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1. Transcriptional and functional analyses of neoantigen-specific CD4 T cells during a profound response to anti-PD-L1 in metastatic Merkel cell carcinoma

Author

Vladimir Makarov, Paul Nghiem, Jaehyuk Choi, Timothy A Chan, Kimberly S Smythe, Jean S Campbell, Robert H Pierce, Raphael Gottardo, Candice Church, David M Koelle, Thomas Pulliam, Natalie Longino, Song Y Park, Nadeem Riaz, Lichen Jing, and Robert Amezquita

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Background Merkel cell carcinoma (MCC) often responds to PD-1 pathway blockade, regardless of tumor-viral status (~80% of cases driven by the Merkel cell polyomavirus (MCPyV)). Prior studies have characterized tumor-specific T cell responses to MCPyV, which have typically been CD8, but little is known about the T cell response to UV-induced neoantigens.Methods A patient in her mid-50s with virus-negative (VN) MCC developed large liver metastases after a brief initial response to chemotherapy. She received anti-PD-L1 (avelumab) and had a partial response within 4 weeks. Whole exome sequencing (WES) was performed to determine potential neoantigen peptides. Characterization of peripheral blood neoantigen T cell responses was evaluated via interferon-gamma (IFNγ) ELISpot, flow cytometry and single-cell RNA sequencing. Tumor-resident T cells were characterized by multiplexed immunohistochemistry.Results WES identified 1027 tumor-specific somatic mutations, similar to the published average of 1121 for VN-MCCs. Peptide prediction with a binding cut-off of ≤100 nM resulted in 77 peptides that were synthesized for T cell assays. Although peptides were predicted based on class I HLAs, we identified circulating CD4 T cells targeting 5 of 77 neoantigens. In contrast, no neoantigen-specific CD8 T cell responses were detected. Neoantigen-specific CD4 T cells were undetectable in blood before anti-PD-L1 therapy but became readily detectible shortly after starting therapy. T cells produced robust IFNγ when stimulated by neoantigen (mutant) peptides but not by the normal (wild-type) peptides. Single cell RNAseq showed neoantigen-reactive T cells expressed the Th1-associated transcription factor (T-bet) and associated cytokines. These CD4 T cells did not significantly exhibit cytotoxicity or non-Th1 markers. Within the pretreatment tumor, resident CD4 T cells were also Th1-skewed and expressed T-bet.Conclusions We identified and characterized tumor-specific Th1-skewed CD4 T cells targeting multiple neoantigens in a patient who experienced a profound and durable partial response to anti-PD-L1 therapy. To our knowledge, this is the first report of neoantigen-specific T cell responses in MCC. Although CD4 and CD8 T cells recognizing viral tumor antigens are often detectible in virus-positive MCC, only CD4 T cells recognizing neoantigens were detected in this patient. These findings suggest that CD4 T cells can play an important role in the response to anti-PD-(L)1 therapy.

Published
2022
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2. CD4+ T cell and M2 macrophage infiltration predict dedifferentiated liposarcoma patient outcomes

Author

Seth M Pollack, Robin L Jones, Marissa Vignali, Brett A Schroeder, Shihong Zhang, Jose G Mantilla, Kimberly S Smythe, Jean S Campbell, Robert H Pierce, Lee D Cranmer, Michael J Wagner, Bonnie J LaFleur, Brian C Schulte, Natalie A LaFranzo, Rachel M Gittelman, Kevin C Flanagan, Julie Rytlewski, Laura Riolobos, Teresa S Kim, and Eleanor Chen

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Published
2021
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3. IL-15 mediated expansion of rare durable memory T cells following adoptive cellular therapy

Author

Robin L Jones, Erik A Farrar, Jianhong Cao, Venu G Pillarisetty, Stanley R Riddell, Jean Campbell, Brett A Schroeder, Ralph Graeme Black, Shihong Zhang, Karan Kohli, Robert H Pierce, Lu Yao, Theodore Scott Nowicki, Heather Sloan, Dawn Stief, Lee D Cranmer, Douglas S Hawkins, and Edward Y Kim

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Background Synovial sarcoma (SS) and myxoid/round cell liposarcoma (MRCL) are ideal solid tumors for the development of adoptive cellular therapy (ACT) targeting NY-ESO-1, as a high frequency of tumors homogeneously express this cancer-testes antigen. Data from early phase clinical trials have shown antitumor activity after the adoptive transfer of NY-ESO-1–specific T cells. In these studies, persistence of NY-ESO-1 specific T cells is highly correlated with response to ACT, but patients often continue to have detectable transferred cells in their peripheral blood following progression.Method We performed a phase I clinical trial evaluating the safety of NY-ESO-1–specific endogenous T cells (ETC) following cyclophosphamide conditioning. Peripheral blood mononuclear cells (PBMCs) from treated patients were evaluated by flow cytometry and gene expression analysis as well as through ex vivo culture assays with and without IL-15.Results Four patients were treated in a cohort using ETC targeting NY-ESO-1 following cyclophosphamide conditioning. Treatment was well tolerated without significant toxicity, but all patients ultimately had disease progression. In two of four patients, we obtained post-treatment tumor tissue and in both, NY-ESO-1 antigen was retained despite clear detectable persisting NY-ESO-1–specific T cells in the peripheral blood. Despite a memory phenotype, these persisting cells lacked markers of proliferation or activation. However, in ex vivo culture assays, they could be induced to proliferate and kill tumor using IL-15. These results were also seen in PBMCs from two patients who received gene-engineered T-cell receptor–based products at other centers.Conclusions ETC targeting NY-ESO-1 with single-agent cyclophosphamide alone conditioning was well tolerated in patients with SS and those with MRCL. IL-15 can induce proliferation and activity in persisting NY-ESO-1–specific T cells even in patients with disease progression following ACT. These results support future work evaluating whether IL-15 could be incorporated into ACT trials post-infusion or at the time of progression.

Published
2021
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4. C17 prevents inflammatory arthritis and associated joint destruction in mice.

Author

Connie Chao, Barbara Joyce-Shaikh, Jeff Grein, Mehrdad Moshrefi, Fahimeh Raoufi, Drake M Laface, Terril K McClanahan, Patricia A Bourne, Robert H Pierce, Daniel M Gorman, and Stefan Pflanz

Subjects
Medicine, Science
Abstract

C17 was first described about ten years ago as a gene expressed in CD34+ cells. A more recent study has suggested a role for C17 in chondrogenesis and development of cartilage. However, based on sequence analysis, we believe that C17 has homology to IL-2 and hence we present the hypothesis that C17 is a cytokine possessing immune-regulatory properties. We provide evidence that C17 is a secreted protein preferentially expressed in chondrocytes, hence in cartilage-rich tissues. Systemic expression of C17 in vivo reduces disease in a collagen antibody-induced arthritis model in mice (CAIA). Joint protection is evident by delayed disease onset, minimal edema, bone protection and absence of diverse histological features of disease. Expression of genes typically associated with acute joint inflammation and erosion of cartilage or bone is blunted in the presence of C17. Consistent with the observed reduction in bone erosion, we demonstrate reduced levels of RANKL in the paws and sera of mice over-expressing C17. Administration of C17 at the peak of disease, however, had no effect on disease progression, indicating that C17's immune-regulatory activity must be most prominent prior to or at the onset of severe joint inflammation. Based on this data we propose C17 as a cytokine that s contributes to immune homeostasis systemically or in a tissue-specific manner in the joint.

Published
2011
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5. Targeting an alternate Wilms' tumor antigen 1 peptide bypasses immunoproteasome dependency

Author

Miranda C. Lahman, Thomas M. Schmitt, Kelly G. Paulson, Nathalie Vigneron, Denise Buenrostro, Felecia D. Wagener, Valentin Voillet, Lauren Martin, Raphael Gottardo, Jason Bielas, Julie M. McElrath, Derek L. Stirewalt, Era L. Pogosova-Agadjanyan, Cecilia C. Yeung, Robert H. Pierce, Daniel N. Egan, Merav Bar, Paul C. Hendrie, Sinéad Kinsella, Aesha Vakil, Jonah Butler, Mary Chaffee, Jonathan Linton, Megan S. McAfee, Daniel S. Hunter, Marie Bleakley, Anthony Rongvaux, Benoit J. Van den Eynde, Aude G. Chapuis, Philip D. Greenberg, and UCL - SSS/DDUV/GECE - Génétique cellulaire

Subjects
Epitopes, Leukemia, Myeloid, Acute, Mice, Proteasome Endopeptidase Complex, Antigens, Neoplasm, HLA-A2 Antigen, Receptors, Antigen, T-Cell, Animals, Humans, General Medicine, Peptides, WT1 Proteins, Article
Abstract

Designing effective antileukemic immunotherapy will require understanding mechanisms underlying tumor control or resistance. Here, we report a mechanism of escape from immunologic targeting in an acute myeloid leukemia (AML) patient, who relapsed 1 year after immunotherapy with engineered T cells expressing a human leukocyte antigen A*02 (HLA-A2)–restricted T cell receptor (TCR) specific for a Wilms’ tumor antigen 1 epitope, WT1126–134(TTCR-C4). Resistance occurred despite persistence of functional therapeutic T cells and continuous expression of WT1 and HLA-A2 by the patient’s AML cells. Analysis of the recurrent AML revealed expression of the standard proteasome, but limited expression of the immunoproteasome, specifically the beta subunit 1i (β1i), which is required for presentation of WT1126–134. An analysis of a second patient treated with TTCR-C4demonstrated specific loss of AML cells coexpressing β1i and WT1. To determine whether the WT1 protein continued to be processed and presented in the absence of immunoproteasome processing, we identified and tested a TCR targeting an alternative, HLA-A2–restricted WT137–45epitope that was generated by immunoproteasome-deficient cells, including WT1-expressing solid tumor lines. T cells expressing this TCR (TTCR37–45) killed the first patients’ relapsed AML resistant to WT1126–134targeting, as well as other primary AML, in vitro. TTCR37–45controlled solid tumor lines lacking immunoproteasome subunits both in vitro and in an NSG mouse model. As proteasome composition can vary in AML, defining and preferentially targeting these proteasome-independent epitopes may maximize therapeutic efficacy and potentially circumvent AML immune evasion by proteasome-related immunoediting.

Published
2023

6. Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Robert H.I. Andtbacka, Yan Wang, Robert H. Pierce, Jean S. Campbell, Melinda Yushak, Mohammed Milhem, Merrick Ross, Katie Niland, Robert D. Arbeit, Sudha Parasuraman, Kris Bickley, Cecilia CS Yeung, Lauri D. Aicher, Kimberly S. Smythe, and Lu Gan

Abstract

Purpose: Mavorixafor is an oral, selective inhibitor of the CXCR4 chemokine receptor that modulates immune cell trafficking. A biomarker-driven phase Ib study (NCT02823405) was conducted in 16 patients with melanoma to investigate the hypothesis that mavorixafor favorably modulates immune cell profiles in the tumor microenvironment (TME) and to evaluate the safety of mavorixafor alone and in combination with pembrolizumab. Experimental Design: Serial biopsies of melanoma lesions were assessed after 3 weeks of mavorixafor monotherapy and after 6 weeks of combination treatment for immune cell markers by NanoString analysis for gene expression and by multiplexed immunofluorescent staining for in situ protein expression. Serum samples taken at biopsy timepoints were evaluated for key chemokine and cytokine alterations using the Myriad Rules Based Medicine multiplex immunoassays. Results: Within the TME, mavorixafor alone increased CD8+ T-cell infiltration, granzyme B signal, antigen presentation machinery, and both tumor inflammatory signature (TIS) and IFNγ gene expression signature scores. Increases in the key serum cytokines CXCL9 and CXCL10 were further enhanced when mavorixafor was combined with pembrolizumab. Adverse events (AE), as assessed by the investigator according to NCI Common Terminology Criteria for Adverse Events (v4.03), related to either mavorixafor or pembrolizumab (≥15%) were diarrhea, fatigue, maculopapular rash, and dry eye. Reported AEs were all ≤ grade 3. Conclusion/Discussion: Treatment with single-agent mavorixafor resulted in enhanced immune cell infiltration and activation in the TME, leading to increases in TIS and IFNγ gene signatures. Mavorixafor as a single agent, and in combination with pembrolizumab, has an acceptable safety profile. These data support further investigation of the use of mavorixafor for patients unresponsive to checkpoint inhibitors. Significance: Despite survival improvements in patients with melanoma treated with checkpoint inhibitor therapy, a significant unmet medical need exists for therapies that enhance effectiveness. We propose that mavorixafor sensitizes the melanoma tumor microenvironment and enhances the activity of checkpoint inhibitors, and thereby may translate to a promising treatment for broader patient populations.

Published
2022

7. Effects of HLA single chain trimer design on peptide presentation and stability

Author

Kathryn A. K. Finton, Peter B. Rupert, Della J. Friend, Ana Dinca, Erica S. Lovelace, Matthew Buerger, Domnita V. Rusnac, Ulysses Foote-McNabb, William Chour, James R. Heath, Jean S. Campbell, Robert H. Pierce, and Roland K. Strong

Subjects
Immunology, Immunology and Allergy
Abstract

MHC class I “single-chain trimer” molecules, coupling MHC heavy chain, β2-microglobulin, and a specific peptide into a single polypeptide chain, are widely used in research. To more fully understand caveats associated with this design that may affect its use for basic and translational studies, we evaluated a set of engineered single-chain trimers with combinations of stabilizing mutations across eight different classical and non-classical human class I alleles with 44 different peptides, including a novel human/murine chimeric design. While, overall, single-chain trimers accurately recapitulate native molecules, care was needed in selecting designs for studying peptides longer or shorter than 9-mers, as single-chain trimer design could affect peptide conformation. In the process, we observed that predictions of peptide binding were often discordant with experiment and that yields and stabilities varied widely with construct design. We also developed novel reagents to improve the crystallizability of these proteins and confirmed novel modes of peptide presentation.

Published
2023

8. Data from Intratumoral Plasmid IL12 Electroporation Therapy in Patients with Advanced Melanoma Induces Systemic and Intratumoral T-cell Responses

Author

Lawrence Fong, Adil I. Daud, Mai H. Le, Robert H. Pierce, Alan Paciorek, Li Zhang, Christopher G. Twitty, Lawrence Chen, Kathryn T. Takamura, Katy K. Tsai, Alain P. Algazi, and Samantha K. Greaney

Abstract

Whereas systemic IL12 is associated with potentially life-threatening toxicity, intratumoral delivery of IL12 through tavokinogene telseplasmid electroporation (tavo) is safe and can induce tumor regression at distant sites. The mechanism by which these responses are mediated is unknown but is presumed to result from a cellular immune response. In a phase II clinical trial of tavo (NCT01502293), samples from 29 patients with cutaneous melanoma with in-transit disease were assessed for immune responses induced with this treatment. Within the blood circulating immune cell population, we found that the frequencies of circulating PD-1+ CD4+ and CD8+ T cells declined with treatment. Circulating immune responses to gp100 were also detected following treatment as measured by IFNγ ELISpot. Patients with a greater antigen-specific circulating immune response also had higher numbers of CD8+ T cells within the tumor. Clinical response was also associated with increased intratumoral CD3+ T cells. Finally, intratumoral T-cell clonality and convergence were increased after treatment, indicating a focusing of the T-cell receptor repertoire. These results indicated that local treatment with tavo can induce a systemic T-cell response and recruit T cells to the tumor microenvironment.

Published
2023

9. Supplementary Table 1 from Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Lu Gan, Kimberly S. Smythe, Lauri D. Aicher, Cecilia CS Yeung, Kris Bickley, Sudha Parasuraman, Robert D. Arbeit, Katie Niland, Merrick Ross, Mohammed Milhem, Melinda Yushak, Jean S. Campbell, Robert H. Pierce, Yan Wang, and Robert H.I. Andtbacka

Abstract

Antibody panels used for mIF analyses.

Published
2023

12. Supplementary Table 2 from Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Lu Gan, Kimberly S. Smythe, Lauri D. Aicher, Cecilia CS Yeung, Kris Bickley, Sudha Parasuraman, Robert D. Arbeit, Katie Niland, Merrick Ross, Mohammed Milhem, Melinda Yushak, Jean S. Campbell, Robert H. Pierce, Yan Wang, and Robert H.I. Andtbacka

Abstract

Serum cytokine and chemokine changes at the end of the 3-week monotherapy period compared to baseline.

Published
2023

13. Data from Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Lu Gan, Kimberly S. Smythe, Lauri D. Aicher, Cecilia CS Yeung, Kris Bickley, Sudha Parasuraman, Robert D. Arbeit, Katie Niland, Merrick Ross, Mohammed Milhem, Melinda Yushak, Jean S. Campbell, Robert H. Pierce, Yan Wang, and Robert H.I. Andtbacka

Abstract

Purpose:Mavorixafor is an oral, selective inhibitor of the CXCR4 chemokine receptor that modulates immune cell trafficking. A biomarker-driven phase Ib study (NCT02823405) was conducted in 16 patients with melanoma to investigate the hypothesis that mavorixafor favorably modulates immune cell profiles in the tumor microenvironment (TME) and to evaluate the safety of mavorixafor alone and in combination with pembrolizumab.Experimental Design:Serial biopsies of melanoma lesions were assessed after 3 weeks of mavorixafor monotherapy and after 6 weeks of combination treatment for immune cell markers by NanoString analysis for gene expression and by multiplexed immunofluorescent staining for in situ protein expression. Serum samples taken at biopsy timepoints were evaluated for key chemokine and cytokine alterations using the Myriad Rules Based Medicine multiplex immunoassays.Results:Within the TME, mavorixafor alone increased CD8+ T-cell infiltration, granzyme B signal, antigen presentation machinery, and both tumor inflammatory signature (TIS) and IFNγ gene expression signature scores. Increases in the key serum cytokines CXCL9 and CXCL10 were further enhanced when mavorixafor was combined with pembrolizumab. Adverse events (AE), as assessed by the investigator according to NCI Common Terminology Criteria for Adverse Events (v4.03), related to either mavorixafor or pembrolizumab (≥15%) were diarrhea, fatigue, maculopapular rash, and dry eye. Reported AEs were all ≤ grade 3.Conclusion/Discussion:Treatment with single-agent mavorixafor resulted in enhanced immune cell infiltration and activation in the TME, leading to increases in TIS and IFNγ gene signatures. Mavorixafor as a single agent, and in combination with pembrolizumab, has an acceptable safety profile. These data support further investigation of the use of mavorixafor for patients unresponsive to checkpoint inhibitors.Significance:Despite survival improvements in patients with melanoma treated with checkpoint inhibitor therapy, a significant unmet medical need exists for therapies that enhance effectiveness. We propose that mavorixafor sensitizes the melanoma tumor microenvironment and enhances the activity of checkpoint inhibitors, and thereby may translate to a promising treatment for broader patient populations.

Published
2023

15. Supplementary Figure 1 from Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Lu Gan, Kimberly S. Smythe, Lauri D. Aicher, Cecilia CS Yeung, Kris Bickley, Sudha Parasuraman, Robert D. Arbeit, Katie Niland, Merrick Ross, Mohammed Milhem, Melinda Yushak, Jean S. Campbell, Robert H. Pierce, Yan Wang, and Robert H.I. Andtbacka

Abstract

Shared TCR TIL sequences taken from tumor biopsy of patient #5 at various timepoints.

Published
2023

17. Data from Differential Effects of Depleting versus Programming Tumor-Associated Macrophages on Engineered T Cells in Pancreatic Ductal Adenocarcinoma

Author

Sunil R. Hingorani, Philip D. Greenberg, Robert H. Pierce, Ellen J. Spartz, Jackson F. Raynor, J. Scott Brockenbrough, Cheryl Black, Patrick Bonson, Ayaka Hulbert, Adam L. Burrack, and Ingunn M. Stromnes

Abstract

Pancreatic ductal adenocarcinoma (PDA) is a lethal malignancy resistant to therapies, including immune-checkpoint blockade. We investigated two distinct strategies to modulate tumor-associated macrophages (TAM) to enhance cellular therapy targeting mesothelin in an autochthonous PDA mouse model. Administration of an antibody to colony-stimulating factor (anti-Csf1R) depleted Ly6Clow protumorigenic TAMs and significantly enhanced endogenous T-cell intratumoral accumulation. Despite increasing the number of endogenous T cells at the tumor site, as previously reported, TAM depletion had only minimal impact on intratumoral accumulation and persistence of T cells engineered to express a murine mesothelin-specific T-cell receptor (TCR). TAM depletion interfered with the antitumor activity of the infused T cells in PDA, evidenced by reduced tumor cell apoptosis. In contrast, TAM programming with agonistic anti-CD40 increased both Ly6Chigh TAMs and the intratumoral accumulation and longevity of TCR-engineered T cells. Anti-CD40 significantly increased the frequency and number of proliferating and granzyme B+ engineered T cells, and increased tumor cell apoptosis. However, anti-CD40 failed to rescue intratumoral engineered T-cell IFNγ production. Thus, although functional modulation, rather than TAM depletion, enhanced the longevity of engineered T cells and increased tumor cell apoptosis, ultimately, anti-CD40 modulation was insufficient to rescue key effector defects in tumor-reactive T cells. This study highlights critical distinctions between how endogenous T cells that evolve in vivo, and engineered T cells with previously acquired effector activity, respond to modifications of the tumor microenvironment.

Published
2023

18. Supplementary Figure 2 from Mavorixafor, an Orally Bioavailable CXCR4 Antagonist, Increases Immune Cell Infiltration and Inflammatory Status of Tumor Microenvironment in Patients with Melanoma

Author

Lu Gan, Kimberly S. Smythe, Lauri D. Aicher, Cecilia CS Yeung, Kris Bickley, Sudha Parasuraman, Robert D. Arbeit, Katie Niland, Merrick Ross, Mohammed Milhem, Melinda Yushak, Jean S. Campbell, Robert H. Pierce, Yan Wang, and Robert H.I. Andtbacka

Abstract

Depiction of T cell clone mobilization from peripheral blood to melanoma site on day 1 and at EOT.

Published
2023

19. Data from Systemic Interferon-γ Increases MHC Class I Expression and T-cell Infiltration in Cold Tumors: Results of a Phase 0 Clinical Trial

Author

Seth M. Pollack, Robin L. Jones, Stanley R. Riddell, Robert H. Pierce, Cassian Yee, Brian A. Van Tine, Lee D. Cranmer, Venu G. Pillarisetty, Qianchuan He, Sydney M. Spadinger, Lu Yao, R. Graeme Black, Karan Kohli, and Shihong Zhang

Abstract

Interferon-γ (IFNγ) has been studied as a cancer treatment with limited evidence of clinical benefit. However, it could play a role in cancer immunotherapy combination treatments. Despite high expression of immunogenic cancer–testis antigens, synovial sarcoma (SS) and myxoid/round cell liposarcoma (MRCL) have a cold tumor microenvironment (TME), with few infiltrating T cells and low expression of major histocompatibility complex class I (MHC-I). We hypothesized that IFNγ treatment could drive inflammation in a cold TME, facilitating further immunotherapy. We conducted a phase 0 clinical trial treating 8 SS or MRCL patients with weekly systemic IFNγ. We performed pre- and posttreatment biopsies. IFNγ changed the SS and MRCL TME, inducing tumor-surface MHC-I expression and significant T-cell infiltration (P < 0.05). Gene-expression analysis suggested increased tumor antigen presentation and less exhausted phenotypes of the tumor-infiltrating T cells. Newly emergent antigen-specific humoral and/or T-cell responses were found in 3 of 7 evaluable patients. However, increased expression of PD-L1 was observed on tumor-infiltrating myeloid cells and in some cases tumor cells. These findings suggest that systemic IFNγ used to convert SS and MRCL into “hot” tumors will work in concert with anti–PD-1 therapy to provide patient benefit.

Published
2023

20. Data from T-cell Localization, Activation, and Clonal Expansion in Human Pancreatic Ductal Adenocarcinoma

Author

Sunil R. Hingorani, Philip D. Greenberg, Robert H. Pierce, Ayaka Hulbert, and Ingunn M. Stromnes

Abstract

Pancreatic ductal adenocarcinoma (PDA) is a lethal malignancy resistant to most therapies, including immune checkpoint blockade. To elucidate mechanisms of immunotherapy resistance, we assessed immune parameters in resected human PDA. We demonstrate significant interpatient variability in T-cell number, localization, and phenotype. CD8+ T cells, Foxp3+ regulatory T cells, and PD-1+ and PD-L1+ cells were preferentially enriched in tertiary lymphoid structures that were found in most tumors compared with stroma and tumor cell nests. Tumors containing more CD8+ T cells also had increased granulocytes, CD163+ (M2 immunosuppressive phenotype) macrophages, and FOXP3+ regulatory T cells. PD-L1 was rare on tumor cells, but was expressed by CD163+ macrophages and an additional stromal cell subset commonly found clustered together adjacent to tumor epithelium. The majority of tumoral CD8+ T cells did not express molecules suggestive of recent T-cell receptor (TCR) signaling. However, 41BB+PD-1+ T cells were still significantly enriched in tumors compared with circulation. Tumoral CD8+PD-1+ T cells commonly expressed additional inhibitory receptors, yet were mostly T-BEThi and EOMESlo, consistent with a less terminally exhausted state. Analysis of gene expression and rearranged TCR genes by deep sequencing suggested most patients have a limited tumor-reactive T-cell response. Multiplex immunohistochemistry revealed variable T-cell infiltration based on abundance and location, which may result in different mechanisms of immunotherapy resistance. Overall, the data support the need for therapies that either induce endogenous, or provide engineered, tumor-specific T-cell responses, and concurrently relieve suppressive mechanisms operative at the tumor site. Cancer Immunol Res; 5(11); 978–91. ©2017 AACR.

Published
2023

21. Supplementary Figure 2 from Liver Metastasis and Treatment Outcome with Anti-PD-1 Monoclonal Antibody in Patients with Melanoma and NSCLC

Author

Adil Daud, Robert H. Pierce, Edward B. Garon, Simone M. Goldinger, Jimmy Hwang, David Elashoff, Tristan R. Grogan, Reinhard Dummer, Bartosz Chmielowski, Alain P. Algazi, Pamela N. Munster, Emma J. Taylor, Peter D. Boasberg, I. Peter Shintaku, Jeremy Chang, Dan L. Nguyen-Kim, Juan C. Osorio, Nooriel Banayan, Phillip J. Sanchez, Eduardo V. Sosa, Andrew Tucker, Matthew F. Krummel, Adi Nosrati, Neharika Khurana, Nathan Handley, Janis M. Taube, Christina L. Harview, Michael Rosenblum, Matthew A. Gubens, Kimberly L. Loo, Katy K. Tsai, Omid Hamid, Matthew D. Hellmann, and Paul C. Tumeh

Abstract

Quantitative CD8+ Counts in patients with Liver and skin metastases.

Published
2023

22. Supplementary Figure 1 from Liver Metastasis and Treatment Outcome with Anti-PD-1 Monoclonal Antibody in Patients with Melanoma and NSCLC

Author

Adil Daud, Robert H. Pierce, Edward B. Garon, Simone M. Goldinger, Jimmy Hwang, David Elashoff, Tristan R. Grogan, Reinhard Dummer, Bartosz Chmielowski, Alain P. Algazi, Pamela N. Munster, Emma J. Taylor, Peter D. Boasberg, I. Peter Shintaku, Jeremy Chang, Dan L. Nguyen-Kim, Juan C. Osorio, Nooriel Banayan, Phillip J. Sanchez, Eduardo V. Sosa, Andrew Tucker, Matthew F. Krummel, Adi Nosrati, Neharika Khurana, Nathan Handley, Janis M. Taube, Christina L. Harview, Michael Rosenblum, Matthew A. Gubens, Kimberly L. Loo, Katy K. Tsai, Omid Hamid, Matthew D. Hellmann, and Paul C. Tumeh

Abstract

Univariate Analysis of Pretreatment prognostic factors in the Discovery cohort.

Published
2023

23. Supplemental Information and Legends from Safety and Efficacy of Intratumoral Injections of Chimeric Antigen Receptor (CAR) T Cells in Metastatic Breast Cancer

Author

Carl H. June, Robert H. Vonderheide, Lynn M. Schuchter, Laurence J. Cooper, Amy S. Clark, Angela M. DeMichele, Jennifer M. Matro, Robert H. Pierce, Jean Campbell, Shannon McGettigan, Regina M. Young, Gabriela Plesa, Jose R. Conejo-Garcia, Alycia So, Austin D. Williams, Avery D. Posey, Simon F. Lacey, Xiaojun Liu, Andrea L Brennan, Irina Kulikovskaya, Jan Joseph Melenhorst, Megan M. Davis, Paul J Zhang, Bruce L. Levine, Yangbing Zhao, and Julia Tchou

Abstract

Supplemental Information and Legends

Published
2023

24. Supplemental Table S3 from Safety and Efficacy of Intratumoral Injections of Chimeric Antigen Receptor (CAR) T Cells in Metastatic Breast Cancer

Author

Carl H. June, Robert H. Vonderheide, Lynn M. Schuchter, Laurence J. Cooper, Amy S. Clark, Angela M. DeMichele, Jennifer M. Matro, Robert H. Pierce, Jean Campbell, Shannon McGettigan, Regina M. Young, Gabriela Plesa, Jose R. Conejo-Garcia, Alycia So, Austin D. Williams, Avery D. Posey, Simon F. Lacey, Xiaojun Liu, Andrea L Brennan, Irina Kulikovskaya, Jan Joseph Melenhorst, Megan M. Davis, Paul J Zhang, Bruce L. Levine, Yangbing Zhao, and Julia Tchou

Abstract

S3. Serial quantification of serum IL6 from a patient with prolonged subjectove myalgia post IT injection of mRNA c-Met CAR T cells.

Published
2023

25. Figures S1 - S5 from Safety and Efficacy of Intratumoral Injections of Chimeric Antigen Receptor (CAR) T Cells in Metastatic Breast Cancer

Author

Carl H. June, Robert H. Vonderheide, Lynn M. Schuchter, Laurence J. Cooper, Amy S. Clark, Angela M. DeMichele, Jennifer M. Matro, Robert H. Pierce, Jean Campbell, Shannon McGettigan, Regina M. Young, Gabriela Plesa, Jose R. Conejo-Garcia, Alycia So, Austin D. Williams, Avery D. Posey, Simon F. Lacey, Xiaojun Liu, Andrea L Brennan, Irina Kulikovskaya, Jan Joseph Melenhorst, Megan M. Davis, Paul J Zhang, Bruce L. Levine, Yangbing Zhao, and Julia Tchou

Abstract

S1. Clinical trial schema. S2. Representative immunohistochemistry (IHC). S3. Histology and IHC of tumor tissue pre and post intratumoral injection of RNA CAR T c- Met from one patient. S4. Histology and IHC of tumor tissue pre and post intratumoral injection with lidocaine (1 mL) and RNA CAR T c-Met (1 mL) from another patient. S5. Characterization of CD68+ tumor infiltrated immune cells using multiplex IHC analyses as described (1) in pre and post IT injection of RNA CAR T c-Met tumor tissue sections from two patients.

Published
2023

26. Data from Safety and Efficacy of Intratumoral Injections of Chimeric Antigen Receptor (CAR) T Cells in Metastatic Breast Cancer

Author

Carl H. June, Robert H. Vonderheide, Lynn M. Schuchter, Laurence J. Cooper, Amy S. Clark, Angela M. DeMichele, Jennifer M. Matro, Robert H. Pierce, Jean Campbell, Shannon McGettigan, Regina M. Young, Gabriela Plesa, Jose R. Conejo-Garcia, Alycia So, Austin D. Williams, Avery D. Posey, Simon F. Lacey, Xiaojun Liu, Andrea L Brennan, Irina Kulikovskaya, Jan Joseph Melenhorst, Megan M. Davis, Paul J Zhang, Bruce L. Levine, Yangbing Zhao, and Julia Tchou

Abstract

Chimeric antigen receptors (CAR) are synthetic molecules that provide new specificities to T cells. Although successful in treatment of hematologic malignancies, CAR T cells are ineffective for solid tumors to date. We found that the cell-surface molecule c-Met was expressed in ∼50% of breast tumors, prompting the construction of a CAR T cell specific for c-Met, which halted tumor growth in immune-incompetent mice with tumor xenografts. We then evaluated the safety and feasibility of treating metastatic breast cancer with intratumoral administration of mRNA-transfected c-Met-CAR T cells in a phase 0 clinical trial (NCT01837602). Introducing the CAR construct via mRNA ensured safety by limiting the nontumor cell effects (on-target/off-tumor) of targeting c-Met. Patients with metastatic breast cancer with accessible cutaneous or lymph node metastases received a single intratumoral injection of 3 × 107 or 3 × 108 cells. CAR T mRNA was detectable in peripheral blood and in the injected tumor tissues after intratumoral injection in 2 and 4 patients, respectively. mRNA c-Met-CAR T cell injections were well tolerated, as none of the patients had study drug–related adverse effects greater than grade 1. Tumors treated with intratumoral injected mRNA c-Met-CAR T cells were excised and analyzed by immunohistochemistry, revealing extensive tumor necrosis at the injection site, cellular debris, loss of c-Met immunoreactivity, all surrounded by macrophages at the leading edges and within necrotic zones. We conclude that intratumoral injections of mRNA c-Met-CAR T cells are well tolerated and evoke an inflammatory response within tumors. Cancer Immunol Res; 5(12); 1152–61. ©2017 AACR.

Published
2023

27. Supplementary Figures 1-5 and Supplementary Tables 1-3 from T-cell Localization, Activation, and Clonal Expansion in Human Pancreatic Ductal Adenocarcinoma

Author

Sunil R. Hingorani, Philip D. Greenberg, Robert H. Pierce, Ayaka Hulbert, and Ingunn M. Stromnes

Abstract

S1. TLS composition and immunological features of resected PDA. S2. Gating strategy for analyzing CD244 (2B4) and Tim3 expression on CD8 T cells in blood of normal individuals (Nl), in blood of PDA patients (PDA blood) and in tumors. S3. Representative human PDA section stained with the multiplex immunohistochemical panel. S4. Representative images of human PDA from the multiplex without (top row, A and B) and with (bottom, C and D), the stromal vs. tumor regions demarcated and cell numbers quantified. S5. PD-L1+ stromal cells in PDA include CD163+ macrophages (Figure 6A) as well as an additional CD163- cell subset shown here. Supplementary Table 1. Antibodies used for tissue multiplex in Figure 6. Supplementary Table 2. Patient characteristics. Supplementary Table 3. TCRβ CDR3 sequence data in blood and tumors from PDA patients.

Published
2023

29. Figure S5 from Intratumoral Plasmid IL12 Expands CD8+ T Cells and Induces a CXCR3 Gene Signature in Triple-negative Breast Tumors that Sensitizes Patients to Anti–PD-1 Therapy

Author

Erika J. Crosby, H. Kim Lyerly, Takuya Osada, Christopher G. Twitty, David A. Canton, Kellie Malloy Foerter, Jendy Sell, Kim Jaffe, Donna Bannavong, Lauren Svenson, Reneta Hermiz, Erica Browning, Robert H. Pierce, Mai Hope Le, Carmen Ballesteros-Merino, Shawn M. Jensen, Carlo B. Bifulco, Bernard A. Fox, Kaitlin Zablotsky, Chaitanya R. Acharya, Irene Wapnir, Hiroshi Nagata, and Melinda L. Telli

Abstract

Figure S5

Published
2023

30. Data from Neoadjuvant Therapy Induces a Potent Immune Response to Sarcoma, Dominated by Myeloid and B Cells

Author

Seth M. Pollack, Teresa S. Kim, Natalie A. LaFranzo, Kevin C. Flanagan, Jon Earls, Terrill K. McClanahan, Wendy M. Blumenschein, Erin Murphy, Robin L. Jones, Elizabeth T. Loggers, Michael J. Wagner, Lee D. Cranmer, Matthew J. Thompson, Robert Ricciotti, Eleanor Y. Chen, Jose G. Mantilla, Gabrielle M. Kane, Stephanie K. Schaub, Edward Y. Kim, Qianchuan He, Yuzheng Zhang, Robert H. Pierce, Jean S. Campbell, Kimberly S. Smythe, Y. David Seo, Matthew B. Spraker, Bonnie J. LaFleur, Laura Riolobos, and Peter H. Goff

Abstract

Purpose:To characterize changes in the soft-tissue sarcoma (STS) tumor immune microenvironment induced by standard neoadjuvant therapy with the goal of informing neoadjuvant immunotherapy trial design.Experimental Design:Paired pre- and postneoadjuvant therapy specimens were retrospectively identified for 32 patients with STSs and analyzed by three modalities: multiplexed IHC, NanoString, and RNA sequencing with ImmunoPrism analysis.Results:All 32 patients, representing a variety of STS histologic subtypes, received neoadjuvant radiotherapy and 21 (66%) received chemotherapy prior to radiotherapy. The most prevalent immune cells in the tumor before neoadjuvant therapy were myeloid cells (45% of all immune cells) and B cells (37%), with T (13%) and natural killer (NK) cells (5%) also present. Neoadjuvant therapy significantly increased the total immune cells infiltrating the tumors across all histologic subtypes for patients receiving neoadjuvant radiotherapy with or without chemotherapy. An increase in the percentage of monocytes and macrophages, particularly M2 macrophages, B cells, and CD4+ T cells was observed postneoadjuvant therapy. Upregulation of genes and cytokines associated with antigen presentation was also observed, and a favorable pathologic response (≥90% necrosis postneoadjuvant therapy) was associated with an increase in monocytic infiltrate. Upregulation of the T-cell checkpoint TIM3 and downregulation of OX40 were observed posttreatment.Conclusions:Standard neoadjuvant therapy induces both immunostimulatory and immunosuppressive effects within a complex sarcoma microenvironment dominated by myeloid and B cells. This work informs ongoing efforts to incorporate immune checkpoint inhibitors and novel immunotherapies into the neoadjuvant setting for STSs.

Published
2023

31. Supplementary Figure 1 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Figure 1. Supplementary Figure 1 shows the staining pattern of tumoral PD-L1 staining.

Published
2023

32. Supplementary Tables S1-2, Figure 1 from Phase I Study of Pembrolizumab (MK-3475; Anti–PD-1 Monoclonal Antibody) in Patients with Advanced Solid Tumors

Author

Anthony W. Tolcher, Robert Iannone, Manfred Lehnert, Omar Laterza, Dianna Wu, Jennifer H. Yearley, Robert H. Pierce, Xiaoyun Nicole Li, Jill A. Lindia, Adil Daud, Liliana Delgado, Kevin Gergich, Guillermo Espino, Lon Smith, Cong Chen, Ronald Drengler, Muralidhar Beeram, Jeroen Elassaiss-Schaap, Kyriakos P. Papadopoulos, Drew Rasco, S. Peter Kang, and Amita Patnaik

Abstract

Supplementary Tables S1-2, Figure 1. Supplementary Table S1. Matrix view of Part A-2 dose titration and PK sampling scheme. Supplementary Table S2. Efficacy outcomes by investigator review per RECIST v1.1. Supplementary Figure 1. Seventeen patients were tested with IFN-γ ELISPOT assay.

Published
2023

33. Supplementary Figure 2 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Figure 2. Supplementary Figure 2 shows tumoral PD-L1 staining in association with PD-1, CD8, and CD4 TILs.

Published
2023

34. Supplementary Figure 5 from Mobilization of CD8+ T Cells via CXCR4 Blockade Facilitates PD-1 Checkpoint Therapy in Human Pancreatic Cancer

Author

Venu G. Pillarisetty, Harlan Robins, Robert H. Pierce, Ian Nicholas Crispe, Raymond Yeung, Teresa S. Kim, Seth M. Pollack, Sara K. Daniel, James O. Park, Marissa Vignali, Arezou Abbasi, Kimberly S. Smythe, Florencia G. Jalikis, Kevin M. Sullivan, Xiuyun Jiang, and Yongwoo David Seo

Abstract

Live microscopy analysis of CD8+ T cell distribution in slice cultures

Published
2023

35. Supplementary Figures 3-9 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Figures 3-9. Supplementary Figure 3. Representative multi-color immunofluorescence staining shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 4. Representative multi-color immunofluorescence staining of a PD-L1 negative tumor shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 5. CD4+ T cells show markedly more specific PD-L1 localization in OTSCC tumors compared to CD8+ T cells. Supplementary Figure 6. Representative multi-color immunofluorescence staining of an OTSCC tumor shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 7. Higher magnification multi-color immunofluorescence staining of a representative OTSCC tumor stained with PD-L1, PD-1, CD4, and CD8. Supplementary Figure 8. Diffuse tumoral PD-L1 staining shows low infiltration of CD4+ and CD8+ T cells. Supplementary Figure 9. Representative multi-color immunofluorescence staining of FoxP3, PD1, and Ki67 in OTSCC.

Published
2023

36. Table S1 from Intratumoral Plasmid IL12 Expands CD8+ T Cells and Induces a CXCR3 Gene Signature in Triple-negative Breast Tumors that Sensitizes Patients to Anti–PD-1 Therapy

Author

Erika J. Crosby, H. Kim Lyerly, Takuya Osada, Christopher G. Twitty, David A. Canton, Kellie Malloy Foerter, Jendy Sell, Kim Jaffe, Donna Bannavong, Lauren Svenson, Reneta Hermiz, Erica Browning, Robert H. Pierce, Mai Hope Le, Carmen Ballesteros-Merino, Shawn M. Jensen, Carlo B. Bifulco, Bernard A. Fox, Kaitlin Zablotsky, Chaitanya R. Acharya, Irene Wapnir, Hiroshi Nagata, and Melinda L. Telli

Abstract

Table S1

Published
2023

37. Supplementary Table 1 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Table 1. Supplementary Table 1 shows the immunohistochemical staining for PD-L1, PD-1, CD4, and CD8 in the samples analyzed in the manuscript.

Published
2023

38. Supplementary Table 2 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Table 2. Supplementary Table 2 shows that the proliferative capacity of PD-1 expressing CD8, CD4, and FoxP3+ TILs are decreased compared to non-PD-1 expressing TILs in OTSCC.

Published
2023

39. Supplementary Data from Neoadjuvant Therapy Induces a Potent Immune Response to Sarcoma, Dominated by Myeloid and B Cells

Author

Seth M. Pollack, Teresa S. Kim, Natalie A. LaFranzo, Kevin C. Flanagan, Jon Earls, Terrill K. McClanahan, Wendy M. Blumenschein, Erin Murphy, Robin L. Jones, Elizabeth T. Loggers, Michael J. Wagner, Lee D. Cranmer, Matthew J. Thompson, Robert Ricciotti, Eleanor Y. Chen, Jose G. Mantilla, Gabrielle M. Kane, Stephanie K. Schaub, Edward Y. Kim, Qianchuan He, Yuzheng Zhang, Robert H. Pierce, Jean S. Campbell, Kimberly S. Smythe, Y. David Seo, Matthew B. Spraker, Bonnie J. LaFleur, Laura Riolobos, and Peter H. Goff

Abstract

Supplementary Data from Neoadjuvant Therapy Induces a Potent Immune Response to Sarcoma, Dominated by Myeloid and B Cells

Published
2023

40. Figure S1 from Phase I Study of Pembrolizumab (MK-3475; Anti–PD-1 Monoclonal Antibody) in Patients with Advanced Solid Tumors

Author

Anthony W. Tolcher, Robert Iannone, Manfred Lehnert, Omar Laterza, Dianna Wu, Jennifer H. Yearley, Robert H. Pierce, Xiaoyun Nicole Li, Jill A. Lindia, Adil Daud, Liliana Delgado, Kevin Gergich, Guillermo Espino, Lon Smith, Cong Chen, Ronald Drengler, Muralidhar Beeram, Jeroen Elassaiss-Schaap, Kyriakos P. Papadopoulos, Drew Rasco, S. Peter Kang, and Amita Patnaik

Abstract

Figure S1. Seventeen patients were tested with IFN-γ ELISPOT assay.

Published
2023

41. Supplementary Figure from Neoadjuvant Therapy Induces a Potent Immune Response to Sarcoma, Dominated by Myeloid and B Cells

Author

Seth M. Pollack, Teresa S. Kim, Natalie A. LaFranzo, Kevin C. Flanagan, Jon Earls, Terrill K. McClanahan, Wendy M. Blumenschein, Erin Murphy, Robin L. Jones, Elizabeth T. Loggers, Michael J. Wagner, Lee D. Cranmer, Matthew J. Thompson, Robert Ricciotti, Eleanor Y. Chen, Jose G. Mantilla, Gabrielle M. Kane, Stephanie K. Schaub, Edward Y. Kim, Qianchuan He, Yuzheng Zhang, Robert H. Pierce, Jean S. Campbell, Kimberly S. Smythe, Y. David Seo, Matthew B. Spraker, Bonnie J. LaFleur, Laura Riolobos, and Peter H. Goff

Abstract

Supplementary Figure from Neoadjuvant Therapy Induces a Potent Immune Response to Sarcoma, Dominated by Myeloid and B Cells

Published
2023

42. Supplementary Figure Legends from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains the figure legends for supplementary figures 1-9. Supplementary Figure 1. Staining pattern of tumoral PD-L1 staining. Supplementary Figure 2. Tumoral PD-L1 staining in association with PD-1, CD8, and CD4 TILs. Supplementary Figure 3. Representative multi-color immunofluorescence staining shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 4. Representative multi-color immunofluorescence staining of a PD-L1 negative tumor shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 5. CD4+ T cells show markedly more specific PD-L1 localization in OTSCC tumors compared to CD8+ T cells. Supplementary Figure 6. Representative multi-color immunofluorescence staining of an OTSCC tumor shows that PD-1+CD4+ T cells demonstrate greater PD-1 expression than PD1+CD8+ T cells. Supplementary Figure 7. Higher magnification multi-color immunofluorescence staining of a representative OTSCC tumor stained with PD-L1, PD-1, CD4, and CD8. Supplementary Figure 8. Diffuse tumoral PD-L1 staining shows low infiltration of CD4+ and CD8+ T cells. Supplementary Figure 9. Representative multi-color immunofluorescence staining of FoxP3, PD1, and Ki67 in OTSCC.

Published
2023

43. Data from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

Oral tongue squamous cell carcinoma (OTSCC) is the most common oral cavity tumor. In this study, we examined the basis for the activity of programmed cell death protein (PD-1)-based immune checkpoint therapy that is being explored widely in head and neck cancers. Using multispectral imaging, we systematically investigated the OTSCC tumor microenvironment (TME) by evaluating the frequency of PD-1 expression in CD8+, CD4+, and FoxP3+ tumor-infiltrating lymphocytes (TIL). We also defined the cellular sources of PD-1 ligand (PD-L1) to evaluate the utility of PD-1:PD-L1 blocking antibody therapy in this patient population. PD-L1 was expressed in 79% of the OTSCC specimens examined within the TME. Expression of PD-L1 was associated with moderate to high levels of CD4+ and CD8+ TILs. We found that CD4+ TILs were present in equal or greater frequencies than CD8+ TILs in 94% of OTSCC and that CD4+FOXP3neg TILs were colocalized with PD-1/PD-L1/CD68 more frequently than CD8+ TILs. Both CD4+PD1+ and CD8+PD1+ TILs were anergic in the setting of PD-L1 expression. Overall, our results highlight the importance of CD4+ TILs as pivotal regulators of PD-L1 levels and in determining the responsiveness of OTSCC to PD1-based immune checkpoint therapy. Cancer Res; 77(22); 6365–74. ©2017 AACR.

Published
2023

44. Data from Phase I Study of Pembrolizumab (MK-3475; Anti–PD-1 Monoclonal Antibody) in Patients with Advanced Solid Tumors

Author

Anthony W. Tolcher, Robert Iannone, Manfred Lehnert, Omar Laterza, Dianna Wu, Jennifer H. Yearley, Robert H. Pierce, Xiaoyun Nicole Li, Jill A. Lindia, Adil Daud, Liliana Delgado, Kevin Gergich, Guillermo Espino, Lon Smith, Cong Chen, Ronald Drengler, Muralidhar Beeram, Jeroen Elassaiss-Schaap, Kyriakos P. Papadopoulos, Drew Rasco, S. Peter Kang, and Amita Patnaik

Abstract

Purpose: This phase I study evaluated the safety, maximum tolerated dose, antitumor activity, and pharmacokinetics and pharmacodynamics of pembrolizumab in patients with advanced solid tumors.Experimental Design: In a 3 + 3 dose escalation study, 10 patients received pembrolizumab 1, 3, or 10 mg/kg intravenously every 2 weeks until progression or intolerable toxicity. Seven additional patients received 10 mg/kg every 2 weeks. Thirteen patients participated in a 3-week intrapatient dose escalation (dose range, 0.005–10 mg/kg) followed by 2 or 10 mg/kg every 3 weeks. Tumor response was assessed by Response Evaluation Criteria in Solid Tumors (RECIST) version 1.1.Results: No dose-limiting toxicities were observed. Maximum administered dose was 10 mg/kg every 2 weeks. One patient with melanoma and one with Merkel cell carcinoma experienced complete responses of 57 and 56+ weeks' duration, respectively. Three patients with melanoma experienced partial responses. Fifteen patients with various malignancies experienced stable disease. One patient died of cryptococcal infection 92 days after pembrolizumab discontinuation, following prolonged corticosteroid use for grade 2 gastritis considered drug related. Pembrolizumab exhibited pharmacokinetic characteristics typical of humanized monoclonal antibodies. Maximum serum target engagement was reached with trough levels of doses greater than or equal to 1 mg/kg every 3 weeks. Mechanism-based translational models with a focus on intratumor exposure prediction suggested robust clinical activity would be observed at doses ≥2 mg/kg every 3 weeks.Conclusions: Pembrolizumab was well tolerated and associated with durable antitumor activity in multiple solid tumors. The lowest dose with full potential for antitumor activity was 2 mg/kg every 3 weeks. Clin Cancer Res; 21(19); 4286–93. ©2015 AACR.See related commentary by van Elsas et al., p. 4251

Published
2023

45. Supplementary Figure 3 from Mobilization of CD8+ T Cells via CXCR4 Blockade Facilitates PD-1 Checkpoint Therapy in Human Pancreatic Cancer

Author

Venu G. Pillarisetty, Harlan Robins, Robert H. Pierce, Ian Nicholas Crispe, Raymond Yeung, Teresa S. Kim, Seth M. Pollack, Sara K. Daniel, James O. Park, Marissa Vignali, Arezou Abbasi, Kimberly S. Smythe, Florencia G. Jalikis, Kevin M. Sullivan, Xiuyun Jiang, and Yongwoo David Seo

Abstract

PDA tumor slice culture platform utilized for multimodal analysis before and after ex vivo immune modulation

Published
2023

46. Supplementary methods from Intratumoral Plasmid IL12 Expands CD8+ T Cells and Induces a CXCR3 Gene Signature in Triple-negative Breast Tumors that Sensitizes Patients to Anti–PD-1 Therapy

Author

Erika J. Crosby, H. Kim Lyerly, Takuya Osada, Christopher G. Twitty, David A. Canton, Kellie Malloy Foerter, Jendy Sell, Kim Jaffe, Donna Bannavong, Lauren Svenson, Reneta Hermiz, Erica Browning, Robert H. Pierce, Mai Hope Le, Carmen Ballesteros-Merino, Shawn M. Jensen, Carlo B. Bifulco, Bernard A. Fox, Kaitlin Zablotsky, Chaitanya R. Acharya, Irene Wapnir, Hiroshi Nagata, and Melinda L. Telli

Abstract

Supplementary methods

Published
2023

48. Supplementary Table 3 from PD-1 Expression in Head and Neck Squamous Cell Carcinomas Derives Primarily from Functionally Anergic CD4+ TILs in the Presence of PD-L1+ TAMs

Author

Sara I. Pai, Neil M. Iyengar, Mark C. Poznansky, Huabiao Chen, Yang C. Zeng, Lauren Johnson, Patrick D. Chakravarty, Eiichi Ishida, Armida Lefranc-Torres, Lori J. Wirth, Derrick T. Lin, Luc G. Morris, Thomas J. Diefenbach, William C. Faquin, Ronald Ghossein, Robert H. Pierce, William H. Westra, Jina Lee, and Austin K. Mattox

Abstract

This file contains Supplementary Table 3. Supplementary Table 3 shows the clinicopathological characteristics of the patient cohort.

Published
2023

49. Data from Mobilization of CD8+ T Cells via CXCR4 Blockade Facilitates PD-1 Checkpoint Therapy in Human Pancreatic Cancer

Author

Venu G. Pillarisetty, Harlan Robins, Robert H. Pierce, Ian Nicholas Crispe, Raymond Yeung, Teresa S. Kim, Seth M. Pollack, Sara K. Daniel, James O. Park, Marissa Vignali, Arezou Abbasi, Kimberly S. Smythe, Florencia G. Jalikis, Kevin M. Sullivan, Xiuyun Jiang, and Yongwoo David Seo

Abstract

Purpose:Pancreatic ductal adenocarcinoma (PDA) is rarely cured, and single-agent immune checkpoint inhibition has not demonstrated clinical benefit despite the presence of large numbers of CD8+ T cells. We hypothesized that tumor-infiltrating CD8+ T cells harbor latent antitumor activity that can be reactivated using combination immunotherapy.Experimental Design:Preserved human PDA specimens were analyzed using multiplex IHC (mIHC) and T-cell receptor (TCR) sequencing. Fresh tumor was treated in organotypic slice culture to test the effects of combination PD-1 and CXCR4 blockade. Slices were analyzed using IHC, flow cytometry, and live fluorescent microscopy to assess tumor kill, in addition to T-cell expansion and mobilization.Results:mIHC demonstrated fewer CD8+ T cells in juxtatumoral stroma containing carcinoma cells than in stroma devoid of them. Using TCR sequencing, we found clonal expansion in each tumor; high-frequency clones had multiple DNA rearrangements coding for the same amino acid binding sequence, which suggests response to common tumor antigens. Treatment of fresh human PDA slices with combination PD-1 and CXCR4 blockade led to increased tumor cell death concomitant with lymphocyte expansion. Live microscopy after combination therapy demonstrated CD8+ T-cell migration into the juxtatumoral compartment and rapid increase in tumor cell apoptosis.Conclusions:Endogenous tumor-reactive T cells are present within the human PDA tumor microenvironment and can be reactivated by combined blockade of PD-1 and CXCR4. This provides a new basis for the rational selection of combination immunotherapy for PDA.See related commentary by Medina and Miller, p. 3747

Published
2023

50. Supplementary Data from Intratumoral Delivery of Plasmid IL12 Via Electroporation Leads to Regression of Injected and Noninjected Tumors in Merkel Cell Carcinoma

Author

Paul Nghiem, Adil I. Daud, Richard Heller, Robert H. Pierce, Sharron Gargosky, Mai H. Le, Jean S. Campbell, Christopher G. Twitty, Upendra Parvathaneni, David R. Byrd, Astrid Blom, Dafina Ibrani, Jayasri G. Iyer, Rima Kulikauskas, Natalie J. Miller, Natalie V. Longino, and Shailender Bhatia

Abstract

Figure S1, Table S1, Table S2

Published
2023

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