Adam Christopher D, Schellinger Emily D, White Alicia, Joksimovic Srdjan M, Takano Hajime, Coulter Douglas A
Department of Neuroscience, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA 19104.
The Research Institute of the Children's Hospital of Philadelphia, Philadelphia, PA 19104.
bioRxiv. 2024 Nov 14:2024.11.12.623184. doi: 10.1101/2024.11.12.623184.
The dentate gyrus has often been posited to act as a gate that dampens highly active afferent input into the hippocampus. Effective gating is thought to prevent seizure initiation and propagation in the hippocampus and support learning and memory processes. Pathological changes to DG circuitry that occur in temporal lobe epilepsy (TLE) can increase DG excitability and impair its gating ability which can contribute to seizures and cognitive deficits. There is evidence that TLE pathologies and seizures may independently contribute to learning and memory deficits in TLE through distinct mechanisms. These two factors are difficult to untangle since TLE pathologies can drive seizures, and seizures can worsen TLE pathologies. Here we assessed whether chemogenetically increasing dentate granule cell (DGC) excitability was enough to break down the dentate gate in the absence of TLE pathologies. We found that increasing excitability specifically in DGCs caused seizures in non-epileptic mice. Importantly, due to the modulatory nature of DREADD effects, seizures were driven by intrinsic circuit activity rather than direct activation of DGCs. These seizures resulted in a spatial memory deficit when induced after training in the spatial object recognition task and showed stereotypical patterns of activity in miniscope calcium recordings. Our results provide direct support for the dentate gate hypothesis since seizures could be induced in non-epileptic animals by artificially degrading the dentate gate with chemogenetics in the absence of epilepsy pathologies.
齿状回常被认为起到一种闸门的作用,可抑制传入海马体的高度活跃输入。有效的闸门作用被认为能防止海马体中癫痫发作的起始和传播,并支持学习和记忆过程。颞叶癫痫(TLE)中发生的齿状回回路的病理变化会增加齿状回的兴奋性并损害其闸门能力,这可能导致癫痫发作和认知缺陷。有证据表明,TLE的病理变化和癫痫发作可能通过不同机制独立导致TLE中的学习和记忆缺陷。这两个因素难以区分,因为TLE的病理变化可引发癫痫发作,而癫痫发作又会使TLE的病理变化恶化。在这里,我们评估了在不存在TLE病理变化的情况下,通过化学遗传学方法增加齿状颗粒细胞(DGC)的兴奋性是否足以打破齿状回闸门。我们发现,特异性增加DGC的兴奋性会在非癫痫小鼠中引发癫痫发作。重要的是,由于DREADD效应的调节性质,癫痫发作是由内在回路活动驱动的,而不是DGC的直接激活。在空间物体识别任务训练后诱发这些癫痫发作会导致空间记忆缺陷,并在微型显微镜钙记录中显示出刻板的活动模式。我们的结果为齿状回闸门假说提供了直接支持,因为在不存在癫痫病理变化的情况下,通过化学遗传学方法人为破坏齿状回闸门可在非癫痫动物中诱发癫痫发作。
