Lee Sang-Hun, Kang Young-Jin, Smith Bret N
bioRxiv. 2024 Apr 8:2024.04.05.588316. doi: 10.1101/2024.04.05.588316.
Parvalbumin-positive (PV+) GABAergic interneurons in the dentate gyrus provide powerful perisomatic inhibition of dentate granule cells (DGCs) to prevent overexcitation and maintain the stability of dentate gyrus circuits. Most dentate PV+ interneurons survive status epilepticus, but surviving PV+ interneuron mediated inhibition is compromised in the dentate gyrus shortly after status epilepticus, contributing to epileptogenesis in temporal lobe epilepsy. It is uncertain whether the impaired activity of dentate PV+ interneurons recovers at later times or if it continues for months following status epilepticus. The development of compensatory modifications related to PV+ interneuron circuits in the months following status epilepticus is unknown, although reduced dentate GABAergic inhibition persists long after status epilepticus. We employed PV immunostaining and whole-cell patch-clamp recordings from dentate PV+ interneurons and DGCs in slices from male and female sham controls and intrahippocampal kainate (IHK) treated mice that developed spontaneous seizures months after status epilepticus to study epilepsy-associated changes in dentate PV+ interneuron circuits. We found that the number of dentate PV+ cells was reduced in IHK treated mice. Electrical recordings showed that: 1) Action potential firing rates of dentate PV+ interneurons were reduced in IHK treated mice up to four months after status epilepticus; 2) Spontaneous inhibitory postsynaptic currents (sIPSCs) in DGCs exhibited reduced frequency but increased amplitude in IHK treated mice; and 3) The amplitude of evoked IPSCs in DGCs by optogenetic activation of dentate PV+ cells was upregulated without changes in short-term plasticity. Video-EEG recordings revealed that IHK treated mice showed spontaneous epileptiform activity in the dentate gyrus and that chemogenetic activation of PV+ interneurons abolished the epileptiform activity. Our results suggest not only that the compensatory changes in PV+ interneuron circuits develop after IHK treatment, but also that increased PV+ interneuron mediated inhibition in the dentate gyrus may compensate for cell loss and reduced intrinsic excitability of dentate PV+ interneurons to stop seizures in temporal lobe epilepsy.
Reduced number of dentate PV+ interneurons in TLE micePersistently reduced action potential firing rates of dentate PV+ interneurons in TLE miceEnhanced amplitude but decreased frequency of spontaneous IPSCs in the dentate gyrus in TLE miceIncreased amplitude of evoked IPSCs mediated by dentate PV+ interneurons in TLE miceChemogenetic activation of PV+ interneurons prevents epileptiform activity in TLE mice.
齿状回中表达小白蛋白的(PV+)γ-氨基丁酸能中间神经元对齿状颗粒细胞(DGCs)提供强大的胞体周围抑制,以防止过度兴奋并维持齿状回回路的稳定性。大多数齿状PV+中间神经元在癫痫持续状态后存活,但癫痫持续状态后不久,齿状回中存活的PV+中间神经元介导的抑制作用受损,这有助于颞叶癫痫的癫痫发生。尚不确定齿状PV+中间神经元的受损活动在后期是否恢复,或者在癫痫持续状态后是否会持续数月。癫痫持续状态后数月与PV+中间神经元回路相关的代偿性改变的发展情况尚不清楚,尽管齿状γ-氨基丁酸能抑制在癫痫持续状态后很长时间仍然持续降低。我们采用PV免疫染色以及对雄性和雌性假手术对照组和海马内注射红藻氨酸(IHK)处理的小鼠(这些小鼠在癫痫持续状态数月后出现自发性癫痫发作)脑片中的齿状PV+中间神经元和DGCs进行全细胞膜片钳记录,以研究齿状PV+中间神经元回路中与癫痫相关的变化。我们发现,IHK处理的小鼠中齿状PV+细胞数量减少。电生理记录显示:1)在癫痫持续状态后长达四个月的时间里,IHK处理的小鼠中齿状PV+中间神经元的动作电位发放频率降低;2)在IHK处理的小鼠中,DGCs中的自发性抑制性突触后电流(sIPSCs)频率降低但幅度增加;3)通过光遗传学激活齿状PV+细胞诱发的DGCs中的抑制性突触后电流(IPSCs)幅度上调,短期可塑性无变化。视频脑电图记录显示,IHK处理的小鼠在齿状回中表现出自发性癫痫样活动,而PV+中间神经元的化学遗传学激活消除了癫痫样活动。我们的结果表明,不仅PV+中间神经元回路的代偿性变化在IHK处理后出现,而且齿状回中PV+中间神经元介导的抑制作用增强可能会补偿细胞损失以及齿状PV+中间神经元内在兴奋性的降低,从而在颞叶癫痫中阻止癫痫发作。
颞叶癫痫(TLE)小鼠中齿状PV+中间神经元数量减少
颞叶癫痫小鼠中齿状PV+中间神经元的动作电位发放频率持续降低
颞叶癫痫小鼠齿状回中自发性IPSCs幅度增强但频率降低
颞叶癫痫小鼠中齿状PV+中间神经元介导的诱发IPSCs幅度增加
PV+中间神经元的化学遗传学激活可防止颞叶癫痫小鼠的癫痫样活动
