Cook Ashley L, Sur Surojit, Dobbyn Laura, Watson Evangeline, Cohen Joshua D, Ptak Blair, Lee Bum Seok, Paul Suman, Hsiue Emily, Popoli Maria, Vogelstein Bert, Papadopoulos Nickolas, Bettegowda Chetan, Gabrielson Kathy, Zhou Shibin, Kinzler Kenneth W, Wyhs Nicolas
Ludwig Center for Cancer Genetics and Therapeutics, Johns Hopkins University School of Medicine, Baltimore, United States.
Cellular and Molecular Medicine Graduate Program, Johns Hopkins University School of Medicine, Baltimore, United States.
Elife. 2025 Feb 17;13:RP95952. doi: 10.7554/eLife.95952.
Despite exciting developments in cancer immunotherapy, its broad application is limited by the paucity of targetable antigens on the tumor cell surface. As an intrinsic cellular pathway, nonsense-mediated decay (NMD) conceals neoantigens through the destruction of the RNA products from genes harboring truncating mutations. We developed and conducted a high-throughput screen, based on the ratiometric analysis of transcripts, to identify critical mediators of NMD in human cells. This screen implicated disruption of kinase SMG1's phosphorylation of UPF1 as a potential disruptor of NMD. This led us to design a novel SMG1 inhibitor, KVS0001, that elevates the expression of transcripts and proteins resulting from human and murine truncating mutations in vitro and murine cells in vivo. Most importantly, KVS0001 concomitantly increased the presentation of immune-targetable human leukocyte antigens (HLA) class I-associated peptides from NMD-downregulated proteins on the surface of human cancer cells. KVS0001 provides new opportunities for studying NMD and the diseases in which NMD plays a role, including cancer and inherited diseases.
尽管癌症免疫疗法取得了令人兴奋的进展,但其广泛应用受到肿瘤细胞表面可靶向抗原稀缺的限制。作为一种内在的细胞途径,无义介导的衰变(NMD)通过破坏携带截短突变的基因的RNA产物来隐藏新抗原。我们基于转录本的比例分析开发并进行了一项高通量筛选,以确定人类细胞中NMD的关键介质。该筛选表明,激酶SMG1对UPF1的磷酸化的破坏是NMD的潜在破坏因素。这促使我们设计了一种新型SMG1抑制剂KVS0001,它在体外可提高人类截短突变体的转录本和蛋白质的表达,在体内可提高小鼠细胞中截短突变体的转录本和蛋白质的表达。最重要的是,KVS0001同时增加了人类癌细胞表面NMD下调蛋白的与免疫可靶向的人类白细胞抗原(HLA)I类相关肽的呈递。KVS0001为研究NMD以及NMD起作用的疾病(包括癌症和遗传性疾病)提供了新机会。
