Your search keyword '"Richard Carvajal"' showing total 5 results

1. Angiopoietin-2-dependent spatial vascular destabilization promotes T-cell exclusion and limits immunotherapy in melanoma

Author

Ha-Ram Park, Anahita Shiva, Portia Cummings, Seoyeon Kim, Sungsoo Kim, Eunhyeong Lee, Alessandra Leong, Subrata Chowdhury, Carrie Shawber, Richard Carvajal, Gavin Thurston, Joon Yong An, Amanda W. Lund, Hee Won Yang, and Minah Kim

Subjects

Cancer Research, Oncology

Abstract

T cell position in the tumor microenvironment determines the probability of target encounter and tumor killing. CD8+ T cell exclusion from the tumor parenchyma is associated with poor response to immunotherapy, and yet the biology that underpins this distinct pattern remains unclear. Here we show that the vascular destabilizing factor angiopoietin-2 (ANGPT2) causes compromised vascular integrity in the tumor periphery, leading to impaired T cell infiltration to the tumor core. The spatial regulation of ANGPT2 in whole tumor cross-sections was analyzed in conjunction with T cell distribution, vascular integrity, and response to immunotherapy in syngeneic murine melanoma models. T cell exclusion was associated with ANGPT2 upregulation and elevated vascular leakage at the periphery of human and murine melanomas. Both pharmacological and genetic blockade of ANGPT2 promoted CD8+ T cell infiltration into the tumor core, exerting antitumor effects. Importantly, the reversal of T cell exclusion following ANGPT2 blockade not only enhanced response to anti-PD-1 immune checkpoint blockade therapy in immunogenic, therapy responsive mouse melanomas, but it also rendered non-responsive tumors susceptible to immunotherapy. Therapeutic response after ANGPT2 blockade, driven by improved CD8+ T cell infiltration to the tumor core, coincided with spatial TIE2 signaling activation and increased vascular integrity at the tumor periphery where endothelial expression of adhesion molecules was reduced. These data highlight ANGPT2/TIE2 signaling as a key mediator of T cell exclusion and a promising target to potentiate immune checkpoint blockade efficacy in melanoma.

Published

2023

2. Abstract 5881: PERIO-01: Initial safety experience and immunologic effects of a Class C TLR9 agonist using pressure- enabled drug delivery in a phase 1 trial of hepatic arterial infusion of SD-101 +/- checkpoint inhibition in metastatic uveal melanoma

Author

Sapna P. Patel, Cara Haymaker, Rahul A. Sheth, Joshua D. Kuban, Joshua Weintraub, Eric Wehrenberg-Klee, Paula Novelli, Carin Gonsalves, Robert Adamo, Virgina Honaker, Laura Timciuc, Tarin Hennegan, Juan C. Amador Molina, Dzifa Duose, Edwin R. Parras Cuenta, Anthony Lucci, Salyna Meas, Vanessa Sarli, Victor G. Prieto, Jason LaPorte, Ann-Marie Hulstine, Ashley Moody, Bryan Cox, David Geller, Diwakar Davar, Kamaneh Montazeri, Marlana Orloff, Steven C. Katz, and Richard Carvajal

Subjects

Cancer Research, Oncology

Abstract

Immune checkpoint inhibitors (ICI) have demonstrated limited success in patients with metastatic uveal melanoma (MUM) with liver involvement due to an immunosuppressive tumor microenvironment (TME) driven in part by myeloid-derived suppressor cells (MDSCs). Toll-like receptor-9 agonists (TLR-9A) have improved ICI response rates in cutaneous melanoma, but delivery challenges have limited their application for MUM. Hepatic arterial infusion (HAI) of TLR-9A using a pressure-enabled drug deliveryTM (PEDDTM) device has the potential to enhance responsiveness to ICI by optimizing delivery to intrahepatic tumors and reprogramming the TME, including elimination of MDSCs.PERIO-01 is an open-label first-in-human Phase 1 trial of SD-101 given by HAI using a PEDDTM in MUM (NCT04935229). The study consists of dose-escalation cohorts of single agent SD-101 alone and with ICI. SD-101 is delivered over 2 cycles, with 3 weekly doses per cycle. Research blood, tumor and normal liver biopsies are collected serially for correlative studies. At data cutoff, a total of 20 patients were enrolled, with 13 in the single agent dose escalation cohort (2, 4, and 8 mg) and 7 patients with SD-101 (2 mg) + nivolumab. The median age was 65.5 years with an equal gender distribution. Only 2 patients were treatment-naïve and the median number of liver metastases was 5.1. The average number of SD-101 infusions was 5.2. One patient in the combination cohort experienced a serious adverse event related to treatment - asymptomatic Grade 3 increase in liver enzymes. PEDDTM resulted in high drug levels in the liver (up to 2,340 ng/ml at 8mg) with only transient exposure in the periphery ( Citation Format: Sapna P. Patel, Cara Haymaker, Rahul A. Sheth, Joshua D. Kuban, Joshua Weintraub, Eric Wehrenberg-Klee, Paula Novelli, Carin Gonsalves, Robert Adamo, Virgina Honaker, Laura Timciuc, Tarin Hennegan, Juan C. Amador Molina, Dzifa Duose, Edwin R. Parras Cuenta, Anthony Lucci, Salyna Meas, Vanessa Sarli, Victor G. Prieto, Jason LaPorte, Ann-Marie Hulstine, Ashley Moody, Bryan Cox, David Geller, Diwakar Davar, Kamaneh Montazeri, Marlana Orloff, Steven C. Katz, Richard Carvajal. PERIO-01: Initial safety experience and immunologic effects of a Class C TLR9 agonist using pressure- enabled drug delivery in a phase 1 trial of hepatic arterial infusion of SD-101 +/- checkpoint inhibition in metastatic uveal melanoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5881.

Published

2023

3. Abstract 3876: Kinetics of RTK activation determine ERK signaling dynamics and resistance to BRAF and MEK inhibitors

Author

Sungsoo Kim, Richard Carvajal, Minah Kim, and Hee Won Yang

Subjects

Cancer Research, Oncology

Abstract

Combination treatment of BRAF inhibitor (BRAFi) and MEK inhibitor (MEKi) produces remarkable response rates and is expected to prevent ERK activation in BRAF-mutant melanoma. However, sporadic ERK reactivation occurs in melanoma models, and efficacy is severely limited by the emergence of drug resistance. The underlying molecular mechanisms that drive ERK reactivation and adaptation to BRAFi/MEKi remain elusive. Here, using single-cell imaging and optogenetic approaches, we show that the strength and duration of receptor tyrosine kinase (RTK) activation determines ERK reactivation and the development of BRAFi/MEKi-resistant cells. Single-cell data reveal that despite global RTK activation by the same external stimuli, only small subsets of melanoma cells induce effective RTK and ERK activation to develop BRAFi/MEKi resistance. Furthermore, by directly controlling RTK activity, we demonstrate that the kinetics of RTK activation determine ERK signaling dynamics and the percentage of drug-resistant cells. While these drug-resistant cells are rare during early stages of drug treatment, they eventually become the dominant population through sustained RTK-mediated ERK activation that drives cell proliferation. Thus, RTK activation in established drug-resistant cells causes effective ERK activation and cell proliferation. Importantly, limiting RTK signaling activation reverses the BRAFi/MEKi-resistant state. We show that targeting SHP2, a mediator of RTK signaling, effectively suppresses RTK-mediated ERK activation and cell proliferation in BRAFi/MEKi-resistant cells. Our results provide mechanistic insights into the contribution of heterogeneity in RTK activation kinetics to ERK reactivation and BRAFi/MEKi resistance, also highlighting SHP2 activity as a promising target to overcome drug resistance in BRAF-mutant melanoma. Citation Format: Sungsoo Kim, Richard Carvajal, Minah Kim, Hee Won Yang. Kinetics of RTK activation determine ERK signaling dynamics and resistance to BRAF and MEK inhibitors. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3876.

Published

2023

4. Abstract 4588: Vascular regulation of T-cell exclusion in melanoma

Author

Ha-Ram Park, Anahita Shiva, Portia Cummings, Richard Carvajal, Gavin Thurston, Joon-Yong An, Amanda W. Lund, Hee Won Yang, and Minah Kim

Subjects

Cancer Research, Oncology

Abstract

T-cell position in the tumor microenvironment determines the probability of target encounter and tumor killing. CD8+ T-cell exclusion from the tumor parenchyma is associated with poor response to immunotherapy and yet the biology that underpins this distinct pattern remains unclear. Here we show that the vascular destabilizing factor angiopoietin-2 (ANGPT2) causes compromised vascular integrity in the tumor periphery, leading to impaired T-cell infiltration within tumor. We analyzed the spatial regulation of ANGPT2 in whole tumor cross-sections and its impact on CD8+ T-cell position, vascular integrity, and response to immunotherapy using syngeneic murine melanomas. We found that T-cell exclusion was associated with peritumoral expression of ANGPT2 and elevated vascular leakage in human and murine melanomas. Both pharmacological and genetic blockade of ANGPT2 promoted CD8+ T-cell infiltration to the tumor core, exerting antitumor effects. Importantly, the reversal of T-cell exclusion following ANGPT2 blockade not only enhanced response to anti-PD-1 therapy in immunogenic, therapy responsive mouse melanomas, but also rendered non-responsive tumors susceptible. Therapeutic response after ANGPT2 blockade, driven by improved CD8+ T-cell infiltration, coincided with TIE2 signaling activation and increased vascular integrity in the tumor periphery, indicating that maintenance of vascular integrity within tumors is necessary for robust response to immunotherapy. These data highlight ANGPT2/TIE2 signaling as a key mediator of T-cell exclusion and a promising target to potentiate checkpoint inhibitor efficacy in melanoma. Citation Format: Ha-Ram Park, Anahita Shiva, Portia Cummings, Richard Carvajal, Gavin Thurston, Joon-Yong An, Amanda W. Lund, Hee Won Yang, Minah Kim. Vascular regulation of T-cell exclusion in melanoma. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 4588.

Published

2023

5. Abstract 984: Dissecting the ecosystem of treatment-naïve melanoma brain metastasis using multi-modal single-cell analysis

Author

Johannes C. Melms, Jana Biermann, Amit Dipak Amin, Yiping Wang, Somnath Tagore, Massimo Andreatta, Ajay Nair, Meri Rogava, Patricia Ho, Lindsay A. Caprio, Zachary H. Walsh, Shivem Shah, Daniel H. Vacarro, Blake Caldwell, Adrienne M. Luoma, Joseph Driver, Matthew Ingham, Suthee Rapisuwon, Jennifer Wargo, Craig L. Slinguff, Evan Z. Macosco, Fei Chen, Richard Carvajal, Michael B. Atkins, Michael A. Davies, Elham Azizi, Santiago J. Carmona, Hanina Hibshoosh, Peter D. Canoll, Jeffrey N. Bruce, Wenya L. Bi, Gary K. Schwartz, and Benjamin Izar

Subjects

Cancer Research, Oncology

Abstract

Brain metastases are the most frequent malignancies in the brain and are associated with significant morbidity and mortality. Melanoma brain metastases (MBM) occur in most patients with advanced melanoma and are challenging to treat. Our understanding of the treatment-naïve landscape of MBM is still rudimentary, and there are no site-specific molecular therapies available. To gain comprehensive insights into the niche-specific biology of MBM, we performed multi-modal profiling of fresh and frozen samples using single-cell RNA-seq, single-cell TCR-seq, single-nuclei RNA-seq, and spatial transcriptional profiling. We evolved single-nucleus RNA-seq processing methods to enable profiling of minute amounts of archival, frozen specimens and compared data quality and structure between matched fresh and frozen MBM. We curated a treatment-naïve single-transcriptome atlas of MBM, collected either fresh samples over 1 year or profiled frozen samples dating back more than 15 years, and compared these samples to extracranial melanoma metastases (ECMM). In total, we profiled 25 samples with more than 114,000 transcriptomes. We identified more than 20 different cell types, including diverse tumor-infiltrating T-cell subsets and rare dendritic cell types, and tissue-specific cell types, such as activated microglia. Tumor cells in MBM showed an increase in copy number alterations (CNAs) compared to ECMM, which we validated using an external dataset of whole exome sequencing (WES) data including both MBM and ECMM. MBM-derived tumor cells show enrichment of genes involved in neuronal development and function, and site-specific metabolic programs (e.g., oxidative phosphorylation). Comparison with an external bulk RNA-seq dataset validated enriched key genes in MBM and ECMM as putative dependencies. We recovered cell-cell interactions between tumor and brain-resident cells involved in brain development, homeostasis, and disease. Similar to ECMM, the tumor microenvironment of MBM contained CD8+ T cells across a spectrum of differentiation, exhaustion and expansion, which was associated with loss of TCF7 expression and adoption of a TOX+ cell state. CD4+ T cells included T regulatory, T helper and T follicular-helper-like expression profiles. Plasma cells showed spatially localized expansion and limited heterogeneity. Myeloid cells largely adopted pro-tumorigenic cell states, including microglia, the brain-resident myeloid cells, which showed an activation trajectory characterized by expression of SPP1 (osteopontin). Spatial transcriptional analysis revealed restricted expression of antigen presentation genes with only a subset of these locations showing a type I interferon response. In summary, this work presents a multi-modal single-cell approach to dissect and compare the landscape of treatment-naïve MBM and ECMM. Citation Format: Johannes C. Melms, Jana Biermann, Amit Dipak Amin, Yiping Wang, Somnath Tagore, Massimo Andreatta, Ajay Nair, Meri Rogava, Patricia Ho, Lindsay A. Caprio, Zachary H. Walsh, Shivem Shah, Daniel H. Vacarro, Blake Caldwell, Adrienne M. Luoma, Joseph Driver, Matthew Ingham, Suthee Rapisuwon, Jennifer Wargo, Craig L. Slinguff, Evan Z. Macosco, Fei Chen, Richard Carvajal, Michael B. Atkins, Michael A. Davies, Elham Azizi, Santiago J. Carmona, Hanina Hibshoosh, Peter D. Canoll, Jeffrey N. Bruce, Wenya L. Bi, Gary K. Schwartz, Benjamin Izar. Dissecting the ecosystem of treatment-naïve melanoma brain metastasis using multi-modal single-cell analysis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 984.

Published

2022