Your search keyword '"Joseph McClanaghan"' showing total 26 results

1. SULT1A1-dependent sulfonation of alkylators is a lineage-dependent vulnerability of liver cancers

Author

Lei Shi, William Shen, Mindy I. Davis, Ke Kong, Phuong Vu, Supriya K. Saha, Ramzi Adil, Johannes Kreuzer, Regina Egan, Tobie D. Lee, Patricia Greninger, Jonathan H. Shrimp, Wei Zhao, Ting-Yu Wei, Mi Zhou, Jason Eccleston, Jonathan Sussman, Ujjawal Manocha, Vajira Weerasekara, Hiroshi Kondo, Vindhya Vijay, Meng-Ju Wu, Sara E. Kearney, Jeffrey Ho, Joseph McClanaghan, Ellen Murchie, Giovanna S. Crowther, Samarjit Patnaik, Matthew B. Boxer, Min Shen, David T. Ting, William Y. Kim, Ben Z. Stanger, Vikram Deshpande, Cristina R. Ferrone, Cyril H. Benes, Wilhelm Haas, Matthew D. Hall, and Nabeel Bardeesy

Subjects

Cancer Research, Oncology

Published

2023

2. Data S3 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Data 3

Published

2023

3. Supplementary Information from NOTCH1 Represses MCL-1 Levels in GSI-resistant T-ALL, Making them Susceptible to ABT-263

Author

Cyril H. Benes, Anthony C. Faber, Michelle Kelliher, Jeffrey A. Engelman, Kathryn Rizzo, Steven Grant, Jorge Almenara, Mathew J. Garnett, Ultan McDermott, Jessica Boisvert, Neha U. Patel, Justine Roderick, Max Greenberg, Joseph McClanaghan, August Williams, Xunqin Yin, Carlotta Costa, AHyun Choi, and Anahita Dastur

Abstract

Materials & Methods

Published

2023

4. Figure S1 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 1

Published

2023

5. Data from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Purpose:KRAS-mutant lung cancers have been recalcitrant to treatments including those targeting the MAPK pathway. Covalent inhibitors of KRAS p.G12C allele allow for direct and specific inhibition of mutant KRAS in cancer cells. However, as for other targeted therapies, the therapeutic potential of these inhibitors can be impaired by intrinsic resistance mechanisms. Therefore, combination strategies are likely needed to improve efficacy.Experimental Design: To identify strategies to maximally leverage direct KRAS inhibition we defined the response of a panel of NSCLC models bearing the KRAS G12C–activating mutation in vitro and in vivo. We used a second-generation KRAS G12C inhibitor, ARS1620 with improved bioavailability over the first generation. We analyzed KRAS downstream effectors signaling to identify mechanisms underlying differential response. To identify candidate combination strategies, we performed a high-throughput drug screening across 112 drugs in combination with ARS1620. We validated the top hits in vitro and in vivo including patient-derived xenograft models.Results:Response to direct KRAS G12C inhibition was heterogeneous across models. Adaptive resistance mechanisms involving reactivation of MAPK pathway and failure to induce PI3K–AKT pathway inactivation were identified as likely resistance events. We identified several model-specific effective combinations as well as a broad-sensitizing effect of PI3K-AKT–mTOR pathway inhibitors. The G12Ci+PI3Ki combination was effective in vitro and in vivo on models resistant to single-agent ARS1620 including patient-derived xenografts models.Conclusions:Our findings suggest that signaling adaptation can in some instances limit the efficacy of ARS1620 but combination with PI3K inhibitors can overcome this resistance.

Published

2023

6. Data from NOTCH1 Represses MCL-1 Levels in GSI-resistant T-ALL, Making them Susceptible to ABT-263

Author

Cyril H. Benes, Anthony C. Faber, Michelle Kelliher, Jeffrey A. Engelman, Kathryn Rizzo, Steven Grant, Jorge Almenara, Mathew J. Garnett, Ultan McDermott, Jessica Boisvert, Neha U. Patel, Justine Roderick, Max Greenberg, Joseph McClanaghan, August Williams, Xunqin Yin, Carlotta Costa, AHyun Choi, and Anahita Dastur

Abstract

Purpose:Effective targeted therapies are lacking for refractory and relapsed T-cell acute lymphoblastic leukemia (T-ALL). Suppression of the NOTCH pathway using gamma-secretase inhibitors (GSI) is toxic and clinically not effective. The goal of this study was to identify alternative therapeutic strategies for T-ALL.Experimental Design:We performed a comprehensive analysis of our high-throughput drug screen across hundreds of human cell lines including 15 T-ALL models. We validated and further studied the top hit, navitoclax (ABT-263). We used multiple human T-ALL cell lines as well as primary patient samples, and performed both in vitro experiments and in vivo studies on patient-derived xenograft models.Results:We found that T-ALL are hypersensitive to navitoclax, an inhibitor of BCL2 family of antiapoptotic proteins. Importantly, GSI-resistant T-ALL are also susceptible to navitoclax. Sensitivity to navitoclax is due to low levels of MCL-1 in T-ALL. We identify an unsuspected regulation of mTORC1 by the NOTCH pathway, resulting in increased MCL-1 upon GSI treatment. Finally, we show that pharmacologic inhibition of mTORC1 lowers MCL-1 levels and further sensitizes cells to navitoclax in vitro and leads to tumor regressions in vivo.Conclusions:Our results support the development of navitoclax, as single agent and in combination with mTOR inhibitors, as a new therapeutic strategy for T-ALL, including in the setting of GSI resistance.

Published

2023

7. Figure S5 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 5

Published

2023

8. Table S1 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Table 1

Published

2023

9. Figure S4 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 4

Published

2023

10. Figure S2 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 2

Published

2023

11. Figure S6 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 6

Published

2023

12. Figure S7 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 7

Published

2023

13. Data S2 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Data 2

Published

2023

14. Supplementary Figs S1-S15 from NOTCH1 Represses MCL-1 Levels in GSI-resistant T-ALL, Making them Susceptible to ABT-263

Author

Cyril H. Benes, Anthony C. Faber, Michelle Kelliher, Jeffrey A. Engelman, Kathryn Rizzo, Steven Grant, Jorge Almenara, Mathew J. Garnett, Ultan McDermott, Jessica Boisvert, Neha U. Patel, Justine Roderick, Max Greenberg, Joseph McClanaghan, August Williams, Xunqin Yin, Carlotta Costa, AHyun Choi, and Anahita Dastur

Abstract

Figures S1-S15 support the data in the main paper.

Published

2023

15. Figure S3 from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Supplementary Figure 3

Published

2023

16. Supplementary Figures Legends from KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Cyril H. Benes, Aaron N. Hata, Yi Liu, Lian-Sheng Li, Matthew R. Janes, Patrick P. Zarrinkar, Ellen Murchie, Giovanna T. Stein, Joseph McClanaghan, Regina K. Egan, Patricia Greninger, Varuna Nangia, Max Greenberg, Maria Gomez-Caraballo, Dana Lee, David T. Myers, Daria Timonina, Samantha Bilton, Chendi Li, Eliane Cortez, Jackson P. Fatherree, and Sandra Misale

Abstract

Legends to supplementary table, data and figures

Published

2023

17. A landscape of synergistic drug combinations in non-small-cell lung cancer

Author

Daniel A. Haber, Patricia Greninger, Nishanth Ulhas Nair, Amy Tam, Joshua W. K. Ho, Avinash Das Sahu, Anahita Dastur, Eytan Ruppin, Arnaud Amzallag, Mathew J. Garnett, Leah J. Damon, Jessica L. Boisvert, Ellen Murchie, Adam Friedman, Joseph McClanaghan, Jeffrey A. Engelman, Giovanna Stein Crowther, Eliane Cortez, Jae-Seong Lee, Regina K. Egan, and Cyril H. Benes

Subjects

Drug, media_common.quotation_subject, medicine.medical_treatment, Cancer, Biology, medicine.disease, Tumor heterogeneity, Drug synergism, Targeted therapy, medicine.anatomical_structure, medicine, Cancer research, Non small cell, Lung cancer, Sensitization, media_common

Abstract

SummaryTargeted therapeutics have advanced cancer treatment, but single agent activity remains limited by de novo and acquired resistance. Combining targeted drugs is broadly seen as a way to improve treatment outcome, motivating the ongoing search for efficacious combinations. To identify synergistic targeted therapy combinations and study the impact of tumor heterogeneity on combination outcome, we systematically tested over 5,000 two drug combinations at multiple doses across a collection of 81 non-small cancer cell lines. Both known and novel synergistic combinations were identified. Strikingly, very few combinations yield synergy across the majority of cell line models. Importantly, synergism mainly arises due to sensitization of single agent resistant models, rather than further sensitize already sensitive cell lines, frequently via dual targeting of a single or two highly interconnected pathways. This drug combinations resource, the largest of its kind should help delineate new synergistic regimens by facilitating the understanding of drug synergism in cancer.

Published

2021

18. Catastrophic ATP loss underlies a metabolic combination therapy tailored for

Author

Krista M, Dalton, Timothy L, Lochmann, Konstantinos V, Floros, Marissa L, Calbert, Richard, Kurupi, Giovanna T, Stein, Joseph, McClanaghan, Ellen, Murchie, Regina K, Egan, Patricia, Greninger, Mikhail, Dozmorov, Sivapriya, Ramamoorthy, Madhavi, Puchalapalli, Bin, Hu, Lisa, Shock, Jennifer, Koblinski, John, Glod, Sosipatros A, Boikos, Cyril H, Benes, and Anthony C, Faber

Subjects

Monocarboxylic Acid Transporters, N-Myc Proto-Oncogene Protein, Electron Transport Complex I, Symporters, Gene Amplification, Apoptosis, Pyrimidinones, Thiophenes, Biological Sciences, Xenograft Model Antitumor Assays, Mitochondria, Mice, Neuroblastoma, Phenformin, Cell Line, Tumor, Antineoplastic Combined Chemotherapy Protocols, Basigin, Animals, Humans, neoplasms, Cell Proliferation

Abstract

MYCN-amplified neuroblastoma is a lethal subset of pediatric cancer. MYCN drives numerous effects in the cell, including metabolic changes that are critical for oncogenesis. The understanding that both compensatory pathways and intrinsic redundancy in cell systems exists implies that the use of combination therapies for effective and durable responses is necessary. Additionally, the most effective targeted therapies exploit an “Achilles’ heel” and are tailored to the genetics of the cancer under study. We performed an unbiased screen on select metabolic targeted therapy combinations and correlated sensitivity with over 20 subsets of cancer. We found that MYCN-amplified neuroblastoma is hypersensitive to the combination of an inhibitor of the lactate transporter MCT1, AZD3965, and complex I of the mitochondrion, phenformin. Our data demonstrate that MCT4 is highly correlated with resistance to the combination in the screen and lowly expressed in MYCN-amplified neuroblastoma. Low MCT4 combines with high expression of the MCT2 and MCT1 chaperone CD147 in MYCN-amplified neuroblastoma, altogether conferring sensitivity to the AZD3965 and phenformin combination. The result is simultaneous disruption of glycolysis and oxidative phosphorylation, resulting in dramatic disruption of adenosine triphosphate (ATP) production, endoplasmic reticulum stress, and cell death. In mouse models of MYCN-amplified neuroblastoma, the combination was tolerable at concentrations where it shrank tumors and did not increase white-blood-cell toxicity compared to single drugs. Therefore, we demonstrate that a metabolic combination screen can identify vulnerabilities in subsets of cancer and put forth a metabolic combination therapy tailored for MYCN-amplified neuroblastoma that demonstrates efficacy and tolerability in vivo.

Published

2021

19. Catastrophic ATP loss underlies a metabolic combination therapy tailored for MYCN -amplified neuroblastoma

Author

Lisa S. Shock, Bin Hu, Timothy L. Lochmann, John Glod, Anthony C. Faber, Ellen Murchie, Cyril H. Benes, Sosipatros A. Boikos, Patricia Greninger, Sivapriya Ramamoorthy, Krista M. Dalton, Madhavi Puchalapalli, Regina K. Egan, Mikhail G. Dozmorov, Joseph McClanaghan, Marissa L. Calbert, Jennifer E. Koblinski, Richard Kurupi, Konstantinos V. Floros, and Giovanna T. Stein

Subjects

Multidisciplinary, Combination therapy, business.industry, medicine.medical_treatment, Cancer, Mitochondrion, Phenformin, medicine.disease_cause, medicine.disease, Pediatric cancer, Targeted therapy, chemistry.chemical_compound, chemistry, Neuroblastoma, medicine, Cancer research, Carcinogenesis, business, neoplasms

Abstract

MYCN-amplified neuroblastoma is a lethal subset of pediatric cancer. MYCN drives numerous effects in the cell, including metabolic changes that are critical for oncogenesis. The understanding that both compensatory pathways and intrinsic redundancy in cell systems exists implies that the use of combination therapies for effective and durable responses is necessary. Additionally, the most effective targeted therapies exploit an "Achilles' heel" and are tailored to the genetics of the cancer under study. We performed an unbiased screen on select metabolic targeted therapy combinations and correlated sensitivity with over 20 subsets of cancer. We found that MYCN-amplified neuroblastoma is hypersensitive to the combination of an inhibitor of the lactate transporter MCT1, AZD3965, and complex I of the mitochondrion, phenformin. Our data demonstrate that MCT4 is highly correlated with resistance to the combination in the screen and lowly expressed in MYCN-amplified neuroblastoma. Low MCT4 combines with high expression of the MCT2 and MCT1 chaperone CD147 in MYCN-amplified neuroblastoma, altogether conferring sensitivity to the AZD3965 and phenformin combination. The result is simultaneous disruption of glycolysis and oxidative phosphorylation, resulting in dramatic disruption of adenosine triphosphate (ATP) production, endoplasmic reticulum stress, and cell death. In mouse models of MYCN-amplified neuroblastoma, the combination was tolerable at concentrations where it shrank tumors and did not increase white-blood-cell toxicity compared to single drugs. Therefore, we demonstrate that a metabolic combination screen can identify vulnerabilities in subsets of cancer and put forth a metabolic combination therapy tailored for MYCN-amplified neuroblastoma that demonstrates efficacy and tolerability in vivo.

Published

2021

20. High-risk neuroblastoma with NF1 loss of function is targetable using SHP2 inhibition

Author

Jinyang Cai, Sheeba Jacob, Richard Kurupi, Krista M. Dalton, Colin Coon, Patricia Greninger, Regina K. Egan, Giovanna T. Stein, Ellen Murchie, Joseph McClanaghan, Yuta Adachi, Kentaro Hirade, Mikhail Dozmorov, John Glod, Sosipatros A. Boikos, Hiromichi Ebi, Huaixiang Hao, Giordano Caponigro, Cyril H. Benes, and Anthony C. Faber

Subjects

Mitogen-Activated Protein Kinase Kinases, Mice, Neuroblastoma, Neurofibromin 1, Cell Line, Tumor, Animals, Protein Tyrosine Phosphatase, Non-Receptor Type 11, Mitogen-Activated Protein Kinases, Neoplasm Recurrence, Local, Protein Kinase Inhibitors, General Biochemistry, Genetics and Molecular Biology

Abstract

Reoccurring/high-risk neuroblastoma (NB) tumors have the enrichment of non-RAS/RAF mutations along the mitogen-activated protein kinase (MAPK) signaling pathway, suggesting that activation of MEK/ERK is critical for their survival. However, based on preclinical data, MEK inhibitors are unlikely to be active in NB and have demonstrated dose-limiting toxicities that limit their use. Here, we explore an alternative way to target the MAPK pathway in high-risk NB. We find that NB models are among the most sensitive among over 900 tumor-derived cell lines to the allosteric SHP2 inhibitor SHP099. Sensitivity to SHP099 in NB is greater in models with loss or low expression of the RAS GTPase activation protein (GAP) neurofibromin 1 (NF1). Furthermore, NF1 is lower in advanced and relapsed NB and NF1 loss is enriched in high-risk NB tumors regardless of MYCN status. SHP2 inhibition consistently blocks tumor growth in high-risk NB mouse models, revealing a new drug target in relapsed NB.

Published

2022

21. KRAS G12C NSCLC Models Are Sensitive to Direct Targeting of KRAS in Combination with PI3K Inhibition

Author

Sandra Misale, Samantha J. Bilton, Patrick P. Zarrinkar, Maria Gomez-Caraballo, Daria Timonina, Giovanna T. Stein, Jackson P. Fatherree, Dana Lee, Ellen Murchie, Matthew R. Janes, Max Greenberg, Eliane Cortez, Joseph McClanaghan, Aaron N. Hata, Yi Liu, Regina K. Egan, Chendi Li, Varuna Nangia, Patricia Greninger, Cyril H. Benes, David T. Myers, and Lian-Sheng Li

Subjects

0301 basic medicine, MAPK/ERK pathway, Cancer Research, Drug resistance, Biology, medicine.disease_cause, Proto-Oncogene Proteins p21(ras), Mice, Phosphatidylinositol 3-Kinases, 03 medical and health sciences, 0302 clinical medicine, In vivo, Cell Line, Tumor, medicine, Animals, Humans, Gene silencing, Gene Silencing, Protein Kinase Inhibitors, Alleles, PI3K/AKT/mTOR pathway, Cell Proliferation, Phosphoinositide-3 Kinase Inhibitors, In vitro, 3. Good health, 030104 developmental biology, Oncology, Drug Resistance, Neoplasm, 030220 oncology & carcinogenesis, Mutation, Cancer cell, Cancer research, KRAS, Drug Screening Assays, Antitumor, Signal Transduction

Abstract

Purpose: KRAS-mutant lung cancers have been recalcitrant to treatments including those targeting the MAPK pathway. Covalent inhibitors of KRAS p.G12C allele allow for direct and specific inhibition of mutant KRAS in cancer cells. However, as for other targeted therapies, the therapeutic potential of these inhibitors can be impaired by intrinsic resistance mechanisms. Therefore, combination strategies are likely needed to improve efficacy. Experimental Design: To identify strategies to maximally leverage direct KRAS inhibition we defined the response of a panel of NSCLC models bearing the KRAS G12C–activating mutation in vitro and in vivo. We used a second-generation KRAS G12C inhibitor, ARS1620 with improved bioavailability over the first generation. We analyzed KRAS downstream effectors signaling to identify mechanisms underlying differential response. To identify candidate combination strategies, we performed a high-throughput drug screening across 112 drugs in combination with ARS1620. We validated the top hits in vitro and in vivo including patient-derived xenograft models. Results: Response to direct KRAS G12C inhibition was heterogeneous across models. Adaptive resistance mechanisms involving reactivation of MAPK pathway and failure to induce PI3K–AKT pathway inactivation were identified as likely resistance events. We identified several model-specific effective combinations as well as a broad-sensitizing effect of PI3K-AKT–mTOR pathway inhibitors. The G12Ci+PI3Ki combination was effective in vitro and in vivo on models resistant to single-agent ARS1620 including patient-derived xenografts models. Conclusions: Our findings suggest that signaling adaptation can in some instances limit the efficacy of ARS1620 but combination with PI3K inhibitors can overcome this resistance.

Published

2019

22. NOTCH1 Represses MCL-1 Levels in GSI-resistant T-ALL, Making them Susceptible to ABT-263

Author

Justine E. Roderick, Xunqin Yin, Jeffrey A. Engelman, Michelle A. Kelliher, Neha U. Patel, AHyun Choi, August Williams, Jessica L. Boisvert, Jorge A. Almenara, Cyril H. Benes, Ultan McDermott, Anthony C. Faber, Kathryn A. Rizzo, Anahita Dastur, Carlotta Costa, Steven Grant, Joseph McClanaghan, Max Greenberg, and Mathew J. Garnett

Subjects

0301 basic medicine, Cancer Research, Notch signaling pathway, Apoptosis, mTORC1, Drug resistance, Mechanistic Target of Rapamycin Complex 1, Precursor T-Cell Lymphoblastic Leukemia-Lymphoma, Article, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, In vivo, Cell Line, Tumor, Animals, Humans, Medicine, Receptor, Notch1, Receptor, Cell Proliferation, Sulfonamides, Aniline Compounds, Navitoclax, business.industry, In vitro, 3. Good health, 030104 developmental biology, Oncology, chemistry, Drug Resistance, Neoplasm, Cell culture, 030220 oncology & carcinogenesis, Cancer research, Heterografts, Myeloid Cell Leukemia Sequence 1 Protein, Amyloid Precursor Protein Secretases, business, Signal Transduction

Abstract

Purpose: Effective targeted therapies are lacking for refractory and relapsed T-cell acute lymphoblastic leukemia (T-ALL). Suppression of the NOTCH pathway using gamma-secretase inhibitors (GSI) is toxic and clinically not effective. The goal of this study was to identify alternative therapeutic strategies for T-ALL. Experimental Design: We performed a comprehensive analysis of our high-throughput drug screen across hundreds of human cell lines including 15 T-ALL models. We validated and further studied the top hit, navitoclax (ABT-263). We used multiple human T-ALL cell lines as well as primary patient samples, and performed both in vitro experiments and in vivo studies on patient-derived xenograft models. Results: We found that T-ALL are hypersensitive to navitoclax, an inhibitor of BCL2 family of antiapoptotic proteins. Importantly, GSI-resistant T-ALL are also susceptible to navitoclax. Sensitivity to navitoclax is due to low levels of MCL-1 in T-ALL. We identify an unsuspected regulation of mTORC1 by the NOTCH pathway, resulting in increased MCL-1 upon GSI treatment. Finally, we show that pharmacologic inhibition of mTORC1 lowers MCL-1 levels and further sensitizes cells to navitoclax in vitro and leads to tumor regressions in vivo. Conclusions: Our results support the development of navitoclax, as single agent and in combination with mTOR inhibitors, as a new therapeutic strategy for T-ALL, including in the setting of GSI resistance.

Published

2019

23. Abstract PO-024: Catastrophic ATP loss underlines a metabolic combination therapy tailored for MYCN-amplified neuroblastoma

Author

Ellen Murchie, Jennifer Koblisnski, Timonthy L. Lochmann, Mikhail G. Dozmorov, Bin Hu, John Glod, Cyril H. Benes, Patricia Greninger, Richard Kurupi, Sivapriya Ramamoorthy, Lisa S. Shock, Krista M. Powell, Anthony C. Faber, Sosipatros A. Boikos, Konstantinos V. Floros, Giovanna T. Stein, Joseph McClanaghan, Marissa L. Calbert, Madhavi Puchalapalli, and Regina K. Egan

Subjects

Cancer Research, Combination therapy, business.industry, medicine.medical_treatment, Cell, Mitochondrion, Phenformin, medicine.disease_cause, medicine.disease, Targeted therapy, chemistry.chemical_compound, medicine.anatomical_structure, Oncology, chemistry, Neuroblastoma, Cancer research, medicine, Glycolysis, Carcinogenesis, business, neoplasms

Abstract

MYCN-amplified neuroblastoma is responsible for ~10% of all cancer-related deaths in the pediatric population. MYCN drives numerous effects in the cell, including metabolic changes that are critical for oncogenesis. The understanding that both compensatory pathways and intrinsic redundancy in cell systems exists implies that the use of combination therapies for effective and durable responses is necessary. Additionally, the most effective targeted therapies exploit an “Achilles’ heels” and are tailored to the genetics of the cancer under study. We performed an unbiased screen on select metabolic targeted therapy combinations and correlated sensitivity with over 20 subsets of cancer. We found that MYCN-amplified neuroblastoma are hypersensitive to the combination of AZD3965, an inhibitor of the lactate transporter MCT1, and phenformin, an inhibitor of complex I of the mitochondrion. Our data demonstrate MCT4 is highly correlated with resistance to the combination of AZD3965 and phenformin through the screen, is heavily methylated, and lowly expressed in MYCN-amplified neuroblastoma. Low MCT4 combines with high expression of the MCT2 and MCT1 chaperone CD147 in MYCN-amplified neuroblastoma, altogether conferring sensitivity to AZD3965 and phenformin combination. Metabolomic analysis showed that the result is simultaneous disruption of glycolysis and oxidative phosphorylation, resulting in dramatic disruption of adenosine triphosphate (ATP) production, endoplasmic reticulum (ER) stress, and apoptosis, which was seen through cell viability assays and protein analysis. In mouse models of MYCN-amplified neuroblastoma, the combination was tolerable at concentrations where it shrank tumors and did not increase white blood cell toxicity compared to single-drugs. Therefore, we demonstrate a metabolic combination screen can identify vulnerabilities in subsets of cancer and put forth a metabolic combination therapy tailored for MYCN-amplified neuroblastoma that demonstrates efficacy and tolerability in vivo. Citation Format: Krista M. Powell, Timonthy L. Lochmann, Konstantinos V. Floros, Marissa L. Calbert, Richard Kurupi, Giovanna T. Stein, Joseph McClanaghan, Ellen Murchie, Regina K. Egan, Patricia Greninger, Mikhail Dozmorov, Sivapriya Ramamoorthy, Madhavi Puchalapalli, Bin Hu, Lisa Shock, Jennifer Koblisnski, John Glod, Sosipatros A. Boikos, Cyril H. Benes, Anthony C. Faber. Catastrophic ATP loss underlines a metabolic combination therapy tailored for MYCN-amplified neuroblastoma [abstract]. In: Abstracts: AACR Special Virtual Conference on Epigenetics and Metabolism; October 15-16, 2020; 2020 Oct 15-16. Philadelphia (PA): AACR; Cancer Res 2020;80(23 Suppl):Abstract nr PO-024.

Published

2020

24. AMG 176, a Selective MCL1 Inhibitor, Is Effective in Hematologic Cancer Models Alone and in Combination with Established Therapies

Author

Jia-Nan Gong, Angela Coxon, Sean Caenepeel, Cyril H. Benes, Andrew W. Roberts, Tao Osgood, Donia M Moujalled, Elaina Cajulis, Andrew H. Wei, Regina K. Egan, Mario G. Cardozo, Pedro J. Beltran, Liusheng Zhu, Marc Vimolratana, Sean P. Brown, Brian Lucas, Xin Huang, Gordon Moody, Paul E. Hughes, David C.S. Huang, Giovanna Pomilio, Joshua Taygerly, Jan Sun, Danny Chui, Leszek Poppe, Jude Canon, Douglas A. Whittington, Yunxiao Li, Manuel Zancanella, Nick A. Paras, Joseph McClanaghan, Xianghong Wang, Alan C. Cheng, Kathleen S. Keegan, Jonathan B. Houze, Leah J. Damon, Patricia Greninger, and Brian Belmontes

Subjects

0301 basic medicine, Apoptosis Inhibitor, Venetoclax, business.industry, Cancer, Myeloid leukemia, medicine.disease, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Oncology, chemistry, Apoptosis, Cell culture, Pharmacodynamics, Cancer research, medicine, MCL1, business

Abstract

The prosurvival BCL2 family member MCL1 is frequently dysregulated in cancer. To overcome the significant challenges associated with inhibition of MCL1 protein–protein interactions, we rigorously applied small-molecule conformational restriction, which culminated in the discovery of AMG 176, the first selective MCL1 inhibitor to be studied in humans. We demonstrate that MCL1 inhibition induces a rapid and committed step toward apoptosis in subsets of hematologic cancer cell lines, tumor xenograft models, and primary patient samples. With the use of a human MCL1 knock-in mouse, we demonstrate that MCL1 inhibition at active doses of AMG 176 is tolerated and correlates with clear pharmacodynamic effects, demonstrated by reductions in B cells, monocytes, and neutrophils. Furthermore, the combination of AMG 176 and venetoclax is synergistic in acute myeloid leukemia (AML) tumor models and in primary patient samples at tolerated doses. These results highlight the therapeutic promise of AMG 176 and the potential for combinations with other BH3 mimetics. Significance: AMG 176 is a potent, selective, and orally bioavailable MCL1 inhibitor that induces a rapid commitment to apoptosis in models of hematologic malignancies. The synergistic combination of AMG 176 and venetoclax demonstrates robust activity in models of AML at tolerated doses, highlighting the promise of BH3-mimetic combinations in hematologic cancers. See related commentary by Leber et al., p. 1511. This article is highlighted in the In This Issue feature, p. 1494

Published

2018

25. Abstract C064: The investigational peptide drug ALRN-6924, a dual inhibitor of MDMX and MDM2, is an effective myelopreservation agent

Author

A. Annis, Joseph McClanaghan, Luis A. Carvajal, Vojislav Vukovic, Manuel Aivado, Mariam Mounir, David Sutton, and Vincent Guerlavais

Subjects

Cancer Research, Chemotherapy, business.industry, medicine.medical_treatment, CD34, Cell cycle, medicine.anatomical_structure, Oncology, Cancer cell, medicine, Cancer research, Topotecan, Bone marrow, Progenitor cell, business, Ex vivo, medicine.drug

Abstract

Aim: We investigated whether p53 activation with ALRN-6924 can prevent or reduce chemotherapy-induced hematopoietic toxicity while preserving or enhancing anti-tumor efficacy of chemotherapy in p53-mutant tumors. Materials and methods: ALRN-6924 is a clinical-stage, first-in-class, stabilized cell-permeating alpha-helical peptide that disrupts the interaction of the p53 tumor suppressor protein with its endogenous inhibitors, MDMX and MDM2. For p53 wild-type cells such as normal bone marrow, p53 activation can induce transient, dose-dependent cell cycle arrest, reducing sensitivity to chemotherapy-induced cellular toxicity. For p53-mutant cancer cells, ALRN-6924 has no effect on the cell cycle, leaving them vulnerable to chemotherapy. ALRN-6924-induced cell cycle arrest was measured by flow cytometry in human bone marrow CD34+ cells following incubation with ALRN-6924 ex vivo for 24 hours. DNA synthesis and DNA content were quantified by flow cytometry using EdU incorporation and Hoechst 33342 staining, respectively. Cell cycle arrest in the bone marrow of ALRN-6924-treated C57BL/6 mice was measured by flow cytometry using EdU incorporation in lineage negative, Kit positive hematopoietic stem and progenitor cells. Topotecan-induced DNA damage was measured in human bone marrow CD34+ cells by H2γX incorporation following exposure to vehicle or ALRN-6924 for 24 hours to induce cell cycle arrest, then incubated with topotecan for an additional 24 hours following a wash-out step. Topotecan-induced neutropenia was measured in female C57BL/6 mice following topotecan treatment on days 1-5 and either ALRN-6924 or vehicle on days 0-4. Female C57BL/6 mice bearing subcutaneous p53-mutant MC38 syngeneic tumors were treated with ALRN-6924, vehicle and topotecan on the same dosing regimen and followed until tumors reached >1000mm3. Results: ALRN-6924 induces transient, reversible cell cycle arrest in bone marrow cells in vitro and in vivo, and protects human bone marrow cells against topotecan-induced DNA damage ex vivo. In a mouse model of topotecan-induced neutropenia, ALRN-6924 protected against neutrophil depletion when daily administration started 24 hours prior to the 1st dose and 30 minutes before each subsequent dose of topotecan. ALRN-6924 does not diminish topotecan’s anti-tumor activity in the p53-mutant MC38 syngeneic mouse cancer model, with the ALRN-6924 + topotecan combination yielding modest enhancement of survival. Body weights and mortality data suggest ALRN-6924 and combinations with topotecan were tolerated at the doses tested. Conclusions: ALRN-6924 reduces chemotherapy-induced hematopoietic toxicity in healthy human bone marrow cells ex vivo and in mouse models of topotecan-induced neutropenia in vivo, while preserving or enhancing anti-tumor efficacy in p53-mutant tumors when administered intravenously prior to chemotherapy. These results support the first ALRN-6924 clinical trial for myelopreservation in topotecan-treated small-cell lung cancer patients (NCT04022876). Additional studies are underway to support ALRN-6924 as a tumor type-agnostic myelopreservation agent for cancer patients with tumors bearing p53 mutations who are treated with chemotherapy. Citation Format: Luis A Carvajal, David Sutton, Mariam Mounir, Joseph McClanaghan, Vincent Guerlavais, Manuel Aivado, Vojislav Vukovic, Allen Annis. The investigational peptide drug ALRN-6924, a dual inhibitor of MDMX and MDM2, is an effective myelopreservation agent [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 C064. doi:10.1158/1535-7163.TARG-19-C064

Published

2019

26. Potent and selective effect of the mir-10b inhibitor MN-anti-mir10b in human cancer cells of diverse primary disease origin

Author

Patricia Greninger, Giovanna T. Stein, Cyril H. Benes, Regina K. Egan, Zdravka Medarova, Joseph McClanaghan, Byunghee Yoo, and Anna Moore

Subjects

0301 basic medicine, Cancer Treatment, lcsh:Medicine, medicine.disease_cause, Proto-Oncogene Mas, Biochemistry, Metastasis, Mice, Mathematical and Statistical Techniques, 0302 clinical medicine, Basic Cancer Research, Medicine and Health Sciences, Nanotechnology, Neoplasm Metastasis, lcsh:Science, Cell Analysis, Multidisciplinary, Pharmaceutics, Genomics, Metastatic breast cancer, Nucleic acids, Bioassays and Physiological Analysis, Oncology, 030220 oncology & carcinogenesis, Physical Sciences, Engineering and Technology, Regression Analysis, Experimental pathology, Female, Statistics (Mathematics), Research Article, Clinical Oncology, Cell Viability Testing, Cell Survival, Linear Regression Analysis, Biology, Research and Analysis Methods, Cancer Chemotherapy, 03 medical and health sciences, Drug Therapy, Cell Line, Tumor, microRNA, Genetics, medicine, Animals, Humans, Chemotherapy, Statistical Methods, Non-coding RNA, Gene, Biology and life sciences, lcsh:R, Antagomirs, Mammary Neoplasms, Experimental, Cancers and Neoplasms, medicine.disease, Gene regulation, MicroRNAs, 030104 developmental biology, Metastatic Tumors, Cell culture, Cancer research, Nanoparticles, RNA, lcsh:Q, Gene expression, Clinical Medicine, Carcinogenesis, Mathematics, Human cancer

Abstract

Since microRNAs (miRNAs, miRs) have been implicated in oncogenesis, many of them have been identified as therapeutic targets. Previously we have demonstrated that miRNA-10b acts as a master regulator of the viability of metastatic tumor cells and represents a target for therapeutic intervention. We designed and synthesized an inhibitor of miR-10b, termed MN-anti-miR10b. We showed that treatment with MN-anti-miR10b led to durable regression/elimination of established metastases in murine models of metastatic breast cancer. Since miRNA-10b has been associated with various metastatic and non-metastatic cancers, in the present study, we investigated the effect of MN-anti-miR10b in a panel of over 600 cell lines derived from a variety of human malignancies. We observed an effect on the viability of multiple cell lines within each cancer type and a mostly dichotomous response with cell lines either strongly responsive to MN-anti-miR10b or not at all even at maximum dose tested, suggesting a very high specificity of the effect. Genomic modeling of the drug response showed enrichment of genes associated with the proto-oncogene, c-Jun.

Published

2018