Structural and Molecular Insight into Resistance Mechanisms of First Generation cMET Inhibitors (original) (raw)
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Design Strategies, Structures and Molecular Interactions of Small Molecule Src Inhibitors
Anti-Cancer Agents in Medicinal Chemistry, 2016
In recent years, several small molecules approved by FDA for clinical studies are promising anti-cancer agent. Among the kinases, Abelson Leukaemia (Abl), sarcoma (Src), epidermal growth factor receptor (EGFR) and vascular endotelhial growth factor receptor (VEGFR) are considered as primary molecular targets for selective inhibition and the best successful targeted therapy of tyrosine kinase inhibitors (TKIs) has been achieved in the treatment of Bcr (break point cluster)-Abl leukemia. The majority of type 1 kinase inhibitors target the active conformation of ATP binding site. In consequence of intensive studies on kinases, type 2, type 3 (allosteric) and type 4 (covalent) inhibitors have been discovered beyond the type 1 inhibitors. Although the selectivity is a major problem for type 1 inhibitors, these new type of inhibitors are promising for finding new selective compounds, which may provide other therapeutic options for cancer therapy. They may also be a solution to overcome drug resistance that remains unresolved yet. Threedimensional structural determination provides the development of specific and highly binding properties of compounds. Studying the prediction of a binding mode of inhibitors, homology model developments from kinaseligand co-crystal structures and isosteric replacements have been used to improve binding properties of inhibitors. In this review, critical results related to the design strategies of kinase specifically targeted to Src and Bcr-Abl kinases and therapeutic potential of novel inhibitors will be evaluated. The readers will be endowed with the functional role of Src and Bcr-Abl kinases that lead inhibitor design, the structural analysis of binding modes of kinase inhibitors, the current progress in terms of therapeutic interventions and the mission of leading groups in the field.
Structural biology contributions to tyrosine kinase drug discovery
Current Opinion in Cell Biology, 2009
Successful kinase inhibitor drug discovery relies heavily on the structural knowledge of the interaction of inhibitors with the target. Structural biology of kinases and in particular of tyrosine kinases has given detailed insights into the intrinsic flexibility of the catalytic domain and has provided a rational basis for obtaining selective inhibitors. Important progress has been made recently, both in academia and in the pharmaceutical industry, with respect to solving structures of inactive, multidomain or protein-protein complexes of kinases, which helps our understanding of the dynamics of regulation of kinase activity. This leads to a better understanding of how mutations lead to activation of kinases and resistance, in addition to providing opportunities for novel modes of targeting kinases.
Structural insight into selectivity and resistance profiles of ROS1 tyrosine kinase inhibitors
Proceedings of the National Academy of Sciences of the United States of America, 2015
Oncogenic ROS1 fusion proteins are molecular drivers in multiple malignancies, including a subset of non-small cell lung cancer (NSCLC). The phylogenetic proximity of the ROS1 and anaplastic lymphoma kinase (ALK) catalytic domains led to the clinical repurposing of the Food and Drug Administration (FDA)-approved ALK inhibitor crizotinib as a ROS1 inhibitor. Despite the antitumor activity of crizotinib observed in both ROS1- and ALK-rearranged NSCLC patients, resistance due to acquisition of ROS1 or ALK kinase domain mutations has been observed clinically, spurring the development of second-generation inhibitors. Here, we profile the sensitivity and selectivity of seven ROS1 and/or ALK inhibitors at various levels of clinical development. In contrast to crizotinib's dual ROS1/ALK activity, cabozantinib (XL-184) and its structural analog foretinib (XL-880) demonstrate a striking selectivity for ROS1 over ALK. Molecular dynamics simulation studies reveal structural features that di...
Structural insights into how irreversible inhibitors can overcome drug resistance in EGFR
Bioorganic & Medicinal Chemistry, 2008
Resistance to kinase-targeted cancer drugs has recently been linked to a single point mutation in the ATP binding site of the kinase. In EGFR, the crucial Thr790 gatekeeper residue is mutated to a Met and prevents reversible ATP competitive inhibitors from binding. Irreversible 4-(phenylamino)quinazolines have been shown to overcome this drug resistance and are currently in clinical trials. In order to obtain a detailed structural understanding of how irreversible inhibitors overcome drug resistance, we used Src kinase as a model system for drug resistant EGFR-T790M. We report the first crystal structure of a drug resistant kinase in complex with an irreversible inhibitor. This 4-(phenylamino)quinazoline inhibits wild type and drug resistant EGFR in vitro at low nM concentrations. The co-crystal structure of drug resistant cSrc-T338M kinase domain provides the structural basis of this activity.
Asian Pacific Journal of Cancer Prevention, 2020
Objective: BCR-ABL fusion oncogene is the hallmark of chronic myeloid leukemia (CML), causing genomic instability which leads to accumulation of mutations in BCR-ABL as well as other genes. BCR-ABL mutations are the cause of tyrosine kinase inhibitors (TKIs) resistance in CML. Recently, compound BCR-ABL mutations have been reported to resist all FDA approved TKIs. Therefore, finding novel compound BCR-ABL mutations can help and clinically manage CML. Therefore, our objective was to find out novel drug-resistant compound BCR-ABL mutations in CML and carry out their protein modelling studies. Methodology: Peripheral blood samples were collected from ten imatinib resistant CML patients receiving nilotinib treatment. BCR-ABL transcript mutations were investigated by employing capillary sequencing. Patient follow-up was carried out using European LeukemiaNet guidelines. Protein modeling studies were carried out for new compound mutations using PyMol to see the effects of mutations at structural level. Results: A novel compound mutation (K245N mutation along with G250W mutation) and previously known T351I utation was detected in two of the nilotinib resistance CML patients respectively while in the rest of 8 nilotinib responders, no resistant mutations were detected. Protein modelling studies indicated changes in BCR-ABL mutant protein which may have negatively impacted its binding with nilotinib leading to drug resistance. Conclusion: We report a novel nilotinib resistant BCR-ABL compound mutation (K245N along with G250W mutation) which impacts structural modification in BCR-ABL mutant protein leading to drug resistance. As compound mutations pose a new threat by causing resistance to all FDA approved tyrosine kinase inhibitors in BCR-ABL+ leukemias, our study opens a new direction for in vitro characterization of novel BCR-ABL compound mutations and their resistant to second generation and third generation TKIs.
Journal of Advanced Research, 2022
Structure-function Targeted-therapies Drug-discovery with higher druggability potential than the adenine-binding site and with important implications in the regulation of phospho-tyrosine kinase activity. Crystal structure and simulation data show that the binding mode of highly-selective RET kinase inhibitors LOXO-292 and BLU-667 is controlled by a synchronous open P-loop and aC-in configuration that allows accessibility to the post-lysine pocket. Molecular dynamics simulation show that these inhibitors efficiently occupy the post-lysine pocket with high stability through the simulation timescale (300 ns), with both inhibitors forming hydrophobic contacts in the pocket further stabilized by pi-cation interactions with the catalytic K758. Engineered mutants targeting the post-lysine pocket impact on inhibitor binding and sensitivity, as well as RET tyrosine kinase activity. Conclusions: The identification of the post-lysine pocket as a cryptic druggable vulnerability in the RET kinase and its exploitation by second generation RET inhibitors has important implications for future drug design and the development of personalized therapies for patients with RET-driven cancers.
Structural Insights into the Design of Small Molecule Inhibitors That Selectively Antagonize Mcl-1
Journal of Medicinal Chemistry, 2010
Despite their structural similarities, the natural products chelerythrine (5) and sanguinarine (6) target different binding sites on the pro-survival Bcl-X L protein. This paper details the synthesis of phenanthridine-based analogues of the natural products that were used to probe this difference in binding profiles. The inhibitory constants for these compounds were then measured in a fluorescence polarization assay against Bcl-X L and the tagged Bak-BH3 peptide. The results led to structure-activity relationship studies, which identified the structural motifs required for binding-site specificity as well as inhibitory activity. We also identified synthetic analogues of the natural products that display similar binding modes but with more potent IC 50 values. Figure 1. Structures of some small molecule inhibitors of Bcl-XL.
Journal of Biological Chemistry, 2019
Edited by Xiao-Fan Wang RET is a transmembrane growth factor receptor. Aberrantly activated RET is found in several types of human cancer and is a target for treating RET aberration-associated cancer. Multiple clinically relevant RET protein-tyrosine kinase inhibitors (TKIs) have been identified, but how TKIs bind to RET is unknown except for vandetanib. Nintedanib is a RET TKI that inhibits the vandetanib-resistant RET(G810A) mutant. Here, we determined the X-ray co-crystal structure of RET kinase domain-nintedanib complex to 1.87 Å resolution and a RET(G810A) kinase domain crystal structure to 1.99 Å resolution. We also identified a vandetanib-resistant RET(L881V) mutation previously found in familial medullary thyroid carcinoma. Drug-sensitivity profiling of RET(L881V) revealed that it remains sensitive to nintedanib. The RET-nintedanib co-crystal structure disclosed that Leu-730 in RET engages in hydrophobic interactions with the piperazine, anilino, and phenyl groups of nintedanib, providing a structural basis for explaining
PLOS ONE
Multidrug resistance protein 4 (MRP4/ABCC4) is an ATP-binding cassette (ABC) transporter. It is associated with multidrug resistance (MDR), which is becoming a growing challenge to the treatment of cancer and infections. In the context of several types of cancer in which MRP4 is overexpressed, MRP4 inhibition manifests striking effects against cancer progression and drug resistance. In this study, we combined ligand-based and structurebased drug design strategy, by searching the SPECS chemical library to find compounds that are most likely to bind to MRP4. Clustering analysis based on a two-dimensional fingerprint was performed to help with visual selection of potential compounds. Cell viability assays with potential inhibitors and the anticancer drug 6-MP were carried out to identify their bioactivity. As a result, 39 compounds were tested and seven of them reached inhibition above 55% with 6-MP. Then compound Cpd23 was discovered to improve HEK293/ MRP4 cell sensibility to 6-MP dramatically, and low concentration Cpd23 (5 μM) achieved the equivalent effect of 50 μM MK571. The accumulation of 6-MP was determined by validated high-performance liquid chromatography methods, and pretreatment of the HEK293/ MRP4 cells with 50 μM MK571 or Cpd23 resulted in significantly increased accumulation of 6-MP by approximately 1.5 times. This compound was first reported with a novel scaffold compared with previously known MRP4 inhibitors, which is a hopeful molecular tool that can be used for overcoming multidrug resistance research.