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Tryptophan catabolism by the enzymes indoleamine 2,3-dioxygenase 1 and tryptophan 2,3-dioxygenase 2 (IDO/TDO) promotes immunosuppression across different cancer types. The tryptophan metabolite L-Kynurenine (Kyn) interacts with the ligand-activated transcription factor aryl hydrocarbon receptor (AHR) to drive the generation of Tregs and tolerogenic myeloid cells and PD-1 up-regulation in CD8 + T cells. Here, we show that the AHR pathway is selectively active in IDO/TDO-overexpressing tumors and is associated with resistance to immune checkpoint inhibitors. We demonstrate that IDO-Kyn-AHR-mediated immunosuppression depends on an interplay between Tregs and tumor-associated macrophages, which can be reversed by AHR inhibition. Selective AHR blockade delays progression in IDO/TDO-overexpressing tumors, and its efficacy is improved in combination with PD-1 blockade. Our findings suggest that blocking the AHR pathway in IDO/TDO expressing tumors would overcome the limitation of single IDO or TDO targeting agents and constitutes a personalized approach to immunotherapy, particularly in combination with immune checkpoint inhibitors. The tryptophan metabolite kynurenine is an endogenous ligand of the aryl hydrocarbon receptor (AHR). Here, the authors show that AHR targeting in IDO/TDO-expressing tumours counteracts a regulatory T cell/macrophage suppressive axis and synergizes with immune checkpoint blockade to hinder tumour growth.

In a comparison of tumors from patients with melanoma who benefitted from blockade of cytotoxic T-lymphocyte antigen 4 (CTLA-4) with tumors from patients who did not benefit, tumor neoantigens were detected that were strongly associated with a response. Immune checkpoint blockade has led to durable antitumor effects in patients with metastatic melanoma, non–small-cell lung cancer, and other tumor types, but the factors determining whether a patient will have a response remain elusive. 1 , 2 The fully human monoclonal antibodies ipilimumab and tremelimumab block cytotoxic T-lymphocyte antigen 4 (CTLA-4), resulting in T-cell activation. Some studies have established correlations between outcomes with ipilimumab and peripheral-blood lymphocyte count, markers of T-cell activation, 3 an “inflammatory” microenvironment, 4 , 5 and maintenance of high-frequency T-cell receptor clonotypes. 6 The relationship among the genomic landscape of the tumor, the mutational load, and the benefit from treatment remains obscure. . . .

Modulating T cell homeostatic mechanisms with checkpoint blockade can efficiently promote endogenous anti-tumor T cell responses1–11. However, many patients still do not benefit from checkpoint blockade12, highlighting the need for targeting of alternative immune pathways13. Glucocorticoid-induced tumor necrosis factor receptor-related protein (GITR) is an attractive target for immunotherapy, owing to its capacity to promote effector T cell (Teff) functions14,15 and hamper regulatory T cell (Treg) suppression16–20. On the basis of the potent preclinical anti-tumor activity of agonist anti-GITR antibodies, reported by us and others16,21,22, we initiated the first in-human phase 1 trial of GITR agonism with the anti-GITR antibody TRX518 (NCT01239134). Here, we report the safety profile and immune effects of TRX518 monotherapy in patients with advanced cancer and provide mechanistic preclinical evidence to rationally combine GITR agonism with checkpoint blockade in future clinical trials. We demonstrate that TRX518 reduces circulating and intratumoral Treg cells to similar extents, providing an easily assessable biomarker of anti-GITR activity. Despite Treg reductions and increased Teff:Treg ratios, substantial clinical responses were not seen. Similarly, in mice with advanced tumors, GITR agonism was not sufficient to activate cytolytic T cells due to persistent exhaustion. We demonstrate that T cell reinvigoration with PD-1 blockade can overcome resistance of advanced tumors to anti-GITR monotherapy. These findings led us to start investigating TRX518 with PD-1 pathway blockade in patients with advanced refractory tumors (NCT02628574).GITR agonism can be exploited in combination with checkpoint blockade to overcome immune refractoriness in solid tumors.

Background This study aimed to investigate the knowledge, attitudes, and practices (KAP) regarding whole-course management among patients with gastrointestinal (GI) cancers. Methods This cross-sectional study enrolled patients with GI cancers at the Inner Mongolia Hospital of Peking University Cancer Hospital between November 2023 and April 2024. Data were collected through a self-administered questionnaire, which captured demographic information and scores on KAP. Results A total of 408 participants were included in this study. The mean KAP scores were 10.62 ± 3.14 (out of a maximum of 15), 39.11 ± 4.94 (out of a maximum of 50), and 31.35 ± 5.60 (out of a maximum of 40), respectively. Knowledge was positively correlated with attitudes ( r  = 0.307, P  < 0.001) and practices ( r  = 0.417, P  < 0.001), while attitudes were positively correlated with practices ( r  = 0.383, P  < 0.001). The structural equation model indicated that knowledge influenced attitudes (β = 0.573, P  < 0.001) and practices (β = 0.466, P  < 0.001), while attitudes influenced practices (β = 0.525, P  < 0.001). Conclusions Patients with GI cancers demonstrated insufficient knowledge, moderate attitudes, and suboptimal practices regarding whole-course management. Improvements in practice could be achieved by enhancing knowledge and attitudes through specialized health education.

In addition to playing a major role in tumor cell biology, p53 generates a microenvironment that promotes antitumor immune surveillance via tumor-associated macrophages. We examined whether increasing p53 signaling in the tumor microenvironment influences antitumor T cell immunity. Our findings indicate that increased p53 signaling induced either pharmacologically with APR-246 (eprenetapopt) or in p53-overexpressing transgenic mice can disinhibit antitumor T cell immunity and augment the efficacy of immune checkpoint blockade. We demonstrated that increased p53 expression in tumor-associated macrophages induces canonical p53-associated functions such as senescence and activation of a p53 dependent senescence-associated secretory phenotype. This was linked with decreased expression of proteins associated with M2 polarization by tumor-associated macrophages. Our preclinical data led to the development of a clinical trial in patients with solid tumors combining APR-246 with pembrolizumab. Biospecimens from select patients participating in this ongoing trial showed that there was a suppression of M2-polarized myeloid cells and increase in T cell proliferation with therapy in those who responded to the therapy. Our findings, based on both genetic and a small molecule-based pharmacological approach, suggest that increasing p53 expression in tumor-associated macrophages reprograms the tumor microenvironment to augment the response to immune checkpoint blockade.

In vivo GITR ligation has previously been shown to augment T-cell-mediated anti-tumor immunity, yet the underlying mechanisms of this activity, particularly its in vivo effects on CD4+ foxp3+ regulatory T cells (Tregs), have not been fully elucidated. In order to translate this immunotherapeutic approach to the clinic it is important gain better understanding of its mechanism(s) of action. Utilizing the agonist anti-GITR monoclonal antibody DTA-1, we found that in vivo GITR ligation modulates regulatory T cells (Tregs) directly during induction of melanoma tumor immunity. As a monotherapy, DTA-1 induced regression of small established B16 melanoma tumors. Although DTA-1 did not alter systemic Treg frequencies nor abrogate the intrinsic suppressive activity of Tregs within the tumor-draining lymph node, intra-tumor Treg accumulation was significantly impaired. This resulted in a greater Teff:Treg ratio and enhanced tumor-specific CD8+ T-cell activity. The decreased intra-tumor Treg accumulation was due both to impaired infiltration, coupled with DTA-1-induced loss of foxp3 expression in intra-tumor Tregs. Histological analysis of B16 tumors grown in Foxp3-GFP mice showed that the majority of GFP+ cells had lost Foxp3 expression. These \"unstable\" Tregs were absent in IgG-treated tumors and in DTA-1 treated TDLN, demonstrating a tumor-specific effect. Impairment of Treg infiltration was lost if Tregs were GITR(-/-), and the protective effects of DTA-1 were reduced in reconstituted RAG1(-/-) mice if either the Treg or Teff subset were GITR-negative and absent if both were negative. Our results demonstrate that DTA-1 modulates both Teffs and Tregs during effective tumor treatment. The data suggest that DTA-1 prevents intra-tumor Treg accumulation by altering their stability, and as a result of the loss of foxp3 expression, may modify their intra-tumor suppressive capacity. These findings provide further support for the continued development of agonist anti-GITR mAbs as an immunotherapeutic strategy for cancer.

BackgroundThe immune system eliminates cancers in the early stages of malignant transformation. However, the presence of immune cells exerts selective pressure on tumors, which can result in tumor editing, leading to the development of immune escape variants. A common occurrence in cancers is the loss of antigenic protein expression on tumor cells, which creates antigenic heterogeneity and makes tumors resistant to immunotherapies such as adoptive cell therapies. Consequently, it is necessary to study and engage multiple components of the immune system in immunotherapeutic interventions to effectively eradicate heterogeneous tumors.MethodsThis study aimed to assess the efficacy of a combination therapy involving CD4+ T cells recognizing the melanoma antigen Trp1 in conjunction with either OX40 co-stimulation or CTLA-4 blockade (ICB) for eradicating advanced melanomas containing antigen escape variants in preclinical mouse models.ResultsThe combination therapy successfully eliminated antigen-loss variant clones in a preclinical mouse model of melanoma with heterogeneous Trp1 expression. Mechanistically, tumors from treated mice exhibited significant infiltration of activated neutrophils, which was also observed in cancer patients following ICB therapy. Depletion of neutrophils in our preclinical melanoma model of antigenic heterogeneity abolished the therapeutic efficacy of the combination treatment. Our findings revealed the importance of inducible nitric oxide synthase in neutrophil-mediated elimination of escape variants. Furthermore, neutrophils derived from tumors of treated mice exhibited a distinct transcriptomic and protein surface signature associated with anti-tumorigenic properties. This anti-tumorigenic neutrophil signature was also observed in tumors from melanoma patients treated with ICB that experienced survival benefits.ConclusionsOur findings demonstrate the interplay between T cells, which initiate the anti-tumor immune response, and neutrophils, which contribute to the elimination of tumor antigen loss variants in later stages. These insights underscore the potential of combined therapies in overcoming clonal escape variants in melanoma and provide valuable information on the role of neutrophils in tumor eradication when employing T cell immunotherapies.Ethics ApprovalAll tissues collected at MSKCC following study protocol approval by the MSKCC Institutional Review Board. Informed consent was obtained for all patients. The study was in strict compliance with all institutional ethical regulations.

BackgroundMultiple suppressive mechanisms within the tumor microenvironment are capable of blunting anti-tumor T cell responses, including the engagement of inhibitory receptors expressed in tumor-associated, exhausted CD8+ T cells, such as programmed cell death protein 1 (PD-1), T-cell immunoglobulin and mucin-domain containing-3 (TIM-3), lymphocyte-activation gene 3 (LAG-3), 2B4 (also known as CD244), and T cell immunoreceptor with Ig and ITIM domains (TIGIT).1 2 While immune checkpoint blockade therapies aimed at reinvigorating T cell effector function have demonstrated their clinical effectiveness,3 4 not all patients demonstrate long-term disease control.5 The refractory nature of terminally differentiated, exhausted CD8+ T cells to be reinvigorated by PD-1 blockade is one potential cause.6–8 This limitation warrants the need to explore modulatory pathways that potentially program T cells toward exhaustion.MethodsSingle cell-RNA sequencing (scRNA-seq) data derived from the tumor-infiltrating lymphocytes (TILs) of melanoma patients9 were used for transcriptomic analysis and flow cytometry results were used to quantify protein levels in TILs. Murine B16-F10 (B16) melanoma model was used for both in vitro and in vivo studies. TCR-transgenic Pmel-1 and OT-1 transgenic mice, as well as CD47-/- (knockout, KO) mice were purchased from the Jackson Laboratory to generate CD47+/+ (wild-type, WT), CD47± (heterozygote, HET) mice with Pmel-1 or OT-1 background. For T cell co-transfer studies, Rag-deficient mice or C57BL/6j mice with sub-lethal irradiation (600cGy) were used as recipients. Naïve TCR-transgenic CD47-WT and CD47-HET CD8+ T cells were labelled, mixed in a 1:1 ratio for co-transfer experiments.ResultsFlow cytometry analysis of human melanoma TILs found a strong upregulation of CD47 expression in tumor-associated, exhausted CD8+ T cells. We confirmed that CD47 transcription is significantly elevated among CD8+ T cells with a phenotype consistent with exhaustion using scRNA-seq results of TILs derived from melanoma patients.9 Our study in murine B16 melanoma model confirms our finding in melanoma patients. To specifically address the role of CD47 in anti-tumor CD8 effector function, we conducted T cell co-transfer studies and found that CD8+ T cells with lower copy number of CD47 (CD47-HET) significantly outnumber the co-transferred CD47-WT CD8+ T cells within the tumor, exhibiting an enhanced effector function and less exhausted phenotype. Our study demonstrates a potentially novel role for CD47 in mediating CD8+ T cell exhaustion.ConclusionsCD47 expression in CD8+ T cells programs T cells toward exhaustion.Ethics ApprovalAll mice were maintained in microisolator cages and treated in accordance with the NIH and American Association of Laboratory Animal Care regulations. All mouse procedures and experiments for this study were approved by the MSKCC Institutional Animal Care and Use Committee (IACUC).ReferencesWherry EJ and M Kurachi. Molecular and cellular insights into T cell exhaustion. Nat Rev Immunol 2015;15(8): p. 486–99.Thommen DS and Schumacher TN. T Cell Dysfunction in Cancer. Cancer Cell 2018;33(4): p. 547–562.Ribas A and Wolchok JD. Cancer immunotherapy using checkpoint blockade. Science 2018. 359(6382): p. 1350–1355.Sharma P and Allison JP. The future of immune checkpoint therapy. Science 2015; 48(6230): p. 56–61.Sharma P, et al. Primary, adaptive, and acquired resistance to cancer immunotherapy. Cell 2017. 168(4): p. 707–723.Schietinger, A., et al., Tumor-specific T cell dysfunction is a dynamic antigen-driven differentiation program initiated early during tumorigenesis. Immunity 2016;45(2): p. 389–401.Pauken KE, et al., Epigenetic stability of exhausted T cells limits durability of reinvigoration by PD-1 blockade. Science 2016;354(6316): p. 1160–1165.Philip M, et al., Chromatin states define tumour-specific T cell dysfunction and reprogramming. Nature 2017;545(7655): p. 452–456.Sade-Feldman M, et al., Defining T Cell States associated with response to checkpoint immunotherapy in melanoma. Cell 2018;175(4): p. 998–1013e20.

Only a subset of cancer patients responds to checkpoint blockade inhibition in the clinic. Strategies to overcome resistance are promising areas of investigation. Targeting glucocorticoid-induced tumor necrosis factor receptor-related protein (GITR) has shown efficacy in preclinical models, but GITR engagement is ineffective in controlling advanced, poorly immunogenic tumors, such as B16 melanoma, and has not yielded benefit in clinical trials. The alkylating agent cyclophosphamide (CTX) depletes regulatory T cells (Tregs), expands tumor-specific effector T cells (Teffs) via homeostatic proliferation, and induces immunogenic cell death. GITR agonism has an inhibitory effect on Tregs and activates Teffs. We therefore hypothesized that CTX and GITR agonism would promote effective antitumor immunity. Here we show that the combination of CTX and GITR agonism controlled tumor growth in clinically relevant mouse models. Mechanistically, we show that the combination therapy caused tumor cell death, clonal expansion of highly active CD8+ T cells, and depletion of Tregs by activation-induced cell death. Control of tumor growth was associated with the presence of an expanded population of highly activated, tumor-infiltrating, oligoclonal CD8+ T cells that led to a diminished TCR repertoire. Our studies show that the combination of CTX and GITR agonism is a rational chemoimmunotherapeutic approach that warrants further clinical investigation.

BackgroundTargeted immune-based therapies such as adoptive T cell transfer (ACT) are often ineffective because tumors evolve over time and under selective pressure display antigen loss variant clones. A classic example in melanoma is de-differentiation and loss of expression of antigenic proteins. Therapies that activate multiple branches of the immune system may eliminate such escape variantsMethodsHere we show that melanoma-specific CD4+ ACT therapy in combination with OX40 co-stimulation or CTLA-4 blockade can eradicate large melanoma tumors with clonal escape variants.ResultsEarly on-target recognition of melanoma antigens by adoptively transferred tumor-specific CD4+ T cells was required. Surprisingly, however, complete tumor eradication was partially dependent on neutrophils. Supporting these findings, extensive neutrophil activation and neutrophil extracellular traps were found in mouse tumors and in biopsies of melanoma patients treated with immune checkpoint blockade.ConclusionsOur findings uncover a novel interplay between T cells mediating the initial tumor- and tissue-specific immune response, and neutrophils mediating tumor destruction of antigen loss variants.Ethics ApprovalAll tissues were collected at MSKCC following study protocol approval by the MSKCC Institutional Review Board. All mouse procedures were performed in accordance with institutional protocol guidelines at Memorial Sloan-Kettering Cancer Center (MSKCC) under an approved protocol.