Primary Resistance to PD-1 Blockade Mediated by <i>JAK1/2</i> Mutations

Shin, Daniel Sanghoon; Zaretsky, Jesse M.; Escuin-Ordinas, Helena; García-Díaz, Ángel; Hu‐Lieskovan, Siwen; Kalbasi, Anusha; Grasso, Catherine S.; Hugo, Willy; Sandoval, Salemiz; Torrejon, Davis Y.; Palaskas, Nicolaos; Rodriguez, Gabriel Abril; Parisi, Giulia; Azhdam, Ariel M.; Chmielowski, Bartosz; Cherry, Grace; Seja, Elizabeth; Berent-Maoz, Beata; Shintaku, I. Peter; Le, Dung T.; Pardoll, Drew M.; Díaz, Luis A.; Tumeh, Paul C.; Graeber, Thomas G.; Lo, Roger S.; Comı́n-Anduix, Begoña; Ribas, Antoni

doi:10.1158/2159-8290.cd-16-1223

Cited by 1,019 publications

(832 citation statements)

References 49 publications

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“…Analyses of tumours with a very low IFNγ-associated geneexpression score, or a 'non-T-cell-inflamed' tumour microenvironment have revealed roles for activation of the WNT/β-catenin-signalling pathway 145 , and an enrichment for mutations in PTEN 146 in immune evasion. Deleterious mutations in the genes encoding JAK1 and JAK2 (which are involved in IFNγ signalling), or β 2 microglobulin (an MHC class I subunit), as well as loss of expression of interferon regulatory factor 1 (IRF1) have also been described in anti-PD-1-antibody-resistant patient samples and cell lines 147,148 . These intratumoural changes are associated with deficits in autophagy, antigen presentation, and the type I interferon response, suggesting that rational drug combinations should be explored to either suppress these pathways using β-catenin or PI3Kβ inhibitors, and/or amplify antigen presentation, perhaps via an approach such as FLT3-ligand agonism.…”

Section: Braf-mek-inhibitor Resistance and Biomarkersmentioning

confidence: 99%

Targeted agents and immunotherapies: optimizing outcomes in melanoma

et al. 2017

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Section: Braf-mek-inhibitor Resistance and Biomarkersmentioning

confidence: 99%

Targeted agents and immunotherapies: optimizing outcomes in melanoma

et al. 2017

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“…Ipilimumab-refractory melanoma tumors were insensitive to IFN-γ signaling due to mutations in IFNGR1, IFNGR2, JAK2, and interferon regulatory factor 1 (IRF1) which is responsible for the INF-γ-induced upregulation of PD-L1 (86). Mutations in JAK1 and JAK2 were also found in melanoma and colorectal cancer patients who failed to respond to anti-PD1 despite having tumors with high mutational load (87,88). Similar mutations in JAK1 and JAK2 were also detected in relapsing tumors from melanoma patients who initially responded to anti-PD-1 therapy, indicating that loss of responsiveness to IFN-γ signaling may be a potential tumor escape mechanism contributing to relapse following immune checkpoint blockade (81).…”

Section: Mechanisms Of Resistance To Immune Checkpoint Blockadementioning

confidence: 99%

Immune Checkpoint Inhibitors in the Treatment of Melanoma: From Basic Science to Clinical Application

Rausch¹,

Hastings

2017

Cutaneous Melanoma: Etiology and Therapy

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Abstract:Immune checkpoint blockade has revolutionized the treatment of patients with advanced melanoma and many other cancers. Blockade of inhibitory receptors, CTLA-4 and PD-1, enhances T-cell-mediated antitumor immune responses, leading to improved survival and durable responses in patients. Based on their mechanism of action, immune checkpoint inhibitors can also induce immune-related adverse events that require careful monitoring and prompt treatment. Despite these successes, only a fraction of patients benefit from immune checkpoint blockade. Basic science approaches and clinical experience are defining predictive biomarkers to identify patients most likely to respond to therapy as well as mechanisms of resistance that limit responses in certain tumors or shorten the duration of response. New approaches and combination therapies are under development to broaden the clinical impact of immune checkpoint blockade by overcoming resistance to therapy and limiting adverse events.

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“…JAK1/2 loss of function mutations may have important role in the absence of response to PD-1 inhibitors due to lower ability of immune T cells to recognize tumor cells. It has also been shown that these mutations may result in a lack of T-cell infiltrates due to deficit of chemokine production [8]. Zaretsky et al showed that loss-of-function mutations of JAK1/2 encoding IFN-γ receptor were implicated in acquired resistance to pembrolizumab in the management of metastatic melanoma.…”

Section: Primary Resistance To Icimentioning

confidence: 99%

Negative Predictive Biomarkers of Checkpoint Inhibitors in Hyper-Progressive Tumors

et al. 2017

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Immune checkpoint inhibitors (ICI) are becoming an integral part of the management of cancer patients. PD-1 and PD-L1 inhibitors led to distinguished clinical responses in patients with different types of cancer ranging from 20 to 30% when used in monotherapy. Anti-PD1 and anti-PDL1 agents are approved by the US FDA in the treatment of multiple malignancies from renal cell carcinoma, classical Hodgkin lymphoma, non-small-cell lung cancer, squamous cell carcinoma of head and neck, metastatic melanoma and urothelial carcinoma of the bladder [1].Defining predictive biomarker of treatment response and toxicity represents one of the challenges of these new agents. In fact, several biomarkers were evoked in order to explain the response to ICI such as PD-L1 expression/amplification, high tumor mutational burden and mismatch repair gene defect [2]. These immune checkpoint inhibitors were also associated with specific adverse events which were mainly immune related such as colitis, hypophysitis and pneumonitis. Some predictive biomarkers are under investigation to predict these adverse events like neutrophil activation markers (CD117 and CEACAM1), several immunoglobulin genes, Il6 level at baseline and Il17/eosinophil pathway element's level [3]. Interestingly, immunotherapy may also result in a unique tumor response pattern such as pseudo-progression defined as initial tumor increasing size on imaging tools followed by delayed tumor response. Recent anecdotal reports described a subset of patients whose disease paradoxically rapidly progressed after ICI administration suggesting that immunotherapy may have a deleterious effect by accelerating the disease [4,5]. Hyper-progression disease definition & outcome Two recent reports by Champiat et al. and Kato et al. described this new pattern of progression in patients treatedwith PD-1/PD-L1 inhibitors [2,6]. The definition of hyper-progressive disease (HPD) is still not clear and is different according to each study methodology. Kato et al. defined HPD as time to treatment failure <2 months, >50% increase in tumor burden compared with preimmunotherapy imaging that was obtained within 2 months of the initiation of immunotherapy, and >2-fold increase in progression pace [6]. However, Champiat et al. defined it as RECIST progression after the first evaluation and ≥2-fold increase of the tumor growth rate between the reference and experimental periods, tumor growth rate being a measure to assess tumor growth over time allowing for quantitative and dynamic evaluation of the tumor. Champiat et al. reported in their study a prevalence of 9% of HPD (12 patients/131 evaluable patients); these patients were significantly older than patients without HPD which can be due to a different immunological background in older patients such as higher inflammatory cytokines concentrations. HPD was associated with shorter overall survival (4.6 vs 7.6 months; p = 0.19). No association was reported between HPD and tumor burden at baseline, tumor type, number of metastatic sites, number of previous...

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Primary Resistance to PD-1 Blockade Mediated by JAK1/2 Mutations

Cited by 1,019 publications

References 49 publications

Targeted agents and immunotherapies: optimizing outcomes in melanoma

Targeted agents and immunotherapies: optimizing outcomes in melanoma

Immune Checkpoint Inhibitors in the Treatment of Melanoma: From Basic Science to Clinical Application

Negative Predictive Biomarkers of Checkpoint Inhibitors in Hyper-Progressive Tumors

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