The hereditary N363K POLE exonuclease mutant extends PPAP tumor spectrum to glioblastomas by causing DNA damage and aneuploidy in addition to increased mismatch mutagenicity.

NAR Cancer Pub Date : 2023-03-11 eCollection Date: 2023-06-01 DOI:10.1093/narcan/zcad011
Guillaume Labrousse, Pierre Vande Perre, Genis Parra, Marion Jaffrelot, Laura Leroy, Frederic Chibon, Frederic Escudie, Janick Selves, Jean-Sebastien Hoffmann, Rosine Guimbaud, Malik Lutzmann
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Abstract

The exonuclease domain of DNA polymerases epsilon's catalytic subunit (POLE) removes misincorporated nucleotides, called proofreading. POLE-exonuclease mutations cause colorectal- and endometrial cancers with an extreme burden of single nucleotide substitutions. We recently reported that particularly the hereditary POLE exonuclease mutation N363K predisposes in addition to aggressive giant cell glioblastomas. We knocked-in this mutation homozygously into human cell lines and compared its properties to knock-ins of the likewise hereditary POLE L424V mutation and to a complete proofreading-inactivating mutation (exo-null). We found that N363K cells have higher mutation rates as both L424V- or exo-null mutant cells. In contrast to L424V cells, N363K cells expose a growth defect, replication stress and DNA damage. In non-transformed cells, these burdens lead to aneuploidy but macroscopically normal nuclei. In contrast, transformed N363K cells phenocopy the enlarged and disorganized nuclei of giant cell glioblastomas. Taken together, our data characterize a POLE exonuclease domain mutant that not only causes single nucleotide hypermutation, but in addition DNA damage and chromosome instability, leading to an extended tumor spectrum. Our results expand the understanding of the polymerase exonuclease domain and suggest that an assessment of both the mutational potential and the genetic instability might refine classification and treatment of POLE-mutated tumors.

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遗传性 N363K POLE 外切酶突变体除了增加错配诱变性外,还造成 DNA 损伤和非整倍体,从而将 PPAP 的肿瘤谱扩展到胶质母细胞瘤。
DNA 聚合酶epsilon催化亚基(POLE)的外切酶结构域能清除误入的核苷酸,称为校对。POLE-exonuclease 基因突变导致的结直肠癌和子宫内膜癌中,单核苷酸置换的比例极高。我们最近报告说,遗传性 POLE 外切酶突变 N363K 除了容易导致侵袭性巨细胞胶质母细胞瘤外,还容易导致遗传性 POLE 外切酶突变 N363K。我们在人类细胞系中同源敲入了这一突变,并将其特性与同样具有遗传性的 POLE L424V 突变的敲入和完全校对失活突变(exo-null)进行了比较。我们发现,N363K 细胞的突变率高于 L424V 突变细胞或 exo-null 突变细胞。与 L424V 细胞相比,N363K 细胞暴露出生长缺陷、复制压力和 DNA 损伤。在非转化细胞中,这些负担会导致非整倍体,但细胞核宏观上正常。相反,转化的 N363K 细胞则表现出巨细胞胶质母细胞瘤细胞核的增大和紊乱。综上所述,我们的数据描述了一种 POLE 外切酶结构域突变体的特征,它不仅会引起单核苷酸高突变,还会造成 DNA 损伤和染色体不稳定,从而导致肿瘤范围扩大。我们的研究结果拓展了人们对聚合酶外切酶结构域的认识,并表明对突变潜能和遗传不稳定性的评估可能会完善POLE突变肿瘤的分类和治疗。
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