Abstract 1639: DP-9149, an investigational small molecule modulator of the Integrated Stress Response kinase GCN2, pre-clinically causes solid tumor growth inhibition as a single agent and regression in combination with standard of care agents

Background: The Integrated Stress Response (ISR) is one of the major adaptive stress response pathways in cancer and plays an important role in cell fate determination. Oncogene addicted solid tumors are under high stress levels, both extrinsic as well as intrinsic, and are dependent on a well-balanced ISR pathway activity to cope with the high demand for accelerated growth. The ISR is well known to be a double edge sword of survival and cell death and depending on context, the activation of the ISR kinase, GCN2, and downstream pathway can have either cytoprotective or cytotoxic effects. Given the context-dependent nature of the ISR pathway, the inhibition or stimulation of GCN2 in solid tumors can be pharmacologically leveraged to induce anti-tumoral effects.

Methods: Modulation of ISR kinases was characterized using enzymatic assays. Kinome selectivity profiling was determined using enzymatic and cellular assays. Cellular modulation of the ISR pathway (phospho-GCN2, ATF4, CHOP) or the apoptosis pathway (PARP and Caspase3/7) was assessed via Western blot or ELISA. In vivo upregulation of tumoral ATF4 was determined in a fibrosarcoma PK/PD xenograft model. In vivo inhibition of tumor growth was determined in solid tumor xenografts.

Results: Selective and potent modulators of GCN2 kinase with favorable drug-like properties were designed. These compounds were found to upregulate components of the ISR pathway (phospho-GCN2, ATF4, CHOP). The mechanism by which GCN2 modulator DP-9149 treatment induced the ISR pathway was found to be through the direct binding and activation of GCN2. Upregulation of the ISR pathway downstream of GCN2 led to induction of a programmed cell death pathway in oncogene-driven solid tumor cell lines in vitro. DP-9149-mediated activation of the ISR pathway led to cell growth arrest both as a single agent and in combination with standard-of-care (SOC) agents. Furthermore, oral dosing of DP-9149 in RAS mutant and other oncogene-driven xenograft models in vivo induced ATF4, and significantly inhibited tumor growth as a single agent and in combination with SOC agents. Additionally, therapeutic agents targeting the tumor microenvironment, including anti-angiogenic agents, synergized with DP-9149 to induce tumor regressions in vivo.

Conclusions: The ISR is a targetable vulnerability in oncogene addicted solid tumors. Upregulating the ISR by paradoxical activation of the ISR family member kinase, GCN2, by DP-9149 can be leveraged as a novel mechanism to cause anti-tumoral effects in solid tumors in vitro and in vivo, likely through the induction of an unresolved stress response. In particular, DP-9149 exhibited robust activity in RAS mutant cancers and in VHL-mutant renal cancers as a single agent and in combination with SOC agents in vivo.

Citation Format: Gada Al-Ani, Qi Groer, Kristin M. Elliott, Aaron J. Rudeen, Patrick C. Kearney, Jeffery D. Zwicker, Yu Mi Ahn, Stacie L. Bulfer, Cale L. Heiniger, Molly M. Hood, Salim Javid, Joshua W. Large, Max D. Petty, Kristen L. Stoltz, Bertrand Le Bourdonnec, Bryan D. Smith, Daniel L. Flynn. DP-9149, an investigational small molecule modulator of the Integrated Stress Response kinase GCN2, pre-clinically causes solid tumor growth inhibition as a single agent and regression in combination with standard of care agents [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1639.

Abstract 4045: DCC-3084, a RAF dimer inhibitor, broadly inhibits BRAF class I, II, III, BRAF fusions, and RAS-driven solid tumors leading to tumor regression in preclinical models

Background: Mutations in the RAS/MAPK pathway are a frequent driver of cancer, with oncogenic RAS or RAF mutations occurring in >30% of all cancers. First generation BRAF inhibitors are approved for use for tumors with Class I BRAF mutations (V600X). However, these drugs are not efficacious in RAF dimer mutant and RAS mutant cancers due to paradoxical activation of RAF dimers. Herein, we describe DCC-3084, a potent and selective investigational Switch Control inhibitor of BRAF and CRAF kinase dimers that targets Class I, II and III BRAF mutations, BRAF fusions, and BRAF/CRAF heterodimers. DCC-3084 combines with inhibitors of additional nodes in the MAPK pathway to potentially target a large unmet medical need in RAS and RAF mutant cancers.

Methods: Inhibition of RAF kinases, including off-rate analysis, was measured using recombinant enzymes. X-ray crystallography was used for structure-based drug design. Cellular proliferation was measured using resazurin to monitor cell viability. Synergy in cells was measured using BLISS scores and curve shift analysis. Inhibition of ERK or RSK phosphorylation was measured by AlphaLISA or ELISA. Pharmacokinetics (PK) in the plasma, brain and CSF compartments were measured following oral dosing in Wistar rats. RAF and RAS mutant mouse xenograft models were used to assess PK, pharmacodynamics (PD), and efficacy.

Results: DCC-3084 is a potent and selective Switch Control inhibitor of RAF dimers that was designed to target Class I, II, III BRAF mutants, BRAF fusions, and BRAF/CRAF heterodimers. DCC-3084 inhibits BRAF and CRAF, exhibiting slow off-rates (t1/2 >20 hr). Potent single-agent inhibition of MAPK pathway signaling and cellular proliferation was observed in a wide range of Class I, II, III BRAF and BRAF fusion altered cell lines. Synergy was observed in combination with inhibitors of other nodes in the RAS/MAPK pathway in RAS mutant cell lines. DCC-3084 was demonstrated to be CNS penetrable and exhibited dose dependent oral exposure with robust inhibition of the RAS/MAPK pathway in PK/PD models. DCC-3084 accumulated in tumor tissue relative to plasma, further demonstrating a favorable pharmaceutical profile. Oral treatment of DCC-3084 as a single agent resulted in tumor regression in BRAF mutant and KRAS Q61K mutant mouse xenograft models and tumor growth inhibition in KRAS G12C/D mutant models. Additionally, DCC-3084 in combination with a MEKi resulted in tumor regression in KRAS mutant models.

Conclusions: The Switch Control inhibitor DCC-3084 broadly inhibits Class I, II and III BRAF mutations, BRAF fusions, and BRAF/CRAF heterodimers leading to tumor regression in preclinical models. The overall preclinical profile of DCC-3084 supports IND-enabling activities towards clinical development in a key area of unmet medical need in RAS and RAF mutant cancers.

Citation Format: Stacie L. Bulfer, Bertrand Le Bourdonnec, Jeffery D. Zwicker, Yu Mi Ahn, Gada Al-Ani, Hikmat Al-Hashimi, Chase Crawley, Kristin M. Elliott, Saqib Faisal, Andrew M. Harned, Cale L. Heiniger, Molly M. Hood, Salim Javed, Michael Kennedy, Joshua W. Large, Cynthia B. Leary, Wei-Ping Lu, Kylie Luther, Max D. Petty, Hunter R. Picard, Justin T. Proto, Yeni K. Romero, Forrest A. Stanley, Kristen L. Stoltz, Daniel C. Tanner, Hanumaiah Telikepalli, Mary J. Timson, Lakshminarayana Vogeti, Subha Vogeti, Sihyung Yang, Lexy H. Zhong, Bryan D. Smith, Daniel L. Flynn. DCC-3084, a RAF dimer inhibitor, broadly inhibits BRAF class I, II, III, BRAF fusions, and RAS-driven solid tumors leading to tumor regression in preclinical models. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 4045.

Abstract 1640: DP-9024, an investigational small molecule modulator of the Integrated Stress Response kinase PERK, causes B-cell cancer growth inhibition as single agent and in combination with standard-of-care agents

Background: The Integrated Stress Response (ISR) is a major adaptive stress response pathway in cancer cell maintenance. The ISR kinase family member PERK controls one of the three arms of the Unfolded Protein Response (UPR). The UPR is considered an Achilles’ heel in B-cell cancers. Multiple myeloma (MM) and B-cell lymphomas are dependent on a well-balanced UPR pathway to cope with the high demand for protein folding and their secretory nature. Given the double-edge sword nature of the UPR, the activation of PERK and downstream pathway can have cytoprotective or cytotoxic effects. In B-cell cancers the UPR is at close to maximum cytoprotective capacity, such that further pharmacological stimulation of PERK can potentially be leveraged to cause a cancer cell cytotoxic response and induce antitumoral effects.

Methods: Modulation of ISR kinases was characterized using enzymatic assays. Kinome selectivity profiling was determined using enzymatic and cellular assays. Cellular assays of PERK activation assessed ATF4 by ELISA. Cellular assays of GCN2 modulation assessed phospho-GCN2 and ATF4 by Western blot or ELISA (under basal or low amino acid conditions). DP-9024-induced upregulation of components of the ISR/UPR pathway (ATF4, CHOP) or the apoptosis pathway (PARP and Caspase 3/7) was measured by Western blot or ELISA assays. Compound-mediated PERK activation was investigated mechanistically using a cellular nanoBRET dimerization assay. In vivo upregulation of tumoral ATF4 was determined in a MM PK/PD xenograft model. In vivo inhibition of tumor growth was determined in MM and B-cell lymphoma xenografts.

Results: DP-9024 was designed as a selective and potent modulator of PERK and GCN2. DP-9024 was found to upregulate the ISR/UPR pathway (ATF4, CHOP). The mechanism by which DP-9024 treatment induced the UPR pathway was found to be through the dimerization and activation of PERK. Upregulation of the UPR pathway downstream of PERK led to induction of apoptosis (PARP and Caspase 3/7) in MM and B-cell lymphoma lines in vitro. DP-9024 mediated activation of the UPR pathway in cell lines with high basal level of endoplasmic reticulum (ER) stress led to growth arrest in combination with FDA approved therapies. Oral dosing of DP-9024 in MM xenograft models induced ATF4, and combination efficacy was observed in MM and B-cell lymphoma xenografts in combination with FDA approved agents in vivo.

Conclusions: The ISR/UPR is a targetable vulnerability in cancers with high basal levels of ER stress. DP-9024 increases UPR signaling via activating PERK dimerization. This novel mechanism leads to antitumoral effects in B-cell cancers in vitro and in vivo likely through the induction of unresolved ER stress, which may potentially provide an alternative mechanism to current UPR targeting therapies.

Citation Format: Gada Al-Ani, Qi Groer, Aaron J. Rudeen, Kristin M. Elliott, Patrick C. Kearney, Jeffery D. Zwicker, Yu Mi Ahn, Stacie L. Bulfer, Cale L. Heiniger, Molly M. Hood, Salim Javed, Joshua W. Large, Max D. Petty, Kristen L. Stoltz, Bertrand Le Bourdonnec, Bryan D. Smith, Daniel L. Flynn. DP-9024, an investigational small molecule modulator of the Integrated Stress Response kinase PERK, causes B-cell cancer growth inhibition as single agent and in combination with standard-of-care agents [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1640.

Abstract 1613: Dimerization-induced activation of the integrated stress response kinase PERK by an investigational small molecule modulator, DP-9024

Background: The Integrated Stress Response (ISR) is a major adaptive stress response pathway in cancers. The ISR kinase family member PERK controls one of the three arms of the Unfolded Protein Response (UPR). The UPR is considered an Achilles’ heel in B-cell cancers. Myelomas and B-cell lymphomas are dependent on a well-balanced UPR pathway to cope with the high demand for protein folding and their secretory nature. Given the double-edge sword nature of the UPR, the activation of PERK and downstream pathway can have cytoprotective or cytotoxic effects. In B-cell cancers the UPR is at close to maximum cytoprotective capacity, such that further pharmacological stimulation of PERK drives a cytotoxic outcome leveraged to induce antitumoral effects. Methods: Recombinant WT and mutant PERK constructs were assayed in the presence of DP-9024. Structures of compound-bound PERK were determined by X-ray crystallography. Kinome profiling was determined using enzymatic and cellular assays. Cellular modulation of the ISR/UPR pathway (phospho-GCN2, PERK, ATF4, CHOP) or the apoptosis pathway (cleaved-PARP, cleaved-Caspase 3/7) was measured by Western blot or ELISA. The level of DP-9024-induced PERK activation was determined using a cellular nanoBRET dimerization assay utilizing WT and mutant PERK constructs. Results: DP-9024 was designed as a selective and potent modulator of PERK and GCN2. DP-9024 was found to upregulate the ISR/UPR pathway (ATF4, CHOP). The mechanism by which DP-9024 induced the UPR pathway was found to be through dimerization-dependent activation of PERK. Utilizing recombinant biophysical and cellular assays of WT and mutant PERK constructs, we found that DP-9024 directly binds to a switch control site in the kinase domain of PERK that governs dimerization and that the binding of the compound to one monomer was sufficient to induce dimerization-mediated activation of the unoccupied monomer. This paradoxical stimulation of the unbound PERK monomer is reminiscent of the phenomenon observed with some BRAF inhibitors.1 X-ray crystallography studies revealed that PERK crystalizes as a dimer with both monomers bound to compound, due to the high concentration of compound used during crystallization. DP-9024-mediated PERK dimerization and transactivation led to the activation of downstream pathways (ATF4, CHOP), apoptotic pathway (Caspase 3/7, PARP1), and growth arrest in cell lines with high levels of endoplasmic reticulum (ER) stress such as multiple myeloma and B-cell lymphoma. Conclusions: Paradoxical stimulation of the ISR family member kinase PERK, through direct binding and dimerization by DP-9024, led to unresolved ER stress that can potentially be leveraged as a novel mechanism to induce growth arrest in UPR vulnerable cancers, including myelomas and B-cell lymphomas. References: 1. Poulikakos et al. 2010. Nature 464:427-30

Citation Format: Gada Al-Ani, Aaron J. Rudeen, Qi Groer, Kristin M. Elliott, Patrick C. Kearney, Jeffery D. Zwicker, Yu Mi Ahn, Stacie L. Bulfer, Cale L. Heiniger, Molly M. Hood, Salim Javid, Joshua W. Large, Max D. Petty, Kristen L. Stoltz, Bertrand Le Bourdonnec, Bryan D. Smith, Daniel L. Flynn. Dimerization-induced activation of the integrated stress response kinase PERK by an investigational small molecule modulator, DP-9024 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1613.

Discovery of vimseltinib (DCC-3014), a highly selective CSF1R switch-control kinase inhibitor, in clinical development for the treatment of Tenosynovial Giant Cell Tumor (TGCT)

Based on knowledge of kinase switch-control inhibition and using a combination of structure-based drug design and standard medicinal chemistry principles, we identified a novel series of dihydropyrimidone-based CSF1R kinase inhibitors displaying exquisite selectivity for CSF1R versus a large panel of kinases and non-kinase protein targets. Starting with lead compound 3, an SAR optimization campaign led to the discovery of vimseltinib (DCC-3014; compound 20) currently undergoing clinical evaluation for the treatment of Tenosynovial Giant Cell Tumor (TGCT), a locally aggressive benign tumor associated with substantial morbidity. 2021 Elsevier ltd. All rights reserved.

Discovery of acyl ureas as highly selective small molecule CSF1R kinase inhibitors

Based on the structure of an early lead identified in Deciphera's proprietary compound collection of switch control kinase inhibitors and using a combination of medicinal chemistry guided structure activity relationships and structure-based drug design, a novel series of potent acyl urea-based CSF1R inhibitors was identified displaying high selectivity for CSF1R versus the other members of the Type III receptor tyrosine kinase (RTK) family members (KIT, PDGFR-α, PDGFR-β, and FLT3), VEGFR2 and MET. Based on in vitro biology, in vitro ADME and in vivo PK/PD studies, compound 10 was selected as an advanced lead for Deciphera's CSF1R research program.

Ripretinib (DCC-2618) Is a Switch Control Kinase Inhibitor of a Broad Spectrum of Oncogenic and Drug-Resistant KIT and PDGFRA Variants

Ripretinib (DCC-2618) was designed to inhibit the full spectrum of mutant KIT and PDGFRA kinases found in cancers and myeloproliferative neoplasms, particularly in gastrointestinal stromal tumors (GISTs), in which the heterogeneity of drug-resistant KIT mutations is a major challenge. Ripretinib is a "switch-control" kinase inhibitor that forces the activation loop (or activation "switch") into an inactive conformation. Ripretinib inhibits all tested KIT and PDGFRA mutants, and notably is a type II kinase inhibitor demonstrated to broadly inhibit activation loop mutations in KIT and PDGFRA, previously thought only achievable with type I inhibitors. Ripretinib shows efficacy in preclinical cancer models, and preliminary clinical data provide proof-of-concept that ripretinib inhibits a wide range of KIT mutants in patients with drug-resistant GISTs.

The Selective Tie2 Inhibitor Rebastinib Blocks Recruitment and Function of Tie2Hi Macrophages in Breast Cancer and Pancreatic Neuroendocrine Tumors

Tumor-infiltrating myeloid cells promote tumor progression by mediating angiogenesis, tumor cell intravasation, and metastasis, which can offset the effects of chemotherapy, radiation, and antiangiogenic therapy. Here, we show that the kinase switch control inhibitor rebastinib inhibits Tie2, a tyrosine kinase receptor expressed on endothelial cells and protumoral Tie2-expressing macrophages in mouse models of metastatic cancer. Rebastinib reduces tumor growth and metastasis in an orthotopic mouse model of metastatic mammary carcinoma through reduction of Tie2⁺ myeloid cell infiltration, antiangiogenic effects, and blockade of tumor cell intravasation mediated by perivascular Tie2^Hi/Vegf-A^Hi macrophages in the tumor microenvironment of metastasis (TMEM). The antitumor effects of rebastinib enhance the efficacy of microtubule inhibiting chemotherapeutic agents, either eribulin or paclitaxel, by reducing tumor volume, metastasis, and improving overall survival. Rebastinib inhibition of angiopoietin/Tie2 signaling impairs multiple pathways in tumor progression mediated by protumoral Tie2⁺ macrophages, including TMEM-dependent dissemination and angiopoietin/Tie2-dependent angiogenesis. Rebastinib is a promising therapy for achieving Tie2 inhibition in cancer patients. Mol Cancer Ther; 16(11); 2486-501. ©2017 AACR.

Altiratinib Inhibits Tumor Growth, Invasion, Angiogenesis, and Microenvironment-Mediated Drug Resistance via Balanced Inhibition of MET, TIE2, and VEGFR2

Altiratinib (DCC-2701) was designed based on the rationale of engineering a single therapeutic agent able to address multiple hallmarks of cancer (1). Specifically, altiratinib inhibits not only mechanisms of tumor initiation and progression, but also drug resistance mechanisms in the tumor and microenvironment through balanced inhibition of MET, TIE2 (TEK), and VEGFR2 (KDR) kinases. This profile was achieved by optimizing binding into the switch control pocket of all three kinases, inducing type II inactive conformations. Altiratinib durably inhibits MET, both wild-type and mutated forms, in vitro and in vivo. Through its balanced inhibitory potency versus MET, TIE2, and VEGFR2, altiratinib provides an agent that inhibits three major evasive (re)vascularization and resistance pathways (HGF, ANG, and VEGF) and blocks tumor invasion and metastasis. Altiratinib exhibits properties amenable to oral administration and exhibits substantial blood-brain barrier penetration, an attribute of significance for eventual treatment of brain cancers and brain metastases.

Discovery of 1-(3,3-dimethylbutyl)-3-(2-fluoro-4-methyl-5-(7-methyl-2-(methylamino)pyrido[2,3-d]pyrimidin-6-yl)phenyl)urea (LY3009120) as a pan-RAF inhibitor with minimal paradoxical activation and activity against BRAF or RAS mutant tumor cells

The RAS-RAF-MEK-MAPK cascade is an essential signaling pathway, with activation typically mediated through cell surface receptors. The kinase inhibitors vemurafenib and dabrafenib, which target oncogenic BRAF V600E, have shown significant clinical efficacy in melanoma patients harboring this mutation. Because of paradoxical pathway activation, both agents were demonstrated to promote growth and metastasis of tumor cells with RAS mutations in preclinical models and are contraindicated for treatment of cancer patients with BRAF WT background, including patients with KRAS or NRAS mutations. In order to eliminate the issues associated with paradoxical MAPK pathway activation and to provide therapeutic benefit to patients with RAS mutant cancers, we sought to identify a compound not only active against BRAF V600E but also wild type BRAF and CRAF. On the basis of its superior in vitro and in vivo profile, compound 13 was selected for further development and is currently being evaluated in phase I clinical studies.

Abstract PR01: Rebastinib, a selective TIE2 kinase inhibitor, decreases TIE2-expressing macrophages, reduces metastasis, and increases survival in murine cancer models

In the tumor microenvironment, TIE2 expression on tissue macrophages, bone marrow derived TIE2-expressing monocytes (TEMs), osteoclasts, and vascular endothelial cells promotes tumor invasiveness, dissemination, and metastasis. Additionally, a subset of TIE2-expressing macrophages, located within specialized vascular structures known as tumor microenvironment for metastases (TMEMs), are linked to intravasation of cancer cells into circulation and dissemination to metastatic sites. Rebastinib is a picomolar inhibitor of TIE2 kinase, and exhibits an extraordinarily long off-rate from TIE2, measured to be over 24 hours in a cell-based assay. Herein, we examine the efficacy of rebastinib in the polyoma middle-T antigen (PyMT) syngeneic mouse breast cancer model. In this model, PyMT breast cancer cells are implanted in the mammary fat pad, and primary tumor growth leads to lung metastasis, which is known to be modulated by TEMs and TMEM vascular structures. We examined multiple dosing schedules of rebastinib in combination with anti-tubulin agents (ATAs). Rebastinib treatment in this model significantly ablated TEMs in the primary tumor stroma and caused a significant decrease in lung metastases. Furthermore, the combination of rebastinib with ATAs, even with once or twice weekly oral dosing of rebastinib, led to a significant further decrease in lung metastases compared to single-agent treatment with ATAs. Rebastinib also enhanced the activity of ATAs in reducing primary tumor growth and regrowth of tumor post-resection. TIE2 inhibition with targeted therapy represents a novel treatment approach for metastatic breast cancer and other cancers that rely on TEMs and TMEMs for growth and metastasis. As such, rebastinib has been selected for further clinical development in solid tumors with a Phase 1b trial being planned for 2014.

This abstract is also presented as Poster A5.

Citation Format: Daniel L. Flynn, Michael D. Kaufman, Cynthia B. Leary, Molly M. Hood, Wei-Ping Lu, Benjamin A. Turner, Scott C. Wise, Marc S. Rudoltz, Bryan D. Smith. Rebastinib, a selective TIE2 kinase inhibitor, decreases TIE2-expressing macrophages, reduces metastasis, and increases survival in murine cancer models. [abstract]. In: Abstracts: AACR Special Conference on Cellular Heterogeneity in the Tumor Microenvironment; 2014 Feb 26-Mar 1; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2015;75(1 Suppl):Abstract nr PR01. doi:10.1158/1538-7445.CHTME14-PR01

The relationship between coping, health competence and patient participation among patients with inactive inflammatory bowel disease

BACKGROUND

Coping is an integral part of adjustment for patients with Inflammatory Bowel Disease but has not been well described in the literature. This study explored the relationship between coping, perceived health competence, patient preference for involvement in their treatment, depression and quality of life, particularly among patients with inactive disease (in remission).

METHODS

Subjects (n=70) with active and inactive IBD completed questionnaires, including the Inflammatory Bowel Disease Quality of Life Questionnaire, Beck Depression Inventory, Perceived Health Competence Scale and the Coping Inventory for Stressful Situations. The Harvey Bradshaw Index measured disease activity.

RESULTS

Patients with inactive IBD demonstrated significantly more interest in participating in their treatment (p<.05), more perceived health competence (p=.001), less depressive symptoms (p<.001), more task oriented coping (p=.02), and better quality of life than those with active disease. Only Task Oriented Coping was significantly negatively associated with the number of flares among inactive patients (p<.001). Patient preference for participation in treatment was inversely associated with Avoidance (p=.005), Distraction (p=.008), and Social Diversion (p=.008) coping among inactive patients.

CONCLUSION

Among patients in remission, those who expressed a greater interest in treatment participation were also less likely to practice maladaptive coping. Our data demonstrate that a more active coping style may be associated with improved health outcome. Compared to patients with active disease, patients in remission are more likely to employ task oriented coping, demonstrate a higher interest in treatment participation, report greater perceived control of their health, and exhibit less depression symptoms. Our findings may increase awareness of the importance of identifying coping strategies for IBD patients, including those in remission.

Abstract P4-15-12: Rebastinib in combination with eribulin ablates TIE2-expressing macrophages, reduces metastasis, and increases survival in the PyMT metastatic breast cancer model

In cancer models, TIE2 kinase plays an important role in angiogenesis, vasculogenesis, and tumor metastasis. TIE2 expression is largely restricted to vascular endothelial cells, tissue macrophages, and bone marrow derived TIE2-expressing monocytes (TEMs), which are proangiogenic, provasculogenic and enhance invasiveness. The hypoxic tumor environment engendered by damaging the vasculature with chemotherapy, radiation, or anti-angiogenic treatments leads to rebound tumor vascularization by an angiogenic switch from the VEGF pathway to the angiopoietin/TIE2 pathway. This leads to recruitment of provasculogenic TEMs from the bone marrow, leading to the growth of residual tumor cells and disease progression. Significantly, a subset of TIE2-expressing macrophages are located within specialized vascular structures known as tumor microenvironment for metastases (TMEMs). Recent observations have linked TIE2-expressing macrophages within TMEM structures to intravasation of cancer cells into circulation and subsequent dissemination to metastatic sites. We hypothesized that TIE2 inhibition should decrease migration and association of TEMs with blood vessels in the tumor stroma, therefore blocking their proangiogenic activity and leading to reduced tumor growth. TIE2 inhibition may also alter TMEM function, leading directly to a blockade of metastasis.

Rebastinib is a picomolar inhibitor of TIE2 kinase, and exhibits an extraordinarily long off-rate from TIE2, measured to be over 24 hours in a cell-based assay. Herein, we examine the efficacy of rebastinib in the polyoma middle-T antigen (PyMT) syngeneic mouse breast cancer model. In this model, PyMT breast cancer cells are implanted in the mammary fat pad, and primary tumor growth leads to metastasis, which is known to be modulated by TEMs and TMEM vascular structures. We examined dosing rebastinib in combination with eribulin, an inhibitor of microtubule dynamics that recently was FDA-approved for treatment-refractory metastatic breast cancer. Rebastinib treatment in this model significantly ablated TEMs in the primary tumor stroma and caused a significant decrease in lung metastases. Furthermore, the combination of rebastinib and eribulin led to a significant further decrease in lung metastases compared to treatment with eribulin alone (Table 1). Rebastinib also enhanced the activity of eribulin in reducing primary tumor growth and regrowth of tumor post-resection.

TIE2 inhibition represents a novel treatment approach for metastatic breast cancer and other cancers that rely on TEMs and TMEMs for growth and metastasis. As such, rebastinib has been selected for further clinical development in combination with eribulin for treatment-refractory metastatic breast cancer, with a Phase 1b trial being planned for late 2013.

Rebastinib reduces lung metastases in the PyMT breast cancer modelTreatmentLung Metastases (% of Control)Vehicle100%Eribulin 1 mg/kg three times/week71%Rebastinib 10 mg/kg twice/week + Eribulin 1 mg/kg23%Eribulin 0.3 mg/kg three times/week71%Rebastinib 10 mg/kg twice/week + Eribulin 0.3 mg/kg51%Eribulin 0.1 mg/kg three times/week72%Rebastinib 10 mg/kg twice/week + Eribulin 0.1 mg/kg43%

Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr P4-15-12.

Abstract P4-15-13: Rebastinib in combination with paclitaxel ablates TIE2-expressing macrophages, reduces metastasis, and increases survival in the PyMT metastatic breast cancer model

In cancer models, TIE2 kinase plays an important role in angiogenesis, vasculogenesis, and tumor metastasis. TIE2 expression is largely restricted to vascular endothelial cells, tissue macrophages, and bone marrow derived TIE2-expressing monocytes (TEMs), which are proangiogenic, provasculogenic and enhance invasiveness. The hypoxic tumor environment engendered by damaging the vasculature with chemotherapy, radiation, or anti-angiogenic treatments leads to rebound tumor vascularization by an angiogenic switch from the VEGF pathway to the angiopoietin/TIE2 pathway. This leads to recruitment of provasculogenic TEMs from the bone marrow, leading to the growth of residual tumor cells and disease progression. Significantly, a subset of TIE2-expressing macrophages are located within specialized vascular structures known as tumor microenvironment for metastases (TMEMs). Recent observations have linked TIE2-expressing macrophages within TMEM structures to intravasation of cancer cells into circulation and subsequent dissemination to metastatic sites. We hypothesized that TIE2 inhibition should decrease migration and association of TEMs with blood vessels in the tumor stroma, therefore blocking their proangiogenic activity and leading to reduced tumor growth. TIE2 inhibition may also alter TMEM function, leading directly to a blockade of metastasis.

Rebastinib is a picomolar inhibitor of TIE2 kinase, and exhibits an extraordinarily long off-rate from TIE2, measured to be over 24 hours in a cell-based assay. Herein, we examine the efficacy of rebastinib in the polyoma middle-T antigen (PyMT) syngeneic mouse breast cancer model. In this model, PyMT breast cancer cells are implanted in the mammary fat pad, and primary tumor growth leads to metastasis, which is known to be modulated by TEMs and TMEM vascular structures. We examined multiple dosing schedules of rebastinib in combination with paclitaxel. Rebastinib treatment in this model significantly ablated TEMs in the primary tumor stroma and caused a significant decrease in lung metastases (Table 1). Furthermore, the combination of rebastinib and paclitaxel led to a significant further decrease in lung metastases compared to treatment with paclitaxel or rebastinib alone. Rebastinib also enhanced the activity of paclitaxel in reducing primary tumor growth and regrowth of tumor post-resection.

TIE2 inhibition with targeted therapy represents a novel treatment approach for metastatic breast cancer and other cancers that rely on TEMs and TMEMs for growth and metastasis. As such, rebastinib has been selected for further clinical development for treatment-refractory metastatic breast cancer, with a Phase 1b trial being planned for late 2013.

Rebastinib reduces lung metastases in the PyMT breast cancer modelStudynTreatmentLung Metastases (% of Control)110Vehicle100%110Paclitaxel 10 mg/kg Q5D36%110Rebastinib 10 mg/kg BID28%110Rebastinib 10 mg/kg BID + Paclitaxel7%210Vehicle100%210Paclitaxel 10 mg/kg Q5D51%210Rebastinib 10 mg/kg QD + Paclitaxel21%33Vehicle100%33Paclitaxel 10 mg/kg Q5D58%33Rebastinib 10 mg/kg twice/week + Paclitaxel28%

Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr P4-15-13.

Abstract B78: Rebastinib, a small molecule TIE2 kinase inhibitor, prevents primary tumor growth and lung metastasis in the PyMT breast cancer model

Rebastinib is an inhibitor of tyrosine kinases TIE2 and ABL1. A clinical trial in chronic myeloid leukemia (CML) to inhibit BCR-ABL was previously performed but efficacy was modest and development in CML is not continuing. Rebastinib is approximately 50 times more potent as an inhibitor of TIE2 than BCR-ABL. Biomarker analysis of patients from the CML trial of rebastinib revealed that a majority displayed significant increases in circulating angiopoietin 2 (ANG2) levels. Increases in ANG2, a TIE2 ligand, have been previously reported to correlate with inhibition of the TIE2 pathway. The hypoxic tumor environment engendered by radiation therapy, cytotoxic chemotherapy, or anti-angiogenic treatments (such as anti-VEGF therapies) leads to rebound tumor vascularization by the recruitment of pro-vasculogenic TIE2 expressing monocytes (TEMs) from the bone marrow to these hypoxic tumor sites. TEMs are believed to play an important role in the revascularization of tumors after these treatments, leading to progression of residual tumor. Thus, inhibition of TEM recruitment and activity could lead to better patient outcomes.

The polyoma middle-T antigen (PyMT) syngeneic mouse breast cancer model utilizes the mouse mammary tumor virus (MMTV) promoter, a breast specific promoter, to express PyMT in mouse breast tissue. In this model, primary breast cancers spontaneously occur, proliferate, and metastasize (mainly to the lungs) and lead to the death of the mice. Unlike xenografts, the PyMT model utilizes fully immunocompetent mice and metastasis in this model is known to be modulated by TEMs. Rebastinib has been evaluated in a PyMT mouse where primary tumors were allowed to reach 800 mg in size before starting treatment. Rebastinib therapy resulted in a significant decrease in the growth rate of the primary breast tumor (75%), a 71% reduction in lung metastases, a decrease in the levels of tumoral TIE2 staining by immunohistochemical analysis (IHC) and caused the remaining tumor to become necrotic. Combining rebastinib with paclitaxel resulted in a synergistic response with 90% inhibition of tumor growth and a 93% reduction of lung metastases.

This presentation will focus on the biochemical, cellular and in vivo activity of rebastinib as a novel small molecule inhibitor of TIE2 kinase and its potential for prevention of primary tumor rebound and metastasis in combination with first line interventional therapy. A clinical trial exploring this activity is planned for 2013.

Citation Format: Bryan D. Smith, Molly M. Hood, Michael D. Kaufman, Mark Berger, Daniel L. Flynn, Scott C. Wise. Rebastinib, a small molecule TIE2 kinase inhibitor, prevents primary tumor growth and lung metastasis in the PyMT breast cancer model. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Invasion and Metastasis; Jan 20-23, 2013; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2013;73(3 Suppl):Abstract nr B78.

Abstract 3594: Conformational control of FMS kinase for treatment of human malignancies

FMS kinase is involved in the process of osteoclast maturation. Osteoclasts have been shown to play a role not only in arthritic diseases but also in a cancers ability to metastasize to the bone. This is especially true for breast, lung and prostate cancer. Taken together the ability to prevent osteoclast maturation and accumulation through FMS inhibition should be a good target for small molecule therapy of bone metastasis. Using Deciphera Pharmaceutical's approach to kinase inhibition, compounds have been designed that potently inhibit FMS kinase. These inhibitors can be highly selective with lead compounds inhibiting only a single kinase within 20 fold of FMS activity in a 300 kinase profile. A second class broadens the profile to include anti-angiogenic kinase targets in addition to potent FMS inhibition. This presentation will highlight the attributes and development status of these compounds for treatment of human malignancies.

Deciphera's FMS program has afforded potent inhibitors that achieve single digit nanomolar inhibition in biochemical assays of FMS activity. The inhibitors retain this same level of potency in the presence of high (5mM) ATP concentrations. These same compounds are also selective with some inhibiting as few as three kinases within 50 fold of FMS potency. In addition, proliferation and FMS phosphoprotein assays performed with M-NFS-60 and THP-1 cells have demonstrated excellent inhibitory profiles with achieved potencies in the low nanomolar range. In functional osteoclast differentiation models, key compounds have demonstrated single digit nanomolar inhibition as assessed by TRAP assays. In vivo evaluation of the inhibitors produced excellent tolerance in two week MTD studies. Potent and durable efficacy in pharmacokinetic/pharmacodynamic xenograft models was also observed demonstrating on target effects. In vivo models of bone invasion coupled with non-invasive translational image-based biomarkers potentially provide a powerful method for visualization and quantification of osteoclast activity and FMS inhibition. Early results in imaging of bone invasion will be presented using micro CT and fluorescent activateable probes.

Deciphera's FMS inhibitors show acceptable ADME properties in cell permeability, cytochrome p450 inhibition, microsomal clearance and are orally bioavailable in rat and dog. Key prototype compounds have been evaluated in a two week rat tolerability study. These data demonstrate that Deciphera's technology has been used to identify potent and selective FMS inhibitors to be developed for treatment of cancers where metastasis to bone is an issue.

Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 3594. doi:10.1158/1538-7445.AM2011-3594

Conformational control inhibition of the BCR-ABL1 tyrosine kinase, including the gatekeeper T315I mutant, by the switch-control inhibitor DCC-2036

Acquired resistance to ABL1 tyrosine kinase inhibitors (TKIs) through ABL1 kinase domain mutations, particularly the gatekeeper mutant T315I, is a significant problem for patients with chronic myeloid leukemia (CML). Using structure-based drug design, we developed compounds that bind to residues (Arg386/Glu282) ABL1 uses to switch between inactive and active conformations. The lead "switch-control" inhibitor, DCC-2036, potently inhibits both unphosphorylated and phosphorylated ABL1 by inducing a type II inactive conformation, and retains efficacy against the majority of clinically relevant CML-resistance mutants, including T315I. DCC-2036 inhibits BCR-ABL1(T315I)-expressing cell lines, prolongs survival in mouse models of T315I mutant CML and B-lymphoblastic leukemia, and inhibits primary patient leukemia cells expressing T315I in vitro and in vivo, supporting its clinical development in TKI-resistant Ph(+) leukemia.

Switch control pocket inhibitors of p38-MAP kinase. Durable type II inhibitors that do not require binding into the canonical ATP hinge region

Switch control pocket inhibitors of p38-alpha kinase are described. Durable type II inhibitors were designed which bind to arginines (Arg67 or Arg70) that function as key residues for mediating phospho-threonine 180 dependant conformational fluxing of p38-alpha from an inactive type II state to an active type I state. Binding to Arg70 in particular led to potent inhibitors, exemplified by DP-802, which also exhibited high kinase selectivity. Binding to Arg70 obviated the requirement for binding into the ATP Hinge region. X-ray crystallography revealed that DP-802 and analogs induce an enhanced type II conformation upon binding to either the unphosphorylated or the doubly phosphorylated form of p38-alpha kinase.

Abstract LB-300: Small molecule modulators of MET kinase for treatment of human malignancies

MET kinase is involved in numerous cancers including lung, melanoma and gastric. MET can not only be the oncogenic driver of the cancer cell but also is a key player in the cells ability to metastasize and invade tissues distant from the primary tumor site. It has been shown that 2 out of 3 cancers involving MET leads to a poor prognosis for patient survival. Using Deciphera Pharmaceutical's approach to kinase inhibition, compounds have been designed which effectively inhibit wild type and mutant MET kinase forms. These inhibitors are selective, including sparing of close family members AXL and RON. This presentation will highlight the attributes and development status of these compounds for treatment of human malignancy. Deciphera's MET program has afforded potent inhibitors that achieve low nanomolar inhibition of wild type MET and secondary activating mutant forms. Data will be presented on DP-4693 and DP-4756.IC50MET Kinasep-MET MKN-45MKN-45 Proliferationp-MET EBC-1EBC-1 ProliferationA549 MigrationDP-46934nM13 nM44 nM10 nM3nM260 nMDP-47566nM6nM23 nM2nM5nM21 nM

DP-4693 and DP-4756 are selective, having as few as three kinases within 50 fold of MET potency. Inhibitor bound crystal structures will be shown which demonstrate the compounds mechanism of action. In addition, proliferation and MET phosphoprotein analysis performed with EBC-1 and MKN-45 cell lines have demonstrated excellent inhibitory profiles with potencies in the low nanomolar range. The compounds also inhibit HGF dependent cell motility in an A549 migration assay. In vivo evaluation of DP-4693 in an MKN-45 gastric cancer xenograft PK/PD model revealed complete target suppression at doses as low as 6 mpk. Futher studies will be presented highlighting the efficacy in both autocrine and paracrine (HGF-dependent) xenograft models.

Deciphera's MET inhibitors also show acceptable ADME properties and are orally bioavailable in rat and dog using simple vehicles. These inhibitors have also been evaluated in two week toxicology studies, exhibiting excellent tolerability up to doses of 300 mpk. Further studies are ongoing to enable Development Candidate selection for progression into clinical trials.

Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr LB-300.

Selective shunt in the management of variceal bleeding in the era of liver transplantation

This study reports the Emory experience with 147 distal splenorenal shunts (DSRS) and 110 orthotopic liver transplants (OLT) between January 1987 and December 1991. The purpose was to clarify which patients with variceal bleeding should be treated by DSRS versus OLT. Distal splenorenal shunts were selected for patients with adequate or good liver function. Orthotopic liver transplant was offered to patients with end-stage liver disease who fulfilled other selection criteria. The DSRS group comprised 71 Child's A, 70 Child's B, and 6 Child's C patients. The mean galactose elimination capacity for all DSRS patients was 330 +/- 98 mg/minute, which was significantly (p less than 0.01) above the galactose elimination capacity of 237 +/- 82 mg/minute in the OLT group. Survival analysis for the DSRS group showed 91% 1-year and 77% 3-year survival, which was better than the 74% 1-year and 60% 3-year survivals in the OLT group. Variceal bleeding as a major component of end-stage disease leading to OLT had significantly (p less than 0.05) poorer survival (50%) at 1 year compared with patients without variceal bleeding (80%). Hepatic function was maintained after DSRS, as measured by serum albumin and prothrombin time, but galactose elimination capacity decreased significantly (p less than 0.05) to 298 +/- 97 mg/minute. Quality of life, measured by a self-assessment questionnaire, was not significantly different in the DSRS and OLT groups. Hospital charges were significantly higher for OLT (median, $113,733) compared with DSRS ($32,674). These data support a role for selective shunt in the management of patients with variceal bleeding who require surgery and have good hepatic function. Transplantation should be reserved for patients with end-stage liver disease. A thorough evaluation, including tests of liver function, help in selection of the most appropriate therapeutic approach.