Metastatic pancreatic neuroendocrine tumors feature elevated T cell infiltration
Jacques Greenberg, Jessica Limberg, Akanksha Verma, David Kim, Xiang Chen, Yeon J. Lee, Maureen D. Moore, Timothy M. Ullmann, Jessica W. Thiesmeyer, Zachary Loewenstein, Kevin J. Chen, Caitlin E. Egan, Dessislava Stefanova, Rohan Bareja, Rasa Zarnegar, Brendan M. Finnerty, Theresa Scognamiglio, Yi-Chieh Nancy Du, Olivier Elemento, Thomas J. Fahey III, Irene M. Min
Jacques Greenberg, Jessica Limberg, Akanksha Verma, David Kim, Xiang Chen, Yeon J. Lee, Maureen D. Moore, Timothy M. Ullmann, Jessica W. Thiesmeyer, Zachary Loewenstein, Kevin J. Chen, Caitlin E. Egan, Dessislava Stefanova, Rohan Bareja, Rasa Zarnegar, Brendan M. Finnerty, Theresa Scognamiglio, Yi-Chieh Nancy Du, Olivier Elemento, Thomas J. Fahey III, Irene M. Min
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Research Article Immunology Therapeutics

Metastatic pancreatic neuroendocrine tumors feature elevated T cell infiltration

Abstract

Pancreatic neuroendocrine tumors (PNETs) are malignancies arising from the islets of Langerhans. Therapeutic options are limited for the over 50% of patients who present with metastatic disease. We aimed to identify mechanisms to remodel the PNET tumor microenvironment (TME) to ultimately enhance susceptibility to immunotherapy. The TMEs of localized and metastatic PNETs were investigated using an approach that combines RNA-Seq, cancer and T cell profiling, and pharmacologic perturbations. RNA-Seq analysis indicated that the primary tumors of metastatic PNETs showed significant activation of inflammatory and immune-related pathways. We determined that metastatic PNETs featured increased numbers of tumor-infiltrating T cells compared with localized tumors. T cells isolated from both localized and metastatic PNETs showed evidence of recruitment and antigen-dependent activation, suggestive of an immune-permissive microenvironment. A computational analysis suggested that vorinostat, a histone deacetylase inhibitor, may perturb the transcriptomic signature of metastatic PNETs. Treatment of PNET cell lines with vorinostat increased chemokine CCR5 expression by NF-κB activation. Vorinostat treatment of patient-derived metastatic PNET tissues augmented recruitment of autologous T cells, and this augmentation was substantiated in a mouse model of PNET. Pharmacologic induction of chemokine expression may represent a promising approach for enhancing the immunogenicity of metastatic PNET TMEs.

Authors

Jacques Greenberg, Jessica Limberg, Akanksha Verma, David Kim, Xiang Chen, Yeon J. Lee, Maureen D. Moore, Timothy M. Ullmann, Jessica W. Thiesmeyer, Zachary Loewenstein, Kevin J. Chen, Caitlin E. Egan, Dessislava Stefanova, Rohan Bareja, Rasa Zarnegar, Brendan M. Finnerty, Theresa Scognamiglio, Yi-Chieh Nancy Du, Olivier Elemento, Thomas J. Fahey III, Irene M. Min

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Figure 6

Vorinostat regulates tumoral CCR5 expression via the NF-κB pathway, which augments T cell recruitment to PNET.

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Vorinostat regulates tumoral CCR5 expression via the NF-κB pathway, whic...
(A) Graphical representation of L1000 drug screen. (B) Cell growth assay of PNET cell lines upon exposure to vorinostat (n = 9 for each cell line from 3 independent experiments). (C and D) Representative flow cytometry plots of CCR5 expression. PNET cell lines were treated with subtoxic doses of vorinostat (vor). Fold increase of mean fluorescence intensity (MFI) was obtained by normalization of CCR5 expression in vor-treated cells by vehicle-treated (veh-treated) cells. Experiments were repeated at least 2 times independently (n = 4–5). (E) Model for vorinostat modulation of canonical STING and NF-κB pathways. Inhibitors MRT67307 (MRT) and TPCA-1 block STING and NF-κB pathways, respectively. (F) Measurement of NF-κB activity. PNET cell lines were treated with vor alone (+ and ++ indicates 0.1 μM and 0.5 μM, respectively) or in combination with MRT (200 nM) or TPCA-1 (20 μM). Luminescence units were normalized to veh-treated control group (n = 6–9 from 3 independent experiments). (G) RT-PCR analysis of CCR5 expression in BON-1 cells following 24-hour treatment with vor (0.1 μM), MRT (200 nM), and TPCA-1 (20 μM). Fold change was normalized to veh-treatment condition (n = 6 from 2 independent experiments). (H) Left: T cell migration assay was performed with fresh metastatic PNET tissue and patient-matched peripheral T cells. Right: Relative number of migrated T cells normalized to veh-treatment group. In treatment groups, PNET tissues were exposed to vorinostat (0.05 μM) for 72 hours prior to autologous T cell addition. Competitive CCR5 antagonist maraviroc (10 μM) or cGAMP (1 μM) was added, as indicated. Data were combined from 2 patients with metastatic PNETs (n = 4–7). Statistical analysis was performed using 1-way ANOVA with Tukey’s multiple-comparison test (*P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001). Data are shown as mean ± SEM.