Periostin Safeguards EGFR-Driven Genomic Instability and Sustains the Immune-Suppressive Niche in Glioblastoma.

IF 3.7 2区医学 Q2 GENETICS & HEREDITY

Human Mutation Pub Date : 2026-05-03 eCollection Date: 2026-01-01 DOI:10.1155/humu/9501906

Hongjun Liu, Shasha Tan, Jian Qi, Zhenjiang Du, Jinliang You, Sajjad Muhammad, Xiaoping Tang, Jianji Li

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Abstract

Glioblastoma (GBM) heterogeneity limits the efficacy of EGFR-targeted therapies. Here, we present a spatially stratified single-cell atlas of IDH-wildtype GBM to dissect the impact of EGFR amplification on tumor architecture. We demonstrate that EGFR amplification disrupts the spatial coupling between evolutionary state and anatomical location, resulting in premature acquisition of invasive phenotypes-a phenomenon we term "accelerated evolutionary velocity." Unlike nonamplified tumors which maintain a strict "Core-to-Margin" developmental gradient, malignant cells in EGFR-amplified tumors acquire invasive mesenchymal traits preemptively regardless of their spatial niche. This accelerated evolution parallels the Core behaving as a "genotoxic stress reservoir" characterized by elevated chromosomal instability (CIN) (p < 2.2 × 10^-16). This genotoxic stress coincides with the emergence of a localized tumor-myeloid axis and an immune-suppressive niche. Using the PriorityScore2 framework, we prioritized Periostin (POSTN) as a top-tier clinically relevant candidate. In the high-CIN environment of EGFR-amplified GBM, in silico network perturbation suggested that POSTN may function as a candidate modulator of mitotic fidelity, potentially buffering against lethal genomic instability while sustaining rapid clonal evolution. Validated across multicenter cohorts, POSTN showed robust upregulation, strong diagnostic performance (AUC = 0.961), and significant prognostic relevance, emerging as a potential therapeutic vulnerability linking accelerated evolution with immune privilege in the GBM ecosystem.

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骨膜蛋白保护egfr驱动的基因组不稳定性并维持胶质母细胞瘤的免疫抑制生态位。

胶质母细胞瘤（GBM）的异质性限制了egfr靶向治疗的疗效。在这里，我们提出了idh野生型GBM的空间分层单细胞图谱，以解剖EGFR扩增对肿瘤结构的影响。我们证明，EGFR扩增破坏了进化状态和解剖位置之间的空间耦合，导致过早获得侵入性表型——我们称之为“加速进化速度”的现象。与保持严格的“核心到边缘”发育梯度的非扩增肿瘤不同，egfr扩增肿瘤中的恶性细胞无论其空间生态位如何，都会预先获得侵袭性间充质特征。这种加速的进化与Core作为“基因毒性应激库”的行为相似，其特征是染色体不稳定性（CIN）升高（p < 2.2 × 10-16）。这种基因毒性应激与局部肿瘤-髓系轴和免疫抑制生态位的出现一致。使用优先级框架，我们优先考虑Periostin （POSTN）作为顶级临床相关候选药物。在egfr扩增的GBM的高cin环境中，硅网络扰动表明，POSTN可能作为有丝分裂保真度的候选调节剂，潜在地缓冲致命的基因组不稳定性，同时维持快速的克隆进化。通过多中心队列验证，POSTN显示出强大的上调，强大的诊断性能（AUC = 0.961）和显著的预后相关性，成为GBM生态系统中加速进化与免疫特权相关的潜在治疗脆弱性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Human Mutation 医学-遗传学

CiteScore

8.40

自引率

5.10%

发文量

190

审稿时长

2 months

期刊介绍： Human Mutation is a peer-reviewed journal that offers publication of original Research Articles, Methods, Mutation Updates, Reviews, Database Articles, Rapid Communications, and Letters on broad aspects of mutation research in humans. Reports of novel DNA variations and their phenotypic consequences, reports of SNPs demonstrated as valuable for genomic analysis, descriptions of new molecular detection methods, and novel approaches to clinical diagnosis are welcomed. Novel reports of gene organization at the genomic level, reported in the context of mutation investigation, may be considered. The journal provides a unique forum for the exchange of ideas, methods, and applications of interest to molecular, human, and medical geneticists in academic, industrial, and clinical research settings worldwide.