神经变性通过神经-免疫-癌症轴重新连接肿瘤微环境

IF 4.1 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

iScience Pub Date : 2025-09-15 DOI:10.1016/j.isci.2025.113550

Jhommara Bautista , Emily C. Coral-Riofrio , Salomé Suárez Urresta , David Palacios-Zavala , Carolina E. Echeverría , Salomé Araujo-Abad , Andrés López-Cortés

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引用次数: 0

摘要

神经退化和癌症，长期以来被认为是对立的过程，神经元损失和不受控制的增殖，越来越多地认识到在机制上趋同。这篇综述通过将神经退行性变定位为肿瘤进化的积极驱动因素来重新构建该领域。整合多组学、空间转录组学和神经免疫微生物群研究的见解，我们展示了退化的神经元如何破坏DNA修复、线粒体功能、免疫调节和屏障完整性，从而创造肿瘤允许的生态位。特别强调的是肠神经系统，在那里神经元损失通过免疫抑制和微生物生态失调促进结直肠癌和胰腺癌。共享的分子调节因子，包括p53、Pin1、STING和biglycan - il -10微生物群轴，表现出双重作用，在神经元中促进凋亡，在肿瘤中促进生存，突出了环境依赖性生物学。我们提出一种机制的、基于靶标的治疗分类，它超越了疾病的界限。认识到神经退行性变是一个肿瘤促进过程，揭示了新的诊断和治疗机会，将癌症神经科学扩展到目前的范式之外。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Neurodegeneration rewires the tumor microenvironment via the neuro–immune–cancer axis

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Neurodegeneration rewires the tumor microenvironment via the neuro–immune–cancer axis

Neurodegeneration and cancer, long considered opposing processes, neuronal loss versus uncontrolled proliferation, are increasingly recognized as mechanistically convergent. This review reframes the field by positioning neurodegeneration as an active driver of tumor evolution. Integrating insights from multi-omics, spatial transcriptomics, and neuroimmune–microbiota studies, we show how degenerating neurons disrupt DNA repair, mitochondrial function, immune regulation, and barrier integrity, thereby creating tumor-permissive niches. Particular emphasis is placed on the enteric nervous system, where neuronal loss promotes colorectal and pancreatic cancers through immune suppression and microbial dysbiosis. Shared molecular regulators, including p53, Pin1, STING, and the Biglycan–IL-10–microbiota axis, exhibit dual roles, pro-apoptotic in neurons yet pro-survival in tumors, highlighting context-dependent biology. We propose a mechanistic, target-based therapeutic classification that transcends disease boundaries. Recognizing neurodegeneration as a tumor-promoting process uncovers novel diagnostic and therapeutic opportunities, expanding cancer neuroscience beyond its current paradigm.

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来源期刊

iScience Multidisciplinary-Multidisciplinary

CiteScore

7.20

自引率

1.70%

发文量

1972

审稿时长

6 weeks

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