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综合基因组分析鉴定儿童肝癌中的驱动基因和顺铂耐药前体细胞表型。

Integrated Genomic Analysis Identifies Driver Genes and Cisplatin-Resistant Progenitor Phenotype in Pediatric Liver Cancer.

机构信息

Centre de Recherche des Cordeliers, Sorbonne Université, Université de Paris, INSERM, Paris, France.

Department of Pediatric Pathology, APHP, Robert Debré Hospital, Paris, France.

出版信息

Cancer Discov. 2021 Oct;11(10):2524-2543. doi: 10.1158/2159-8290.CD-20-1809. Epub 2021 Apr 23.

DOI:10.1158/2159-8290.CD-20-1809
PMID:33893148
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8916021/
Abstract

Pediatric liver cancers (PLC) comprise diverse diseases affecting infants, children, and adolescents. Despite overall good prognosis, PLCs display heterogeneous response to chemotherapy. Integrated genomic analysis of 126 pediatric liver tumors showed a continuum of driver mechanisms associated with patient age, including new targetable oncogenes. In 10% of patients with hepatoblastoma, all before three years old, we identified a mosaic premalignant clonal expansion of cells altered at the 11p15.5 locus. Analysis of spatial and longitudinal heterogeneity revealed an important plasticity between "hepatocytic," "liver progenitor," and "mesenchymal" molecular subgroups of hepatoblastoma. We showed that during chemotherapy, "liver progenitor" cells accumulated massive loads of cisplatin-induced mutations with a specific mutational signature, leading to the development of heavily mutated relapses and metastases. Drug screening in PLC cell lines identified promising targets for cisplatin-resistant progenitor cells, validated in mouse xenograft experiments. These data provide new insights into cisplatin resistance mechanisms in PLC and suggest alternative therapies. SIGNIFICANCE: PLCs are deadly when they resist chemotherapy, with limited alternative treatment options. Using a multiomics approach, we identified PLC driver genes and the cellular phenotype at the origin of cisplatin resistance. We validated new treatments targeting these molecular features in cell lines and xenografts..

摘要

儿科肝脏肿瘤(PLC)包括影响婴儿、儿童和青少年的多种疾病。尽管总体预后良好,但 PLC 对化疗的反应存在异质性。对 126 例儿科肝脏肿瘤的综合基因组分析显示,与患者年龄相关的驱动机制呈连续统,包括新的可靶向致癌基因。在 10%的肝母细胞瘤患者中,所有患者均在三岁之前,我们在 11p15.5 位点发现了改变的马赛克性癌前克隆扩展细胞。对空间和纵向异质性的分析揭示了肝母细胞瘤的“肝细胞”、“肝祖细胞”和“间充质”分子亚群之间的重要可塑性。我们表明,在化疗过程中,“肝祖细胞”积累了大量顺铂诱导突变的负荷,具有特定的突变特征,导致高度突变的复发和转移的发展。在 PLC 细胞系中的药物筛选鉴定了针对顺铂耐药祖细胞的有前途的靶点,并在小鼠异种移植实验中得到了验证。这些数据为 PLC 中顺铂耐药机制提供了新的见解,并提示了替代疗法。意义:当 PLC 对化疗产生耐药性时,其死亡率很高,替代治疗选择有限。我们使用多组学方法鉴定了 PLC 的驱动基因和起源于顺铂耐药的细胞表型。我们在细胞系和异种移植模型中验证了针对这些分子特征的新治疗方法。

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