Comparative profiling of white matter development in the human and mouse brain reveals volumetric deficits and delayed myelination in Angelman syndrome.

IF 6.3 1区医学 Q1 GENETICS & HEREDITY Molecular Autism Pub Date : 2024-12-26 DOI:10.1186/s13229-024-00636-y

Siddhi S Ozarkar, Ridthi K-R Patel, Tasmai Vulli, Audrey L Smith, Martin A Styner, Li-Ming Hsu, Sung-Ho Lee, Yen-Yu Ian Shih, Heather C Hazlett, Mark D Shen, Alain C Burette, Benjamin D Philpot

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Abstract

Background: Angelman syndrome (AS), a severe neurodevelopmental disorder resulting from the loss of the maternal UBE3A gene, is marked by changes in the brain's white matter (WM). The extent of WM abnormalities seems to correlate with the severity of clinical symptoms, but these deficits are still poorly characterized or understood. This study provides the first large-scale measurement of WM volume reduction in children with AS. Furthermore, we probed the possibility of underlying WM neuropathology by examining the progression of myelination in an AS mouse model.

Methods: We conducted magnetic resonance imaging (MRI) on children with AS (n = 32) and neurotypical controls (n = 99) aged 0.5-12 years. In parallel, we examined myelination in postnatal Ube3a maternal-null mice (Ube3a^m-/p+; AS model), Ube3a paternal-null mice (Ube3a^m+/p-), and wildtype controls (Ube3a^m+/p+) using MRI, immunohistochemistry, western blotting, and electron microscopy.

Results: Our data revealed that AS individuals exhibit significant reductions in brain volume by ~ 1 year of age, and by 6-12 years of age WM is reduced by 26% and gray matter by 21%-approximately twice the reductions observed in the adult AS mouse model. Our AS mouse model saw a global delay in the onset of myelination, which normalized within days (likely corresponding to months or years in human development). This myelination delay is caused by the loss of UBE3A in neurons rather than UBE3A haploinsufficiency in oligodendrocytes. Interestingly, ultrastructural analyses did not reveal abnormalities in myelinated or unmyelinated axons.

Limitations: It is difficult to extrapolate the timing and duration of the myelination delay observed in AS model mice to individuals with AS.

Conclusions: This study reveals WM deficits as a hallmark in children with AS, demonstrating for the first time that these deficits are already apparent at 1 year of age. Parallel studies in a mouse model of AS show these deficits occur alongside the delayed onset of myelination, which results from the loss of neuronal (but not glial) UBE3A, though the causal relationship between these phenotypes remains to be determined. These findings emphasize the potential of WM as both a therapeutic target for interventions and a valuable biomarker for tracking the progression of AS and the effectiveness of potential treatments.

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人类和小鼠脑白质发育的比较分析揭示了Angelman综合征的体积缺陷和延迟髓鞘形成。

背景：Angelman综合征（AS）是一种严重的神经发育障碍，由母体UBE3A基因缺失引起，其特征是大脑白质（WM）的变化。WM异常的程度似乎与临床症状的严重程度相关，但这些缺陷仍然缺乏特征或理解。这项研究提供了第一个大规模测量的WM体积减少的儿童AS。此外，我们通过检查AS小鼠模型中髓鞘形成的进展来探讨WM潜在神经病理学的可能性。方法：对年龄0.5 ~ 12岁的AS患儿（32例）和正常对照组（99例）进行磁共振成像（MRI）检查。同时，我们检测了出生后Ube3a母鼠的髓鞘形成(Ube3am-/p+；通过MRI、免疫组织化学、western blotting和电子显微镜观察，研究了AS模型、Ube3a无父本小鼠（Ube3am+/p-）和野生型对照（Ube3am+/p+）。结果：我们的数据显示，AS个体在1岁左右表现出显著的脑容量减少，到6-12岁时，WM减少26%，灰质减少21%，大约是成年AS小鼠模型中观察到的减少量的两倍。我们的AS小鼠模型看到髓鞘形成的整体延迟，在几天内正常化（可能对应于人类发育的数月或数年）。这种髓鞘形成延迟是由神经元中UBE3A的缺失引起的，而不是由少突胶质细胞中UBE3A单倍体不足引起的。有趣的是，超微结构分析未发现有髓鞘或无髓鞘轴突异常。局限性：很难将在AS模型小鼠中观察到的髓鞘形成延迟的时间和持续时间推断为AS患者。结论：这项研究揭示了WM缺陷是as儿童的一个标志，首次证明这些缺陷在1岁时就已经很明显了。在AS小鼠模型中进行的平行研究表明，这些缺陷与髓鞘形成的延迟发生同时发生，髓鞘形成是由于神经元（而不是胶质）UBE3A的缺失造成的，尽管这些表型之间的因果关系仍有待确定。这些发现强调了WM作为干预的治疗靶点和跟踪as进展和潜在治疗有效性的有价值的生物标志物的潜力。

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

Molecular Autism GENETICS & HEREDITY-NEUROSCIENCES

CiteScore

12.10

自引率

1.60%

发文量

审稿时长

17 weeks

期刊介绍： Molecular Autism is a peer-reviewed, open access journal that publishes high-quality basic, translational and clinical research that has relevance to the etiology, pathobiology, or treatment of autism and related neurodevelopmental conditions. Research that includes integration across levels is encouraged. Molecular Autism publishes empirical studies, reviews, and brief communications.