loop). These studies shed light on how imatinib is able to obtain its high target selectivity and reveal how the conformational preference of flexible active site regions can vary between closely related kinases.

Bioorthogonal ligation methods that allow the selective conjugation of fluorophores or biotin to proteins and small molecule probes that contain inert chemical handles are an important component of many chemical proteomic strategies. Here, we present a new catch-and-release enrichment strategy that utilizes a hexylchloride group as a bioorthogonal chemical handle. Proteins and small molecules that contain a hexylchloride tag can be efficiently captured by an immobilized version of the self-labeling protein HaloTag. Furthermore, by using a HaloTag fusion protein that contains a protease cleavage site, captured proteins can be selectively eluted under mild conditions. We demonstrate the utility of the hexylchloride-based catch-and-release strategy by enriching protein kinases that are covalently and noncovalently bound to ATP-binding site-directed probes from mammalian cell lysates. Our catch-and-release system creates new possibilities for profiling enzyme families and for the identification of the cellular targets of bioactive small molecules.

Protein kinases are key components of most mammalian signal transduction networks and are therapeutically relevant drug targets. Efforts to study protein kinase function would benefit from new technologies that are able to profile kinases in complex proteomes. Here, we describe active site-directed probes for profiling kinases in whole cell extracts and live cells. These probes contain general ligands that stabilize a specific inactive conformation of the ATP-binding sites of protein kinases, as well as trifluoromethylphenyl diazirine and alkyne moieties that allow covalent modification and enrichment of kinases, respectively. A diverse group of serine/threonine and tyrosine kinases were identified as specific targets of these probes in whole cell extracts. In addition, a number of kinase targets were selectively labeled in live cells. Our chemical proteomics approach should be valuable for interrogating protein kinase active sites in physiologically relevant environments.

Toxoplasmosis is a disease of prominent health concern that is caused by the protozoan parasite Toxoplasma gondii. Proliferation of T. gondii is dependent on its ability to invade host cells, which is mediated in part by calcium-dependent protein kinase 1 (CDPK1). We have developed ATP competitive inhibitors of TgCDPK1 that block invasion of parasites into host cells, preventing their proliferation. The presence of a unique glycine gatekeeper residue in TgCDPK1 permits selective inhibition of the parasite enzyme over human kinases. These potent TgCDPK1 inhibitors do not inhibit the growth of human cell lines and represent promising candidates as toxoplasmosis therapeutics.

Diseases caused by the apicomplexan protozoans Toxoplasma gondii and Cryptosporidium parvum are a major health concern. The life cycle of these parasites is regulated by a family of calcium-dependent protein kinases (CDPKs) that have no direct homologues in the human host. Fortuitously, CDPK1 from both parasites contains a rare glycine gatekeeper residue adjacent to the ATP-binding pocket. This has allowed creation of a series of C3-substituted pyrazolopyrimidine compounds that are potent inhibitors selective for CDPK1 over a panel of human kinases. Here we demonstrate that selectivity is further enhanced by modification of the scaffold at the C1 position. The explanation for this unexpected result is provided by crystal structures of the inhibitors bound to CDPK1 and the human kinase c-SRC. Furthermore, the insight gained from these studies was applied to transform an alternative ATP-competitive scaffold lacking potency and selectivity for CDPK1 into a low nanomolar inhibitor of this enzyme with no activity against SRC.

The identification of potent and selective modulators of protein kinase function remains a challenge, and new strategies are needed for generating these useful ligands. Here, we describe the generation of bivalent inhibitors of three unrelated protein kinases: the CAMK family kinase Pim1, the mitogen-activated protein kinase (MAPK) p38α, and the receptor tyrosine kinase (RTK) epidermal growth factor receptor (EGFR). These bivalent inhibitors consist of an ATP-competitive inhibitor that is covalently tethered to an engineered form of the self-labeling protein O6-alkylguanine-DNA alkyltransferase (SNAP-tag). In each example, SNAP-tag is fused to a peptide ligand that binds to a signaling interaction site of the kinase being targeted. These interactions increase the overall selectivity and potency of the bivalent inhibitors that were generated. The ability to exploit disparate binding sites in diverse kinases points to the generality of the method described. Finally, we demonstrate that ATP-competitive inhibitors that are conjugated to the bio-orthogonal tag O4-benzyl-2-chloro-6-aminopyrimidine (CLP) are cell-permeable. The selective labeling of SNAP-tag with CLP conjugates allows the rapid assembly of bivalent inhibitors in living cells.

We recently reported a chemical genetic method for generating bivalent inhibitors of protein kinases. This method relies on the use of the DNA repair enzymeO6-alkylguanine-DNA alkyltransferase (AGT) to display an ATP-competitive inhibitor and a ligand that targets a secondary binding domain. With this method potent and selective inhibitors of the tyrosine kinases SRC and ABL were identified. Here, we dissect the molecular determinants of the potency and selectivity of these bivalent ligands. Systematic analysis of ATP-competitive inhibitors with varying linker lengths revealed that SRC and ABL have differential sensitivities to ligand presentation. Generation of bivalent constructs that contain ligands with differential affinities for the ATP-binding sites and SH3 domains of SRC and ABL demonstrated the modular nature of inhibitors based on the AGT scaffold. Furthermore, these studies revealed that the interaction between the SH3 domain ligand and the kinase SH3 domain is the major selectivity determinant amongst closely-related tyrosine kinases. Finally, the potency of bivalent inhibitors against distinct phospho-isoforms of SRC was determined. Overall, these results provide insight into how individual ligands can be modified to provide more potent and selective bivalent inhibitors of protein kinases.

Bcl-2 family proteins are key mediators of programmed cell death. Over-expression of anti-apoptotic Bcl-2 family members (Bcl-2, Bcl-xL, and Mcl-1) has been associated with tumor progression and chemotherapeutic resistance. Pharmacological agents that neutralize the functions of anti-apoptotic Bcl-2 family proteins have emerged as a promising new class of anti-cancer agents. Biochemical analyses have demonstrated that small molecule inhibitors and some pro-apoptotic proteins exhibit distinct binding preferences for anti-apoptotic proteins. While numerous structures of anti-apoptotic proteins bound to ligands have been reported, the source of this selectivity is still unclear. Here, we present a systematic analysis of a series of Bcl-xL variants that contain mutations within the hydrophobic ligand-binding cleft. The ability of these Bcl-xL mutants to interact with both small molecule inhibitors and BH3 peptides was determined. These studies provide information on the contributions of specific residues to small molecule inhibitor binding and shed light on the ligand selectivity of these therapeutically important proteins.

A number of small-molecule inhibitors have been developed that target the catalytic domains of protein kinases that are not in an active conformation. An inactive form that has been observed in several kinases is the DFG-out conformation. This conformation is characterized by an almost 180° rotation of the conserved Asp-Phe-Gly (DFG) motif in the ATP-binding cleft relative to the active form. However, the sequence and structural determinants that allow a kinase to stably adopt the DFG-out conformation are not known. Here, we characterize a series of inhibitors based on a general pharmacophore for this inactive form. We demonstrate that modified versions of these inhibitors can be used to study the thermodynamics and kinetics of ligand binding to DFG-out-adopting kinases and for enriching these kinases from complex protein mixtures.Graphical AbstractFigure optionsDownload full-size imageDownload high-quality image (251 K)Download as PowerPoint slideHighlights► The determinants that allow kinases to adopt different inactive forms are not known ► A pharmacophore for a specific inactive form (DFG-out) of kinases was identified ► Immobilized type II inhibitors effectively enrich DFG-out-adopting kinases ► A STE20 kinase, LOK, was identified as a DFG-out-adopting protein kinase

Protein kinases have emerged as one of the most frequently targeted families of proteins in drug discovery. While the development of small-molecule inhibitors that have the potency and selectivity necessary to be effective cancer drugs is still a formidable challenge, there have been several notable successes in this area over the past decade. However, in the course of the clinical use of these inhibitors, it has become apparent that drug resistance is a recurring problem. Because kinase inhibitors act by targeting a specific kinase or set of kinases, there is a strong selective pressure for the development of mutations that hinder drug binding but preserve the catalytic activity of these enzymes. To date, resistance mutations to clinically approved kinase inhibitors have been identified in a number of kinases. This review will highlight recent work that has been performed to understand how mutations in the kinase catalytic domain confer drug resistance. In addition, recent experimental efforts to predict potential sites of clinical drug resistance will be discussed.Keywords: DFG motif: A conserved Asp-Phe-Gly motif that is at the beginning of the activation loop of protein kinases. The conformation of the DFG motif controls access to a specificity pocket adjacent to ATP-binding site.; Gatekeeper residue: A residue that lines the adenine-binding site in the ATP-binding pocket of protein kinases. The size of the side chain at this position controls access to a hydrophobic pocket (Hydrophobic Pocket II) adjacent to the site of ATP binding.; Hydrogen bond: The sharing of a proton between two electronegative atoms.; IC50: Inhibitor concentration that causes a 50 percent decrease in enzyme activity.; Imatinib: A 2-phenylaminopyrimidine inhibitor that targets the ATP-binding site of BCR-ABL. Currently, imatinib is used to treat chronic myelogenous leukemia (CML) and several other types of cancer.; Kd: The equilibrium dissociation constant.; P-loop: The phosphate-binding loop (also called the glycine-rich loop (G-loop)). In kinases, the P-loop is a flexible, glycine-rich loop that interacts with the phosphate groups of ATP and forms the roof of the ATP-binding pocket.; Protein kinase: An enzyme that catalyzes the transfer of the γ-phosphate of ATP to a serine, threonine, or tyrosine residue in a peptide/protein substrate.

The protozoans Cryptosporidium parvum and Toxoplasma gondii are parasites of major health concern to humans. Both parasites contain a group of calcium-dependent protein kinases (CDPKs) which are found in plants and ciliates but not in humans or fungi. Here, we describe a series of potent inhibitors that target CDPK1 in C. parvum (CpCDPK1) and T. gondii (TgCDPK1). These inhibitors are highly selective for CpCDPK1 and TgCDPK1 over the mammalian kinases SRC and ABL. Furthermore, they are able to block an early stage of C. parvum invasion of HCT-8 host cells, which is similar to their effects on T. gondii invasion of human fibroblasts.Keywords (keywords): apicomplexan; calcium-dependent protein kinases; Cryptosporidium parvum; Phosphorylation; protozoans; Toxoplasma gondii

We report a new chemical genetic method for creating bivalent ligands of protein kinases. The kinase inhibitors that are generated with this methodology consist of two components: (1) a synthetic, small molecule that targets the ATP-binding cleft and (2) a peptidic ligand that enhances selectivity between kinases by targeting a secondary binding domain. A key feature of these bivalent inhibitors is that they are assembled on a protein scaffold with a chemoselective protein labeling technique. The utility of this methodology is demonstrated through the generation of a panel of protein-small molecule conjugates that simultaneously target the SH1 and SH3 domains of the closely related tyrosine kinases Src and Abl. The assembled bivalent ligands are significantly more potent inhibitors of Src and Abl than either modular component alone. Importantly, these protein-small molecule conjugates show a high degree of selectivity for their intended kinase target.

Selective, pharmacological agents are attractive tools for studying signal transduction because they allow rapid, reversible, and dose-dependent control over intracellular protein function. However, for many targets the identification of potent and selective small molecule agonists and antagonists is a formidable challenge. An attractive strategy for circumventing this problem is to engineer a protein of interest to be sensitive to a pharmacological agent of choice. Here, we report a chemical genetic method for regulating the catalytic activity of signaling enzymes with a small molecule. This approach uses the interaction of the antiapoptotic protein Bcl-xL and a BH3 peptide as an autoinhibitory switch that can be controlled with a small molecule. We applied this strategy to the guanine nucleotide exchange factor Intersectin, which is a selective activator of the GTPase Cdc42. Replacing Intersectin’s regulatory domains with the BH3 peptide/Bcl-xL binding module generated a panel of synthetic GEF constructs that can be activated with a competitive ligand. Importantly, the nucleotide exchange activities of these synthetic Intersectin constructs can be controlled in a rapid and dose-dependent manner. The modular nature of this strategy should make it useful for engineering other enzymes involved in signal transduction.

Immobilized kinase inhibitors have emerged as powerful reagents for the determination of kinase inhibitor selectivity and for the enrichment of protein targets from cellular lysates. Here, we report the design and synthesis of a set of “clickable” 4-anilinoquinazolinekinase inhibitors. We demonstrate that the attachment of a flexible tether that contains a bio-orthogonal azide functionality does not adversely affect the potency or selectivity of these inhibitors. Furthermore, we demonstrate the utility of these inhibitors through the generation of an affinity matrix for the enrichment of interacting proteins from cellular lysates.

Despite the importance that many components of the intermembrane space (IMS) of mitochondria play in cellular function, the targeting sequences that are responsible for transporting proteins to this subcellular compartment are not fully understood. A recent study has identified a minimized protein sequence that is sufficient for localizing the apoptogenic protein Smac/DIABLO in the IMS. This newly identified targeting sequence is capable of directing other proteins to this submitochondrial compartment as well.