Sequential Administration of XPO1 and ATR Inhibitors Enhances Therapeutic Response in TP53-mutated Colorectal Cancer

BACKGROUND & AIMS

Understanding the mechanisms by which tumors adapt to therapy is critical for developing effective combination therapeutic approaches to improve clinical outcomes for patients with cancer.

METHODS

To identify promising and clinically actionable targets for managing colorectal cancer (CRC), we conducted a patient-centered functional genomics platform that includes approximately 200 genes and paired this with a high-throughput drug screen that includes 262 compounds in four patient-derived xenografts (PDXs) from patients with CRC.

RESULTS

Both screening methods identified exportin 1 (XPO1) inhibitors as drivers of DNA damage-induced lethality in CRC. Molecular characterization of the cellular response to XPO1 inhibition uncovered an adaptive mechanism that limited the duration of response in TP53-mutated, but not in TP53-wild-type CRC models. Comprehensive proteomic and transcriptomic characterization revealed that the ATM/ATR-CHK1/2 axes were selectively engaged in TP53-mutant CRC cells upon XPO1 inhibitor treatment and that this response was required for adapting to therapy and escaping cell death. Administration of KPT-8602, an XPO1 inhibitor, followed by AZD-6738, an ATR inhibitor, resulted in dramatic antitumor effects and prolonged survival in TP53-mutant models of CRC.

CONCLUSIONS

Our findings anticipate tremendous therapeutic benefit and support the further evaluation of XPO1 inhibitors, especially in combination with DNA damage checkpoint inhibitors, to elicit an enduring clinical response in patients with CRC harboring TP53 mutations.

Allosteric SHP2 Inhibitor, IACS-13909, Overcomes EGFR-Dependent and EGFR-Independent Resistance Mechanisms toward Osimertinib

Src homology 2 domain-containing phosphatase (SHP2) is a phosphatase that mediates signaling downstream of multiple receptor tyrosine kinases (RTK) and is required for full activation of the MAPK pathway. SHP2 inhibition has demonstrated tumor growth inhibition in RTK-activated cancers in preclinical studies. The long-term effectiveness of tyrosine kinase inhibitors such as the EGFR inhibitor (EGFRi), osimertinib, in non-small cell lung cancer (NSCLC) is limited by acquired resistance. Multiple clinically identified mechanisms underlie resistance to osimertinib, including mutations in EGFR that preclude drug binding as well as EGFR-independent activation of the MAPK pathway through alternate RTK (RTK-bypass). It has also been noted that frequently a tumor from a single patient harbors more than one resistance mechanism, and the plasticity between multiple resistance mechanisms could restrict the effectiveness of therapies targeting a single node of the oncogenic signaling network. Here, we report the discovery of IACS-13909, a specific and potent allosteric inhibitor of SHP2, that suppresses signaling through the MAPK pathway. IACS-13909 potently impeded proliferation of tumors harboring a broad spectrum of activated RTKs as the oncogenic driver. In EGFR-mutant osimertinib-resistant NSCLC models with EGFR-dependent and EGFR-independent resistance mechanisms, IACS-13909, administered as a single agent or in combination with osimertinib, potently suppressed tumor cell proliferation in vitro and caused tumor regression in vivo. Together, our findings provide preclinical evidence for using a SHP2 inhibitor as a therapeutic strategy in acquired EGFRi-resistant NSCLC. SIGNIFICANCE: These findings highlight the discovery of IACS-13909 as a potent, selective inhibitor of SHP2 with drug-like properties, and targeting SHP2 may serve as a therapeutic strategy to overcome tumor resistance to osimertinib.

Abstract C036: Discovery of IACS-13909, an allosteric SHP2 inhibitor that overcomes multiple mechanisms underlying osimertinib resistance

Osimertinib, a third generation EGFR inhibitor, is a front-line therapy for EGFR mutated non-small lung cancer (NSCLC). The long-term effectiveness of osimertinib is limited by acquired resistance. Clinically identified resistance mechanisms include EGFR-dependent mechanisms such as mutations on EGFR that preclude drug binding, and EGFR-independent activation of the MAPK pathway, for instance via activation of alternate RTKs. It has also been noted that frequently a tumor from a single patient harbors more than one resistance mechanism, and the plasticity between the multiple resistance mechanisms will restrict the effectiveness of therapies targeting a single node of the oncogenic signaling network. SHP2 (Src homology 2 domain-containing phosphatase) is a phosphatase that mediates the signaling of multiple RTKs and is required for full activation of the MAPK pathway. Here we report IACS-13909 - a specific and potent allosteric inhibitor of SHP2 - suppresses the signaling of RTK/MAPK pathway. IACS-13909 potently impedes the proliferation of tumors with a broad spectrum of RTKs as the oncogenic driver. Importantly, in NSCLC models with acquired resistance to osimertinib, IACS-13909 administered as a single agent or in combination with osimertinib potently reduces tumor cell proliferation in vitro and in vivo. Together, our findings provide preclinical evidence for using a SHP2 inhibitor as a therapeutic strategy in acquired EGFR inhibitor-resistant NSCLC. Currently, a compound that potently inhibits SHP2 has been selected as the clinical development candidate and is undergoing IND-enabling studies with a projected first-in-human target of early 2020.

Citation Format: Yuting Sun, Brooke A Meyers, Sarah B Johnson, Angela L Harris, Barbara Czako, Jason B Cross, Paul G Leonard, Faika Mseeh, Maria E Di Francesco, Connor A Parker, Qi Wu, Christopher A Bristow, Jason P Burke, Caroline C Carrillo, Christopher L Carroll, Qing Chang, Ningping Feng, Sonal Gera, Gao Guang, Justin Kwang-Lay Huang, Yongying Jiang, Zhijun Kang, Jeffrey J Kovacs, Xiaoyan Ma, Pijus K Mandal, Timothy McAfoos, Robert A Mullinax, Michael D Peoples, Vandhana Ramamoorthy, Sahil Seth, Erika Suzuki, Christopher Conrad Williams, Simon S Yu, Andy M Zuniga, Giulio F Draetta, Joseph R Marszalek, Timothy P Heffernan, Nancy E Kohl, Philip Jones. Discovery of IACS-13909, an allosteric SHP2 inhibitor that overcomes multiple mechanisms underlying osimertinib resistance [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference on Molecular Targets and Cancer Therapeutics; 2019 Oct 26-30; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2019;18(12 Suppl):Abstract nr C036. doi:10.1158/1535-7163.TARG-19-C036

Abstract 3277: IACS-9779, a development candidate that inhibits 2,3-dioxygenase (IDO) activity by blocking heme incorporation into IDO apoenzyme

Increased expression of IDO1 is believed to create a tumor microenvironment that is immunosuppressive. In the course of our research directed at identifying potent and selective inhibitors of IDO1, we identified a class of compounds that inhibited IDO1 activity in a cellular context, but not in isolated enzymatic assays. We have conducted detailed mechanistic studies and shown that these molecules inhibit IDO1 by binding to the apo-enzyme, thus preventing the incorporation of the heme-cofactor into the active site of the holo-enzyme.

Through an extensive medicinal chemistry campaign, we optimized a series of orally bioavailable, highly potent and selective inhibitors of IDO1 that possess excellent pharmacological properties. For several lead molecules, pharmacokinetic (PK) - pharmacodynamic (PD) relationships were established in whole blood and SKOV3 xenograft assays. The inhibition of IDO1 in a human whole-blood assay correlated well with the suppression of tumor kynurenine (KYN) that was observed in SKOV3 xenografts. At plasma concentrations of 3 µM, IACS-9779 supressed tumor KYN levels by 90%. IACS-9779 was well tolerated with excellent in vivo PK properties across multiple preclinical species, and a human PK prediction consistent with a low daily dose needed for full suppression of KYN production via IDO1.

Note: This abstract was not presented at the meeting.

Citation Format: Faika Mseeh, Matthew M. Hamilton, Joseph R. Marszalek, Norma E. Rogers, Connor A. Parker, Simon S. Yu, Zhen Liu, Naphtali J. Reyna, Timothy McAfoos, Brett W. Virgin-Downey, Paul G. Leonard, Jason B. Cross, Ningping Feng, Angela L. Harris, Andy M. Zuniga, Keith Mikule, Martin Tremblay, Yongying Jiang, Mikhila Mahendra, Jihai Pang, Qi Wu, Quanyun Xu, Timothy P. Heffernan, Philip Jones, Richard T. Lewis. IACS-9779, a development candidate that inhibits 2,3-dioxygenase (IDO) activity by blocking heme incorporation into IDO apoenzyme [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3277.

Abstract LB-071: Discovery of an imidazopyridine series of potent human IDO1 inhibitors with robust target engagement in a preclinical tumor model

Indoleamine 2,3-dioxygenase (IDO1 and IDO2) and tryptophan dioxygenase (TDO) are heme-containing enzymes that mediate the rate limiting step in the oxidative degradation of L-tryptophan (L-TRP) to kynurenine (KYN) metabolites. Tryptophan catabolism through the KYN metabolic pathway is now recognized as one of many mechanisms involved in tumor cell evasion of the immune surveillance system. Inhibition of the KYN pathway in the tumor microenvironment can lead to improved immune response and tumor growth suppression. Recently, clinical proof of concept of this mechanism has been demonstrated using an Indoleamine 2,3-dioxygenase (IDO1) inhibitor in combination with a PD-1 antagonist in a variety of tumor contexts. Consideration of known low molecular weight heme-co-ordinating ligands identified from the PDB, in conjunction with a virtual screen performed in-silico identified a number of potentially interesting starting points for medicinal chemistry development. Identification of an attractive indazole fragment as a starting point, and expansion into alternative bicyclic cores, resulted in the discovery of a family of imidazopyridines as potent human IDO1 inhibitors with >200 fold selectivity against TDO. Utilizing a structure-based design approach allowed rapid lead optimization that resulted in the identification of IACS-8968. Crystallography studies were conducted, and binding of IACS-8968 to the heme domain of the human IDO1 was confirmed. The homochiral imidazopyridine IACS-8968 displayed cellular IC50= 29 nM in a HeLa cell line expressing human IDO1 and IC50= 21 nM in a PANC02 mouse cell line expressing the murine IDO1 enzyme, showed satisfactory selectivity margin (> 150 fold) versus its CYP450 inhibition profile and good oral bioavailability across species. PK/PD experiments indicated that, at equivalent exposure, IACS-8968 (sodium salt) and epacadostat decreased tumor KYN at comparable levels in CT26 syngeneic mouse model.

Citation Format: Alessia Petrocchi, Naphtali J. Reyna, Faika Mseeh, Connor A. Parker, Simon Yu, Quanyun Xu, Ningping Feng, Paul Leonard, Norma Rogers, Jason B. Cross, Angela L. Harris, Yongying Jiang, Tin Oo Khor, Mikhila G. Mahendra, Jihai Pang, Qi Wu, Andy M. Zuniga, Timothy McAfoos, Timothy McAfoos, Matthew M. Hamilton, Joe R. Marszalek, Keith Mikule, Paul Vancutsem, Keith Wilcoxen, Martin Tremblay, Philip Jones, Richard T. Lewis. Discovery of an imidazopyridine series of potent human IDO1 inhibitors with robust target engagement in a preclinical tumor model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr LB-071.

Abstract LB-124: Promoting an anti-tumor immune environment with a novel, exquisitely selective CSF1R inhibitor

Tumor-associated macrophages (TAMs) are critical drivers of tumor progression and immunosuppression within the tumor microenvironment. The dominant TAM phenotype is broadly characterized as harboring M2-like macrophage properties, which are anti-inflammatory and pro-tumor, as opposed to M1-like macrophages, which possess tumoricidal and pro-inflammatory characteristics. The dependence of M2 TAMs on CSF1 receptor (CSF1R) kinase signaling has made CSF1R a desirable therapeutic target, and the need for highly selective therapies for use in combinations. Through an extensive medicinal chemistry campaign, we identified a series of orally bioavailable, highly potent, exquisitely selective inhibitors of CSF1R (IC50 < 10 nM) with excellent pharmacologic properties that are appropriate for evaluation as a cancer therapy. The aim of our study was to assess the biological impact of our lead CSF1R inhibitor (CSF1Ri) on macrophage populations and the consequent effect on T effector cells. In vitro biochemical activity was evaluated in various kinase assays comparing our CSF1Ri to BLZ945. The compound was evaluated using syngeneic murine models of colorectal cancer (MC38) and pancreatic adenocarcinoma (PANC02). Tumors were immune profiled using NanoString, immunohistochemistry and flow cytometric analysis establishing that there was a depletion of macrophages and a reduction in the relative amount of M2+ (CD206+MHCII-) cells, with a concomitant increase in M1+ (MHCII+CD206-) cells. Myeloid-derived suppressor cells (MDSCs), CD4, and CD8 cell infiltration were also altered with an elevation of cytotoxic immune cells. In conclusion, we have identified and characterized a novel potent and selective inhibitor of CSF1R with highly favorable PK/PD properties, that compares favorably to BLZ945. We also have clear evidence that our novel CSF1R inhibitors modulates TAM infiltration and phenotype altering the immune cell milieu toward a more favorable anti-tumor environment.

Citation Format: Erika Suzuki, Jeffrey J. Kovacs, Nakia D. Spencer, Sonal Sonal, Ningping Feng, Angela L. Harris, Robert A. Mullinax, Andy M. Zuniga, Sarah B. Johnson, Mikhila Mahendra, Tin Oo Khor, Faika Mseeh, Zhen Liu, Jason P. Burke, Keith Mikule, Martin Tremblay, Timothy P. Heffernan, Philip Jones, Barbara Czako, Joseph R. Marszalek. Promoting an anti-tumor immune environment with a novel, exquisitely selective CSF1R inhibitor [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr LB-124.