Catalytic Degraders Effectively Address Kinase Site Mutations in EML4-ALK Oncogenic Fusions.

Heterobifunctional degraders, known as proteolysis targeting chimeras (PROTACs), theoretically possess a catalytic mode-of-action, yet few studies have either confirmed or exploited this potential advantage of event-driven pharmacology. Degraders of oncogenic EML4-ALK fusions were developed by conjugating ALK inhibitors to cereblon ligands. Simultaneous optimization of pharmacology and compound properties using ternary complex modeling and physicochemical considerations yielded multiple catalytic degraders that were more resilient to clinically relevant ATP-binding site mutations than kinase inhibitor drugs. Our strategy culminated in the design of the orally bioavailable derivative CPD-1224 that avoided hemolysis (a feature of detergent-like PROTACs), degraded the otherwise recalcitrant mutant L1196M/G1202R in vivo, and commensurately slowed tumor growth, while the third generation ALK inhibitor drug lorlatinib had no effect. These results validate our original therapeutic hypothesis by exemplifying opportunities for catalytic degraders to proactively address binding site resistant mutations in cancer.

[1]  Zhe-Sheng Chen,et al.  Development of Alectinib-Based PROTACs as Novel Potent Degraders of Anaplastic Lymphoma Kinase (ALK). , 2021, Journal of medicinal chemistry.

[2]  B. Jiang,et al.  Structure-based discovery of SIAIS001 as an oral bioavailability ALK degrader constructed from Alectinib. , 2021, European journal of medicinal chemistry.

[3]  Jie Yang,et al.  Discovery of a PROTAC targeting ALK with in vivo activity. , 2021, European journal of medicinal chemistry.

[4]  R. Nowak,et al.  Target Validation Using PROTACs: Applying the Four Pillars Framework , 2020, SLAS discovery : advancing life sciences R & D.

[5]  N. Gray,et al.  Mapping the Degradable Kinome Provides a Resource for Expedited Degrader Development , 2020, Cell.

[6]  Stephen Brown,et al.  Snapshots and ensembles of BTK and cIAP1 protein degrader ternary complexes , 2020, Nature Chemical Biology.

[7]  D. Mcginnity,et al.  Optimising proteolysis-targeting chimeras (PROTACs) for oral drug delivery: a drug metabolism and pharmacokinetics perspective. , 2020, Drug discovery today.

[8]  Aditya R. Thawani,et al.  Extended pharmacodynamic responses observed upon PROTAC-mediated degradation of RIPK2 , 2020, Communications Biology.

[9]  B. Jiang,et al.  Development of a Brigatinib degrader (SIAIS117) as a potential treatment for ALK positive cancer resistance. , 2020, European journal of medicinal chemistry.

[10]  C. Crews,et al.  Proteolysis-Targeting Chimeras as Therapeutics and Tools for Biological Discovery , 2020, Cell.

[11]  Philip P. Chamberlain,et al.  Development of targeted protein degradation therapeutics , 2019, Nature Chemical Biology.

[12]  Nathanael S Gray,et al.  Small molecule degraders of the hepatitis C virus protease reduce susceptibility to resistance mutations , 2019, Nature Communications.

[13]  Michelle C. Chen,et al.  Crbn I391V is sufficient to confer in vivo sensitivity to thalidomide and its derivatives in mice. , 2018, Blood.

[14]  Liu Liu,et al.  Discovery of QCA570 as an Exceptionally Potent and Efficacious Proteolysis Targeting Chimera (PROTAC) Degrader of the Bromodomain and Extra-Terminal (BET) Proteins Capable of Inducing Complete and Durable Tumor Regression. , 2018, Journal of medicinal chemistry.

[15]  J. Byrd,et al.  Targeting the C481S Ibrutinib-Resistance Mutation in Bruton's Tyrosine Kinase Using PROTAC-Mediated Degradation. , 2018, Biochemistry.

[16]  Y. Xiong,et al.  Proteolysis Targeting Chimeras (PROTACs) of Anaplastic Lymphoma Kinase (ALK). , 2018, European journal of medicinal chemistry.

[17]  P. Jänne,et al.  Chemically Induced Degradation of Anaplastic Lymphoma Kinase (ALK). , 2018, Journal of medicinal chemistry.

[18]  T. Willson,et al.  Quantitative, Wide-Spectrum Kinase Profiling in Live Cells for Assessing the Effect of Cellular ATP on Target Engagement , 2017, Cell chemical biology.

[19]  L. Jones Small-Molecule Kinase Downregulators. , 2017, Cell chemical biology.

[20]  Kris Zimmerman,et al.  CRISPR-Mediated Tagging of Endogenous Proteins with a Luminescent Peptide. , 2017, ACS chemical biology.

[21]  Bin Fang,et al.  Polypharmacology-based ceritinib repurposing using integrated functional proteomics. , 2017, Nature chemical biology.

[22]  R. Bayliss,et al.  EML4-ALK Variants: Biological and Molecular Properties, and the Implications for Patients , 2017, Cancers.

[23]  T. Clackson,et al.  Discovery of Brigatinib (AP26113), a Phosphine Oxide-Containing, Potent, Orally Active Inhibitor of Anaplastic Lymphoma Kinase. , 2016, Journal of medicinal chemistry.

[24]  G. Petzold,et al.  Structural basis of lenalidomide-induced CK1α degradation by the CRL4CRBN ubiquitin ligase , 2016, Nature.

[25]  I. E. Smith,et al.  Catalytic in vivo protein knockdown by small-molecule PROTACs. , 2015, Nature chemical biology.

[26]  Shibing Deng,et al.  PF-06463922, an ALK/ROS1 Inhibitor, Overcomes Resistance to First and Second Generation ALK Inhibitors in Preclinical Models. , 2015, Cancer cell.

[27]  James E. Bradner,et al.  Phthalimide conjugation as a strategy for in vivo target protein degradation , 2015, Science.

[28]  C. Crews,et al.  Hijacking the E3 Ubiquitin Ligase Cereblon to Efficiently Target BRD4. , 2015, Chemistry & biology.

[29]  Wei Liu,et al.  Discovery of (10R)-7-amino-12-fluoro-2,10,16-trimethyl-15-oxo-10,15,16,17-tetrahydro-2H-8,4-(metheno)pyrazolo[4,3-h][2,5,11]-benzoxadiazacyclotetradecine-3-carbonitrile (PF-06463922), a macrocyclic inhibitor of anaplastic lymphoma kinase (ALK) and c-ros oncogene 1 (ROS1) with preclinical brain expos , 2014, Journal of medicinal chemistry.

[30]  Sungjoon Kim,et al.  Synthesis, structure-activity relationships, and in vivo efficacy of the novel potent and selective anaplastic lymphoma kinase (ALK) inhibitor 5-chloro-N2-(2-isopropoxy-5-methyl-4-(piperidin-4-yl)phenyl)-N4-(2-(isopropylsulfonyl)phenyl)pyrimidine-2,4-diamine (LDK378) currently in phase 1 and phase 2 , 2013, Journal of medicinal chemistry.

[31]  Paul Workman,et al.  ATP-competitive inhibitors block protein kinase recruitment to the Hsp90-Cdc37 system. , 2013, Nature chemical biology.

[32]  S. Yamazaki Translational Pharmacokinetic-Pharmacodynamic Modeling from Nonclinical to Clinical Development: A Case Study of Anticancer Drug, Crizotinib , 2013, The AAPS Journal.

[33]  H. Sakamoto,et al.  Design and synthesis of a highly selective, orally active and potent anaplastic lymphoma kinase inhibitor (CH5424802). , 2012, Bioorganic & medicinal chemistry.

[34]  Mindy I. Davis,et al.  Comprehensive analysis of kinase inhibitor selectivity , 2011, Nature Biotechnology.

[35]  J. Christensen,et al.  Structure based drug design of crizotinib (PF-02341066), a potent and selective dual inhibitor of mesenchymal-epithelial transition factor (c-MET) kinase and anaplastic lymphoma kinase (ALK). , 2011, Journal of medicinal chemistry.

[36]  S. Doniach,et al.  Size and shape of detergent micelles determined by small-angle X-ray scattering. , 2007, The journal of physical chemistry. B.

[37]  Ronald D Snyder,et al.  In vitro detection of drug-induced phospholipidosis using gene expression and fluorescent phospholipid based methodologies. , 2007, Toxicological sciences : an official journal of the Society of Toxicology.

[38]  H. Aburatani,et al.  Identification of the transforming EML4–ALK fusion gene in non-small-cell lung cancer , 2007, Nature.

[39]  Peter G. Schultz,et al.  Identification of NVP-TAE684, a potent, selective, and efficacious inhibitor of NPM-ALK , 2007, Proceedings of the National Academy of Sciences.

[40]  R. Dannenfelser,et al.  In vitro hemolysis: guidance for the pharmaceutical scientist. , 2006, Journal of pharmaceutical sciences.

[41]  Stephen R. Johnson,et al.  Molecular properties that influence the oral bioavailability of drug candidates. , 2002, Journal of medicinal chemistry.