NF1 突变驱动的神经元过度兴奋为小鼠视神经胶质瘤的肿瘤发生和治疗靶向设定了一个阈值。
NF1 mutation-driven neuronal hyperexcitability sets a threshold for tumorigenesis and therapeutic targeting of murine optic glioma.
机构信息
Departments of Neurology, Washington University School of Medicine, St. Louis, Missouri, USA.
Department of Pathology & Immunology, Washington University School of Medicine, St. Louis, Missouri, USA.
出版信息
Neuro Oncol. 2024 Aug 5;26(8):1496-1508. doi: 10.1093/neuonc/noae054.
BACKGROUND
With the recognition that noncancerous cells function as critical regulators of brain tumor growth, we recently demonstrated that neurons drive low-grade glioma initiation and progression. Using mouse models of neurofibromatosis type 1 (NF1)-associated optic pathway glioma (OPG), we showed that Nf1 mutation induces neuronal hyperexcitability and midkine expression, which activates an immune axis to support tumor growth, such that high-dose lamotrigine treatment reduces Nf1-OPG proliferation. Herein, we execute a series of complementary experiments to address several key knowledge gaps relevant to future clinical translation.
METHODS
We leverage a collection of Nf1-mutant mice that spontaneously develop OPGs to alter both germline and retinal neuron-specific midkine expression. Nf1-mutant mice harboring several different NF1 patient-derived germline mutations were employed to evaluate neuronal excitability and midkine expression. Two distinct Nf1-OPG preclinical mouse models were used to assess lamotrigine effects on tumor progression and growth in vivo.
RESULTS
We establish that neuronal midkine is both necessary and sufficient for Nf1-OPG growth, demonstrating an obligate relationship between germline Nf1 mutation, neuronal excitability, midkine production, and Nf1-OPG proliferation. We show anti-epileptic drug (lamotrigine) specificity in suppressing neuronal midkine production. Relevant to clinical translation, lamotrigine prevents Nf1-OPG progression and suppresses the growth of existing tumors for months following drug cessation. Importantly, lamotrigine abrogates tumor growth in two Nf1-OPG strains using pediatric epilepsy clinical dosing.
CONCLUSIONS
Together, these findings establish midkine and neuronal hyperexcitability as targetable drivers of Nf1-OPG growth and support the use of lamotrigine as a potential chemoprevention or chemotherapy agent for children with NF1-OPG.
背景
由于认识到非癌性细胞是脑肿瘤生长的关键调节因子,我们最近证明神经元驱动低级别神经胶质瘤的起始和进展。使用神经纤维瘤病 1 型 (NF1) 相关视神经通路胶质瘤 (OPG) 的小鼠模型,我们表明 Nf1 突变诱导神经元过度兴奋和中期因子表达,这激活了支持肿瘤生长的免疫轴,使得高剂量拉莫三嗪治疗可减少 Nf1-OPG 增殖。在此,我们执行了一系列互补实验,以解决与未来临床转化相关的几个关键知识空白。
方法
我们利用一组自发发生 OPG 的 Nf1 突变小鼠来改变生殖细胞和视网膜神经元特异性中期因子表达。使用携带几种不同 NF1 患者衍生种系突变的 Nf1 突变小鼠来评估神经元兴奋性和中期因子表达。使用两种不同的 Nf1-OPG 临床前小鼠模型来评估拉莫三嗪对体内肿瘤进展和生长的影响。
结果
我们证实神经元中期因子对于 Nf1-OPG 的生长是必要且充分的,证明了种系 Nf1 突变、神经元兴奋性、中期因子产生和 Nf1-OPG 增殖之间的强制性关系。我们表明抗癫痫药物(拉莫三嗪)特异性抑制神经元中期因子的产生。与临床转化相关的是,拉莫三嗪可预防 Nf1-OPG 的进展,并在停药后数月内抑制现有肿瘤的生长。重要的是,拉莫三嗪使用儿科癫痫临床剂量可消除两种 Nf1-OPG 株的肿瘤生长。
结论
这些发现共同确定中期因子和神经元过度兴奋是 Nf1-OPG 生长的可靶向驱动因素,并支持将拉莫三嗪用作 NF1-OPG 儿童的潜在化学预防或化疗药物。
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