Your search keyword '"Trang N. Tieu"' showing total 32 results

1. Supplementary Table S5 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Overlapped genes between Genes upregulated in Ptenpc-/-Smad4pc-/- tumors as compared to Ptenpc-/- tumors ({greater than or equal to}2 fold) and genes upregulated in GFP+ tumors cells from Ptenpc-/-Smad4pc-/- mice as compared to Tomato+ cells ({greater than or equal to}4 fold).

Published

2023

2. Supplementary Figure S1 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

PTEN loss in melanoma promotes resistance to T cell-mediated anti-tumor activity in the context of concurrent a selective inhibitor for mutant BRAF.

Published

2023

3. Supplementary Table S1 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Markers used in CyTOF analysis.

Published

2023

4. Supplementary Figure S7 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

Improved antitumor activity can be achieved by combining the PI3Kbeta inhibitor and immune checkpoint blockers.

Published

2023

5. Supplementary Figure S6 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

The effect of PI3Kbeta inhibitor on melanoma with PTEN loss.

Published

2023

6. Supplementary Table S3 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Genes upregulated in Ptenpc-/-Smad4pc-/- tumors as compared to Ptenpc-/- tumors ({greater than or equal to}2 fold).

Published

2023

7. Supplementary Figure S2 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

Lymphocyte infiltration status and the expression level of MHC class I in tumors from patients with melanoma.

Published

2023

8. Supplementary Table S2 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Detailed pathology description of the Gr1 treated mice and Cxcr2 inhibitor treated mice.

Published

2023

9. Supplementary Figure S3 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

Examples of increased VEGF expression in regions with loss of PTEN in melanoma patients with heterogeneous PTEN expression.

Published

2023

10. Supplementary Table S4 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Table S4. Genes upregulated in GFP+ tumors cells from Ptenpc-/-Smad4pc-/- mice as compared to Tomato+ cells ({greater than or equal to}4 fold).

Published

2023

11. Supplementary Figure S4 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

List of genes which are differentially expressed in melanomas with PTEN loss.

Published

2023

12. Supplementary Methods, Figure Legends, Figures S1 - S7 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Supplementary Figure S1. CyTOF analysis of biological samples from Ptenpc-/-Smad4pc-/- mice (Related to Figure 2). Supplementary Figure S2. Strategy used for MDSCs Isolation (Related to Figure 3). Supplementary Figure S3. Treatment scheme for Gr-1 antibody, peptibody, and Cxcr2 inhibitor SB225002. Supplementary Figure S4. IHC staining of Ki67, CD45, Vimentin, Smooth muscle actin (SMA) and Trichrome staining of mouse prostate tissues treated with IgG control or Gr1 antibody. Supplementary Figure S5. The top 10 differentially expressed genes in Ptenpc-/-Smad4pc-/- tumors as compared to Ptenpc-/- tumors, identified by microarray analysis (n=5). Figure S6. Top 10 activated oncogenic signatures identified by GSEA analysis in Ptenpc-/- Smad4pc-/- tumors as compared to Ptenpc-/- tumors (n=5). Figure S7. Clustering of primary prostate tumors from Wallace et al into MDSC-high and MDSC-low subtypes.

Published

2023

13. Supplementary Figure S5 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

Autophagy activity regulated by the PI3K pathway plays a critical role in T cell-induced tumor apoptosis.

Published

2023

14. Supplementary Table S6 from Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Ronald A. DePinho, Y. Alan Wang, Lynda Chin, Mark J. McArthur, Christopher J. Logothetis, Patricia Troncoso, Qing Chang, Liren Li, Yanxia Shi, Zhihu Ding, Xiaolu Pan, Wantong Yao, Eun-Jung Jin, Baoli Hu, Pingping Hou, Sunada Khadka, Xiaoying Shang, Di Zhao, Tim Heffernan, Trang N. Tieu, Vandhana Ramamoorthy, Zhenglin Guo, Neelay Bhaskar Patel, Chang-Jiun Wu, Avnish Kapoor, Elsa M. Li-Ning-Tapia, Jianhua Zhang, Sujun Hua, Ramakrishna Konaparthi, Kun Zhao, Zhuangna Fang, Shan Jiang, Chia Chin Wu, Pingna Deng, Prasenjit Dey, Xin Lu, and Guocan Wang

Abstract

Detailed information for the YAP1 IHC staining in human prostate cancers.

Published

2023

15. Supplementary Methods, Figure Legends, Tables S1 - S3 from Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Patrick Hwu, Michael A. Davies, Laszlo Radvanyi, Jeffrey E. Gershenwald, Jennifer A. Wargo, Thomas F. Gajewski, Jason Roszik, Gregory Lizée, Willem W. Overwijk, Scott E. Woodman, Marcus W. Bosenberg, Roland L. Bassett, Jianhua Hu, Timothy P. Heffernan, Lawrence N. Kwong, Haiyan S. Li, Tina Cascone, Isabella C. Glitza, Jennifer L. McQuade, Rodabe Amaria, Cara Haymaker, Marie-Andree Forget, Chantale Bernatchez, Xiaoxing Yu, Stefani Spranger, Trang N. Tieu, Pei-Ling Chen, Zachary A. Cooper, Carlos A. Torres-Cabala, Alexander J. Lazar, Rina Mbofung, Guo Chen, Wanleng Deng, Leila J. Williams, Xiaoxuan Liang, Chunlei Zhang, Jodi A. McKenzie, Chunyu Xu, Michael T. Tetzlaff, Caitlin Creasy, Shruti Malu, Chengwen Liu, Jie Qing Chen, and Weiyi Peng

Abstract

Supplementary Table S1. Patient characteristics of the single-agent anti-PD-1 cohort. Supplementary Table S2. List of primers used for gene expression analysis by real-time PCR. Supplementary Table S3. List of autophagy-related genes for overexpressing experiment.

Published

2023

16. Supplementary Figures 1 - 8 from The SMARCA2/4 ATPase Domain Surpasses the Bromodomain as a Drug Target in SWI/SNF-Mutant Cancers: Insights from cDNA Rescue and PFI-3 Inhibitor Studies

Author

Jannik N. Andersen, Shikhar Sharma, Wylie S. Palmer, Philip Jones, Giulio Draetta, Dafydd R. Owen, Dominique Verhelle, Alessia Petrocchi, Carlo Toniatti, Joseph R. Marszalek, Timothy P. Heffernan, Mike Peoples, Trang N. Tieu, Andrew Futreal, Alexei Protopopov, Harshad S. Mahadeshwar, Elisabetta Leo, Yanai Zhan, Xi Shi, Lisa Nottebaum, Maria Kost-Alimova, Parantu K. Shah, Thomas A. Paul, and Bhavatarini Vangamudi

Abstract

Figure S1. Genomic analysis of SWI/SNF alterations in human cancer. Figure S2. SMARCA4-deficient lung cancer cells depend on SMARCA2 expression for growth. Figure S3. In-situ cell extraction assay for PFI-3 treatment. Figure S4. SMARCA2/4 bromodomain inhibitor does not alter growth of lung cancer cells. Figure S5. Analysis of SMARCA4 target gene expression and promoter occupancy following prolonged treatment with PFI-3. Figure S6. Pharmacological PFI-3 inhibitor studies in leukemia cells. Figure S7. Pharmacological EZH2 inhibitor studies. Figure S8. Genome-wide microarray analysis of SMARCA2 knockdown in A549 cells reconstituted with SMARCA4 cDNAs. Table S1: Survey of genomic lesions in SWI/SNF across different cancer types. Table S2: Sequence information of shRNA's and siRNA's used in the study. Table S3. BROMOScan (DiscoveRx) profiling of PFI-3 (at 2uM) against 32 bromodomains. Table S4. Definition of gene sets (i.e. SMARCA2 knockdown signatures) from SMARCA4 rescue experiments in A549 cells. Table S5. Summary of GSEA normalized enrichment scores (NES) and false discovery rate (FDR) for rescue experiment using ATP-Dead, BRD-Mut and vector control and compared to WT.

Published

2023

17. Supplementary Methods, Figure Legends from The SMARCA2/4 ATPase Domain Surpasses the Bromodomain as a Drug Target in SWI/SNF-Mutant Cancers: Insights from cDNA Rescue and PFI-3 Inhibitor Studies

Author

Jannik N. Andersen, Shikhar Sharma, Wylie S. Palmer, Philip Jones, Giulio Draetta, Dafydd R. Owen, Dominique Verhelle, Alessia Petrocchi, Carlo Toniatti, Joseph R. Marszalek, Timothy P. Heffernan, Mike Peoples, Trang N. Tieu, Andrew Futreal, Alexei Protopopov, Harshad S. Mahadeshwar, Elisabetta Leo, Yanai Zhan, Xi Shi, Lisa Nottebaum, Maria Kost-Alimova, Parantu K. Shah, Thomas A. Paul, and Bhavatarini Vangamudi

Abstract

Supplementary Methods, Figure Legends

Published

2023

18. Aurora kinase inhibition sensitizes melanoma cells to T-cell-mediated cytotoxicity

Author

Cara Haymaker, Jason Roszik, Jie Qing Chen, Jahan Khalili, Zhe Wang, Nikunj Satani, Rina M. Mbofung, Laurence J.N. Cooper, Marie-Andree Forget, Willem W. Overwijk, Chunyu Xu, Leila Williams, Weiyi Peng, Chengwen Liu, Deborah A. Silverman, Simone Punt, Sourindra Maiti, Florian L. Muller, Elien M Doorduijn, Chantale Bernatchez, Trang N. Tieu, Ana Lucia Dominguez, Soraya Zorro Manrique, Patrick Hwu, Shruti Malu, Emily Ashkin, Jodi A. McKenzie, Rodabe N. Amaria, and Timothy P. Heffernan

Subjects

Cancer Research, High-throughput screen, medicine.medical_treatment, Immunology, Apoptosis, Mice, 03 medical and health sciences, Lymphocytes, Tumor-Infiltrating, 0302 clinical medicine, Aurora kinase, In vivo, Tumor Cells, Cultured, Tumor Microenvironment, medicine, Animals, Aurora Kinase B, Humans, Immunology and Allergy, Cytotoxicity, Melanoma, Aurora Kinase A, Cell Proliferation, 030304 developmental biology, 0303 health sciences, Tumor microenvironment, Chemistry, T-cell cytotoxicity, Immunotherapy, Prognosis, medicine.disease, Xenograft Model Antitumor Assays, Survival Rate, Oncology, Drug Resistance, Neoplasm, 030220 oncology & carcinogenesis, Cancer research, Original Article, Female, T cell mediated cytotoxicity, Immune checkpoint blockade, T-Lymphocytes, Cytotoxic

Abstract

Although immunotherapy has achieved impressive durable clinical responses, many cancers respond only temporarily or not at all to immunotherapy. To find novel, targetable mechanisms of resistance to immunotherapy, patient-derived melanoma cell lines were transduced with 576 open reading frames, or exposed to arrayed libraries of 850 bioactive compounds, prior to co-culture with autologous tumor-infiltrating lymphocytes (TILs). The synergy between the targets and TILs to induce apoptosis, and the mechanisms of inhibiting resistance to TILs were interrogated. Gene expression analyses were performed on tumor samples from patients undergoing immunotherapy for metastatic melanoma. Finally, the effect of inhibiting the top targets on the efficacy of immunotherapy was investigated in multiple preclinical models. Aurora kinase was identified as a mediator of melanoma cell resistance to T-cell-mediated cytotoxicity in both complementary screens. Aurora kinase inhibitors were validated to synergize with T-cell-mediated cytotoxicity in vitro. The Aurora kinase inhibition-mediated sensitivity to T-cell cytotoxicity was shown to be partially driven by p21-mediated induction of cellular senescence. The expression levels of Aurora kinase and related proteins were inversely correlated with immune infiltration, response to immunotherapy and survival in melanoma patients. Aurora kinase inhibition showed variable responses in combination with immunotherapy in vivo, suggesting its activity is modified by other factors in the tumor microenvironment. These data suggest that Aurora kinase inhibition enhances T-cell cytotoxicity in vitro and can potentiate antitumor immunity in vivo in some but not all settings. Further studies are required to determine the mechanism of primary resistance to this therapeutic intervention. Electronic supplementary material The online version of this article (10.1007/s00262-020-02748-9) contains supplementary material, which is available to authorized users.

Published

2020

19. High-Throughput Quantitative Assay Technologies for Accelerating the Discovery and Optimization of Targeted Protein Degradation Therapeutics

Author

Jeffrey R Simard, Trang N. Tieu, Eunice Park, Ellen F. Vieux, Andrew J. K. Phillips, Reina Improgo, Stewart L. Fisher, Linda Lee, and Roy M. Pollock

Subjects

0301 basic medicine, Proteasome Endopeptidase Complex, Recombinant Fusion Proteins, Ubiquitin-Protein Ligases, Protein degradation, Ligands, Biochemistry, Analytical Chemistry, Small Molecule Libraries, 03 medical and health sciences, 0302 clinical medicine, Ubiquitin, Drug Discovery, medicine, Humans, Luciferase, Molecular Targeted Therapy, biology, Staining and Labeling, Chemistry, Drug discovery, Neurodegeneration, Ubiquitination, medicine.disease, Flow Cytometry, Small molecule, Cell biology, High-Throughput Screening Assays, 030104 developmental biology, Eukaryotic Cells, Spectrometry, Fluorescence, Proteasome, 030220 oncology & carcinogenesis, Proteolysis, biology.protein, Molecular Medicine, Protein Processing, Post-Translational, Function (biology), Biotechnology, Protein Binding

Abstract

The aberrant regulation of protein expression and function can drastically alter cellular physiology and lead to numerous pathophysiological conditions such as cancer, inflammatory diseases, and neurodegeneration. The steady-state expression levels of endogenous proteins are controlled by a balance of de novo synthesis rates and degradation rates. Moreover, the levels of activated proteins in signaling cascades can be further modulated by a variety of posttranslational modifications and protein-protein interactions. The field of targeted protein degradation is an emerging area for drug discovery in which small molecules are used to recruit E3 ubiquitin ligases to catalyze the ubiquitination and subsequent degradation of disease-causing target proteins by the proteasome in both a dose- and time-dependent manner. Traditional approaches for quantifying protein level changes in cells, such as Western blots, are typically low throughput with limited quantification, making it hard to drive the rapid development of therapeutics that induce selective, rapid, and sustained protein degradation. In the last decade, a number of techniques and technologies have emerged that have helped to accelerate targeted protein degradation drug discovery efforts, including the use of fluorescent protein fusions and reporter tags, flow cytometry, time-resolved fluorescence energy transfer (TR-FRET), and split luciferase systems. Here we discuss the advantages and disadvantages associated with these technologies and their application to the development and optimization of degraders as therapeutics.

Published

2021

20. The RNA-binding Protein MEX3B Mediates Resistance to Cancer Immunotherapy by Downregulating HLA-A Expression

Author

Amjad H. Talukder, Trang N. Tieu, Miles C. Andrews, Gregory Lizée, Patrick Hwu, Anil Korkut, Richard E. Davis, Shruti Malu, Jason Roszik, Chantale Bernatchez, Jennifer A. Wargo, Leila Williams, Rodabe N. Amaria, Cara Haymaker, Michael A. Davies, Marie Andrée Forget, Jodi A. McKenzie, Roger S. Lo, Scott E. Woodman, Timothy P. Heffernan, Lu Huang, Rina M. Mbofung, Zhiqiang Wang, Weiyi Peng, Tatiana Karpinets, and Zhe Wang

Subjects

Cytotoxicity, Immunologic, 0301 basic medicine, Untranslated region, Cancer Research, medicine.medical_treatment, Programmed Cell Death 1 Receptor, Biology, Article, Interferon-gamma, 03 medical and health sciences, Antineoplastic Agents, Immunological, Lymphocytes, Tumor-Infiltrating, 0302 clinical medicine, Cancer immunotherapy, Genes, Reporter, Cell Line, Tumor, Neoplasms, Biomarkers, Tumor, medicine, Humans, 3' Untranslated Regions, Melanoma, Regulation of gene expression, Messenger RNA, HLA-A Antigens, Three prime untranslated region, RNA-Binding Proteins, Cancer, medicine.disease, Gene Expression Regulation, Neoplastic, 030104 developmental biology, Oncology, Drug Resistance, Neoplasm, Cell culture, 030220 oncology & carcinogenesis, Cancer research, Protein Binding

Abstract

Purpose: Cancer immunotherapy has shown promising clinical outcomes in many patients. However, some patients still fail to respond, and new strategies are needed to overcome resistance. The purpose of this study was to identify novel genes and understand the mechanisms that confer resistance to cancer immunotherapy. Experimental Design: To identify genes mediating resistance to T-cell killing, we performed an open reading frame (ORF) screen of a kinome library to study whether overexpression of a gene in patient-derived melanoma cells could inhibit their susceptibility to killing by autologous tumor-infiltrating lymphocytes (TIL). Results: The RNA-binding protein MEX3B was identified as a top candidate that decreased the susceptibility of melanoma cells to killing by TILs. Further analyses of anti–PD-1–treated melanoma patient tumor samples suggested that higher MEX3B expression is associated with resistance to PD-1 blockade. In addition, significantly decreased levels of IFNγ were secreted from TILs incubated with MEX3B-overexpressing tumor cells. Interestingly, this phenotype was rescued upon overexpression of exogenous HLA-A2. Consistent with this, we observed decreased HLA-A expression in MEX3B-overexpressing tumor cells. Finally, luciferase reporter assays and RNA-binding protein immunoprecipitation assays suggest that this is due to MEX3B binding to the 3′ untranslated region (UTR) of HLA-A to destabilize the mRNA. Conclusions: MEX3B mediates resistance to cancer immunotherapy by binding to the 3′ UTR of HLA-A to destabilize the HLA-A mRNA and thus downregulate HLA-A expression on the surface of tumor cells, thereby making the tumor cells unable to be recognized and killed by T cells. Clin Cancer Res; 24(14); 3366–76. ©2018 AACR. See related commentary by Kalbasi and Ribas, p. 3239

Published

2018

21. The Effect of Topoisomerase I Inhibitors on the Efficacy of T-Cell-Based Cancer Immunotherapy

Author

Marie-Andree Forget, Min Zhang, Rina M. Mbofung, Ashish Kalra, Timothy P. Heffernan, R. Eric Davis, Trang N. Tieu, Weiyi Peng, Florian L. Muller, Seram Devi, Cara Haymaker, Patrick Hwu, Chantale Bernatchez, Chengwen Liu, Soraya Zorro Manrique, Anil K. Sood, Chunyu Xu, Leila Williams, Nikunj Satani, Jodi A. McKenzie, Shruti Malu, Rodabe N. Amaria, Sunila Pradeep, Yuan Chen, Emily Ashkin, Lu Huang, Jason Roszik, and Jianhua Hu

Subjects

0301 basic medicine, Cancer Research, medicine.medical_treatment, T cell, Irinotecan, Immunotherapy, Adoptive, Mice, 03 medical and health sciences, Lymphocytes, Tumor-Infiltrating, 0302 clinical medicine, Cancer immunotherapy, Cell Line, Tumor, Tumor Microenvironment, medicine, Animals, Humans, Cytotoxicity, Melanoma, Tumor microenvironment, biology, business.industry, Topoisomerase, Articles, Immunotherapy, medicine.disease, Combined Modality Therapy, Xenograft Model Antitumor Assays, 3. Good health, Mice, Inbred C57BL, Treatment Outcome, 030104 developmental biology, medicine.anatomical_structure, Oncology, Chemotherapy, Adjuvant, 030220 oncology & carcinogenesis, Cancer research, biology.protein, Female, Topotecan, Topoisomerase I Inhibitors, business, T-Lymphocytes, Cytotoxic, medicine.drug

Abstract

Background Immunotherapy has increasingly become a staple in cancer treatment. However, substantial limitations in the durability of response highlight the need for more rational therapeutic combinations. The aim of this study is to investigate how to make tumor cells more sensitive to T-cell-based cancer immunotherapy. Methods Two pairs of melanoma patient-derived tumor cell lines and their autologous tumor-infiltrating lymphocytes were utilized in a high-throughput screen of 850 compounds to identify bioactive agents that could be used in combinatorial strategies to improve T-cell-mediated killing of tumor cells. RNAi, overexpression, and gene expression analyses were utilized to identify the mechanism underlying the effect of Topoisomerase I (Top1) inhibitors on T-cell-mediated killing. Using a syngeneic mouse model (n = 5 per group), the antitumor efficacy of the combination of a clinically relevant Top1 inhibitor, liposomal irinotecan (MM-398), with immune checkpoint inhibitors was also assessed. All statistical tests were two-sided. Results We found that Top1 inhibitors increased the sensitivity of patient-derived melanoma cell lines (n = 7) to T-cell-mediated cytotoxicity (P < .001, Dunnett’s test). This enhancement is mediated by TP53INP1, whose overexpression increased the susceptibility of melanoma cell lines to T-cell cytotoxicity (2549 cell line: P = .009, unpaired t test), whereas its knockdown impeded T-cell killing of Top1 inhibitor–treated melanoma cells (2549 cell line: P < .001, unpaired t test). In vivo, greater tumor control was achieved with MM-398 in combination with α-PD-L1 or α-PD1 (P < .001, Tukey’s test). Prolonged survival was also observed in tumor-bearing mice treated with MM-398 in combination with α-PD-L1 (P = .002, log-rank test) or α-PD1 (P = .008, log-rank test). Conclusions We demonstrated that Top1 inhibitors can improve the antitumor efficacy of cancer immunotherapy, thus providing the basis for developing novel strategies using Top1 inhibitors to augment the efficacy of immunotherapy.

Published

2017

22. Loss of PTEN Promotes Resistance to T Cell–Mediated Immunotherapy

Author

Shruti Malu, Rodabe N. Amaria, Caitlin Creasy, Marcus Bosenberg, Isabella C. Glitza, Xiaoxing Yu, Timothy P. Heffernan, Alexander J. Lazar, Chengwen Liu, Laszlo Radvanyi, Jeffrey E. Gershenwald, Roland L. Bassett, Stefani Spranger, Jason Roszik, Chunyu Xu, Thomas F. Gajewski, Chunlei Zhang, Lawrence N. Kwong, Michael A. Davies, Michael T. Tetzlaff, Xiaoxuan Liang, Carlos A. Torres-Cabala, Scott E. Woodman, Rina M. Mbofung, Jianhua Hu, Jie Qing Chen, Jennifer L. McQuade, Trang N. Tieu, Tina Cascone, Marie-Andree Forget, Leila Williams, Patrick Hwu, Weiyi Peng, Haiyan S. Li, Gregory Lizée, Chantale Bernatchez, Jennifer A. Wargo, Guo Chen, Pei-Ling Chen, Jodi A. McKenzie, Cara Haymaker, Wanleng Deng, Willem W. Overwijk, and Zachary A. Cooper

Subjects

0301 basic medicine, Programmed cell death, Morpholines, T-Lymphocytes, T cell, medicine.medical_treatment, Programmed Cell Death 1 Receptor, Aminopyridines, Antibodies, Article, Mice, 03 medical and health sciences, 0302 clinical medicine, Immune system, Cell Line, Tumor, medicine, Animals, Humans, PTEN, Neoplasm, CTLA-4 Antigen, Melanoma, biology, Autophagy, PTEN Phosphohydrolase, Drug Synergism, Immunotherapy, medicine.disease, 030104 developmental biology, medicine.anatomical_structure, Oncology, Drug Resistance, Neoplasm, 030220 oncology & carcinogenesis, Immunology, Cancer research, biology.protein

Abstract

T cell–mediated immunotherapies are promising cancer treatments. However, most patients still fail to respond to these therapies. The molecular determinants of immune resistance are poorly understood. We show that loss of PTEN in tumor cells in preclinical models of melanoma inhibits T cell–mediated tumor killing and decreases T-cell trafficking into tumors. In patients, PTEN loss correlates with decreased T-cell infiltration at tumor sites, reduced likelihood of successful T-cell expansion from resected tumors, and inferior outcomes with PD-1 inhibitor therapy. PTEN loss in tumor cells increased the expression of immunosuppressive cytokines, resulting in decreased T-cell infiltration in tumors, and inhibited autophagy, which decreased T cell–mediated cell death. Treatment with a selective PI3Kβ inhibitor improved the efficacy of both anti–PD-1 and anti–CTLA-4 antibodies in murine models. Together, these findings demonstrate that PTEN loss promotes immune resistance and support the rationale to explore combinations of immunotherapies and PI3K–AKT pathway inhibitors. Significance: This study adds to the growing evidence that oncogenic pathways in tumors can promote resistance to the antitumor immune response. As PTEN loss and PI3K–AKT pathway activation occur in multiple tumor types, the results support the rationale to further evaluate combinatorial strategies targeting the PI3K–AKT pathway to increase the efficacy of immunotherapy. Cancer Discov; 6(2); 202–16. ©2015 AACR. See related commentary by Rizvi and Chan, p. 128. This article is highlighted in the In This Issue feature, p. 109

Published

2016

23. Targeting YAP-Dependent MDSC Infiltration Impairs Tumor Progression

Author

Lynda Chin, Sujun Hua, Y. Alan Wang, Jianhua Zhang, Kun Zhao, Timothy P. Heffernan, Elsa M. Li-Ning-Tapia, Xiaolu Pan, Trang N. Tieu, Eun Jung Jin, Zhihu Ding, Vandhana Ramamoorthy, Prasenjit Dey, Ronald A. DePinho, Wantong Yao, Patricia Troncoso, Sunada Khadka, Pingping Hou, Shan Jiang, Zhuangna Fang, Avnish Kapoor, Ramakrishna Konaparthi, Qing Chang, Yanxia Shi, Christopher J. Logothetis, Xiaoying Shang, Chia Chin Wu, Neelay Bhaskar Patel, Guocan Wang, Xin Lu, Pingna Deng, Mark J. McArthur, Chang-Jiun Wu, Baoli Hu, Zhenglin Guo, Di Zhao, and Liren Li

Subjects

Male, 0301 basic medicine, Chemokine CXCL5, Stromal cell, Protein Serine-Threonine Kinases, Article, Receptors, Interleukin-8B, Mice, 03 medical and health sciences, Prostate cancer, Cell Line, Tumor, Animals, Humans, Medicine, PTEN, Hippo Signaling Pathway, Myeloid Cells, CXC chemokine receptors, Adaptor Proteins, Signal Transducing, Smad4 Protein, YAP1, biology, business.industry, PTEN Phosphohydrolase, Prostatic Neoplasms, YAP-Signaling Proteins, Phosphoproteins, medicine.disease, 030104 developmental biology, Oncology, Tumor progression, CXCL5, Immunology, Cancer cell, Disease Progression, Cancer research, biology.protein, business, Signal Transduction, Transcription Factors

Abstract

The signaling mechanisms between prostate cancer cells and infiltrating immune cells may illuminate novel therapeutic approaches. Here, utilizing a prostate adenocarcinoma model driven by loss of Pten and Smad4, we identify polymorphonuclear myeloid-derived suppressor cells (MDSC) as the major infiltrating immune cell type, and depletion of MDSCs blocks progression. Employing a novel dual reporter prostate cancer model, epithelial and stromal transcriptomic profiling identified CXCL5 as a cancer-secreted chemokine to attract CXCR2-expressing MDSCs, and, correspondingly, pharmacologic inhibition of CXCR2 impeded tumor progression. Integrated analyses identified hyperactivated Hippo–YAP signaling in driving CXCL5 upregulation in cancer cells through the YAP–TEAD complex and promoting MDSC recruitment. Clinicopathologic studies reveal upregulation and activation of YAP1 in a subset of human prostate tumors, and the YAP1 signature is enriched in primary prostate tumor samples with stronger expression of MDSC-relevant genes. Together, YAP-driven MDSC recruitment via heterotypic CXCL5–CXCR2 signaling reveals an effective therapeutic strategy for advanced prostate cancer. Significance: We demonstrate a critical role of MDSCs in prostate tumor progression and discover a cancer cell nonautonomous function of the Hippo–YAP pathway in regulation of CXCL5, a ligand for CXCR2-expressing MDSCs. Pharmacologic elimination of MDSCs or blocking the heterotypic CXCL5–CXCR2 signaling circuit elicits robust antitumor responses and prolongs survival. Cancer Discov; 6(1); 80–95. ©2015 AACR. This article is highlighted in the In This Issue feature, p. 1

Published

2016

24. HSP90 inhibition enhances cancer immunotherapy by upregulating interferon response genes

Author

Isere Kuiatse, Jason Roszik, Patrick Hwu, Sam Hanash, Satyendra C. Tripathi, James P. Allison, Nikunj Satani, Rina M. Mbofung, Trang N. Tieu, Timothy P. Heffernan, Florian L. Muller, Shruti Malu, Minying Zhang, Chunyu Xu, R. Eric Davis, Rodabe N. Amaria, Seram Devi, Jodi A. McKenzie, Weiyi Peng, David A. Proia, Hiep Khong, Lu Huang, Chengwen Liu, Emily Ashkin, Leila Williams, Gregory Lizée, Min Zhang, and Amjad H. Talukder

Subjects

0301 basic medicine, T-Lymphocytes, Science, medicine.medical_treatment, Ganetespib, General Physics and Astronomy, Kaplan-Meier Estimate, Pharmacology, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Immune system, Cancer immunotherapy, Downregulation and upregulation, Interferon, Cell Line, Tumor, Animals, Humans, Medicine, HSP90 Heat-Shock Proteins, lcsh:Science, Melanoma, Multidisciplinary, business.industry, Gene Expression Profiling, Cancer, General Chemistry, Immunotherapy, Triazoles, medicine.disease, Ipilimumab, Xenograft Model Antitumor Assays, Tumor Burden, Up-Regulation, 3. Good health, Gene Expression Regulation, Neoplastic, Mice, Inbred C57BL, 030104 developmental biology, 030220 oncology & carcinogenesis, Female, lcsh:Q, Interferons, business, medicine.drug

Abstract

T-cell-based immunotherapies are promising treatments for cancer patients. Although durable responses can be achieved in some patients, many patients fail to respond to these therapies, underscoring the need for improvement with combination therapies. From a screen of 850 bioactive compounds, we identify HSP90 inhibitors as candidates for combination with immunotherapy. We show that inhibition of HSP90 with ganetespib enhances T-cell-mediated killing of patient-derived human melanoma cells by their autologous T cells in vitro and potentiates responses to anti-CTLA4 and anti-PD1 therapy in vivo. Mechanistic studies reveal that HSP90 inhibition results in upregulation of interferon response genes, which are essential for the enhanced killing of ganetespib treated melanoma cells by T cells. Taken together, these findings provide evidence that HSP90 inhibition can potentiate T-cell-mediated anti-tumor immune responses, and rationale to explore the combination of immunotherapy and HSP90 inhibitors., Many patients fail to respond to T cell based immunotherapies. Here, the authors, through a high-throughput screening, identify HSP90 inhibitors as a class of preferred drugs for treatment combination with immunotherapy.

Published

2017

25. Targeting YAP-dependent MDSC infiltration impairs tumor progression

Author

Xin Lu, Y. Alan Wang, Lynda Chin, Christopher J. Logothetis, Elsa M. Li Ning Tapia, Zhuangna Fang, Pingping Hou, Baoli Hu, Trang N. Tieu, Shan Jiang, Kun Zhao, Xiaoying Shang, Guocan Wang, Chia Chin Wu, Ramakrishna Konaparthi, Sujun Hua, Sunada Khadka, Timothy P. Heffernan, Vandhana Ramamoorthy, Ronald A. DePinho, Avnish Kapoor, Pingna Deng, Mark J. McArthur, Zhenglin Guo, Di Zhao, Neelay Bhaskar Patel, Qing Chang, Patricia Troncoso, Prasenjit Dey, and Jianhua Zhang

Subjects

Pharmacology, Cancer Research, business.industry, Immunology, medicine.disease, Bioinformatics, law.invention, Heterogeneous population, Prostate cancer, Oncology, law, Tumor progression, Poster Presentation, Myeloid cells, medicine, Cancer research, Molecular Medicine, Immunology and Allergy, Suppressor, business, Solid tumor, Infiltration (medical)

Abstract

Meeting abstracts Myeloid-derived suppressor cells (MDSCs) represent a phenotypically heterogeneous population of immature myeloid cells that play a tumor-promoting role by maintaining a state of immunological anergy and tolerance. Similar to other solid tumor types, Prostate cancer (PCa) is

Published

2015

26. The SMARCA2/4 ATPase Domain Surpasses the Bromodomain as a Drug Target in SWI/SNF-Mutant Cancers: Insights from cDNA Rescue and PFI-3 Inhibitor Studies

Author

Xi Shi, Alessia Petrocchi, Shikhar Sharma, Lisa Nottebaum, Jannik N. Andersen, Elisabetta Leo, Maria Kost-Alimova, Timothy P. Heffernan, Philip Jones, Bhavatarini Vangamudi, Trang N. Tieu, Dominique Verhelle, Harshad S. Mahadeshwar, Parantu K. Shah, Dafydd R. Owen, Andrew Futreal, Mike Peoples, Giulio Draetta, Thomas A Paul, Yanai Zhan, Wylie S. Palmer, Joseph R. Marszalek, Carlo Toniatti, and Alexei Protopopov

Subjects

Cancer Research, DNA, Complementary, Lung Neoplasms, Chromosomal Proteins, Non-Histone, Pyridines, Protein domain, Biology, Binding, Competitive, Catalysis, Article, Gene Knockout Techniques, Sarcoma, Synovial, RNA interference, Cell Line, Tumor, Neoplasms, Humans, Molecular Targeted Therapy, RNA, Small Interfering, Rhabdoid Tumor, Gene knockdown, Genetic Complementation Test, DNA Helicases, Nuclear Proteins, Chromatin Assembly and Disassembly, Microarray Analysis, SWI/SNF, Chromatin, Bromodomain, Neoplasm Proteins, Protein Structure, Tertiary, Oncology, SMARCA4, Cancer research, RNA Interference, Chromatin immunoprecipitation, Azabicyclo Compounds, Transcription Factors

Abstract

The SWI/SNF multisubunit complex modulates chromatin structure through the activity of two mutually exclusive catalytic subunits, SMARCA2 and SMARCA4, which both contain a bromodomain and an ATPase domain. Using RNAi, cancer-specific vulnerabilities have been identified in SWI/SNF-mutant tumors, including SMARCA4-deficient lung cancer; however, the contribution of conserved, druggable protein domains to this anticancer phenotype is unknown. Here, we functionally deconstruct the SMARCA2/4 paralog dependence of cancer cells using bioinformatics, genetic, and pharmacologic tools. We evaluate a selective SMARCA2/4 bromodomain inhibitor (PFI-3) and characterize its activity in chromatin-binding and cell-functional assays focusing on cells with altered SWI/SNF complex (e.g., lung, synovial sarcoma, leukemia, and rhabdoid tumors). We demonstrate that PFI-3 is a potent, cell-permeable probe capable of displacing ectopically expressed, GFP-tagged SMARCA2-bromodomain from chromatin, yet contrary to target knockdown, the inhibitor fails to display an antiproliferative phenotype. Mechanistically, the lack of pharmacologic efficacy is reconciled by the failure of bromodomain inhibition to displace endogenous, full-length SMARCA2 from chromatin as determined by in situ cell extraction, chromatin immunoprecipitation, and target gene expression studies. Furthermore, using inducible RNAi and cDNA complementation (bromodomain- and ATPase-dead constructs), we unequivocally identify the ATPase domain, and not the bromodomain of SMARCA2, as the relevant therapeutic target with the catalytic activity suppressing defined transcriptional programs. Taken together, our complementary genetic and pharmacologic studies exemplify a general strategy for multidomain protein drug-target validation and in case of SMARCA2/4 highlight the potential for drugging the more challenging helicase/ATPase domain to deliver on the promise of synthetic-lethality therapy. Cancer Res; 75(18); 3865–78. ©2015 AACR.

Published

2015

27. Abstract B105: HSP90 inhibitor, ganetespib, enhances responses to cancer immunotherapy through increased expression of interferon response genes

Author

Rina M. Mbofung, Isere Kuiatse, Zhe Wang, Jodi A. McKenzie, Chengwen Liu, Timothy P. Heffernan, Shruti Malu, Weiyi Peng, Trang N. Tieu, Richard E. Davis, Patrick Hwu, Rodabe N. Amaria, Seram Devi, and Leila Williams

Subjects

Cancer Research, business.industry, Melanoma, medicine.medical_treatment, T cell, Immunology, Ganetespib, Cancer, Ipilimumab, Immunotherapy, medicine.disease, medicine.anatomical_structure, Cancer immunotherapy, Cancer research, Medicine, Cytotoxic T cell, business, medicine.drug

Abstract

Recently, T cell based immunotherapies have moved to the forefront of cancer immunotherapy with the success of Adoptive T cell therapy (ACT) and Immune checkpoint blockade. ACT, where patients are treated with tumor infiltrating T cells (TILs), conferred a clinical response rate of ∼50%. Treatment with anti-CTLA4 therapy, Ipilimumab, conferred response rates of 10-20%, greatly improving the overall survival of patients with advanced melanoma. Despite the encouraging outcomes, there are relatively low response rates coupled with the delay of weeks to months before tumor shrinkage can be appreciated. Thus, understanding mechanisms of resistance to immune therapies, to improve response rates, shorten time to treatment effect and developing predictive biomarkers of response are vital to the care of melanoma patients. In order to identify possible resistance mechanisms to immunotherapy, a high-throughput in vitro screen with 850 different bio-active compounds (Selleckchem), was designed to search for agents that could either increase or decrease the resistance of melanoma tumor cells to T cell mediated killing. Paired patient derived human melanoma tumor samples and TILs were used to assess which compounds when used to treat the melanoma cell lines can enhance the cytotoxic activity of the TILs against the paired melanoma sample, using a flow cytometry based assay in which active caspase 3 was used as a read out of apoptosis. We identified heat shock protein 90 (HSP90) inhibitors amongst the top compounds that improved T cell mediated cytotoxicity of treated tumor cells. We show that treatment with the HSP90 inhibitor ganetespib (Synta) greatly improves T cell mediated cytotoxicity of human cancer cells lines in vitro. Furthermore, in vivo murine studies using the MC38/gp100 tumor model show that ganestespib in combination with anti-CTLA4, resulted in superior antitumor effect and survival compared to either treatment alone (Average tumor volume at day 21 of treatment: Vehicle 294.3mm3, α-CTLA4 193 mm3, Ganetespib 237.5 mm3 and Ganetespib + α-CTLA4 105.8 mm3, P < 0.0001). Microarray analysis of human cell lines treated with ganetespib in vitro revealed an increase in interferon response genes including IFIT1, IFIT2, IFIT3. We confirmed these findings with quantitative real time PCR and western blot analyses and found IFIT1, IFIT2 and IFIT3 to be consistently upregulated across multiple melanoma cell lines following treatment with ganetespib. We next sought to verify the importance of the IFIT genes in the synergy observed between ganetespib treatment and T cell killing. First, we overexpressed IFIT1, IFIT2 and IFIT3 in human melanoma cell lines to recapitulate the improved sensitivity of the human melanoma cell lines to T cell killing following treatment with ganetespib. We then co-cultured these cells with their autologous T cells and found that overexpressing IFIT1, IFIT2 and IFIT3 mimicked the effects of ganetespib by increasing the sensitivity to T cell killing over the GFP control. On the other hand, silencing IFIT1, IFIT2 and IFIT3 simultaneously, abrogated the synergy between ganetespib and T cell killing. We are further elucidating the role of these genes in lowering the apoptotic threshold of cancer cells and contributing to the synergy of ganetespib and immunotherapy. This will enable the emergence of a new combination therapy of HSP90 inhibitors and anti-CTLA4 for the treatment of melanoma patients that will increase the percentage of patients responding to immunotherapy and achieving long term responses. Citation Format: Rina M. Mbofung, Jodi A. McKenzie, Shruti Malu, Chengwen Liu, Weiyi Peng, Isere Kuiatse, Leila Williams, Seram Devi, Zhe Wang, Trang Tieu, Tim Heffernan, Richard E. Davis, Rodabe Amaria, Patrick Hwu. HSP90 inhibitor, ganetespib, enhances responses to cancer immunotherapy through increased expression of interferon response genes [abstract]. In: Proceedings of the Second CRI-CIMT-EATI-AACR International Cancer Immunotherapy Conference: Translating Science into Survival; 2016 Sept 25-28; New York, NY. Philadelphia (PA): AACR; Cancer Immunol Res 2016;4(11 Suppl):Abstract nr B105.

Published

2016

28. Abstract B110: Topoisomerase I inhibitors enhance efficacy of immunotherapy through a p53 regulatory pathway

Author

Shruti Malu, Leila Williams, Rina M. Mbofung, Emily Ashkin, Richard E. Davis, Trang N. Tieu, Seram Devi, Rodabe N. Amaria, Patrick Hwu, Jason Roszik, Jodi A. McKenzie, Weiyi Peng, and Timothy P. Heffernan

Subjects

Cancer Research, Adoptive cell transfer, business.industry, medicine.medical_treatment, Melanoma, T cell, Immunology, Cancer, Immunotherapy, Pharmacology, medicine.disease, Immune system, medicine.anatomical_structure, Cancer immunotherapy, medicine, business, Camptothecin, medicine.drug

Abstract

Cancer immunotherapy has transformed the treatment landscape for a number of cancer patients, with some achieving durable and long lasting clinical benefit. Cancer immunotherapy engages and intensifies the host immune response to attack and kill tumor cells. However, as evidenced by the heterogeneous response to immunotherapy, tumor cells have evolved a host of known and unknown mechanisms to evade, inhibit or supersede the immune response. Consequently, scientists and clinicians are unable to accurately predict which patients will respond, or how well they will respond to cancer immunotherapy.To address this shortfall, we have asked the question of how we can modulate tumor cells in order to make them more amenable to immunotherapy, thereby increasing its efficacy. We approached this question by conducting a high throughput drug screen of 850 compounds, to identify bioactive drugs that can increase T cell mediated killing of tumor cells. The goal here is to develop rational combination treatment strategies involving T cell based cancer immunotherapy that will increase the breadth and depth of the clinical response to cancer immunotherapy. One of three top hits from the screen was Topoisomerase I (Top1) inhibitors including irinotecan, topotecan, and camptothecin. We then utilized multiple patient-derived cell lines in an in vitro cytotoxicity assay to validate that treatment of melanoma tumor cells with a Top1 inhibitor, before incubation with their autologous tumor infiltrating lymphocytes (TILs) results in a synergistic increase in T cell mediated killing of tumor cells.These findings were further corroborated in a pre-clinical mouse model, where we found that tumor-bearing mice treated with a combination of a clinically relevant Top1 inhibitor nal-IRI (nano-liposomal irinotecan) and an anti-PD-L1 antibody, showed enhanced tumor regression compared to mice treated with either single agent (mean tumor volume: combo vs nal-IRI vs α-PDL1 = 40.04 ± 5.66 vs 136.30 ± 28.96 vs 373.04 ± 23.96 mm3 respectively, on day 21 after tumor inoculation, p < 0.0001). Significantly longer survival was also achieved in tumor-bearing mice treated with the combination in comparison to cohorts treated with either single agent. To investigate the molecular changes being mediated by Top1 inhibitors in the tumor cells, we conducted gene expression analysis on Top1 inhibitor-treated tumor cells. One striking gene expression change in Top1 inhibitor-treated tumor cells was an upregulation of a number of genes known to be functionally important for p53 signaling including TP53INP1 (Teap). We then focused on the functional relevance of Teap to the increased T cell mediated killing of Top1 inhibitor-treated melanoma cells. Overexpression of Teap in melanoma cells resulted in increased T cell mediated killing, recapitulating the phenotype observed in Top1 inhibitor-treated melanoma cells. Complementary to this, silencing of Teap via shRNA in melanoma cells, inhibited T cell mediated killing of Top1 inhibitor-treated cells, indicating that the enhancement of T cell mediated killing observed in Top1 inhibitor-treated cells is dependent on the p53 regulatory gene Teap. These results support our goal of developing combinations involving T cell based cancer immunotherapy to improve therapeutic efficacy in cancer patients. We have demonstrated that Top1 inhibitors can be effectively combined with T cell based cancer immunotherapy. The results are also indicative of a role for p53 signaling in regulating response to T cell based immunotherapy. By understanding the molecular mechanisms in the tumor that can dictate response or resistance to immunotherapy, we can develop a more comprehensive picture of the cancer immunity response cycle and develop more effective strategies to combat not only melanoma, but also other tumor types where immunotherapy is not yet applicable. Citation Format: Jodi A. McKenzie, Rina M. Mbofung, Shruti Malu, Rodabe N. Amaria, Emily L. Ashkin, Seram N. Devi, Weiyi Peng, Leila J. Williams, Richard E. Davis, Jason Roszik, Trang N. Tieu, Timothy Heffernan, Patrick Hwu. Topoisomerase I inhibitors enhance efficacy of immunotherapy through a p53 regulatory pathway [abstract]. In: Proceedings of the Second CRI-CIMT-EATI-AACR International Cancer Immunotherapy Conference: Translating Science into Survival; 2016 Sept 25-28; New York, NY. Philadelphia (PA): AACR; Cancer Immunol Res 2016;4(11 Suppl):Abstract nr B110.

Published

2016

29. Abstract 4363: Loss of PTEN promotes resistance to T cell-mediated immunotherapy

Author

Michael T. Tetzlaff, Timothy P. Heffernan, Alexander J. Lazar, Chunlei Zhang, Lawrence N. Kwong, Pei-Ling Chen, Trang N. Tieu, Tina Cascone, Marie-Andree Forget, Leila Williams, Jodi A. McKenzie, Weiyi Peng, Scott E. Woodman, Zachary A. Cooper, Willem W. Overwijk, Guo Chen, Carlos A. Torres-Cabala, Thomas F. Gajewski, Jie Qing Chen, Xiaoxuan Liang, Patrick Hwu, Rina M. Mbofung, Shruti Malu, Marcus Bosenberg, Laszlo Radvanyi, Cara Haymaker, Rodabe N. Amaria, Jeffrey E. Gershenwald, Xiaoxing Yu, Jason Roszik, Wanleng Deng, Chengwen Liu, Haiyan S. Li, Gregory Lizée, Chantale Bernatchez, Jianhua Hu, Jennifer A. Wargo, Jennifer L. McQuade, Chunyu Xu, Roland L. Bassett, Stefani Spranger, Caitlin Creasy, Isabella C. Glitza, and Michael Davies

Subjects

0301 basic medicine, Cancer Research, Tumor microenvironment, biology, Combination therapy, business.industry, medicine.medical_treatment, T cell, Immunotherapy, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Immune system, Oncology, 030220 oncology & carcinogenesis, Immunology, biology.protein, medicine, Cancer research, PTEN, business, CD8, PI3K/AKT/mTOR pathway

Abstract

T cell-mediated immunotherapies are promising cancer treatments. However, most patients still fail to respond to these therapies. The molecular determinants of immune resistance are poorly understood. Here, we interrogated the role of loss of expression of the tumor suppressor, PTEN, in immune resistance. In preclinical studies, we found that silencing PTEN in tumor cells inhibited T cell-mediated tumor killing and decreased T cell trafficking into tumors. In clinical studies, we observed that tumors with loss of PTEN had significantly less CD8+ T cell infiltration than PTEN-present tumors. In addition, 26% of melanomas that did not yield successful TIL growth demonstrated PTEN loss, which was more frequent than was observed in tumors that yielded successful TIL growth (11%). We further validated the association between reduced number and impaired function of TIL with PTEN loss using another independent cohort, TCGA dataset for SKCM. More importantly, we analyzed clinical outcomes of metastatic melanoma patients treated with the FDA-approved anti-PD-1 antibodies. Our analysis demonstrates that a greater reduction in tumor burden was achieved by PD-1 blockade in PTEN present patients, when compared with PTEN absent patients. To decipher the factors mediating the immunosuppressive effects of PTEN loss, we determined the expression profiles of tumor cells with or without PTEN expression. Our results indicated that PTEN loss increased the production of immunosuppressive factors, including CCL2 and VEGF. Anti-VEGF blocking antibody improved anti-tumor activity of transferred tumor-reactive T cells and enhanced tumor infiltration of transferred T cells in PTEN-silenced tumors. These results suggest that loss of PTEN can facilitate the resistance of T cell-mediated immune responses by increasing the expression of immunosuppressive factors. Given that PTEN loss results in activation of the PI3K pathway, we evaluated the efficacy of immunotherapy in combination with a selective PI3Kβinhibitor to treat spontaneously developed BRAF mutant, PTEN null melanomas in genetically engineered mouse models. Our result showed that the combination of PI3Kβ inhibitor and anti-PD-1 significantly delayed tumor growth in tumor-bearing mice. Mice treated with this combination had a median survival time of 28 days, which is longer than the survival time of mice treated with either therapy. Increased numbers of T cells at tumor sites were found in mice receiving the combination therapy compared with mice receiving either agent alone. Taken together, our results demonstrate that PTEN loss contributes to the generation of immunosuppressive tumor microenvironment. Notably, this study provides the first direct clinical evidence to support the association between PTEN loss and poor clinical outcome in immunotherapy treated patients. In addition, our study indicates that inhibition of the PI3K-AKT pathway can improve the efficacy of immunotherapy in cancer. Citation Format: Weiyi Peng, Jie Qing Chen, Chengwen Liu, Shruti Malu, Caitlin Creasy, Michael Tetzlaff, Chunyu Xu, Jodi McKenzie, Chunlei Zhang, Xiaoxuan Liang, Leila Williams, Wanleng Deng, Guo Chen, Rina Mbofung, Alexander Lazar, Carlos Torres-Cabala, Zachary Cooper, Pei-Ling Chen, Trang Tieu, Stefani Spranger, Xiaoxing Yu, Chantale Bernatchez, Marie-Andree Forget, Cara Haymaker, Rodabe Amaria, Jennifer McQuade, Isabella Glitza, Tina Cascone, Haiyan Li, Lawrence Kwong, Timothy Heffernan, Jianhua Hu, Roland Bassett, Marcus Bosenberg, Scott Woodman, Willem Overwijk, Gregory Lizée, Jason Roszik, Thomas Gajewski, Jennifer Wargo, Jeffrey Gershenwald, Laszlo Radvanyi, Michael Davies, Patrick Hwu. Loss of PTEN promotes resistance to T cell-mediated immunotherapy. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4363.

Published

2016

30. Abstract 4002: Enhancing the antitumor efficacy of immunotherapy by using the topoisomerase I inhibitor MM398

Author

Patrick Hwu, Rina M. Mbofung, Richard E. Davis, Shruti Malu, Rodabe N. Amaria, Trang N. Tieu, Jodi A. McKenzie, Timothy P. Heffernan, and Li Zhang

Subjects

Cancer Research, business.industry, Tumor-infiltrating lymphocytes, medicine.medical_treatment, T cell, Melanoma, Cancer, Immunotherapy, medicine.disease, medicine.anatomical_structure, Immune system, Oncology, Cancer research, Medicine, T cell mediated cytotoxicity, Skin cancer, business

Abstract

Melanoma is a highly aggressive form of skin cancer, whose rates of morbidity and mortality are increasing. The development of immunotherapies like anti-PDL1 and anti-CTLA4 antibodies has resulted in fundamental advances in the treatment of some cancers. However, long lasting responses are only observed in a subset of immunotherapy-treated patients. This shortfall highlights the need for a better understanding of the molecular mechanisms that govern tumor response to immunotherapy. To address this need, autologous patient-derived tumor cell lines and tumor infiltrating lymphocytes (TILs) were utilized in an in vitro high throughput screen, to identify compounds that increase the sensitivity of melanoma cells to T cell mediated cytotoxicity. The screen consisted of an 850 compound library. One group of compounds that was most able to enhance T cell killing of melanoma cells was topoisomerase I (Top1) inhibitors such as topotecan and irinotecan. Our results indicate that treatment of melanoma cells with a Top1 inhibitor prior to exposure to autologous T cells produced a synergistic increase in tumor cell death, as measured by intracellular staining of activated caspase 3. We have also recapitulated this finding in an in vivo model, where a better anti-tumor effect was observed in tumor bearing mice treated with an antibody against the co-inhibitory molecule PDL1 in combination with MM398 (nanoliposomal irinotecan), than in cohorts treated with either α-PDL1 or Top1 inhibitor alone. These findings suggest synergism between Top1 inhibitors and immune-based therapies in the treatment of melanoma. Molecular changes elicited by inhibition of Top1 are now being investigated to identify the factors that mediate the effect of Top1 inhibitors on T cell-mediated killing of melanoma. We have identified a p53-driven gene signature in Top1 inhibitor-treated melanoma cell lines and are investigating the functional relevance of Tumor Protein p53 Inducible Nuclear Protein 1 (TP53INP1) in mediating increased T cell killing of Top1 inhibitor-treated melanoma cells. Our results indicate that TP53INP1 is a critical component of this apoptotic response, as overexpression of TP53INP1 in melanoma cells increased their susceptibility to T cell mediated cytotoxicity. Complementary to this observation, we have also found that knockdown of TP53INP1 by shRNA, impedes the sensitivity of Top1 inhibitor-treated melanoma cells to T cell mediated killing. Understanding how Top1 inhibitors enhance melanoma killing by immunotherapy will allow for the development of predictive biomarkers, and also augment immune-based therapeutic strategies to ensure durable responses in a larger population of melanoma patients. By using melanoma as a model disease system, we can gain valuable insights into the dynamics of cancer immune response that may be applied to other cancers where effective treatment strategies are also lacking. Citation Format: Jodi A. McKenzie, Rina M. Mbofung, Shruti Malu, Rodabe N. Amaria, Richard E. Davis, Li Zhang, Trang N. Tieu, Tim P. Heffernan, Patrick Hwu. Enhancing the antitumor efficacy of immunotherapy by using the topoisomerase I inhibitor MM398. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4002.

Published

2016

31. Abstract 4360: Inhibition of HSP90 enhances T cell-mediated antitumor immune responses through expression of interferon-alpha response Genes

Author

Chengwen Liu, Seram Devi, Trang N. Tieu, Isere Kuiatse, Jason Roszik, Timothy P. Heffernan, Zhe Wang, Rina M. Mbofung, Shuping Zhao, Patrick Hwu, Rodabe N. Amaria, Richard E. Davis, Jodi A. McKenzie, Satyendra C. Tripathi, Emily Ashkin, Leila Williams, Weiyi Peng, Samir M. Hanash, Shruti Malu, and Leah Bailey

Subjects

Cancer Research, business.industry, medicine.medical_treatment, T cell, Melanoma, Ganetespib, Immunotherapy, medicine.disease, Immune checkpoint, medicine.anatomical_structure, Oncology, Cancer immunotherapy, Immunology, Cancer research, Medicine, Cytotoxic T cell, T cell mediated cytotoxicity, business

Abstract

Recently, T cell based immunotherapies have moved to the forefront of cancer immunotherapy with the success of Adoptive T cell therapy (ACT) and Immune checkpoint blockade. ACT, where patients are treated with tumor infiltrating T cells (TILs), conferred a clinical response rate of ∼50%. Treatment with anti-CTLA4 therapy, Ipilimumab, conferred response rates of 10-20%, greatly improving the overall survival of patients with advanced melanoma. Despite the encouraging outcomes, there are relatively low response rates coupled with the delay of weeks to months before tumor shrinkage can be appreciated. Thus, understanding mechanisms of resistance to immune therapies, to improve response rates, shorten time to treatment effect and developing predictive biomarkers of response are vital to the care of melanoma patients. In order to identify possible resistance mechanisms to immunotherapy, a high-throughput in vitro screen with 850 different bio-active compounds (Selleckchem), was designed to search for agents that could either increase or decrease the resistance of melanoma tumor cells to T cell mediated killing. Paired tumor samples and TILs from melanoma patients were used to assess which compounds when used to treat the melanoma cell lines can enhance the cytotoxic activity of the TILs against the paired melanoma sample, using a flow cytometry based assay in which active caspase 3 was used as a read out of apoptosis. We identified heat shock protein 90 (HSP90) inhibitors amongst compounds that improved T cell mediated cytotoxicity. We show that treatment with the HSP90 inhibitor ganetespib (Synta) greatly improves T cell mediated cytotoxicity of both human and murine cancer cells lines in vitro. Furthermore, in vivo murine studies using the MC38/gp100 tumor model show that ganestespib in combination with anti-CTLA4, resulted in superior antitumor effect and survival compared to either treatment alone (Average tumor volume at day 21 of treatment: Vehicle 294.3mm3, α-CTLA4 193 mm3, Ganetespib 237.5 mm3 and Ganetespib + α-CTLA4 105.8 mm3, P < 0.0001). Microarray analysis of human cell lines treated with ganetespib in vitro revealed an increase in interferon alpha (IFN-α) response genes including IFIT1, IFIT2, IFIT3 and IFIH1. Silencing IFIT2 abrogated the synergy observed with ganetespib treatment and T cell mediated killing, suggesting that the IFN-α response pathway plays an important role in this combination therapy. We are further elucidating the role of these genes in the synergy observed. This will enable the emergence of a new combination therapy of HSP90 inhibitors and anti-CTLA4 for the treatment of melanoma patients that will increase the percentage of patients responding to immunotherapy and achieving long term responses. Citation Format: Rina M. Mbofung, Jodi A. McKenzie, Shruti Malu, Chengwen Liu, Leila Williams, Weiyi Peng, Zhe Wang, Satyendra Tripathi, Trang Tieu, Shuping Zhao, Seram Devi, Isere Kuiatse, Emily Ashkin, Leah Bailey, Jason Roszik, Samir Hanash, Timothy Heffernan, Richard E. Davis, Rodabe N. Amaria, Patrick Hwu. Inhibition of HSP90 enhances T cell-mediated antitumor immune responses through expression of interferon-alpha response Genes. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4360.

Published

2016

32. Abstract 3528: The SMARCA2/4 catalytic activity, but not the bromodomain, is a drug target in SWI/SNF mutant cancers

Author

Wylie S. Palmer, Trang N. Tieu, Giulio Draetta, Maria Alimova, Thomas A Paul, Alessia Petrocchi, Jannik N. Andersen, Elisabetta Leo, Bhavatarini Vangamudi, Alexei Protopopov, Mike Peoples, Dafydd R. Owen, Philip Jones, Xi Shi, Timothy P. Heffernan, Shikhar Sharma, Carlo Toniatti, Joseph R. Marszalek, Yanai Zhan, Dominique Verhelle, Lisa Nottebaum, Parantu K. Shah, Harshad S. Mahadeshwar, and Andrew Futreal

Subjects

Cancer Research, Oncology, RNA interference, Cancer cell, Mutant, Cancer research, SMARCA4, Biology, Molecular biology, Chromatin immunoprecipitation, SWI/SNF, Bromodomain, Chromatin

Abstract

The SWI/SNF multi-subunit complex modulates chromatin structure through the activity of two mutually exclusive catalytic subunits, SMARCA2 and SMARCA4, which both contain a bromodomain and an ATPase domain. Using RNAi, cancer-specific vulnerabilities have been identified in SWI/SNF mutant tumors, including SMARCA4-deficient lung cancer, however, the contribution of conserved, druggable protein domains to this anticancer phenotype is unknown. Here, we functionally deconstructed the SMARCA2/4 paralog dependence of cancer cells using bioinformatics, genetic and pharmacological tools. We evaluated a potent and selective SMARCA2/4 bromodomain inhibitor (PFI-3) and characterized its activity in chromatin-binding and cell-functional assays focusing on cells with altered SWI/SNF status (e.g. Lung, Synovial Sarcoma, Leukemia, and Rhabdoid tumors). We demonstrated that PFI-3 is a cell-permeable probe capable of displacing ectopically expressed, GFP-tagged SMARCA2-bromodomain from chromatin, yet contrary to target knockdown, the inhibitor failed to display an antiproliferative phenotype. Mechanistically, the lack of pharmacological efficacy was reconciled by the failure of bromodomain inhibition to displace endogenous, full-length SMARCA2 from chromatin as determined by in situ cell extraction, chromatin immunoprecipitation (ChIP) and target gene expression and promoter occupancy studies. Using RNAi and cDNA complementation (bromodomain and ATPase-dead constructs), we identified the catalytic ATPase domain, and not the bromodomain of SMARCA2, as a relevant therapeutic target. Taken together, our complementary genetic and pharmacological studies exemplify a general strategy for bromodomain drug-target validation and in case of SMARCA2/4 highlight the requirement for drugging the more challenging helicase/ATPase domain affording potential synthetic-lethal treatment options to cancer patients with genetically defined alterations in SWI/SNF. Citation Format: Bhavatarini Vangamudi, Thomas Paul, Parantu K. Shah, Maria K. Alimova, Lisa Nottebaum, Xi Shi, Yanai Zhan, Elisabetta Leo, Harshad S. Mahadeshwar, Alexei Protopopov, Andrew Futreal, Trang N. Tieu, Mike Peoples, Alessia Petrocchi, Joseph R. Marszalek, Carlo Toniatti, Timothy P. Heffernan, Dominique Verhelle, Giulio Draetta, Dafydd Owen, Philip Jones, Wylie Palmer, Shikhar Sharma, Jannik N. Andersen. The SMARCA2/4 catalytic activity, but not the bromodomain, is a drug target in SWI/SNF mutant cancers. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 3528. doi:10.1158/1538-7445.AM2015-3528

Published

2015