A pontine-specific axonal niche supports de novo gliomagenesis

Zhigang Xie, Adrija Pathak, Vytas A. Bankaitis
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Abstract

Diffuse intrinsic pontine gliomas (DIPGs), a major type of pediatric high-grade gliomas located in the pons, are the leading cause of death in children with brain cancer. A subset (20-25%) of DIPGs harbor a lysine 27-to-methionine (K27M) mutation in HIST1H3B, which encodes histone H3.1, and an activating ACVR1 mutation. The occurrence of this pair of mutations in DIPGs, but not in pediatric gliomas in other anatomical locations, suggests the existence of a pontine-specific niche that favors DIPG gliomagenesis. Unfortunately, the identity of the underlying pontine niche remains elusive as available mouse models fail to recapitulate the anatomic specificity that characterizes DIPGs. Herein we show that the trigeminal root entry zone (TREZ), a pontine structure where several major axon tracts intersect, is enriched with proliferating oligodendrocyte-lineage cells during brainstem development. Introducing both H3.1K27M and activating Acvr1 and Pik3ca mutations (which co-occur frequently with H3.1K27M in human DIPGs) into the mouse brain leads to rapid gliomagenesis. This pathology recapitulates the pons specificity of DIPGs as glioma cells proliferate on axon tracts at the TREZ. We further show that a hyaluronan receptor important for cell stemness (HMMR) plays a key role in glioma cell proliferation at the TREZ. We propose that H3.1K27M and its co-occurring mutations drive pontine specific gliomagenesis by inducing a proliferative response of oligodendrocyte-lineage cells with enhanced stemness on large TREZ axon tracts.
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支持从头胶质瘤形成的庞氏特异性轴突生态位
弥漫性桥脑胶质瘤(DIPGs)是位于桥脑的一种主要的小儿高级别胶质瘤,是导致儿童脑癌死亡的主要原因。DIPGs中的一部分(20%-25%)在编码组蛋白H3.1的HIST1H3B中存在赖氨酸27-蛋氨酸(K27M)突变和激活性ACVR1突变。这对突变出现在DIPGs中,而不出现在其他解剖位置的小儿胶质瘤中,这表明存在一个有利于DIPG胶质瘤发生的庞廷特异性位点。遗憾的是,由于现有的小鼠模型无法再现DIPGs的解剖特异性,因此基本的桥脑生态位的身份仍然难以确定。在这里,我们发现三叉神经根入口区(TREZ)是几个主要轴突束交汇的桥脑结构,在脑干发育过程中富含增殖的少突胶质细胞系细胞。将H3.1K27M以及激活性Acvr1和Pik3ca突变(在人类DIPGs中经常与H3.1K27M同时出现)引入小鼠大脑会导致神经胶质瘤的快速发生。这种病理学再现了 DIPGs 的脑桥特异性,因为胶质瘤细胞在 TREZ 的轴突束上增殖。我们进一步发现,一种对细胞干性很重要的透明质酸受体(HMMR)在胶质瘤细胞在TREZ的增殖中起着关键作用。我们提出,H3.1K27M及其共存突变通过诱导少突胶质细胞系细胞的增殖反应,增强TREZ大轴突束上的干性,从而驱动桥脑特异性胶质瘤的发生。
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