Granule cells perform frequency-dependent pattern separation in a computational model of the dentate gyrus

IF 2.4 3区 医学 Q3 NEUROSCIENCES Hippocampus Pub Date : 2023-11-11 DOI:10.1002/hipo.23585
Selena Singh, Suzanna Becker, Thomas Trappenberg, Abraham Nunes
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Abstract

Mnemonic discrimination (MD) may be dependent on oscillatory perforant path input frequencies to the hippocampus in a “U”-shaped fashion, where some studies show that slow and fast input frequencies support MD, while other studies show that intermediate frequencies disrupt MD. We hypothesize that pattern separation (PS) underlies frequency-dependent MD performance. We aim to study, in a computational model of the hippocampal dentate gyrus (DG), the network and cellular mechanisms governing this putative “U”-shaped PS relationship. We implemented a biophysical model of the DG that produces the hypothesized “U”-shaped input frequency–PS relationship, and its associated oscillatory electrophysiological signatures. We subsequently evaluated the network's PS ability using an adapted spatiotemporal task. We undertook systematic lesion studies to identify the network-level mechanisms driving the “U”-shaped input frequency-PS relationship. A minimal circuit of a single granule cell (GC) stimulated with oscillatory inputs was also used to study potential cellular-level mechanisms. Lesioning synapses onto GCs did not impact the “U”-shaped input frequency–PS relationship. Furthermore, GC inhibition limits PS performance for fast frequency inputs, while enhancing PS for slow frequency inputs. GC interspike interval was found to be input frequency dependent in a “U”-shaped fashion, paralleling frequency-dependent PS observed at the network level. Additionally, GCs showed an attenuated firing response for fast frequency inputs. We conclude that independent of network-level inhibition, GCs may intrinsically be capable of producing a “U”-shaped input frequency-PS relationship. GCs may preferentially decorrelate slow and fast inputs via spike timing reorganization and high frequency filtering.

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颗粒细胞在齿状回的计算模型中进行频率依赖性模式分离。
记忆辨别(MD)可能依赖于以“U”形方式向海马体输入的振荡穿通路径频率,其中一些研究表明慢速和快速输入频率支持MD,而其他研究表明中频干扰MD。我们假设模式分离(PS)是频率依赖性MD性能的基础。我们的目的是在海马齿状回(DG)的计算模型中研究控制这种假定的“U”形PS关系的网络和细胞机制。我们实现了DG的生物物理模型,该模型产生了假设的“U”形输入频率PS关系及其相关的振荡电生理特征。随后,我们使用自适应时空任务评估了网络的PS能力。我们进行了系统的病变研究,以确定驱动“U”形输入频率PS关系的网络级机制。用振荡输入刺激的单个颗粒细胞(GC)的最小回路也用于研究潜在的细胞水平机制。损伤GC上的突触不会影响“U”型输入频率PS关系。此外,GC抑制限制了快速频率输入的PS性能,同时增强了慢速频率输入的PS。GC间期以“U”形的方式与输入频率相关,与在网络水平上观察到的频率相关PS平行。此外,GC对于快速频率输入显示出衰减的发射响应。我们得出结论,独立于网络级抑制,GC可能本质上能够产生“U”形输入频率PS关系。GC可以通过尖峰定时重组和高频滤波来优先解相关慢速和快速输入。
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来源期刊
Hippocampus
Hippocampus 医学-神经科学
CiteScore
5.80
自引率
5.70%
发文量
79
审稿时长
3-8 weeks
期刊介绍: Hippocampus provides a forum for the exchange of current information between investigators interested in the neurobiology of the hippocampal formation and related structures. While the relationships of submitted papers to the hippocampal formation will be evaluated liberally, the substance of appropriate papers should deal with the hippocampal formation per se or with the interaction between the hippocampal formation and other brain regions. The scope of Hippocampus is wide: single and multidisciplinary experimental studies from all fields of basic science, theoretical papers, papers dealing with hippocampal preparations as models for understanding the central nervous system, and clinical studies will be considered for publication. The Editor especially encourages the submission of papers that contribute to a functional understanding of the hippocampal formation.
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