Centre for Medical Image Computing, University College London, London, UK.
Department of Neurodegenerative Disease, UCL Queen Square Institute of Neurology, London, UK.
Neuropathol Appl Neurobiol. 2022 Feb;48(1):e12758. doi: 10.1111/nan.12758. Epub 2021 Sep 5.
The causes of distinct patterns of reduced cortical thickness in the common human epilepsies, detectable on neuroimaging and with important clinical consequences, are unknown. We investigated the underlying mechanisms of cortical thinning using a systems-level analysis.
Imaging-based cortical structural maps from a large-scale epilepsy neuroimaging study were overlaid with highly spatially resolved human brain gene expression data from the Allen Human Brain Atlas. Cell-type deconvolution, differential expression analysis and cell-type enrichment analyses were used to identify differences in cell-type distribution. These differences were followed up in post-mortem brain tissue from humans with epilepsy using Iba1 immunolabelling. Furthermore, to investigate a causal effect in cortical thinning, cell-type-specific depletion was used in a murine model of acquired epilepsy.
We identified elevated fractions of microglia and endothelial cells in regions of reduced cortical thickness. Differentially expressed genes showed enrichment for microglial markers and, in particular, activated microglial states. Analysis of post-mortem brain tissue from humans with epilepsy confirmed excess activated microglia. In the murine model, transient depletion of activated microglia during the early phase of the disease development prevented cortical thinning and neuronal cell loss in the temporal cortex. Although the development of chronic seizures was unaffected, the epileptic mice with early depletion of activated microglia did not develop deficits in a non-spatial memory test seen in epileptic mice not depleted of microglia.
These convergent data strongly implicate activated microglia in cortical thinning, representing a new dimension for concern and disease modification in the epilepsies, potentially distinct from seizure control.
在常见的人类癫痫中,神经影像学可检测到皮质厚度明显变薄的不同模式,这些模式具有重要的临床意义,但其原因尚不清楚。我们使用系统水平分析来研究皮质变薄的潜在机制。
在一项大规模癫痫神经影像学研究中,将基于成像的皮质结构图谱与来自艾伦人类大脑图谱的高空间分辨率人类大脑基因表达数据叠加。使用细胞类型去卷积、差异表达分析和细胞类型富集分析来识别细胞类型分布的差异。在癫痫患者的死后脑组织中使用 Iba1 免疫标记对这些差异进行了后续研究。此外,为了研究皮质变薄中的因果效应,在获得性癫痫的小鼠模型中使用了细胞类型特异性耗竭。
我们发现,在皮质厚度减少的区域,小胶质细胞和内皮细胞的比例升高。差异表达的基因富集了小胶质细胞标记物,特别是激活的小胶质细胞状态。对癫痫患者死后脑组织的分析证实了过度激活的小胶质细胞的存在。在小鼠模型中,在疾病早期阶段短暂耗竭激活的小胶质细胞可防止颞叶皮质的皮质变薄和神经元细胞丢失。虽然慢性癫痫发作的发展不受影响,但在早期耗竭激活小胶质细胞的癫痫小鼠中,不会出现未耗竭小胶质细胞的癫痫小鼠在非空间记忆测试中出现的缺陷。
这些一致的数据强烈提示激活的小胶质细胞在皮质变薄中起作用,这代表了癫痫中值得关注和疾病修饰的新维度,可能与控制癫痫发作不同。