人类干细胞来源的雷特综合征神经元网络中钙依赖性过度兴奋

Calcium-Dependent Hyperexcitability in Human Stem Cell-Derived Rett Syndrome Neuronal Networks.

作者信息

Pradeepan Kartik S, McCready Fraser P, Wei Wei, Khaki Milad, Zhang Wenbo, Salter Michael W, Ellis James, Martinez-Trujillo Julio

机构信息

Graduate Program in Neuroscience, Schulich School of Medicine & Dentistry, Western University, London, Ontario, Canada.

Robarts Research Institute, Western University, London, Ontario, Canada.

出版信息

Biol Psychiatry Glob Open Sci. 2024 Jan 24;4(2):100290. doi: 10.1016/j.bpsgos.2024.100290. eCollection 2024 Mar.

BACKGROUND

Mutations in predominantly cause Rett syndrome and can be modeled in vitro using human stem cell-derived neurons. Patients with Rett syndrome have signs of cortical hyperexcitability, such as seizures. Human stem cell-derived null excitatory neurons have smaller soma size and reduced synaptic connectivity but are also hyperexcitable due to higher input resistance. Paradoxically, networks of null neurons show a decrease in the frequency of network bursts consistent with a hypoconnectivity phenotype. Here, we examine this issue.

METHODS

We reanalyzed multielectrode array data from 3 isogenic cell line pairs recorded over 6 weeks ( = 144). We used a custom burst detection algorithm to analyze network events and isolated a phenomenon that we termed reverberating super bursts (RSBs). To probe potential mechanisms of RSBs, we conducted pharmacological manipulations using bicuculline, EGTA-AM, and DMSO on 1 cell line ( = 34).

RESULTS

RSBs, often misidentified as single long-duration bursts, consisted of a large-amplitude initial burst followed by several high-frequency, low-amplitude minibursts. Our analysis revealed that null networks exhibited increased frequency of RSBs, which produced increased bursts compared with isogenic controls. Bicuculline or DMSO treatment did not affect RSBs. EGTA-AM selectively eliminated RSBs and rescued network burst dynamics.

CONCLUSIONS

During early development, null neurons are hyperexcitable and produce hyperexcitable networks. This may predispose them to the emergence of hypersynchronic states that potentially translate into seizures. Network hyperexcitability depends on asynchronous neurotransmitter release that is likely driven by presynaptic Ca and can be rescued by EGTA-AM to restore typical network dynamics.

背景

突变主要导致雷特综合征，并且可以使用人类干细胞衍生的神经元在体外进行建模。雷特综合征患者具有皮质兴奋性过高的体征，如癫痫发作。人类干细胞衍生的缺乏该基因的兴奋性神经元具有较小的胞体大小和减少的突触连接性，但由于较高的输入电阻也表现为兴奋性过高。矛盾的是，缺乏该基因的神经元网络显示网络爆发频率降低，这与低连接表型一致。在此，我们研究这个问题。

方法

我们重新分析了来自3对同基因细胞系的数据，这些数据是在6周内记录的多电极阵列数据（n = 144）。我们使用定制的爆发检测算法来分析网络事件，并分离出一种我们称为回响超级爆发（RSB）的现象。为了探究RSB的潜在机制，我们对1个细胞系（n = 34）使用荷包牡丹碱、乙二醇双乙酸盐（EGTA-AM）和二甲基亚砜（DMSO）进行了药理学操作。

结果

RSB通常被错误地识别为单个长时间爆发，由一个大振幅的初始爆发 followed by several high-frequency, low-amplitude minibursts. Our analysis revealed that null networks exhibited increased frequency of RSBs, which produced increased bursts compared with isogenic controls. Bicuculline or DMSO treatment did not affect RSBs. EGTA-AM selectively eliminated RSBs and rescued network burst dynamics.