G Sari, K Dhatchinamoorthy, L Orellano-Ariza, L M Ferreira, M A Brehm, K Rock
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Also of importance to know is whether the loss of MHC I is reversible and how such loss and/or its restoration would impact responses to immunotherapy. Here, we investigate these issues for loss of IRF1 and IRF2, which are transcription factors that drive expression of MHC I pathway genes and some killing mechanisms.</p><p><strong>Methods: </strong>Bioinformatics analyses of IRF2 and IRF2-dependent gene transcripts were performed for all human cancers in the TCGA RNAseq database. IRF2 protein-DNA-binding was analyzed in ChIPseq databases. CRISRPcas9 was used to knock out IRF1 and IRF2 genes in human and mouse melanoma cells and the resulting phenotypes were analyzed in vitro and in vivo.</p><p><strong>Results: </strong>Transcriptomic analysis revealed that IRF2 expression was reduced in a substantial subset of cases in almost all types of human cancers. When this occurred there was a corresponding reduction in the expression of IRF2-regulated genes that were needed for CD8 T cell recognition. To test cause and effect for these IRF2 correlations and the consequences of IRF2 loss, we gene-edited IRF2 in a patient-derived melanoma and a mouse melanoma. The IRF2 gene-edited melanomas had reduced expression of transcripts for genes in the MHC I pathway and decreased levels of MHC I complexes on the cell surface. Levels of Caspase 7, an IRF2 target gene involved in CD8 T cell killing of tumors, were also reduced. This loss of IRF2 caused both human and mouse melanomas to become resistant to immunotherapy with a checkpoint inhibitor. Importantly, these effects were reversible. Stimulation of the IRF2-deficient melanomas with interferon induced the expression of a functionally homologous transcription factor, IRF1, which then restored the MHC I pathway and responsiveness to CPI.</p><p><strong>Conclusions: </strong>Our study shows that a subset of cases within most types of cancers downregulates IRF2 and that this can allow cancers to escape immune control. This can cause resistance to checkpoint blockade immunotherapy and is reversible with currently available biologics.</p>","PeriodicalId":50199,"journal":{"name":"Journal of Experimental & Clinical Cancer Research","volume":"43 1","pages":"276"},"PeriodicalIF":11.4000,"publicationDate":"2024-10-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11446056/pdf/","citationCount":"0","resultStr":"{\"title\":\"IRF2 loss is associated with reduced MHC I pathway transcripts in subsets of most human cancers and causes resistance to checkpoint immunotherapy in human and mouse melanomas.\",\"authors\":\"G Sari, K Dhatchinamoorthy, L Orellano-Ariza, L M Ferreira, M A Brehm, K Rock\",\"doi\":\"10.1186/s13046-024-03187-5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>In order for cancers to progress, they must evade elimination by CD8 T cells or other immune mechanisms. CD8 T cells recognize and kill tumor cells that display immunogenic tumor peptides bound to MHC I molecules. One of the ways that cancers can escape such killing is by reducing expression of MHC I molecules, and loss of MHC I is frequently observed in tumors. There are multiple different mechanisms that can underly the loss of MHC I complexes on tumor and it is currently unclear whether there are particular mechanisms that occur frequently and, if so, in what types of cancers. Also of importance to know is whether the loss of MHC I is reversible and how such loss and/or its restoration would impact responses to immunotherapy. Here, we investigate these issues for loss of IRF1 and IRF2, which are transcription factors that drive expression of MHC I pathway genes and some killing mechanisms.</p><p><strong>Methods: </strong>Bioinformatics analyses of IRF2 and IRF2-dependent gene transcripts were performed for all human cancers in the TCGA RNAseq database. IRF2 protein-DNA-binding was analyzed in ChIPseq databases. CRISRPcas9 was used to knock out IRF1 and IRF2 genes in human and mouse melanoma cells and the resulting phenotypes were analyzed in vitro and in vivo.</p><p><strong>Results: </strong>Transcriptomic analysis revealed that IRF2 expression was reduced in a substantial subset of cases in almost all types of human cancers. When this occurred there was a corresponding reduction in the expression of IRF2-regulated genes that were needed for CD8 T cell recognition. To test cause and effect for these IRF2 correlations and the consequences of IRF2 loss, we gene-edited IRF2 in a patient-derived melanoma and a mouse melanoma. The IRF2 gene-edited melanomas had reduced expression of transcripts for genes in the MHC I pathway and decreased levels of MHC I complexes on the cell surface. Levels of Caspase 7, an IRF2 target gene involved in CD8 T cell killing of tumors, were also reduced. This loss of IRF2 caused both human and mouse melanomas to become resistant to immunotherapy with a checkpoint inhibitor. Importantly, these effects were reversible. Stimulation of the IRF2-deficient melanomas with interferon induced the expression of a functionally homologous transcription factor, IRF1, which then restored the MHC I pathway and responsiveness to CPI.</p><p><strong>Conclusions: </strong>Our study shows that a subset of cases within most types of cancers downregulates IRF2 and that this can allow cancers to escape immune control. 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引用次数: 0
摘要
背景:癌症要取得进展,必须避开 CD8 T 细胞或其他免疫机制的清除。CD8 T 细胞能识别并杀死显示与 MHC I 分子结合的免疫原性肿瘤肽的肿瘤细胞。癌症逃避这种杀伤的方法之一是减少 MHC I 分子的表达,而 MHC I 的缺失在肿瘤中经常出现。MHC I 复合物在肿瘤中的缺失有多种不同的机制,目前还不清楚是否存在经常发生的特定机制,如果存在,是在哪种类型的癌症中。同样重要的是,MHC I 的缺失是否可逆,以及这种缺失和/或其恢复将如何影响对免疫疗法的反应。IRF1和IRF2是驱动MHC I通路基因表达和一些杀伤机制的转录因子:方法:对 TCGA RNAseq 数据库中所有人类癌症的 IRF2 和 IRF2 依赖性基因转录本进行生物信息学分析。在 ChIPseq 数据库中分析了 IRF2 蛋白-DNA 结合。利用 CRISRPcas9 基因敲除人和小鼠黑色素瘤细胞中的 IRF1 和 IRF2 基因,并对由此产生的表型进行体外和体内分析:结果:转录组分析表明,在几乎所有类型的人类癌症中,IRF2的表达在相当一部分病例中都有所减少。在这种情况下,CD8 T 细胞识别所需的 IRF2 调控基因的表达也相应减少。为了检验这些IRF2相关性的因果关系以及IRF2缺失的后果,我们在患者衍生的黑色素瘤和小鼠黑色素瘤中对IRF2进行了基因编辑。经 IRF2 基因编辑的黑色素瘤的 MHC I 通路基因转录本表达量减少,细胞表面的 MHC I 复合物水平降低。参与CD8 T细胞杀伤肿瘤的IRF2靶基因Caspase 7的水平也有所降低。IRF2的缺失导致人类和小鼠黑色素瘤对使用检查点抑制剂的免疫疗法产生抗药性。重要的是,这些影响是可逆的。用干扰素刺激IRF2缺失的黑色素瘤可诱导功能同源的转录因子IRF1的表达,从而恢复MHC I通路和对CPI的反应性:我们的研究表明,在大多数类型的癌症中,有一部分病例会下调IRF2,这可能会使癌症逃避免疫控制。这可能导致对检查点阻断免疫疗法产生抗药性,而目前可用的生物制剂可逆转这种抗药性。
IRF2 loss is associated with reduced MHC I pathway transcripts in subsets of most human cancers and causes resistance to checkpoint immunotherapy in human and mouse melanomas.
Background: In order for cancers to progress, they must evade elimination by CD8 T cells or other immune mechanisms. CD8 T cells recognize and kill tumor cells that display immunogenic tumor peptides bound to MHC I molecules. One of the ways that cancers can escape such killing is by reducing expression of MHC I molecules, and loss of MHC I is frequently observed in tumors. There are multiple different mechanisms that can underly the loss of MHC I complexes on tumor and it is currently unclear whether there are particular mechanisms that occur frequently and, if so, in what types of cancers. Also of importance to know is whether the loss of MHC I is reversible and how such loss and/or its restoration would impact responses to immunotherapy. Here, we investigate these issues for loss of IRF1 and IRF2, which are transcription factors that drive expression of MHC I pathway genes and some killing mechanisms.
Methods: Bioinformatics analyses of IRF2 and IRF2-dependent gene transcripts were performed for all human cancers in the TCGA RNAseq database. IRF2 protein-DNA-binding was analyzed in ChIPseq databases. CRISRPcas9 was used to knock out IRF1 and IRF2 genes in human and mouse melanoma cells and the resulting phenotypes were analyzed in vitro and in vivo.
Results: Transcriptomic analysis revealed that IRF2 expression was reduced in a substantial subset of cases in almost all types of human cancers. When this occurred there was a corresponding reduction in the expression of IRF2-regulated genes that were needed for CD8 T cell recognition. To test cause and effect for these IRF2 correlations and the consequences of IRF2 loss, we gene-edited IRF2 in a patient-derived melanoma and a mouse melanoma. The IRF2 gene-edited melanomas had reduced expression of transcripts for genes in the MHC I pathway and decreased levels of MHC I complexes on the cell surface. Levels of Caspase 7, an IRF2 target gene involved in CD8 T cell killing of tumors, were also reduced. This loss of IRF2 caused both human and mouse melanomas to become resistant to immunotherapy with a checkpoint inhibitor. Importantly, these effects were reversible. Stimulation of the IRF2-deficient melanomas with interferon induced the expression of a functionally homologous transcription factor, IRF1, which then restored the MHC I pathway and responsiveness to CPI.
Conclusions: Our study shows that a subset of cases within most types of cancers downregulates IRF2 and that this can allow cancers to escape immune control. This can cause resistance to checkpoint blockade immunotherapy and is reversible with currently available biologics.
期刊介绍:
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