H4K20me3-Mediated Repression of Inflammatory Genes is a Characteristic and Targetable Vulnerability of Persister Cancer Cells.

IF 12.5 1区 医学 Q1 ONCOLOGY
Valentina Ramponi, Laia Richart, Marta Kovatcheva, Camille Stephan-Otto Attolini, Jordi Capellades, Alice E Lord, Oscar Yanes, Gabriella Ficz, Manuel Serrano
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Abstract

Anti-cancer therapies can induce cellular senescence, which is highly stable, or drug-tolerant persistence, which is efficiently reversed upon therapy termination. While approaches to target senescent cells have been extensively studied, further understanding of the processes regulating persistence is needed to develop treatment strategies to suppress persister cell survival. Here, we used mTOR/PI3K inhibition to develop and characterize a model of persistence-associated arrest in human cancer cells of various origins. Persister and senescent cancer cells shared an expanded lysosomal compartment and hypersensitivity to BCL-XL inhibition. However, persister cells lacked other features of senescence, such as loss of lamin B1, senescence-associated β-galactosidase activity, upregulation of MHC-I, and an inflammatory and secretory phenotype (SASP). Genome-wide CRISPR/Cas9 screening for genes required for the survival of persister cells revealed that they are hypersensitive to the inhibition of one-carbon (1C) metabolism, which was validated by the pharmacological inhibition of SHMT, a key enzyme that feeds methyl groups from serine into 1C metabolism. Connecting 1C metabolism with the epigenetic regulation of transcription, the repressive heterochromatic mark H4K20me3 was enriched at the promoters of SASP and interferon response genes in persister cells, while it was absent in proliferative or senescent cells. Moreover, persister cells overexpressed the H4K20 methyltransferases KMT5B/C, and their downregulation unleashed inflammatory programs and compromised the survival of persister cells. In summary, this study defined distinctive features of persister cancer cells, identified actionable vulnerabilities, and provided mechanistic insight into their low inflammatory activity.

H4K20me3 介导的炎症基因抑制是顽固性癌细胞的一个特征性弱点,也是可瞄准的弱点。
抗癌疗法可诱导高度稳定的细胞衰老或耐药的持久性,后者可在疗法终止时有效逆转。虽然针对衰老细胞的方法已被广泛研究,但要开发抑制持久细胞存活的治疗策略,还需要进一步了解调控持久性的过程。在这里,我们利用 mTOR/PI3K 抑制技术开发了一个与各种来源的人类癌细胞的持久性相关的停滞模型,并对其进行了表征。持久癌细胞和衰老癌细胞都有一个扩大的溶酶体区和对BCL-XL抑制的超敏性。然而,持久癌细胞缺乏衰老的其他特征,例如片层 B1 的缺失、衰老相关的 β-半乳糖苷酶活性、MHC-I 的上调以及炎症和分泌表型(SASP)。通过全基因组 CRISPR/Cas9 筛选宿主细胞存活所需的基因发现,宿主细胞对抑制一碳(1C)代谢非常不敏感,这一点通过药理抑制 SHMT 得到了验证,SHMT 是将丝氨酸中的甲基基团导入 1C 代谢的关键酶。将 1C 代谢与转录的表观遗传调控联系起来,在持久性细胞中,抑制性异染色质标记 H4K20me3 在 SASP 和干扰素反应基因的启动子上富集,而在增殖或衰老细胞中则不存在。此外,持久性细胞过度表达了H4K20甲基转移酶KMT5B/C,它们的下调释放了炎症程序并影响了持久性细胞的存活。总之,这项研究定义了持久癌细胞的独特特征,确定了可操作的薄弱环节,并从机理上揭示了它们的低炎症活性。
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来源期刊
Cancer research
Cancer research 医学-肿瘤学
CiteScore
16.10
自引率
0.90%
发文量
7677
审稿时长
2.5 months
期刊介绍: Cancer Research, published by the American Association for Cancer Research (AACR), is a journal that focuses on impactful original studies, reviews, and opinion pieces relevant to the broad cancer research community. Manuscripts that present conceptual or technological advances leading to insights into cancer biology are particularly sought after. The journal also places emphasis on convergence science, which involves bridging multiple distinct areas of cancer research. With primary subsections including Cancer Biology, Cancer Immunology, Cancer Metabolism and Molecular Mechanisms, Translational Cancer Biology, Cancer Landscapes, and Convergence Science, Cancer Research has a comprehensive scope. It is published twice a month and has one volume per year, with a print ISSN of 0008-5472 and an online ISSN of 1538-7445. Cancer Research is abstracted and/or indexed in various databases and platforms, including BIOSIS Previews (R) Database, MEDLINE, Current Contents/Life Sciences, Current Contents/Clinical Medicine, Science Citation Index, Scopus, and Web of Science.
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