Your search keyword '"Puig-Saus, Cristina"' showing total 219 results

1. CAR-T cell manufacturing: Major process parameters and next-generation strategies.

Author

Ayala Ceja, Melanie, Khericha, Mobina, Harris, Caitlin, Puig-Saus, Cristina, and Chen, Yvonne

Subjects

Humans, Autoimmune Diseases, Immunotherapy, Adoptive, T-Lymphocytes

Abstract

Chimeric antigen receptor (CAR)-T cell therapies have demonstrated strong curative potential and become a critical component in the array of B-cell malignancy treatments. Successful deployment of CAR-T cell therapies to treat hematologic and solid cancers, as well as other indications such as autoimmune diseases, is dependent on effective CAR-T cell manufacturing that impacts not only product safety and efficacy but also overall accessibility to patients in need. In this review, we discuss the major process parameters of autologous CAR-T cell manufacturing, as well as regulatory considerations and ongoing developments that will enable the next generation of CAR-T cell therapies.

Published

2024

2. CAR-T cell therapy targeting surface expression of TYRP1 to treat cutaneous and rare melanoma subtypes

Author

Jilani, Sameeha, Saco, Justin D., Mugarza, Edurne, Pujol-Morcillo, Aleida, Chokry, Jeffrey, Ng, Clement, Abril-Rodriguez, Gabriel, Berger-Manerio, David, Pant, Ami, Hu, Jane, Gupta, Rubi, Vega-Crespo, Agustin, Baselga-Carretero, Ignacio, Chen, Jia M., Shin, Daniel Sanghoon, Scumpia, Philip, Radu, Roxana A., Chen, Yvonne, Ribas, Antoni, and Puig-Saus, Cristina

Published

2024

3. IRIS: Discovery of cancer immunotherapy targets arising from pre-mRNA alternative splicing

Author

Pan, Yang, Phillips, John W, Zhang, Beatrice D, Noguchi, Miyako, Kutschera, Eric, McLaughlin, Jami, Nesterenko, Pavlo A, Mao, Zhiyuan, Bangayan, Nathanael J, Wang, Robert, Tran, Wendy, Yang, Harry T, Wang, Yuanyuan, Xu, Yang, Obusan, Matthew B, Cheng, Donghui, Lee, Alex H, Kadash-Edmondson, Kathryn E, Champhekar, Ameya, Puig-Saus, Cristina, Ribas, Antoni, Prins, Robert M, Seet, Christopher S, Crooks, Gay M, Witte, Owen N, and Xing, Yi

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Cancer Genomics, Human Genome, Immunotherapy, Immunization, Cancer, Biotechnology, Genetics, Vaccine Related, 5.1 Pharmaceuticals, Good Health and Well Being, Male, Humans, RNA Precursors, Alternative Splicing, Leukocytes, Mononuclear, Receptors, Antigen, T-Cell, Epitopes, T-Lymphocyte, Antigens, Neoplasm, Peptides, Neoplasms, RNA splicing, immunotherapy, T cell receptors

Abstract

Alternative splicing (AS) is prevalent in cancer, generating an extensive but largely unexplored repertoire of novel immunotherapy targets. We describe Isoform peptides from RNA splicing for Immunotherapy target Screening (IRIS), a computational platform capable of discovering AS-derived tumor antigens (TAs) for T cell receptor (TCR) and chimeric antigen receptor T cell (CAR-T) therapies. IRIS leverages large-scale tumor and normal transcriptome data and incorporates multiple screening approaches to discover AS-derived TAs with tumor-associated or tumor-specific expression. In a proof-of-concept analysis integrating transcriptomics and immunopeptidomics data, we showed that hundreds of IRIS-predicted TCR targets are presented by human leukocyte antigen (HLA) molecules. We applied IRIS to RNA-seq data of neuroendocrine prostate cancer (NEPC). From 2,939 NEPC-associated AS events, IRIS predicted 1,651 epitopes from 808 events as potential TCR targets for two common HLA types (A*02:01 and A*03:01). A more stringent screening test prioritized 48 epitopes from 20 events with "neoantigen-like" NEPC-specific expression. Predicted epitopes are often encoded by microexons of ≤30 nucleotides. To validate the immunogenicity and T cell recognition of IRIS-predicted TCR epitopes, we performed in vitro T cell priming in combination with single-cell TCR sequencing. Seven TCRs transduced into human peripheral blood mononuclear cells (PBMCs) showed high activity against individual IRIS-predicted epitopes, providing strong evidence of isolated TCRs reactive to AS-derived peptides. One selected TCR showed efficient cytotoxicity against target cells expressing the target peptide. Our study illustrates the contribution of AS to the TA repertoire of cancer cells and demonstrates the utility of IRIS for discovering AS-derived TAs and expanding cancer immunotherapies.

Published

2023

4. Computational prediction of MHC anchor locations guides neoantigen identification and prioritization

Author

Xia, Huiming, McMichael, Joshua, Becker-Hapak, Michelle, Onyeador, Onyinyechi C, Buchli, Rico, McClain, Ethan, Pence, Patrick, Supabphol, Suangson, Richters, Megan M, Basu, Anamika, Ramirez, Cody A, Puig-Saus, Cristina, Cotto, Kelsy C, Freshour, Sharon L, Hundal, Jasreet, Kiwala, Susanna, Goedegebuure, S Peter, Johanns, Tanner M, Dunn, Gavin P, Ribas, Antoni, Miller, Christopher A, Gillanders, William E, Fehniger, Todd A, Griffith, Obi L, and Griffith, Malachi

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Genetics, Immunization, Human Genome, Vaccine Related, Immunotherapy, Cancer, Humans, Antigens, Neoplasm, T-Lymphocytes, Mutation, Peptides, Neoplasms, Clinical sciences

Abstract

Neoantigens are tumor-specific peptide sequences resulting from sources such as somatic DNA mutations. Upon loading onto major histocompatibility complex (MHC) molecules, they can trigger recognition by T cells. Accurate neoantigen identification is thus critical for both designing cancer vaccines and predicting response to immunotherapies. Neoantigen identification and prioritization relies on correctly predicting whether the presenting peptide sequence can successfully induce an immune response. Because most somatic mutations are single-nucleotide variants, changes between wild-type and mutated peptides are typically subtle and require cautious interpretation. A potentially underappreciated variable in neoantigen prediction pipelines is the mutation position within the peptide relative to its anchor positions for the patient's specific MHC molecules. Whereas a subset of peptide positions are presented to the T cell receptor for recognition, others are responsible for anchoring to the MHC, making these positional considerations critical for predicting T cell responses. We computationally predicted anchor positions for different peptide lengths for 328 common HLA alleles and identified unique anchoring patterns among them. Analysis of 923 tumor samples shows that 6 to 38% of neoantigen candidates are potentially misclassified and can be rescued using allele-specific knowledge of anchor positions. A subset of anchor results were orthogonally validated using protein crystallography structures. Representative anchor trends were experimentally validated using peptide-MHC stability assays and competition binding assays. By incorporating our anchor prediction results into neoantigen prediction pipelines, we hope to formalize, streamline, and improve the identification process for relevant clinical studies.

Published

2023

5. Neoantigen-targeted CD8+ T cell responses with PD-1 blockade therapy

Author

Puig-Saus, Cristina, Sennino, Barbara, Peng, Songming, Wang, Clifford L, Pan, Zheng, Yuen, Benjamin, Purandare, Bhamini, An, Duo, Quach, Boi B, Nguyen, Diana, Xia, Huiming, Jilani, Sameeha, Shao, Kevin, McHugh, Claire, Greer, John, Peabody, Phillip, Nayak, Saparya, Hoover, Jonathan, Said, Sara, Jacoby, Kyle, Dalmas, Olivier, Foy, Susan P, Conroy, Andrew, Yi, Michael C, Shieh, Christine, Lu, William, Heeringa, Katharine, Ma, Yan, Chizari, Shahab, Pilling, Melissa J, Ting, Marc, Tunuguntla, Ramya, Sandoval, Salemiz, Moot, Robert, Hunter, Theresa, Zhao, Sidi, Saco, Justin D, Perez-Garcilazo, Ivan, Medina, Egmidio, Vega-Crespo, Agustin, Baselga-Carretero, Ignacio, Abril-Rodriguez, Gabriel, Cherry, Grace, Wong, Deborah J, Hundal, Jasreet, Chmielowski, Bartosz, Speiser, Daniel E, Bethune, Michael T, Bao, Xiaoyan R, Gros, Alena, Griffith, Obi L, Griffith, Malachi, Heath, James R, Franzusoff, Alex, Mandl, Stefanie J, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Minority Health, Genetics, Immunotherapy, Clinical Research, Cancer, 2.1 Biological and endogenous factors, 5.2 Cellular and gene therapies, 5.1 Pharmaceuticals, Good Health and Well Being, Humans, Antigens, Neoplasm, CD8-Positive T-Lymphocytes, Melanoma, Receptors, Antigen, T-Cell, Immune Checkpoint Inhibitors, HLA Antigens, Neoplasm Metastasis, Precision Medicine, Gene Editing, CRISPR-Cas Systems, Mutation, General Science & Technology

Abstract

Neoantigens are peptides derived from non-synonymous mutations presented by human leukocyte antigens (HLAs), which are recognized by antitumour T cells1-14. The large HLA allele diversity and limiting clinical samples have restricted the study of the landscape of neoantigen-targeted T cell responses in patients over their treatment course. Here we applied recently developed technologies15-17 to capture neoantigen-specific T cells from blood and tumours from patients with metastatic melanoma with or without response to anti-programmed death receptor 1 (PD-1) immunotherapy. We generated personalized libraries of neoantigen-HLA capture reagents to single-cell isolate the T cells and clone their T cell receptors (neoTCRs). Multiple T cells with different neoTCR sequences (T cell clonotypes) recognized a limited number of mutations in samples from seven patients with long-lasting clinical responses. These neoTCR clonotypes were recurrently detected over time in the blood and tumour. Samples from four patients with no response to anti-PD-1 also demonstrated neoantigen-specific T cell responses in the blood and tumour to a restricted number of mutations with lower TCR polyclonality and were not recurrently detected in sequential samples. Reconstitution of the neoTCRs in donor T cells using non-viral CRISPR-Cas9 gene editing demonstrated specific recognition and cytotoxicity to patient-matched melanoma cell lines. Thus, effective anti-PD-1 immunotherapy is associated with the presence of polyclonal CD8+ T cells in the tumour and blood specific for a limited number of immunodominant mutations, which are recurrently recognized over time.

Published

2023

6. Remodeling of the tumor microenvironment through PAK4 inhibition sensitizes tumors to immune checkpoint blockade

Author

Abril-Rodriguez, Gabriel, Torrejon, Davis Y, Karin, Daniel, Campbell, Katie M, Medina, Egmidio, Saco, Justin D, Galvez, Mildred, Champhekar, Ameya S, Perez-Garcilazo, Ivan, Baselga-Carretero, Ignacio, Singh, Jas, Comin-Anduix, Begoña, Puig-Saus, Cristina, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Immunotherapy, Cancer, 5.1 Pharmaceuticals, Animals, Mice, Immune Checkpoint Inhibitors, Tumor Microenvironment, CD8-Positive T-Lymphocytes, Melanoma, Antigens, Neoplasm

Abstract

PAK4 inhibition can sensitize tumors to immune checkpoint blockade (ICB) therapy, however, the underlying mechanisms remain unclear. We report that PAK4 inhibition reverses immune cell exclusion by increasing the infiltration of CD8 T cells and CD103+ dendritic cells (DCs), a specific type of DCs that excel at cross-presenting tumor antigens and constitute a source of CXCL10. Interestingly, in melanoma clinical datasets, PAK4 expression levels negatively correlate with the presence of CCL21, the ligand for CCR7 expressed in CD103+ DCs. Furthermore, we extensively characterized the transcriptome of PAK4 knock out (KO) tumors, in vitro and in vivo, and established the importance of PAK4 expression in the regulation of the extracellular matrix, which can facilitate immune cell infiltration. Comparison between PAK4 wild type (WT) and KO anti-PD-1 treated tumors revealed how PAK4 deletion sensitizes tumors to ICB from a transcriptomic perspective. In addition, we validated genetically and pharmacologically that inhibition of PAK4 kinase activity is sufficient to improve anti-tumor efficacy of anti-PD-1 blockade in multiple melanoma mouse models. Therefore, this study provides novel insights into the mechanism of action of PAK4 inhibition and provides the foundation for a new treatment strategy that aims to overcome resistance to PD-1 blockade by combining anti-PD-1 with a small molecule PAK4 kinase inhibitor.

Published

2022

7. Melanoma dedifferentiation induced by interferon-gamma epigenetic remodeling in response to anti-PD-1 therapy

Author

Kim, Yeon Joo, Sheu, Katherine M, Tsoi, Jennifer, Abril-Rodriguez, Gabriel, Medina, Egmidio, Grasso, Catherine S, Torrejon, Davis Y, Champhekar, Ameya S, Litchfield, Kevin, Swanton, Charles, Speiser, Daniel E, Scumpia, Philip O, Hoffmann, Alexander, Graeber, Thomas G, Puig-Saus, Cristina, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Cancer, Genetics, Biomarkers, Tumor, Cell Dedifferentiation, Cell Line, Tumor, Epigenesis, Genetic, Gene Expression Regulation, Neoplastic, Humans, Immune Checkpoint Inhibitors, Interferon-gamma, Melanocytes, Melanoma, Neoplasm Proteins, Programmed Cell Death 1 Receptor, Cancer immunotherapy, Cytokines, Oncology, Medical and Health Sciences, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Melanoma dedifferentiation has been reported to be a state of cellular resistance to targeted therapies and immunotherapies as cancer cells revert to a more primitive cellular phenotype. Here, we show that, counterintuitively, the biopsies of patient tumors that responded to anti-programmed cell death 1 (anti-PD-1) therapy had decreased expression of melanocytic markers and increased neural crest markers, suggesting treatment-induced dedifferentiation. When modeling the effects in vitro, we documented that melanoma cell lines that were originally differentiated underwent a process of neural crest dedifferentiation when continuously exposed to IFN-γ, through global chromatin landscape changes that led to enrichment in specific hyperaccessible chromatin regions. The IFN-γ-induced dedifferentiation signature corresponded with improved outcomes in patients with melanoma, challenging the notion that neural crest dedifferentiation is entirely an adverse phenotype.

Published

2021

8. Melanoma dedifferentiation induced by IFN-γ epigenetic remodeling in response to anti-PD-1 therapy.

Author

Kim, Yeon Joo, Sheu, Katherine M, Tsoi, Jennifer, Abril-Rodriguez, Gabriel, Medina, Egmidio, Grasso, Catherine S, Torrejon, Davis Y, Champhekar, Ameya S, Litchfield, Kevin, Swanton, Charles, Speiser, Daniel E, Scumpia, Philip O, Hoffmann, Alexander, Graeber, Thomas G, Puig-Saus, Cristina, and Ribas, Antoni

Subjects

Cancer immunotherapy, Cytokines, Oncology, Immunology, Medical and Health Sciences

Abstract

Melanoma dedifferentiation has been reported to be a state of cellular resistance to targeted therapies and immunotherapies as cancer cells revert to a more primitive cellular phenotype. Here, we show that, counterintuitively, the biopsies of patient tumors that responded to anti-programmed cell death 1 (anti-PD-1) therapy had decreased expression of melanocytic markers and increased neural crest markers, suggesting treatment-induced dedifferentiation. When modeling the effects in vitro, we documented that melanoma cell lines that were originally differentiated underwent a process of neural crest dedifferentiation when continuously exposed to IFN-γ, through global chromatin landscape changes that led to enrichment in specific hyperaccessible chromatin regions. The IFN-γ-induced dedifferentiation signature corresponded with improved outcomes in patients with melanoma, challenging the notion that neural crest dedifferentiation is entirely an adverse phenotype.

Published

2021

9. Conserved Interferon-γ Signaling Drives Clinical Response to Immune Checkpoint Blockade Therapy in Melanoma

Author

Grasso, Catherine S, Tsoi, Jennifer, Onyshchenko, Mykola, Abril-Rodriguez, Gabriel, Ross-Macdonald, Petra, Wind-Rotolo, Megan, Champhekar, Ameya, Medina, Egmidio, Torrejon, Davis Y, Shin, Daniel Sanghoon, Tran, Phuong, Kim, Yeon Joo, Puig-Saus, Cristina, Campbell, Katie, Vega-Crespo, Agustin, Quist, Michael, Martignier, Christophe, Luke, Jason J, Wolchok, Jedd D, Johnson, Douglas B, Chmielowski, Bartosz, Hodi, F Stephen, Bhatia, Shailender, Sharfman, William, Urba, Walter J, Slingluff, Craig L, Diab, Adi, Haanen, John BAG, Algarra, Salvador Martin, Pardoll, Drew M, Anagnostou, Valsamo, Topalian, Suzanne L, Velculescu, Victor E, Speiser, Daniel E, Kalbasi, Anusha, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Cancer, Immunotherapy, Vaccine Related, Immunization, 5.1 Pharmaceuticals, 2.1 Biological and endogenous factors, Good Health and Well Being, Neurosciences, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis

Published

2021

10. Precise T cell recognition programs designed by transcriptionally linking multiple receptors.

Author

Williams, Jasper Z, Allen, Greg M, Shah, Devan, Sterin, Igal S, Kim, Ki H, Garcia, Vivian P, Shavey, Gavin E, Yu, Wei, Puig-Saus, Cristina, Tsoi, Jennifer, Ribas, Antoni, Roybal, Kole T, and Lim, Wendell A

Subjects

T-Lymphocytes, Animals, Humans, Mice, Antigens, Neoplasm, Cell Communication, Transcription, Genetic, Receptors, Notch, Cell Engineering, Receptors, Chimeric Antigen, Generic health relevance, Inflammatory and immune system, General Science & Technology

Abstract

Living cells often identify their correct partner or target cells by integrating information from multiple receptors, achieving levels of recognition that are difficult to obtain with individual molecular interactions. In this study, we engineered a diverse library of multireceptor cell-cell recognition circuits by using synthetic Notch receptors to transcriptionally interconnect multiple molecular recognition events. These synthetic circuits allow engineered T cells to integrate extra- and intracellular antigen recognition, are robust to heterogeneity, and achieve precise recognition by integrating up to three different antigens with positive or negative logic. A three-antigen AND gate composed of three sequentially linked receptors shows selectivity in vivo, clearing three-antigen tumors while ignoring related two-antigen tumors. Daisy-chaining multiple molecular recognition events together in synthetic circuits provides a powerful way to engineer cellular-level recognition.

Published

2020

11. Key Parameters of Tumor Epitope Immunogenicity Revealed Through a Consortium Approach Improve Neoantigen Prediction

Author

Wells, Daniel K, van Buuren, Marit M, Dang, Kristen K, Hubbard-Lucey, Vanessa M, Sheehan, Kathleen CF, Campbell, Katie M, Lamb, Andrew, Ward, Jeffrey P, Sidney, John, Blazquez, Ana B, Rech, Andrew J, Zaretsky, Jesse M, Comin-Anduix, Begonya, Ng, Alphonsus HC, Chour, William, Yu, Thomas V, Rizvi, Hira, Chen, Jia M, Manning, Patrice, Steiner, Gabriela M, Doan, Xengie C, Alliance, The Tumor Neoantigen Selection, Khan, Aly A, Lugade, Amit, Lazic, Ana M Mijalkovic, Frentzen, Angela A Elizabeth, Tadmor, Arbel D, Sasson, Ariella S, Rao, Arjun A, Pei, Baikang, Schrörs, Barbara, Berent-Maoz, Beata, Carreno, Beatriz M, Song, Bin, Peters, Bjoern, Li, Bo, Higgs, Brandon W, Stevenson, Brian J, Iseli, Christian, Miller, Christopher A, Morehouse, Christopher A, Melief, Cornelis JM, Puig-Saus, Cristina, van Beek, Daphne, Balli, David, Gfeller, David, Haussler, David, Jäger, Dirk, Cortes, Eduardo, Esaulova, Ekaterina, Sherafat, Elham, Arcila, Francisco, Bartha, Gabor, Liu, Geng, Coukos, George, Richard, Guilhem, Chang, Han, Si, Han, Zörnig, Inka, Xenarios, Ioannis, Mandoiu, Ion, Kooi, Irsan, Conway, James P, Kessler, Jan H, Greenbaum, Jason A, Perera, Jason F, Harris, Jason, Hundal, Jasreet, Shelton, Jennifer M, Wang, Jianmin, Wang, Jiaqian, Greshock, Joel, Blake, Jonathon, Szustakowski, Joseph, Kodysh, Julia, Forman, Juliet, Wei, Lei, Lee, Leo J, Fanchi, Lorenzo F, Slagter, Maarten, Lang, Maren, Mueller, Markus, Lower, Martin, Vormehr, Mathias, Artyomov, Maxim N, Kuziora, Michael, Princiotta, Michael, Bassani-Sternberg, Michal, Macabali, Mignonette, Kojicic, Milica R, Yang, Naibo, Raicevic, Nevena M Ilic, Guex, Nicolas, Robine, Nicolas, Halama, Niels, Skundric, Nikola M, Milicevic, Ognjen S, Gellert, Pascal, Jongeneel, Patrick, and Charoentong, Pornpimol

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Immunology, Cancer, Vaccine Related, Genetics, Immunization, Good Health and Well Being, Alleles, Antigen Presentation, Antigens, Neoplasm, Cohort Studies, Epitopes, Humans, Neoplasms, Peptides, Programmed Cell Death 1 Receptor, Reproducibility of Results, Tumor Neoantigen Selection Alliance, TESLA, epitope, immunogenicity, immunogenomics, immunotherapy, neoantigen, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Many approaches to identify therapeutically relevant neoantigens couple tumor sequencing with bioinformatic algorithms and inferred rules of tumor epitope immunogenicity. However, there are no reference data to compare these approaches, and the parameters governing tumor epitope immunogenicity remain unclear. Here, we assembled a global consortium wherein each participant predicted immunogenic epitopes from shared tumor sequencing data. 608 epitopes were subsequently assessed for T cell binding in patient-matched samples. By integrating peptide features associated with presentation and recognition, we developed a model of tumor epitope immunogenicity that filtered out 98% of non-immunogenic peptides with a precision above 0.70. Pipelines prioritizing model features had superior performance, and pipeline alterations leveraging them improved prediction performance. These findings were validated in an independent cohort of 310 epitopes prioritized from tumor sequencing data and assessed for T cell binding. This data resource enables identification of parameters underlying effective anti-tumor immunity and is available to the research community.

Published

2020

12. Conserved Interferon-γ Signaling Drives Clinical Response to Immune Checkpoint Blockade Therapy in Melanoma

Author

Grasso, Catherine S, Tsoi, Jennifer, Onyshchenko, Mykola, Abril-Rodriguez, Gabriel, Ross-Macdonald, Petra, Wind-Rotolo, Megan, Champhekar, Ameya, Medina, Egmidio, Torrejon, Davis Y, Shin, Daniel Sanghoon, Tran, Phuong, Kim, Yeon Joo, Puig-Saus, Cristina, Campbell, Katie, Vega-Crespo, Agustin, Quist, Michael, Martignier, Christophe, Luke, Jason J, Wolchok, Jedd D, Johnson, Douglas B, Chmielowski, Bartosz, Hodi, F Stephen, Bhatia, Shailender, Sharfman, William, Urba, Walter J, Slingluff, Craig L, Diab, Adi, Haanen, John BAG, Algarra, Salvador Martin, Pardoll, Drew M, Anagnostou, Valsamo, Topalian, Suzanne L, Velculescu, Victor E, Speiser, Daniel E, Kalbasi, Anusha, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Immunotherapy, Vaccine Related, Cancer, Health Disparities, Clinical Research, Human Genome, Genetics, Immunization, Minority Health, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Adult, Aged, Aged, 80 and over, Antineoplastic Combined Chemotherapy Protocols, Cell Line, Cell Line, Tumor, Female, Gene Expression Profiling, Humans, Immune Checkpoint Inhibitors, Interferon-gamma, Ipilimumab, Male, Melanoma, Middle Aged, Nivolumab, T-Lymphocytes, Transcriptome, Young Adult, RNA-seq, anti-CTLA-4, anti-PD-1, biopsies, clinical trial, immune checkpoint blockade, immune exclusion, interferon-γ, resistance, response, transcriptomics, Neurosciences, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

We analyze the transcriptome of baseline and on-therapy tumor biopsies from 101 patients with advanced melanoma treated with nivolumab (anti-PD-1) alone or combined with ipilimumab (anti-CTLA-4). We find that T cell infiltration and interferon-γ (IFN-γ) signaling signatures correspond most highly with clinical response to therapy, with a reciprocal decrease in cell-cycle and WNT signaling pathways in responding biopsies. We model the interaction in 58 human cell lines, where IFN-γ in vitro exposure leads to a conserved transcriptome response unless cells have IFN-γ receptor alterations. This conserved IFN-γ transcriptome response in melanoma cells serves to amplify the antitumor immune response. Therefore, the magnitude of the antitumor T cell response and the corresponding downstream IFN-γ signaling are the main drivers of clinical response or resistance to immune checkpoint blockade therapy.

Published

2020

13. Overcoming Genetically Based Resistance Mechanisms to PD-1 Blockade

Author

Torrejon, Davis Y, Abril-Rodriguez, Gabriel, Champhekar, Ameya S, Tsoi, Jennifer, Campbell, Katie M, Kalbasi, Anusha, Parisi, Giulia, Zaretsky, Jesse M, Garcia-Diaz, Angel, Puig-Saus, Cristina, Cheung-Lau, Gardenia, Wohlwender, Thomas, Krystofinski, Paige, Vega-Crespo, Agustin, Lee, Christopher M, Mascaro, Pau, Grasso, Catherine S, Berent-Maoz, Beata, Comin-Anduix, Begoña, Hu-Lieskovan, Siwen, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Genetics, Immunotherapy, Cancer, Clinical Research, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, 5.2 Cellular and gene therapies, Animals, CD4-Positive T-Lymphocytes, CD8-Positive T-Lymphocytes, Cell Line, Tumor, Cell Proliferation, Drug Resistance, Neoplasm, Humans, Interferons, Interleukin-2, Janus Kinase 1, Janus Kinase 2, Killer Cells, Natural, Loss of Function Mutation, Mice, Inbred C57BL, Neoplasms, Polyethylene Glycols, Programmed Cell Death 1 Receptor, Toll-Like Receptor 9, beta 2-Microglobulin, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

Mechanism-based strategies to overcome resistance to PD-1 blockade therapy are urgently needed. We developed genetic acquired resistant models of JAK1, JAK2, and B2M loss-of-function mutations by gene knockout in human and murine cell lines. Human melanoma cell lines with JAK1/2 knockout became insensitive to IFN-induced antitumor effects, while B2M knockout was no longer recognized by antigen-specific T cells and hence was resistant to cytotoxicity. All of these mutations led to resistance to anti-PD-1 therapy in vivo. JAK1/2-knockout resistance could be overcome with the activation of innate and adaptive immunity by intratumoral Toll-like receptor 9 agonist administration together with anti-PD-1, mediated by natural killer (NK) and CD8 T cells. B2M-knockout resistance could be overcome by NK-cell and CD4 T-cell activation using the CD122 preferential IL2 agonist bempegaldesleukin. Therefore, mechanistically designed combination therapies can overcome genetic resistance to PD-1 blockade therapy. SIGNIFICANCE: The activation of IFN signaling through pattern recognition receptors and the stimulation of NK cells overcome genetic mechanisms of resistance to PD-1 blockade therapy mediated through deficient IFN receptor and antigen presentation pathways. These approaches are being tested in the clinic to improve the antitumor activity of PD-1 blockade therapy.This article is highlighted in the In This Issue feature, p. 1079.

Published

2020

14. Publisher Correction: PAK4 inhibition improves PD-1 blockade immunotherapy

Author

Abril-Rodriguez, Gabriel, Torrejon, Davis Y, Liu, Wei, Zaretsky, Jesse M, Nowicki, Theodore S, Tsoi, Jennifer, Puig-Saus, Cristina, Baselga-Carretero, Ignacio, Medina, Egmidio, Quist, Michael J, Garcia, Alejandro J, Senapedis, William, Baloglu, Erkan, Kalbasi, Anusha, Cheung-Lau, Gardenia, Berent-Maoz, Beata, Comin-Anduix, Begoña, Hu-Lieskovan, Siwen, Wang, Cun-Yu, Grasso, Catherine S, and Ribas, Antoni

Published

2020

15. Persistence of adoptively transferred T cells with a kinetically engineered IL-2 receptor agonist.

Author

Parisi, Giulia, Saco, Justin D, Salazar, Felix B, Tsoi, Jennifer, Krystofinski, Paige, Puig-Saus, Cristina, Zhang, Ruixue, Zhou, Jing, Cheung-Lau, Gardenia C, Garcia, Alejandro J, Grasso, Catherine S, Tavaré, Richard, Hu-Lieskovan, Siwen, Mackay, Sean, Zalevsky, Jonathan, Bernatchez, Chantale, Diab, Adi, Wu, Anna M, Comin-Anduix, Begoña, Charych, Deborah, and Ribas, Antoni

Subjects

T-Lymphocytes, Animals, Mice, Inbred C57BL, Humans, Mice, Melanoma, Melanoma, Experimental, Polyethylene Glycols, Receptors, Interleukin-2, Interleukin-2, Adoptive Transfer, Lymphocyte Activation, Inbred C57BL, Experimental, Receptors

Abstract

Interleukin-2 (IL-2) is a component of most protocols of adoptive cell transfer (ACT) therapy for cancer, but is limited by short exposure and high toxicities. NKTR-214 is a kinetically-engineered IL-2 receptor βγ (IL-2Rβγ)-biased agonist consisting of IL-2 conjugated to multiple releasable polyethylene glycol chains resulting in sustained signaling through IL-2Rβγ. We report that ACT supported by NKTR-214 increases the proliferation, homing and persistence of anti-tumor T cells compared to ACT with IL-2, resulting in superior antitumor activity in a B16-F10 murine melanoma model. The use of NKTR-214 increases the number of polyfunctional T cells in murine spleens and tumors compared to IL-2, and enhances the polyfunctionality of T and NK cells in the peripheral blood of patients receiving NKTR-214 in a phase 1 trial. In conclusion, NKTR-214 may have the potential to improve the antitumor activity of ACT in humans through increased in vivo expansion and polyfunctionality of the adoptively transferred T cells.

Published

2020

16. PAK4 inhibition improves PD-1 blockade immunotherapy

Author

Abril-Rodriguez, Gabriel, Torrejon, Davis Y, Liu, Wei, Zaretsky, Jesse M, Nowicki, Theodore S, Tsoi, Jennifer, Puig-Saus, Cristina, Baselga-Carretero, Ignacio, Medina, Egmidio, Quist, Michael J, Garcia, Alejandro J, Senapedis, William, Baloglu, Erkan, Kalbasi, Anusha, Cheung-Lau, Gardenia, Berent-Maoz, Beata, Comin-Anduix, Begoña, Hu-Lieskovan, Siwen, Wang, Cun-Yu, Grasso, Catherine S, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Immunization, Minority Health, Cancer, Health Disparities, Vaccine Related, Immunotherapy, 5.1 Pharmaceuticals, 2.1 Biological and endogenous factors, 6.1 Pharmaceuticals, Animals, CD8-Positive T-Lymphocytes, Immune Checkpoint Inhibitors, Mice, Neoplasms, Programmed Cell Death 1 Receptor, p21-Activated Kinases, Oncology and carcinogenesis

Abstract

Lack of tumor infiltration by immune cells is the main mechanism of primary resistance to programmed cell death protein 1 (PD-1) blockade therapies for cancer. It has been postulated that cancer cell-intrinsic mechanisms may actively exclude T cells from tumors, suggesting that the finding of actionable molecules that could be inhibited to increase T cell infiltration may synergize with checkpoint inhibitor immunotherapy. Here, we show that p21-activated kinase 4 (PAK4) is enriched in non-responding tumor biopsies with low T cell and dendritic cell infiltration. In mouse models, genetic deletion of PAK4 increased T cell infiltration and reversed resistance to PD-1 blockade in a CD8 T cell-dependent manner. Furthermore, combination of anti-PD-1 with the PAK4 inhibitor KPT-9274 improved anti-tumor response compared with anti-PD-1 alone. Therefore, high PAK4 expression is correlated with low T cell and dendritic cell infiltration and a lack of response to PD-1 blockade, which could be reversed with PAK4 inhibition.

Published

2020

17. Gene editing: Towards the third generation of adoptive T-cell transfer therapies

Author

Puig-Saus, Cristina and Ribas, Antoni

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Rare Diseases, Gene Therapy, Genetics, Cancer, Biotechnology, Development of treatments and therapeutic interventions, 5.2 Cellular and gene therapies, Adoptive T-cell therapy, Gene editing in T cells, Non-viral gene editing in T cells

Abstract

First-generation adoptive T-cell transfer (ACT) administering tumor-infiltrating lymphocytes (TILs), and second-generation ACT using autologous T cells genetically modified to express tumor-specific T-cell receptors (TCRs) or chimeric antigen receptors (CARs) have both shown promise for the treatment of several cancers, including melanoma, leukemia and lymphoma. However, these treatments require labor-intensive manufacturing of the cell product for each patient, frequently utilize lentiviral or retroviral vectors to genetically modify the T cells, and have limited antitumor efficacy in solid tumors. Gene editing is revolutionizing the field of gene therapy, and ACT is at the forefront of this revolution. Gene-editing technologies can be used to re-engineer the phenotype of T cells to increase their antitumor potency, to generate off-the-shelf ACT products, and to replace endogenous TCRs with tumor-specific TCRs or CARs using homology-directed repair (HDR) donor templates. Adeno-associated viral vectors or linear DNA have been used as HDR donor templates. Of note, non-viral delivery substantially reduces the time required to generate clinical-grade reagents for manufacture of T-cell products-a critical step for the translation of personalized T-cell therapies. These technological advances in the field using gene editing open the door to the third generation of ACT therapies.

Published

2019

18. IND-Enabling Studies for a Clinical Trial to Genetically Program a Persistent Cancer-Targeted Immune System

Author

Puig-Saus, Cristina, Parisi, Giulia, Garcia-Diaz, Angel, Krystofinski, Paige E, Sandoval, Salemiz, Zhang, Ruixue, Champhekar, Ameya S, McCabe, James, Cheung-Lau, Gardenia C, Truong, Nhat A, Vega-Crespo, Agustin, Komenan, Marie Desiles S, Pang, Jia, Macabali, Mignonette H, Saco, Justin D, Goodwin, Jeffrey L, Bolon, Brad, Seet, Christopher S, Montel-Hagen, Amelie, Crooks, Gay M, Hollis, Roger P, Campo-Fernandez, Beatriz, Bischof, Daniela, Cornetta, Kenneth, Gschweng, Eric H, Adelson, Celia, Nguyen, Alexander, Yang, Lili, Witte, Owen N, Baltimore, David, Comin-Anduix, Begonya, Kohn, Donald B, Wang, Xiaoyan, Cabrera, Paula, Kaplan-Lefko, Paula J, Berent-Maoz, Beata, and Ribas, Antoni

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Immunology, Immunization, Biotechnology, Hematology, Cancer, Genetics, Gene Therapy, Regenerative Medicine, Stem Cell Research, Transplantation, Vaccine Related, 5.2 Cellular and gene therapies, Blood, Animals, Antigens, Neoplasm, Cells, Cultured, Clinical Trials as Topic, Drugs, Investigational, Genetic Therapy, HLA-A2 Antigen, Hematopoietic Stem Cells, Humans, Immunotherapy, Adoptive, Membrane Proteins, Mice, Inbred C57BL, Mice, Transgenic, Neoplasms, Receptors, Antigen, T-Cell, T-Lymphocytes, Oncology and Carcinogenesis, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis

Abstract

PurposeTo improve persistence of adoptively transferred T-cell receptor (TCR)-engineered T cells and durable clinical responses, we designed a clinical trial to transplant genetically-modified hematopoietic stem cells (HSCs) together with adoptive cell transfer of T cells both engineered to express an NY-ESO-1 TCR. Here, we report the preclinical studies performed to enable an investigational new drug (IND) application.Experimental designHSCs transduced with a lentiviral vector expressing NY-ESO-1 TCR and the PET reporter/suicide gene HSV1-sr39TK and T cells transduced with a retroviral vector expressing NY-ESO-1 TCR were coadministered to myelodepleted HLA-A2/Kb mice within a formal Good Laboratory Practice (GLP)-compliant study to demonstrate safety, persistence, and HSC differentiation into all blood lineages. Non-GLP experiments included assessment of transgene immunogenicity and in vitro viral insertion safety studies. Furthermore, Good Manufacturing Practice (GMP)-compliant cell production qualification runs were performed to establish the manufacturing protocols for clinical use.ResultsTCR genetically modified and ex vivo-cultured HSCs differentiated into all blood subsets in vivo after HSC transplantation, and coadministration of TCR-transduced T cells did not result in increased toxicity. The expression of NY-ESO-1 TCR and sr39TK transgenes did not have a detrimental effect on gene-modified HSC's differentiation to all blood cell lineages. There was no evidence of genotoxicity induced by the lentiviral vector. GMP batches of clinical-grade transgenic cells produced during qualification runs had adequate stability and functionality.ConclusionsCoadministration of HSCs and T cells expressing an NY-ESO-1 TCR is safe in preclinical models. The results presented in this article led to the FDA approval of IND 17471.

Published

2019

19. Global alteration of T-lymphocyte metabolism by PD-L1 checkpoint involves a block of de novo nucleoside phosphate synthesis

Author

Palaskas, Nicolaos Jay, Garcia, Jacob David, Shirazi, Roksana, Shin, Daniel Sanghoon, Puig-Saus, Cristina, Braas, Daniel, Ribas, Antoni, and Graeber, Thomas Glen

Subjects

Biochemistry and Cell Biology, Biological Sciences, Immunotherapy, Cancer, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Cancer microenvironment, DNA metabolism, Metabolomics, RNA metabolism, Tumour immunology, Biochemistry and cell biology

Abstract

Metabolic obstacles of the tumor microenvironment remain a challenge to T-cell-mediated cancer immunotherapies. To better understand the interplay of immune checkpoint signaling and immune metabolism, this study developed and used an optimized metabolite extraction protocol for non-adherent primary human T-cells, to broadly profile in vitro metabolic changes effected by PD-1 signaling by mass spectrometry-based metabolomics and isotopomer analysis. Inhibitory signaling reduced aerobic glycolysis and glutaminolysis. A general scarcity across the panel of metabolites measured supported widespread metabolic regulation by PD-1. Glucose carbon fate analysis supported tricarboxylic acid cycle reliance on pyruvate carboxylation, catabolic-state fluxes into acetyl-CoA and succinyl-CoA, and a block in de novo nucleoside phosphate synthesis that was accompanied by reduced mTORC1 signaling. Nonetheless, exogenous administration of nucleosides was not sufficient to ameliorate proliferation of T-cells in the context of multiple metabolic insufficiencies due to PD-L1 treatment. Carbon fate analysis did not support the use of primarily glucose-derived carbons to fuel fatty acid beta oxidation, in contrast to reports on T-memory cells. These findings add to our understanding of metabolic dysregulation by PD-1 signaling and inform the effort to rationally develop metabolic interventions coupled with immune-checkpoint blockade for increased treatment efficacy.

Published

2019

20. Isolation and characterization of NY-ESO-1–specific T cell receptors restricted on various MHC molecules

Author

Bethune, Michael T, Li, Xiao-Hua, Yu, Jiaji, McLaughlin, Jami, Cheng, Donghui, Mathis, Colleen, Moreno, Blanca Homet, Woods, Katherine, Knights, Ashley J, Garcia-Diaz, Angel, Wong, Stephanie, Hu-Lieskovan, Siwen, Puig-Saus, Cristina, Cebon, Jonathan, Ribas, Antoni, Yang, Lili, Witte, Owen N, and Baltimore, David

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Biotechnology, Gene Therapy, Genetics, Clinical Research, Cancer, 5.2 Cellular and gene therapies, Animals, Cloning, Molecular, Homeodomain Proteins, Humans, Major Histocompatibility Complex, Receptors, Antigen, T-Cell, NY-ESO-1, immunotherapy, T cell receptor gene therapy, TCR, MHC

Abstract

Tumor-specific T cell receptor (TCR) gene transfer enables specific and potent immune targeting of tumor antigens. Due to the prevalence of the HLA-A2 MHC class I supertype in most human populations, the majority of TCR gene therapy trials targeting public antigens have employed HLA-A2-restricted TCRs, limiting this approach to those patients expressing this allele. For these patients, TCR gene therapy trials have resulted in both tantalizing successes and lethal adverse events, underscoring the need for careful selection of antigenic targets. Broad and safe application of public antigen-targeted TCR gene therapies will require (i) selecting public antigens that are highly tumor-specific and (ii) targeting multiple epitopes derived from these antigens by obtaining an assortment of TCRs restricted by multiple common MHC alleles. The canonical cancer-testis antigen, NY-ESO-1, is not expressed in normal tissues but is aberrantly expressed across a broad array of cancer types. It has also been targeted with A2-restricted TCR gene therapy without adverse events or notable side effects. To enable the targeting of NY-ESO-1 in a broader array of HLA haplotypes, we isolated TCRs specific for NY-ESO-1 epitopes presented by four MHC molecules: HLA-A2, -B07, -B18, and -C03. Using these TCRs, we pilot an approach to extend TCR gene therapies targeting NY-ESO-1 to patient populations beyond those expressing HLA-A2.

Published

2018

21. Immunotherapy resistance by inflammation-induced dedifferentiation

Author

Mehta, Arnav, Kim, Yeon Joo, Robert, Lidia, Tsoi, Jennifer, Comin-Anduix, Begoña, Berent-Maoz, Beata, Cochran, Alistair J, Economou, James S, Tumeh, Paul C, Puig-Saus, Cristina, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Vaccine Related, Immunization, Cancer, Immunotherapy, 5.1 Pharmaceuticals, Cell Dedifferentiation, Cell Line, Tumor, Coculture Techniques, Drug Resistance, Neoplasm, Humans, Immunotherapy, Adoptive, MART-1 Antigen, Male, Melanoma, Middle Aged, Neoplasm Metastasis, Nerve Tissue Proteins, Nevus, Pigmented, Receptors, Chimeric Antigen, Receptors, Nerve Growth Factor, Recurrence, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

A promising arsenal of targeted and immunotherapy treatments for metastatic melanoma has emerged over the last decade. With these therapies, we now face new mechanisms of tumor-acquired resistance. We report here a patient whose metastatic melanoma underwent dedifferentiation as a resistance mechanism to adoptive T-cell transfer therapy (ACT) to the MART1 antigen, a phenomenon that had been observed only in mouse studies to date. After an initial period of tumor regression, the patient presented in relapse with tumors lacking melanocytic antigens (MART1, gp100) and expressing an inflammation-induced neural crest marker (NGFR). We demonstrate using human melanoma cell lines that this resistance phenotype can be induced in vitro by treatment with MART1 T cell receptor-expressing T cells or with TNFα, and that the phenotype is reversible with withdrawal of inflammatory stimuli. This supports the hypothesis that acquired resistance to cancer immunotherapy can be mediated by inflammation-induced cancer dedifferentiation.Significance: We report a patient whose metastatic melanoma underwent inflammation-induced dedifferentiation as a resistance mechanism to ACT to the MART1 antigen. Our results suggest that future melanoma ACT protocols may benefit from the simultaneous targeting of multiple tumor antigens, modulating the inflammatory response, and inhibition of inflammatory dedifferentiation-inducing signals. Cancer Discov; 8(8); 935-43. ©2018 AACR.This article is highlighted in the In This Issue feature, p. 899.

Published

2018

22. Reprogramming human T cell function and specificity with non-viral genome targeting.

Author

Roth, Theodore L, Puig-Saus, Cristina, Yu, Ruby, Shifrut, Eric, Carnevale, Julia, Li, P Jonathan, Hiatt, Joseph, Saco, Justin, Krystofinski, Paige, Li, Han, Tobin, Victoria, Nguyen, David N, Lee, Michael R, Putnam, Amy L, Ferris, Andrea L, Chen, Jeff W, Schickel, Jean-Nicolas, Pellerin, Laurence, Carmody, David, Alkorta-Aranburu, Gorka, Del Gaudio, Daniela, Matsumoto, Hiroyuki, Morell, Montse, Mao, Ying, Cho, Min, Quadros, Rolen M, Gurumurthy, Channabasavaiah B, Smith, Baz, Haugwitz, Michael, Hughes, Stephen H, Weissman, Jonathan S, Schumann, Kathrin, Esensten, Jonathan H, May, Andrew P, Ashworth, Alan, Kupfer, Gary M, Greeley, Siri Atma W, Bacchetta, Rosa, Meffre, Eric, Roncarolo, Maria Grazia, Romberg, Neil, Herold, Kevan C, Ribas, Antoni, Leonetti, Manuel D, and Marson, Alexander

Subjects

T-Lymphocytes, Cells, Cultured, Animals, Humans, Mice, Receptors, Antigen, T-Cell, Protein Engineering, Neoplasm Transplantation, Autoimmunity, Genome, Human, Male, Interleukin-2 Receptor alpha Subunit, CRISPR-Cas Systems, Cellular Reprogramming, Gene Editing, Human Genome, Biotechnology, Genetics, Gene Therapy, 5.2 Cellular and gene therapies, 5.1 Pharmaceuticals, Inflammatory and immune system, Cancer, General Science & Technology

Abstract

Decades of work have aimed to genetically reprogram T cells for therapeutic purposes1,2 using recombinant viral vectors, which do not target transgenes to specific genomic sites3,4. The need for viral vectors has slowed down research and clinical use as their manufacturing and testing is lengthy and expensive. Genome editing brought the promise of specific and efficient insertion of large transgenes into target cells using homology-directed repair5,6. Here we developed a CRISPR-Cas9 genome-targeting system that does not require viral vectors, allowing rapid and efficient insertion of large DNA sequences (greater than one kilobase) at specific sites in the genomes of primary human T cells, while preserving cell viability and function. This permits individual or multiplexed modification of endogenous genes. First, we applied this strategy to correct a pathogenic IL2RA mutation in cells from patients with monogenic autoimmune disease, and demonstrate improved signalling function. Second, we replaced the endogenous T cell receptor (TCR) locus with a new TCR that redirected T cells to a cancer antigen. The resulting TCR-engineered T cells specifically recognized tumour antigens and mounted productive anti-tumour cell responses in vitro and in vivo. Together, these studies provide preclinical evidence that non-viral genome targeting can enable rapid and flexible experimental manipulation and therapeutic engineering of primary human immune cells.

Published

2018

23. Genetic mechanisms of immune evasion in colorectal cancer

Author

Grasso, Catherine S, Giannakis, Marios, Wells, Daniel K, Hamada, Tsuyoshi, Mu, Xinmeng Jasmine, Quist, Michael, Nowak, Jonathan A, Nishihara, Reiko, Qian, Zhi Rong, Inamura, Kentaro, Morikawa, Teppei, Nosho, Katsuhiko, Abril-Rodriguez, Gabriel, Connolly, Charles, Escuin-Ordinas, Helena, Geybels, Milan S, Grady, William M, Hsu, Li, Hu-Lieskovan, Siwen, Huyghe, Jeroen R, Kim, Yeon Joo, Krystofinski, Paige, Leiserson, Mark DM, Montoya, Dennis J, Nadel, Brian B, Pellegrini, Matteo, Pritchard, Colin C, Puig-Saus, Cristina, Quist, Elleanor H, Raphael, Ben J, Salipante, Stephen J, Shin, Daniel Sanghoon, Shinbrot, Eve, Shirts, Brian, Shukla, Sachet, Stanford, Janet L, Sun, Wei, Tsoi, Jennifer, Upfill-Brown, Alexander, Wheeler, David A, Wu, Catherine J, Yu, Ming, Zaidi, Syed H, Zaretsky, Jesse M, Gabriel, Stacey B, Lander, Eric S, Garraway, Levi A, Hudson, Thomas J, Fuchs, Charles S, Ribas, Antoni, Ogino, Shuji, and Peters, Ulrike

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Cancer, Digestive Diseases, Genetics, Human Genome, Clinical Research, Immunotherapy, Colo-Rectal Cancer, Cancer Genomics, Genetic Testing, 2.1 Biological and endogenous factors, Colorectal Neoplasms, DNA Copy Number Variations, DNA Methylation, Germ-Line Mutation, HLA Antigens, Humans, Loss of Heterozygosity, Microsatellite Instability, Tumor Escape, Wnt Signaling Pathway, beta 2-Microglobulin, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

To understand the genetic drivers of immune recognition and evasion in colorectal cancer, we analyzed 1,211 colorectal cancer primary tumor samples, including 179 classified as microsatellite instability-high (MSI-high). This set includes The Cancer Genome Atlas colorectal cancer cohort of 592 samples, completed and analyzed here. MSI-high, a hypermutated, immunogenic subtype of colorectal cancer, had a high rate of significantly mutated genes in important immune-modulating pathways and in the antigen presentation machinery, including biallelic losses of B2M and HLA genes due to copy-number alterations and copy-neutral loss of heterozygosity. WNT/β-catenin signaling genes were significantly mutated in all colorectal cancer subtypes, and activated WNT/β-catenin signaling was correlated with the absence of T-cell infiltration. This large-scale genomic analysis of colorectal cancer demonstrates that MSI-high cases frequently undergo an immunoediting process that provides them with genetic events allowing immune escape despite high mutational load and frequent lymphocytic infiltration and, furthermore, that colorectal cancer tumors have genetic and methylation events associated with activated WNT signaling and T-cell exclusion.Significance: This multi-omic analysis of 1,211 colorectal cancer primary tumors reveals that it should be possible to better monitor resistance in the 15% of cases that respond to immune blockade therapy and also to use WNT signaling inhibitors to reverse immune exclusion in the 85% of cases that currently do not. Cancer Discov; 8(6); 730-49. ©2018 AACR.This article is highlighted in the In This Issue feature, p. 663.

Published

2018

24. Key Parameters of Tumor Epitope Immunogenicity Revealed Through a Consortium Approach Improve Neoantigen Prediction

Author

Khan, Aly A., Lugade, Amit, Lazic, Ana M. Mijalkovic, Frentzen, Angela A. Elizabeth, Tadmor, Arbel D., Sasson, Ariella S., Rao, Arjun A., Pei, Baikang, Schrörs, Barbara, Berent-Maoz, Beata, Carreno, Beatriz M., Song, Bin, Peters, Bjoern, Li, Bo, Higgs, Brandon W., Stevenson, Brian J., Iseli, Christian, Miller, Christopher A., Morehouse, Christopher A., Melief, Cornelis J.M., Puig-Saus, Cristina, van Beek, Daphne, Balli, David, Gfeller, David, Haussler, David, Jäger, Dirk, Cortes, Eduardo, Esaulova, Ekaterina, Sherafat, Elham, Arcila, Francisco, Bartha, Gabor, Liu, Geng, Coukos, George, Richard, Guilhem, Chang, Han, Si, Han, Zörnig, Inka, Xenarios, Ioannis, Mandoiu, Ion, Kooi, Irsan, Conway, James P., Kessler, Jan H., Greenbaum, Jason A., Perera, Jason F., Harris, Jason, Hundal, Jasreet, Shelton, Jennifer M., Wang, Jianmin, Wang, Jiaqian, Greshock, Joel, Blake, Jonathon, Szustakowski, Joseph, Kodysh, Julia, Forman, Juliet, Wei, Lei, Lee, Leo J., Fanchi, Lorenzo F., Slagter, Maarten, Lang, Maren, Mueller, Markus, Lower, Martin, Vormehr, Mathias, Artyomov, Maxim N., Kuziora, Michael, Princiotta, Michael, Bassani-Sternberg, Michal, Macabali, Mignonette, Kojicic, Milica R., Yang, Naibo, Raicevic, Nevena M. Ilic, Guex, Nicolas, Robine, Nicolas, Halama, Niels, Skundric, Nikola M., Milicevic, Ognjen S., Gellert, Pascal, Jongeneel, Patrick, Charoentong, Pornpimol, Srivastava, Pramod K., Tanden, Prateek, Shah, Priyanka, Hu, Qiang, Gupta, Ravi, Chen, Richard, Petit, Robert, Ziman, Robert, Hilker, Rolf, Shukla, Sachet A., Al Seesi, Sahar, Boyle, Sean M., Qiu, Si, Sarkizova, Siranush, Salama, Sofie, Liu, Song, Wu, Song, Sridhar, Sriram, Ketelaars, Steven L.C., Jhunjhunwala, Suchit, Shcheglova, Tatiana, Schuepbach, Thierry, Creasy, Todd H., Josipovic, Veliborka, Kovacevic, Vladimir B., Fu, Weixuan, Krebber, Willem-Jan, Hsu, Yi-Hsiang, Sebastian, Yinong, Yalcin, Zeynep Kosaloglu, Huang, Zhiqin, Wells, Daniel K., van Buuren, Marit M., Dang, Kristen K., Hubbard-Lucey, Vanessa M., Sheehan, Kathleen C.F., Campbell, Katie M., Lamb, Andrew, Ward, Jeffrey P., Sidney, John, Blazquez, Ana B., Rech, Andrew J., Zaretsky, Jesse M., Comin-Anduix, Begonya, Ng, Alphonsus H.C., Chour, William, Yu, Thomas V., Rizvi, Hira, Chen, Jia M., Manning, Patrice, Steiner, Gabriela M., Doan, Xengie C., Merghoub, Taha, Guinney, Justin, Kolom, Adam, Selinsky, Cheryl, Ribas, Antoni, Hellmann, Matthew D., Hacohen, Nir, Sette, Alessandro, Heath, James R., Bhardwaj, Nina, Ramsdell, Fred, Schreiber, Robert D., Schumacher, Ton N., Kvistborg, Pia, and Defranoux, Nadine A.

Published

2020

25. Mutations Associated with Acquired Resistance to PD-1 Blockade in Melanoma

Author

Zaretsky, Jesse M, Garcia-Diaz, Angel, Shin, Daniel S, Escuin-Ordinas, Helena, Hugo, Willy, Hu-Lieskovan, Siwen, Torrejon, Davis Y, Abril-Rodriguez, Gabriel, Sandoval, Salemiz, Barthly, Lucas, Saco, Justin, Homet Moreno, Blanca, Mezzadra, Riccardo, Chmielowski, Bartosz, Ruchalski, Kathleen, Shintaku, I Peter, Sanchez, Phillip J, Puig-Saus, Cristina, Cherry, Grace, Seja, Elizabeth, Kong, Xiangju, Pang, Jia, Berent-Maoz, Beata, Comin-Anduix, Begoña, Graeber, Thomas G, Tumeh, Paul C, Schumacher, Ton NM, Lo, Roger S, and Ribas, Antoni

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Immunology, Cancer, Clinical Research, Genetics, Rare Diseases, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Antibodies, Monoclonal, Humanized, Antineoplastic Agents, Biopsy, Drug Resistance, Neoplasm, Exome, Gene Expression Regulation, Neoplastic, Genes, MHC Class I, Humans, Immunotherapy, Interferon-gamma, Janus Kinase 1, Janus Kinase 2, Melanoma, Mutation, Programmed Cell Death 1 Receptor, Recurrence, Sequence Analysis, DNA, Signal Transduction, beta 2-Microglobulin, Medical and Health Sciences, General & Internal Medicine, Biomedical and clinical sciences, Health sciences

Abstract

BackgroundApproximately 75% of objective responses to anti-programmed death 1 (PD-1) therapy in patients with melanoma are durable, lasting for years, but delayed relapses have been noted long after initial objective tumor regression despite continuous therapy. Mechanisms of immune escape in this context are unknown.MethodsWe analyzed biopsy samples from paired baseline and relapsing lesions in four patients with metastatic melanoma who had had an initial objective tumor regression in response to anti-PD-1 therapy (pembrolizumab) followed by disease progression months to years later.ResultsWhole-exome sequencing detected clonal selection and outgrowth of the acquired resistant tumors and, in two of the four patients, revealed resistance-associated loss-of-function mutations in the genes encoding interferon-receptor-associated Janus kinase 1 (JAK1) or Janus kinase 2 (JAK2), concurrent with deletion of the wild-type allele. A truncating mutation in the gene encoding the antigen-presenting protein beta-2-microglobulin (B2M) was identified in a third patient. JAK1 and JAK2 truncating mutations resulted in a lack of response to interferon gamma, including insensitivity to its antiproliferative effects on cancer cells. The B2M truncating mutation led to loss of surface expression of major histocompatibility complex class I.ConclusionsIn this study, acquired resistance to PD-1 blockade immunotherapy in patients with melanoma was associated with defects in the pathways involved in interferon-receptor signaling and in antigen presentation. (Funded by the National Institutes of Health and others.).

Published

2016

26. T-switch-ing TCR specificity.

Author

Hu, Andrew Y. and Puig-Saus, Cristina

Subjects

*T cell receptors, *T cells, *AUTOANTIGENS, *PEPTIDES, *IMMUNOTHERAPY

Abstract

Central tolerance restricts T cells that target self-antigens. In this issue of Immunity , Abdelfattah et al. 1 describe a method to generate self-reactive T cell receptors (TCRs) by directed evolution of non-autoreactive TCRs to recognize self-antigen peptides and demonstrate potential for T cells engineered with such receptors in immunotherapy. Central tolerance restricts T cells that target self-antigens. In this issue of Immunity , Abdelfattah et al. describe a method to generate self-reactive T cell receptors (TCRs) by directed evolution of non-autoreactive TCRs to recognize self-antigen peptides and demonstrate potential for T cells engineered with such receptors in immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2024

27. Supplementary Figure 10 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

28. Supplementary Figure 5 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

29. Supplementary Figure 4 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

30. Supplementary Table 3 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

31. Supplementary Table 1 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

32. Supplementary Figure 8 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

33. Supplementary Table 5 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

34. Supplementary Table 6 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

35. Supplementary Figure 7 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

36. Supplementary Table 2 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

37. Supplementary Figure 3 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

38. Data from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

39. Supplementary Table 4 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

40. Supplementary Figure 6 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

41. Supplementary Figure 9 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

42. Supplementary Figure 2 from Remodeling of the Tumor Microenvironment Through PAK4 Inhibition Sensitizes Tumors to Immune Checkpoint Blockade

Author

Abril-Rodriguez, Gabriel, primary, Torrejon, Davis Y., primary, Karin, Daniel, primary, Campbell, Katie M., primary, Medina, Egmidio, primary, Saco, Justin D., primary, Galvez, Mildred, primary, Champhekar, Ameya S., primary, Perez-Garcilazo, Ivan, primary, Baselga-Carretero, Ignacio, primary, Singh, Jas, primary, Comin-Anduix, Begoña, primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

43. Data from Overcoming Genetically Based Resistance Mechanisms to PD-1 Blockade

Author

Torrejon, Davis Y., primary, Abril-Rodriguez, Gabriel, primary, Champhekar, Ameya S., primary, Tsoi, Jennifer, primary, Campbell, Katie M., primary, Kalbasi, Anusha, primary, Parisi, Giulia, primary, Zaretsky, Jesse M., primary, Garcia-Diaz, Angel, primary, Puig-Saus, Cristina, primary, Cheung-Lau, Gardenia, primary, Wohlwender, Thomas, primary, Krystofinski, Paige, primary, Vega-Crespo, Agustin, primary, Lee, Christopher M., primary, Mascaro, Pau, primary, Grasso, Catherine S., primary, Berent-Maoz, Beata, primary, Comin-Anduix, Begoña, primary, Hu-Lieskovan, Siwen, primary, and Ribas, Antoni, primary

Published

2023

44. Supp. Table S22 from Genetic Mechanisms of Immune Evasion in Colorectal Cancer

Author

Grasso, Catherine S., primary, Giannakis, Marios, primary, Wells, Daniel K., primary, Hamada, Tsuyoshi, primary, Mu, Xinmeng Jasmine, primary, Quist, Michael, primary, Nowak, Jonathan A., primary, Nishihara, Reiko, primary, Qian, Zhi Rong, primary, Inamura, Kentaro, primary, Morikawa, Teppei, primary, Nosho, Katsuhiko, primary, Abril-Rodriguez, Gabriel, primary, Connolly, Charles, primary, Escuin-Ordinas, Helena, primary, Geybels, Milan S., primary, Grady, William M., primary, Hsu, Li, primary, Hu-Lieskovan, Siwen, primary, Huyghe, Jeroen R., primary, Kim, Yeon Joo, primary, Krystofinski, Paige, primary, Leiserson, Mark D.M., primary, Montoya, Dennis J., primary, Nadel, Brian B., primary, Pellegrini, Matteo, primary, Pritchard, Colin C., primary, Puig-Saus, Cristina, primary, Quist, Elleanor H., primary, Raphael, Ben J., primary, Salipante, Stephen J., primary, Shin, Daniel Sanghoon, primary, Shinbrot, Eve, primary, Shirts, Brian, primary, Shukla, Sachet, primary, Stanford, Janet L., primary, Sun, Wei, primary, Tsoi, Jennifer, primary, Upfill-Brown, Alexander, primary, Wheeler, David A., primary, Wu, Catherine J., primary, Yu, Ming, primary, Zaidi, Syed H., primary, Zaretsky, Jesse M., primary, Gabriel, Stacey B., primary, Lander, Eric S., primary, Garraway, Levi A., primary, Hudson, Thomas J., primary, Fuchs, Charles S., primary, Ribas, Antoni, primary, Ogino, Shuji, primary, and Peters, Ulrike, primary

Published

2023

45. Supplementary Data from Immunotherapy Resistance by Inflammation-Induced Dedifferentiation

Author

Mehta, Arnav, primary, Kim, Yeon Joo, primary, Robert, Lidia, primary, Tsoi, Jennifer, primary, Comin-Anduix, Begoña, primary, Berent-Maoz, Beata, primary, Cochran, Alistair J., primary, Economou, James S., primary, Tumeh, Paul C., primary, Puig-Saus, Cristina, primary, and Ribas, Antoni, primary

Published

2023

46. Data from Genetic Mechanisms of Immune Evasion in Colorectal Cancer

Author

Grasso, Catherine S., primary, Giannakis, Marios, primary, Wells, Daniel K., primary, Hamada, Tsuyoshi, primary, Mu, Xinmeng Jasmine, primary, Quist, Michael, primary, Nowak, Jonathan A., primary, Nishihara, Reiko, primary, Qian, Zhi Rong, primary, Inamura, Kentaro, primary, Morikawa, Teppei, primary, Nosho, Katsuhiko, primary, Abril-Rodriguez, Gabriel, primary, Connolly, Charles, primary, Escuin-Ordinas, Helena, primary, Geybels, Milan S., primary, Grady, William M., primary, Hsu, Li, primary, Hu-Lieskovan, Siwen, primary, Huyghe, Jeroen R., primary, Kim, Yeon Joo, primary, Krystofinski, Paige, primary, Leiserson, Mark D.M., primary, Montoya, Dennis J., primary, Nadel, Brian B., primary, Pellegrini, Matteo, primary, Pritchard, Colin C., primary, Puig-Saus, Cristina, primary, Quist, Elleanor H., primary, Raphael, Ben J., primary, Salipante, Stephen J., primary, Shin, Daniel Sanghoon, primary, Shinbrot, Eve, primary, Shirts, Brian, primary, Shukla, Sachet, primary, Stanford, Janet L., primary, Sun, Wei, primary, Tsoi, Jennifer, primary, Upfill-Brown, Alexander, primary, Wheeler, David A., primary, Wu, Catherine J., primary, Yu, Ming, primary, Zaidi, Syed H., primary, Zaretsky, Jesse M., primary, Gabriel, Stacey B., primary, Lander, Eric S., primary, Garraway, Levi A., primary, Hudson, Thomas J., primary, Fuchs, Charles S., primary, Ribas, Antoni, primary, Ogino, Shuji, primary, and Peters, Ulrike, primary

Published

2023

47. Supplementary Data from Overcoming Genetically Based Resistance Mechanisms to PD-1 Blockade

Author

Torrejon, Davis Y., primary, Abril-Rodriguez, Gabriel, primary, Champhekar, Ameya S., primary, Tsoi, Jennifer, primary, Campbell, Katie M., primary, Kalbasi, Anusha, primary, Parisi, Giulia, primary, Zaretsky, Jesse M., primary, Garcia-Diaz, Angel, primary, Puig-Saus, Cristina, primary, Cheung-Lau, Gardenia, primary, Wohlwender, Thomas, primary, Krystofinski, Paige, primary, Vega-Crespo, Agustin, primary, Lee, Christopher M., primary, Mascaro, Pau, primary, Grasso, Catherine S., primary, Berent-Maoz, Beata, primary, Comin-Anduix, Begoña, primary, Hu-Lieskovan, Siwen, primary, and Ribas, Antoni, primary

Published

2023

48. Supp. Tables S1, S3-S15, S20, and S23 from Genetic Mechanisms of Immune Evasion in Colorectal Cancer

Author

Grasso, Catherine S., primary, Giannakis, Marios, primary, Wells, Daniel K., primary, Hamada, Tsuyoshi, primary, Mu, Xinmeng Jasmine, primary, Quist, Michael, primary, Nowak, Jonathan A., primary, Nishihara, Reiko, primary, Qian, Zhi Rong, primary, Inamura, Kentaro, primary, Morikawa, Teppei, primary, Nosho, Katsuhiko, primary, Abril-Rodriguez, Gabriel, primary, Connolly, Charles, primary, Escuin-Ordinas, Helena, primary, Geybels, Milan S., primary, Grady, William M., primary, Hsu, Li, primary, Hu-Lieskovan, Siwen, primary, Huyghe, Jeroen R., primary, Kim, Yeon Joo, primary, Krystofinski, Paige, primary, Leiserson, Mark D.M., primary, Montoya, Dennis J., primary, Nadel, Brian B., primary, Pellegrini, Matteo, primary, Pritchard, Colin C., primary, Puig-Saus, Cristina, primary, Quist, Elleanor H., primary, Raphael, Ben J., primary, Salipante, Stephen J., primary, Shin, Daniel Sanghoon, primary, Shinbrot, Eve, primary, Shirts, Brian, primary, Shukla, Sachet, primary, Stanford, Janet L., primary, Sun, Wei, primary, Tsoi, Jennifer, primary, Upfill-Brown, Alexander, primary, Wheeler, David A., primary, Wu, Catherine J., primary, Yu, Ming, primary, Zaidi, Syed H., primary, Zaretsky, Jesse M., primary, Gabriel, Stacey B., primary, Lander, Eric S., primary, Garraway, Levi A., primary, Hudson, Thomas J., primary, Fuchs, Charles S., primary, Ribas, Antoni, primary, Ogino, Shuji, primary, and Peters, Ulrike, primary

Published

2023

49. Supp. Tables S16-S19 from Genetic Mechanisms of Immune Evasion in Colorectal Cancer

Author

Grasso, Catherine S., primary, Giannakis, Marios, primary, Wells, Daniel K., primary, Hamada, Tsuyoshi, primary, Mu, Xinmeng Jasmine, primary, Quist, Michael, primary, Nowak, Jonathan A., primary, Nishihara, Reiko, primary, Qian, Zhi Rong, primary, Inamura, Kentaro, primary, Morikawa, Teppei, primary, Nosho, Katsuhiko, primary, Abril-Rodriguez, Gabriel, primary, Connolly, Charles, primary, Escuin-Ordinas, Helena, primary, Geybels, Milan S., primary, Grady, William M., primary, Hsu, Li, primary, Hu-Lieskovan, Siwen, primary, Huyghe, Jeroen R., primary, Kim, Yeon Joo, primary, Krystofinski, Paige, primary, Leiserson, Mark D.M., primary, Montoya, Dennis J., primary, Nadel, Brian B., primary, Pellegrini, Matteo, primary, Pritchard, Colin C., primary, Puig-Saus, Cristina, primary, Quist, Elleanor H., primary, Raphael, Ben J., primary, Salipante, Stephen J., primary, Shin, Daniel Sanghoon, primary, Shinbrot, Eve, primary, Shirts, Brian, primary, Shukla, Sachet, primary, Stanford, Janet L., primary, Sun, Wei, primary, Tsoi, Jennifer, primary, Upfill-Brown, Alexander, primary, Wheeler, David A., primary, Wu, Catherine J., primary, Yu, Ming, primary, Zaidi, Syed H., primary, Zaretsky, Jesse M., primary, Gabriel, Stacey B., primary, Lander, Eric S., primary, Garraway, Levi A., primary, Hudson, Thomas J., primary, Fuchs, Charles S., primary, Ribas, Antoni, primary, Ogino, Shuji, primary, and Peters, Ulrike, primary

Published

2023

50. Supp. Figures and Legends from Genetic Mechanisms of Immune Evasion in Colorectal Cancer

Author

Grasso, Catherine S., primary, Giannakis, Marios, primary, Wells, Daniel K., primary, Hamada, Tsuyoshi, primary, Mu, Xinmeng Jasmine, primary, Quist, Michael, primary, Nowak, Jonathan A., primary, Nishihara, Reiko, primary, Qian, Zhi Rong, primary, Inamura, Kentaro, primary, Morikawa, Teppei, primary, Nosho, Katsuhiko, primary, Abril-Rodriguez, Gabriel, primary, Connolly, Charles, primary, Escuin-Ordinas, Helena, primary, Geybels, Milan S., primary, Grady, William M., primary, Hsu, Li, primary, Hu-Lieskovan, Siwen, primary, Huyghe, Jeroen R., primary, Kim, Yeon Joo, primary, Krystofinski, Paige, primary, Leiserson, Mark D.M., primary, Montoya, Dennis J., primary, Nadel, Brian B., primary, Pellegrini, Matteo, primary, Pritchard, Colin C., primary, Puig-Saus, Cristina, primary, Quist, Elleanor H., primary, Raphael, Ben J., primary, Salipante, Stephen J., primary, Shin, Daniel Sanghoon, primary, Shinbrot, Eve, primary, Shirts, Brian, primary, Shukla, Sachet, primary, Stanford, Janet L., primary, Sun, Wei, primary, Tsoi, Jennifer, primary, Upfill-Brown, Alexander, primary, Wheeler, David A., primary, Wu, Catherine J., primary, Yu, Ming, primary, Zaidi, Syed H., primary, Zaretsky, Jesse M., primary, Gabriel, Stacey B., primary, Lander, Eric S., primary, Garraway, Levi A., primary, Hudson, Thomas J., primary, Fuchs, Charles S., primary, Ribas, Antoni, primary, Ogino, Shuji, primary, and Peters, Ulrike, primary

Published

2023