Your search keyword '"Timothy L. Lochmann"' showing total 44 results

1. Figure S3 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

GSK-J4 inhibits histone demethylation of EWS-FLI1 target genes

Published

2023

2. Supplementary Figure 3 from Venetoclax-based Rational Combinations are Effective in Models of MYCN-amplified Neuroblastoma

Author

Anthony C. Faber, Yael P. Mossé, Cyril H. Benes, Andrew J. Souers, Patricia Greninger, Mikhail Dozmorov, Bin Hu, Richard Kurupi, Sheeba Jacob, Jinyang Cai, Colin Coon, Giovanna Stein Crowther, Qasim A. Khan, Alessia D'Aulerio, Colleen Casey, Renata Sano, Timothy L. Lochmann, Kateryna Krytska, and Krista M. Dalton

Abstract

Supplemental Figure 3. Chemotherapy and venetoclax combination cell viability assays. Cell viability assays were performed for 72h treatment of cyclophosphamide and topotecan, venetoclax, or combination at indicated concentrations, with bliss synergy scores in (A) MYCN-amplified, and (B) MYCN-wild-type cell lines. (C) Plot of Bliss sum of cell lines in A-B, calculated by the summation of the bliss synergy scores across the doses presented.

Published

2023

3. Supplementary Figure 2 from Venetoclax-based Rational Combinations are Effective in Models of MYCN-amplified Neuroblastoma

Author

Anthony C. Faber, Yael P. Mossé, Cyril H. Benes, Andrew J. Souers, Patricia Greninger, Mikhail Dozmorov, Bin Hu, Richard Kurupi, Sheeba Jacob, Jinyang Cai, Colin Coon, Giovanna Stein Crowther, Qasim A. Khan, Alessia D'Aulerio, Colleen Casey, Renata Sano, Timothy L. Lochmann, Kateryna Krytska, and Krista M. Dalton

Abstract

Supplemental Figure 2. PDX ex vivo model demonstrated cleavage of PARP with corresponding NOXA upregulation (A) Western blot of COG-N-561 ex vivo cell line treated overnight with antibodies as indicated.

Published

2023

4. Supplementary table 3 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

Gene symbols and names

Published

2023

5. Figure S7 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

The combination of GSK-J4 and THZ1 does not induce toxicity in mice

Published

2023

6. Supplementary table 2 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

The sequences of the primers used for ChIP

Published

2023

7. Figure S6 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

THZ1 inhibits RNA polymerase II in ES tumor

Published

2023

8. Figure S1 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

EWS-FLI1 expression sensitizes cells to GSK-J4

Published

2023

9. Figure S5 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

GSK-J4 in combination with chemotherapeutic agents synergistically inhibit ES cells

Published

2023

10. Supplementary Figure 4 from Venetoclax-based Rational Combinations are Effective in Models of MYCN-amplified Neuroblastoma

Author

Anthony C. Faber, Yael P. Mossé, Cyril H. Benes, Andrew J. Souers, Patricia Greninger, Mikhail Dozmorov, Bin Hu, Richard Kurupi, Sheeba Jacob, Jinyang Cai, Colin Coon, Giovanna Stein Crowther, Qasim A. Khan, Alessia D'Aulerio, Colleen Casey, Renata Sano, Timothy L. Lochmann, Kateryna Krytska, and Krista M. Dalton

Abstract

Supplemental Figure 4. Body Weight of Mice for in vivo treatments. (A) Plot of percent change in body weight from pre-treatment body weight in all in-vivo treatments.

Published

2023

11. Supplementary Figure 1 from Venetoclax-based Rational Combinations are Effective in Models of MYCN-amplified Neuroblastoma

Author

Anthony C. Faber, Yael P. Mossé, Cyril H. Benes, Andrew J. Souers, Patricia Greninger, Mikhail Dozmorov, Bin Hu, Richard Kurupi, Sheeba Jacob, Jinyang Cai, Colin Coon, Giovanna Stein Crowther, Qasim A. Khan, Alessia D'Aulerio, Colleen Casey, Renata Sano, Timothy L. Lochmann, Kateryna Krytska, and Krista M. Dalton

Abstract

Supplemental Figure 1. NVP-CGM097 and venetoclax combination cell viability assays. Cell viability assays were performed for 16h treatment of NVP-CGM097, venetoclax, or combination at indicated concentrations, with bliss synergy scores in (A) MYCN-wild-type, p53-wild-type, (B) MYCN-amplified, p53-mutant, and (C) MYCN-wild-type, p53-mutant NB cell lines. Red indicates synergy, blue indicates antagonism. (D) Plot of Bliss sum of cell lines in A-C along with cell lines in Fig. 1B, calculated by the summation of the bliss synergy scores across the doses presented.

Published

2023

12. Figure S4 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

GSK-J4 inhibits EWS-FLI1 targets EZH2 and tumor growth

Published

2023

13. Figure S2 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

GSK-J4 alters EWS-FLI1 gene targets in ES

Published

2023

14. Supplementary table 1 from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

The sequences of the primers used for qPCR

Published

2023

15. Data from Pharmaceutical Interference of the EWS-FLI1–driven Transcriptome By Cotargeting H3K27ac and RNA Polymerase Activity in Ewing Sarcoma

Author

Anthony C. Faber, Cyril H. Benes, Sosipatros A. Boikos, Mikhail G. Dozmorov, Jennifer E. Koblinski, Yuki Kato Maves, Mayuri Shende, Marissa L. Calbert, Maninderjit S. Ghotra, Richard Kurupi, Timothy L. Lochmann, Sheeba Jacob, and Daniel A.R. Heisey

Abstract

The EWSR1-FLI1 t(11;22)(q24;q12) translocation is the hallmark genomic alteration of Ewing sarcoma, a malignancy of the bone and surrounding tissue, predominantly affecting children and adolescents. Although significant progress has been made for the treatment of localized disease, patients with metastasis or who relapse after chemotherapy have less than a 30% five-year survival rate. EWS-FLI1 is currently not clinically druggable, driving the need for more effective targeted therapies. Treatment with the H3K27 demethylase inhibitor, GSK-J4, leads to an increase in H3K27me and a decrease in H3K27ac, a significant event in Ewing sarcoma because H3K27ac associates strongly with EWS-FLI1 binding at enhancers and promoters and subsequent activity of EWS-FLI1 target genes. We were able to identify targets of EWS-FLI1 tumorigenesis directly inhibited by GSK-J4. GSK-J4 disruption of EWS-FLI1-driven transcription was toxic to Ewing sarcoma cells and slowed tumor growth in patient-derived xenografts (PDX) of Ewing sarcoma. Responses were markedly exacerbated by cotreatment with a disruptor of RNA polymerase II activity, the CDK7 inhibitor THZ1. This combination together suppressed EWS-FLI1 target genes and viability of ex vivo PDX Ewing sarcoma cells in a synergistic manner. In PDX models of Ewing Sarcoma, the combination shrank tumors. We present a new therapeutic strategy to treat Ewing sarcoma by decreasing H3K27ac at EWS-FLI1–driven transcripts, exacerbated by blocking phosphorylation of the C-terminal domain of RNA polymerase II to further hinder the EWS-FLI1–driven transcriptome.

Published

2023

16. SI Table 1 from Epithelial-to-Mesenchymal Transition Antagonizes Response to Targeted Therapies in Lung Cancer by Suppressing BIM

Author

Anthony C. Faber, Jeffrey A. Engelman, Hiromichi Ebi, Bradley Bernstein, Lecia V. Sequist, Mikhail Dozmorov, Shirley M. Taylor, Sinem E. Sahingur, Zofia Piotrowska, Brad E. Windle, Tara J. Nulton, Maria Gomez-Caraballo, Hannah L. Archibald, Shawn Gillepsie, Angel Garcia, Elizabeth L. Lockerman, Neha U. Patel, Mark T. Hughes, Daniel A.R. Heisey, Yotam Drier, Hillary E. Mulvey, Haichuan Hu, Mark A. Hicks, Konstantinos V. Floros, Jungoh Ham, Hidenori Kitai, Aaron N. Hata, Timothy L. Lochmann, Matthew J. Niederst, and Kyung-A Song

Abstract

Top 10 correlated genes to BIM (BCL2L11)

Published

2023

17. Supplemental Table 1 from Venetoclax Is Effective in Small-Cell Lung Cancers with High BCL-2 Expression

Author

Anthony C. Faber, Cyril H. Benes, Hisashi Harada, Geoffrey W. Krystal, Andrew J. Souers, Joel D. Leverson, Sosipatros A. Boikos, Carlotta Costa, Scott J. Dylla, Laura R. Saunders, Yuki Kato Maves, Patricia Greninger, Giovanna T. Stein, Ryan J. March, Wade Cook, Krista M. Powell, Mitra Naseri, Konstantinos V. Floros, and Timothy L. Lochmann

Abstract

Supplemental Table 1 shows venetoclax screen data (AUC and IC50) across 791 solid tumor cell lines.

Published

2023

18. Supplemental legend from Epithelial-to-Mesenchymal Transition Antagonizes Response to Targeted Therapies in Lung Cancer by Suppressing BIM

Author

Anthony C. Faber, Jeffrey A. Engelman, Hiromichi Ebi, Bradley Bernstein, Lecia V. Sequist, Mikhail Dozmorov, Shirley M. Taylor, Sinem E. Sahingur, Zofia Piotrowska, Brad E. Windle, Tara J. Nulton, Maria Gomez-Caraballo, Hannah L. Archibald, Shawn Gillepsie, Angel Garcia, Elizabeth L. Lockerman, Neha U. Patel, Mark T. Hughes, Daniel A.R. Heisey, Yotam Drier, Hillary E. Mulvey, Haichuan Hu, Mark A. Hicks, Konstantinos V. Floros, Jungoh Ham, Hidenori Kitai, Aaron N. Hata, Timothy L. Lochmann, Matthew J. Niederst, and Kyung-A Song

Abstract

Supplemental legend

Published

2023

19. Figure S7 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

EWS-FLI1 increases BCL-2 expression in EWFT.

Published

2023

20. Table S2 from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Sup. Table 2. Top 3 functional pathways from ingenuity pathways analysis (IPA) in DTC.

Published

2023

21. Table S1 from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Sup. Table 1. Genes analyzed by RNA-seq with >1 absolute Log2 fold change between PC9 parental and PC9-DTC.

Published

2023

22. Data from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Purpose: EGFR inhibitors (EGFRi) are effective against EGFR-mutant lung cancers. The efficacy of these drugs, however, is mitigated by the outgrowth of resistant cells, most often driven by a secondary acquired mutation in EGFR, T790M. We recently demonstrated that T790M can arise de novo during treatment; it follows that one potential therapeutic strategy to thwart resistance would be identifying and eliminating these cells [referred to as drug-tolerant cells (DTC)] prior to acquiring secondary mutations like T790M.Experimental Design: We have developed DTCs to EGFRi in EGFR-mutant lung cancer cell lines. Subsequent analyses of DTCs included RNA-seq, high-content microscopy, and protein translational assays. Based on these results, we tested the ability of MCL-1 BH3 mimetics to combine with EGFR inhibitors to eliminate DTCs and shrink EGFR-mutant lung cancer tumors in vivo.Results: We demonstrate surviving EGFR-mutant lung cancer cells upregulate the antiapoptotic protein MCL-1 in response to short-term EGFRi treatment. Mechanistically, DTCs undergo a protein biosynthesis enrichment resulting in increased mTORC1-mediated mRNA translation of MCL-1, revealing a novel mechanism in which lung cancer cells adapt to short-term pressures of apoptosis-inducing kinase inhibitors. Moreover, MCL-1 is a key molecule governing the emergence of early EGFR-mutant DTCs to EGFRi, and we demonstrate it can be effectively cotargeted with clinically emerging MCL-1 inhibitors both in vitro and in vivo.Conclusions: Altogether, these data reveal that this novel therapeutic combination may delay the acquisition of secondary mutations, therefore prolonging therapy efficacy. Clin Cancer Res; 24(22); 5658–72. ©2018 AACR.

Published

2023

23. SI Table 2 from Epithelial-to-Mesenchymal Transition Antagonizes Response to Targeted Therapies in Lung Cancer by Suppressing BIM

Author

Anthony C. Faber, Jeffrey A. Engelman, Hiromichi Ebi, Bradley Bernstein, Lecia V. Sequist, Mikhail Dozmorov, Shirley M. Taylor, Sinem E. Sahingur, Zofia Piotrowska, Brad E. Windle, Tara J. Nulton, Maria Gomez-Caraballo, Hannah L. Archibald, Shawn Gillepsie, Angel Garcia, Elizabeth L. Lockerman, Neha U. Patel, Mark T. Hughes, Daniel A.R. Heisey, Yotam Drier, Hillary E. Mulvey, Haichuan Hu, Mark A. Hicks, Konstantinos V. Floros, Jungoh Ham, Hidenori Kitai, Aaron N. Hata, Timothy L. Lochmann, Matthew J. Niederst, and Kyung-A Song

Abstract

ZEB1 binding sites found in 1975R2 cells compared to 1975 parental cells

Published

2023

24. FIgure S6 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Olaparib sensitivity is modulated by BCL2 family expression

Published

2023

25. Supplemental Figures 1-8 from Venetoclax Is Effective in Small-Cell Lung Cancers with High BCL-2 Expression

Author

Anthony C. Faber, Cyril H. Benes, Hisashi Harada, Geoffrey W. Krystal, Andrew J. Souers, Joel D. Leverson, Sosipatros A. Boikos, Carlotta Costa, Scott J. Dylla, Laura R. Saunders, Yuki Kato Maves, Patricia Greninger, Giovanna T. Stein, Ryan J. March, Wade Cook, Krista M. Powell, Mitra Naseri, Konstantinos V. Floros, and Timothy L. Lochmann

Abstract

Supplemental Figure 1. Venetoclax sensitivity and BCL-2 mRNA correlation analysis; Supplemental Figure 2. Cell viability assays of border line venetoclax-sensitive and - resistant SCLC cell lines and combination of venetoclax with chemotherapy; Supplemental Figure 3. Correlation analysis of BCL-2 family members to venetoclax sensitivity in SCLC cell lines; Supplemental Figure 4. Comparison of BCL-2 family members to venetoclax sensitivity in SCLC cell lines; Supplemental Figure 5. BCL-2 mRNA expression is increased in SCLC compared to other cancer types; Supplemental Figure 6. Cell viability of venetoclax-sensitive and -resistant SCLC cell lines; Supplemental Figure 7. Weight profiles of xenograft and PDX models treated with venetoclax; Supplemental Figure 8. The PDX models from this study express high levels of BCL-2.

Published

2023

26. Figure S2 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

A chemotherapy naive and chemotherapy resistant cell line pair respond differently to olaparib.

Published

2023

27. Data from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Purpose:It was recently demonstrated that the EWSR1-FLI1 t(11;22)(q24;12) translocation contributes to the hypersensitivity of Ewing sarcoma to PARP inhibitors, prompting clinical evaluation of olaparib in a cohort of heavily pretreated Ewing sarcoma tumors. Unfortunately, olaparib activity was disappointing, suggesting an underappreciated resistance mechanism to PARP inhibition in patients with Ewing sarcoma. We sought to elucidate the resistance factors to PARP inhibitor therapy in Ewing sarcoma and identify a rational drug combination capable of rescuing PARP inhibitor activity.Experimental Design:We employed a pair of cell lines derived from the same patient with Ewing sarcoma prior to and following chemotherapy, a panel of Ewing sarcoma cell lines, and several patient-derived xenograft (PDX) and cell line xenograft models.Results:We found olaparib sensitivity was diminished following chemotherapy. The matched cell line pair revealed increased expression of the antiapoptotic protein BCL-2 in the chemotherapy-resistant cells, conferring apoptotic resistance to olaparib. Resistance to olaparib was maintained in this chemotherapy-resistant model in vivo, whereas the addition of the BCL-2/XL inhibitor navitoclax led to tumor growth inhibition. In 2 PDXs, olaparib and navitoclax were minimally effective as monotherapy, yet induced dramatic tumor growth inhibition when dosed in combination. We found that EWS-FLI1 increases BCL-2 expression; however, inhibition of BCL-2 alone by venetoclax is insufficient to sensitize Ewing sarcoma cells to olaparib, revealing a dual necessity for BCL-2 and BCL-XL in Ewing sarcoma survival.Conclusions:These data reveal BCL-2 and BCL-XL act together to drive olaparib resistance in Ewing sarcoma and reveal a novel, rational combination therapy that may be put forward for clinical trial testing.

Published

2023

28. Table S3 from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Sup. Table 3. Fold change of FBX7 from RNA-seq analysis.

Published

2023

29. Figure S8 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

DNA damage is increased with the combination of olaparib and navitoclax

Published

2023

30. Supplementary Figure Legends from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Figure legends for Supplementary Figures S1-S8.

Published

2023

31. Figure S4 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

A chemotherapy naive and chemotherapy resistant cell line pair respond differently to chemotherapeutics

Published

2023

32. Figure S3 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Olaparib induces similar levels of DNA damage in CHLA9 and CHLA10

Published

2023

33. Figure S1, Figure S2, Figure S3, Figure S4, Figure S5 and Figure S6 from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Figure S1. DTCs upregulate TORC1-mediated MCL-1 translation. Figure S2. High-content cell imaging assay. Figure S3. Genetic inhibition of MCL-1 is sufficient to induce apoptosis following EGFR inhibitor treatment. Figure S4. EGFR mutant tumors (PC9) respond to EGFR inhibitor/MCL-1 inhibitor (S63845) combination therapy in vivo. Figure S5. EGFR mutant tumors (HCC827) respond to EGFR inhibitor/MCL-1 inhibitor (S63845) combination therapy in vivo. Figure S6. Upregulation of MCL-1 in EGFR mutant cell lines occurs with other insults.

Published

2023

34. Supplementary Figure Legends from Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Anthony C. Faber, Hiromichi Ebi, Yasushi Yatabe, Sosipatros Boikos, Aaron N. Hata, Andrew J. Souers, Joel D. Leverson, Hisashi Harada, Jennifer E. Koblinski, Yuko Oya, Brad E. Windle, Colin M. Coon, Krista M. Powell, Bin Hu, Jungoh Ham, Neha U. Patel, Yoshiko Murakami, Timothy L. Lochmann, Sheeba Jacob, Crystal Turner, Yasuyuki Hosono, and Kyung-A Song

Abstract

Supplementary figure legends

Published

2023

35. Data from Epithelial-to-Mesenchymal Transition Antagonizes Response to Targeted Therapies in Lung Cancer by Suppressing BIM

Author

Anthony C. Faber, Jeffrey A. Engelman, Hiromichi Ebi, Bradley Bernstein, Lecia V. Sequist, Mikhail Dozmorov, Shirley M. Taylor, Sinem E. Sahingur, Zofia Piotrowska, Brad E. Windle, Tara J. Nulton, Maria Gomez-Caraballo, Hannah L. Archibald, Shawn Gillepsie, Angel Garcia, Elizabeth L. Lockerman, Neha U. Patel, Mark T. Hughes, Daniel A.R. Heisey, Yotam Drier, Hillary E. Mulvey, Haichuan Hu, Mark A. Hicks, Konstantinos V. Floros, Jungoh Ham, Hidenori Kitai, Aaron N. Hata, Timothy L. Lochmann, Matthew J. Niederst, and Kyung-A Song

Abstract

Purpose: Epithelial-to-mesenchymal transition (EMT) confers resistance to a number of targeted therapies and chemotherapies. However, it has been unclear why EMT promotes resistance, thereby impairing progress to overcome it.Experimental Design: We have developed several models of EMT-mediated resistance to EGFR inhibitors (EGFRi) in EGFR-mutant lung cancers to evaluate a novel mechanism of EMT-mediated resistance.Results: We observed that mesenchymal EGFR-mutant lung cancers are resistant to EGFRi-induced apoptosis via insufficient expression of BIM, preventing cell death despite potent suppression of oncogenic signaling following EGFRi treatment. Mechanistically, we observed that the EMT transcription factor ZEB1 inhibits BIM expression by binding directly to the BIM promoter and repressing transcription. Derepression of BIM expression by depletion of ZEB1 or treatment with the BH3 mimetic ABT-263 to enhance “free” cellular BIM levels both led to resensitization of mesenchymal EGFR-mutant cancers to EGFRi. This relationship between EMT and loss of BIM is not restricted to EGFR-mutant lung cancers, as it was also observed in KRAS-mutant lung cancers and large datasets, including different cancer subtypes.Conclusions: Altogether, these data reveal a novel mechanistic link between EMT and resistance to lung cancer targeted therapies. Clin Cancer Res; 24(1); 197–208. ©2017 AACR.

Published

2023

36. Supplementary Figure Legends from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Figure legends for Supplementary Figures S1-S8.

Published

2023

37. Data from Venetoclax Is Effective in Small-Cell Lung Cancers with High BCL-2 Expression

Author

Anthony C. Faber, Cyril H. Benes, Hisashi Harada, Geoffrey W. Krystal, Andrew J. Souers, Joel D. Leverson, Sosipatros A. Boikos, Carlotta Costa, Scott J. Dylla, Laura R. Saunders, Yuki Kato Maves, Patricia Greninger, Giovanna T. Stein, Ryan J. March, Wade Cook, Krista M. Powell, Mitra Naseri, Konstantinos V. Floros, and Timothy L. Lochmann

Abstract

Purpose: Small-cell lung cancer (SCLC) is an often-fatal neuroendocrine carcinoma usually presenting as extensive disease, carrying a 3% 5-year survival. Despite notable advances in SCLC genomics, new therapies remain elusive, largely due to a lack of druggable targets.Experimental Design: We used a high-throughput drug screen to identify a venetoclax-sensitive SCLC subpopulation and validated the findings with multiple patient-derived xenografts of SCLC.Results: Our drug screen consisting of a very large collection of cell lines demonstrated that venetoclax, an FDA-approved BCL-2 inhibitor, was found to be active in a substantial fraction of SCLC cell lines. Venetoclax induced BIM-dependent apoptosis in vitro and blocked tumor growth and induced tumor regressions in mice bearing high BCL-2–expressing SCLC tumors in vivo. BCL-2 expression was a predictive biomarker for sensitivity in SCLC cell lines and was highly expressed in a subset of SCLC cell lines and tumors, suggesting that a substantial fraction of patients with SCLC could benefit from venetoclax. Mechanistically, we uncover a novel role for gene methylation that helped discriminate high BCL-2–expressing SCLCs.Conclusions: Altogether, our findings identify venetoclax as a promising new therapy for high BCL-2–expressing SCLCs. Clin Cancer Res; 24(2); 360–9. ©2017 AACR.

Published

2023

38. Figure S5 from The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Anthony C. Faber, Sosipatros A. Boikos, Andrew J. Souers, Joel D. Leverson, Cyril H. Benes, Steven C. Smith, Yuki Kato Maves, Giovanna T. Stein, Maninderjit S. Ghotra, Marissa L. Calbert, Sheeba Jacob, Krista M. Powell, Colin M. Coon, Konstantinos V. Floros, Timothy L. Lochmann, and Daniel A.R. Heisey

Abstract

Navitoclax sensitizes EWFT to olaparib

Published

2023

39. The Ewing Family of Tumors Relies on BCL-2 and BCL-XL to Escape PARP Inhibitor Toxicity

Author

Sheeba Jacob, Colin M. Coon, Steven C. Smith, Joel D. Leverson, Maninderjit S. Ghotra, Yuki Kato Maves, Giovanna T. Stein, Andrew J. Souers, Daniel A. R. Heisey, Krista M. Powell, Konstantinos V. Floros, Marissa L. Calbert, Timothy L. Lochmann, Sosipatros A. Boikos, Cyril H. Benes, and Anthony C. Faber

Subjects

0301 basic medicine, Cancer Research, Navitoclax, Combination therapy, biology, business.industry, Venetoclax, Bcl-xL, medicine.disease, Olaparib, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, Oncology, chemistry, Ewing family of tumors, 030220 oncology & carcinogenesis, PARP inhibitor, biology.protein, Cancer research, Medicine, Sarcoma, business

Abstract

Purpose: It was recently demonstrated that the EWSR1-FLI1 t(11;22)(q24;12) translocation contributes to the hypersensitivity of Ewing sarcoma to PARP inhibitors, prompting clinical evaluation of olaparib in a cohort of heavily pretreated Ewing sarcoma tumors. Unfortunately, olaparib activity was disappointing, suggesting an underappreciated resistance mechanism to PARP inhibition in patients with Ewing sarcoma. We sought to elucidate the resistance factors to PARP inhibitor therapy in Ewing sarcoma and identify a rational drug combination capable of rescuing PARP inhibitor activity. Experimental Design: We employed a pair of cell lines derived from the same patient with Ewing sarcoma prior to and following chemotherapy, a panel of Ewing sarcoma cell lines, and several patient-derived xenograft (PDX) and cell line xenograft models. Results: We found olaparib sensitivity was diminished following chemotherapy. The matched cell line pair revealed increased expression of the antiapoptotic protein BCL-2 in the chemotherapy-resistant cells, conferring apoptotic resistance to olaparib. Resistance to olaparib was maintained in this chemotherapy-resistant model in vivo, whereas the addition of the BCL-2/XL inhibitor navitoclax led to tumor growth inhibition. In 2 PDXs, olaparib and navitoclax were minimally effective as monotherapy, yet induced dramatic tumor growth inhibition when dosed in combination. We found that EWS-FLI1 increases BCL-2 expression; however, inhibition of BCL-2 alone by venetoclax is insufficient to sensitize Ewing sarcoma cells to olaparib, revealing a dual necessity for BCL-2 and BCL-XL in Ewing sarcoma survival. Conclusions: These data reveal BCL-2 and BCL-XL act together to drive olaparib resistance in Ewing sarcoma and reveal a novel, rational combination therapy that may be put forward for clinical trial testing.

Published

2019

40. Increased Synthesis of MCL-1 Protein Underlies Initial Survival of EGFR-Mutant Lung Cancer to EGFR Inhibitors and Provides a Novel Drug Target

Author

Crystal Turner, Sosipatros A. Boikos, Yoshiko Murakami, Bin Hu, Jungoh Ham, Colin M. Coon, Neha U. Patel, Andrew J. Souers, Anthony C. Faber, Yasushi Yatabe, Yasuyuki Hosono, Timothy L. Lochmann, Joel D. Leverson, Brad Windle, Aaron N. Hata, Jennifer E. Koblinski, Krista M. Powell, Hiromichi Ebi, Hisashi Harada, Sheeba Jacob, Kyung-A Song, and Yuko Oya

Subjects

0301 basic medicine, Cancer Research, Mutation, business.industry, Kinase, Cancer, medicine.disease, medicine.disease_cause, 03 medical and health sciences, T790M, 030104 developmental biology, Oncology, Downregulation and upregulation, In vivo, Cancer research, Medicine, business, Lung cancer, EGFR inhibitors

Abstract

Purpose: EGFR inhibitors (EGFRi) are effective against EGFR-mutant lung cancers. The efficacy of these drugs, however, is mitigated by the outgrowth of resistant cells, most often driven by a secondary acquired mutation in EGFR, T790M. We recently demonstrated that T790M can arise de novo during treatment; it follows that one potential therapeutic strategy to thwart resistance would be identifying and eliminating these cells [referred to as drug-tolerant cells (DTC)] prior to acquiring secondary mutations like T790M. Experimental Design: We have developed DTCs to EGFRi in EGFR-mutant lung cancer cell lines. Subsequent analyses of DTCs included RNA-seq, high-content microscopy, and protein translational assays. Based on these results, we tested the ability of MCL-1 BH3 mimetics to combine with EGFR inhibitors to eliminate DTCs and shrink EGFR-mutant lung cancer tumors in vivo. Results: We demonstrate surviving EGFR-mutant lung cancer cells upregulate the antiapoptotic protein MCL-1 in response to short-term EGFRi treatment. Mechanistically, DTCs undergo a protein biosynthesis enrichment resulting in increased mTORC1-mediated mRNA translation of MCL-1, revealing a novel mechanism in which lung cancer cells adapt to short-term pressures of apoptosis-inducing kinase inhibitors. Moreover, MCL-1 is a key molecule governing the emergence of early EGFR-mutant DTCs to EGFRi, and we demonstrate it can be effectively cotargeted with clinically emerging MCL-1 inhibitors both in vitro and in vivo. Conclusions: Altogether, these data reveal that this novel therapeutic combination may delay the acquisition of secondary mutations, therefore prolonging therapy efficacy. Clin Cancer Res; 24(22); 5658–72. ©2018 AACR.

Published

2018

41. Epithelial-to-Mesenchymal Transition Antagonizes Response to Targeted Therapies in Lung Cancer by Suppressing BIM

Author

Jungoh Ham, Anthony C. Faber, Aaron N. Hata, Maria Gomez-Caraballo, Haichuan Hu, Elizabeth L. Lockerman, Brad Windle, Shawn Gillepsie, Daniel A. R. Heisey, Sinem Esra Sahingur, Mark A. Hicks, Kyung-A Song, Shirley M. Taylor, Hillary E. Mulvey, Timothy L. Lochmann, Hiromichi Ebi, Lecia V. Sequist, Konstantinos V. Floros, Mark T. Hughes, Hidenori Kitai, Hannah L. Archibald, Angel R. Garcia, Yotam Drier, Mikhail G. Dozmorov, Tara J. Nulton, Neha U. Patel, Matthew J. Niederst, Zofia Piotrowska, Bradley E. Bernstein, and Jeffrey A. Engelman

Subjects

0301 basic medicine, Cancer Research, Programmed cell death, Epithelial-Mesenchymal Transition, Lung Neoplasms, Apoptosis, Biology, Bioinformatics, Article, Mice, 03 medical and health sciences, medicine, Animals, Humans, Molecular Targeted Therapy, Epithelial–mesenchymal transition, RNA, Small Interfering, Promoter Regions, Genetic, Lung cancer, Protein Kinase Inhibitors, Transcription factor, EGFR inhibitors, Regulation of gene expression, Sulfonamides, Aniline Compounds, Bcl-2-Like Protein 11, Cell Cycle, Mesenchymal stem cell, medicine.disease, ErbB Receptors, Gene Expression Regulation, Neoplastic, Disease Models, Animal, Editorial, 030104 developmental biology, Oncology, Drug Resistance, Neoplasm, Mutation, Cancer research

Abstract

Purpose: Epithelial-to-mesenchymal transition (EMT) confers resistance to a number of targeted therapies and chemotherapies. However, it has been unclear why EMT promotes resistance, thereby impairing progress to overcome it. Experimental Design: We have developed several models of EMT-mediated resistance to EGFR inhibitors (EGFRi) in EGFR-mutant lung cancers to evaluate a novel mechanism of EMT-mediated resistance. Results: We observed that mesenchymal EGFR-mutant lung cancers are resistant to EGFRi-induced apoptosis via insufficient expression of BIM, preventing cell death despite potent suppression of oncogenic signaling following EGFRi treatment. Mechanistically, we observed that the EMT transcription factor ZEB1 inhibits BIM expression by binding directly to the BIM promoter and repressing transcription. Derepression of BIM expression by depletion of ZEB1 or treatment with the BH3 mimetic ABT-263 to enhance “free” cellular BIM levels both led to resensitization of mesenchymal EGFR-mutant cancers to EGFRi. This relationship between EMT and loss of BIM is not restricted to EGFR-mutant lung cancers, as it was also observed in KRAS-mutant lung cancers and large datasets, including different cancer subtypes. Conclusions: Altogether, these data reveal a novel mechanistic link between EMT and resistance to lung cancer targeted therapies. Clin Cancer Res; 24(1); 197–208. ©2017 AACR.

Published

2018

42. Abstract 4329: Pharmaceutical means of targeting the fusion oncogene EWS-FLI1 in the Ewing family of tumors

Author

Sosipatros A. Boikos, Marissa L. Calbert, Daniel A. R. Heisey, Timothy L. Lochmann, Anthony C. Faber, C. Patrick Reynolds, Cyril H. Benes, Yuki Kato Maves, and Maninderjit S. Ghotra

Subjects

Cancer Research, Oncogene, business.industry, fungi, Cancer, medicine.disease_cause, medicine.disease, Metastasis, Oncology, Ewing family of tumors, FLI1, medicine, Cancer research, Gene silencing, Epigenetics, Carcinogenesis, business

Abstract

The EWS-FLI1 translocation is the hallmark genomic alteration in the Ewing Family of Tumors (EWFT) a malignancy of the bone and surrounding tissue, predominantly affecting children and adolescents. Although significant progress has been made for the treatment of localized disease, patients with metastasis or who relapse after chemotherapy have less than a 30% five year survival rate. EWS-FLI is currently not pharmaceutically druggable, driving the need for more effective targeted therapies. It is well known that the EWS-FLI1 translocation induces a variety of epigenetic changes which impact tumorigenesis and disease progression. Using high throughput drug screening we have identified a novel epigenetic susceptibility in EWFT to the H3K27 demethylase inhibitor GSK-J4 (GlaxoSmithKline). Subsequent treatment with GSK-J4 leads to a decrease in H3K27 acetylation and ultimately silencing of EWS-FLI1 gene targets. We sought to fully characterize the hypersensitivity of EWFT to GSK-J4 and to elucidate the mechanisms of histone modifications caused by the EWS-FLI1 translocation in EWFT. We are examining key shifts in histone modifications at FLI1 target gene enhancer elements in the presence of GSK-J4 as a means of directly regulating FLI1 tumorigenesis. Additionally, we seek to determine the efficacy of GSK-J4 in combination with a CDK7 inhibitor (THZ1), which have shown synergy in vitro, through the utilization of patient derived xenograft models (PDX) and the identification of biomarkers of sensitivity to rationalize the use of this combination for clinical trials. Citation Format: Daniel A. Heisey, Timothy Lochmann, Marissa Calbert, Maninderjit Ghotra, Yuki Kato Maves, Sosipatros Boikos, Cyril Benes, C. Patrick Reynolds, Anthony Faber. Pharmaceutical means of targeting the fusion oncogene EWS-FLI1 in the Ewing family of tumors [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 4329.

Published

2019

43. Abstract B31: A protein synthesis switch underlies initial survival of EGFR-mutant lung cancer to EGFR inhibitors

Author

Jungoh Ham, Kyung-A Song, Aaron N. Hata, Hiromichi Ebi, Hisashi Harada, Brad Windle, Joel D. Leverson, Neha U. Patel, Andrew J. Souers, Anthony C. Faber, and Timothy L. Lochmann

Subjects

Cancer Research, Mutation, business.industry, Kinase, Cancer, medicine.disease_cause, medicine.disease, respiratory tract diseases, T790M, Gefitinib, Oncology, Cancer research, medicine, business, Lung cancer, PI3K/AKT/mTOR pathway, medicine.drug, EGFR inhibitors

Abstract

EGFR inhibitors (EGFRi) are effective at inducing transient tumor shrinkage in EGFR-mutant lung cancers. The efficacy of these drugs however is mitigated by the outgrowth of resistant cells: this is most often manifested by a secondary mutation in EGFR, T790M, which leads to reactivation of key intracellular signaling despite continued drug treatment. We recently demonstrated that T790M can occur both at low frequencies prior to initiation of EGFR inhibitor therapy, or alternatively arise de novo during treatment (Hata et al., Nat Med 2016). Since some cancers form T790M mutations de novo, one potential therapeutic strategy to thwart resistance is to identify the cells surviving initial therapy (referred to as persister cells or drug-tolerant cells [DTCs]) that eventually acquire the T790M mutation, and eliminate them prior to T790M acquisition. To this end, we hypothesized that some cells were refractory to EGFR inhibitor-induced apoptosis, surviving initial therapy and forming a reservoir of cells that could then eventually acquire T790M. We demonstrate that Western blots of lysates from EGFR-mutant lung cancers surviving initial therapy to the EGFR inhibitor gefitinib detect quick ( Citation Format: Kyung-A Song, Timothy L. Lochmann, Neha U. Patel, Jungoh Ham, Brad E. Windle, Hisashi Harada, Joel D. Leverson, Andrew J. Souers, Aaron N. Hata, Hiromichi Ebi, Anthony C. Faber. A protein synthesis switch underlies initial survival of EGFR-mutant lung cancer to EGFR inhibitors [abstract]. In: Proceedings of the Fifth AACR-IASLC International Joint Conference: Lung Cancer Translational Science from the Bench to the Clinic; Jan 8-11, 2018; San Diego, CA. Philadelphia (PA): AACR; Clin Cancer Res 2018;24(17_Suppl):Abstract nr B31.

Published

2018

44. Abstract 3082: Deficient NOXA in HER2-amplified breast cancer drives kinase inhibitor resistance

Author

Anthony C. Faber, Timothy L. Lochmann, Mark T. Hughes, Joel D. Leverson, Andrew J. Souers, Kyung-A Song, Daniel A. R. Heisey, Hisashi Harada, Bin Hu, Konstantinos V. Floros, and Jennifer E. Koblinski

Subjects

0301 basic medicine, Cancer Research, 030102 biochemistry & molecular biology, biology, Combination therapy, business.industry, Kinase, Cancer, medicine.disease, Lapatinib, Receptor tyrosine kinase, 03 medical and health sciences, Breast cancer, Oncology, hemic and lymphatic diseases, medicine, Cancer research, biology.protein, Gene silencing, skin and connective tissue diseases, Receptor, business, neoplasms, medicine.drug

Abstract

The purpose of this study is the development of a novel combination therapy that targets HER2-amplified breast cancer. About one quarter of breast cancers harbor amplification of HER2. HER2 is a transmembrane receptor tyrosine kinase (RTK) belonging to the ERBB family of receptors (ERBB1-4). Upon hetero- and homo-dimerization, HER2 activates several key intracellular pathways, regulating many cellular functions including proliferation and survival. HER2 inhibitors (HER2i) (e.g. the receptor tyrosine kinase (RTK) inhibitor, lapatinib) are now part of standard care for treating HER2-amplified breast cancers. However, despite their anti-cancer benefit, these drugs have limited efficacy as monotherapies, which contrasts to other RTK inhibitors in other RTK-driven cancers. To better understand this apparent dichotomy, in the present study, we evaluated potential modifiers of HER2i therapy. Here, we found that the pro-apoptotic NOXA, a member of the B-cell CLL/lymphoma 2 (BCL2) family which acts mainly via inhibitory binding of the pro-survival MCL-1, was markedly down-regulated in breast cancers compared to other cancers, and this was largely attributed to the HER2-amplified subset. Experimentally, overexpressing NOXA or silencing MCL-1 dramatically sensitizes HER2 amplified breast cancer cell lines to lapatinib via apoptosis. Consistently, pharmaceutical inhibition of MCL-1 sensitizes HER2-amplified breast cancers to lapatinib in vitro and in vivo. Mechanistically, disruption of MCL-1:BIM complexes and MCL-1:BAK underlie dual HER2i/MCL-1i therapy. Therefore, deficient NOXA expression constitutes a bonafide apoptotic block in HER2 amplified breast cancers, contributes to mitigated HER2i responses, and presents a rational combination therapy that may improve HER2i responses. Citation Format: Konstantinos V. Floros, Kyung-A Song, Timothy L. Lochmann, Mark T. Hughes, Daniel A. Heisey, Hisashi Harada, Bin Hu, Jennifer Koblinski, Andrew J. Souers, Joel D. Leverson, Anthony C. Faber. Deficient NOXA in HER2-amplified breast cancer drives kinase inhibitor resistance [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3082. doi:10.1158/1538-7445.AM2017-3082

Published

2017