Cell‐type Specific Effects of AD Mutations on Hippocampal Intrinsic Firing Properties in Genetically Diverse Mice

Abstract

AbstractBackgroundCognitive resilience to Alzheimer’s disease (AD) is a phenomenon whereby individuals with known AD mutations or high levels of pathology exhibit better than predicted cognitive performance. Identification of the factors governing resilience may lead to novel therapeutic interventions to treat AD. Analysis of hippocampal transcriptional profiles from susceptible and resilient AD‐BXD strains indicates that transcriptomic changes in excitatory neurons in CA1 and dentate gyrus (DG) are associated with resilience and we now seek to examine physiological changes.MethodWe adapted the Patch‐Seq method (Cadwell et al., 2017) to investigate cell type‐specific transcriptional and electrophysiological changes associated with AD using the AD‐BXD genetic reference panel (Neuner et al., 2019). Whole‐cell patch clamp was used to evaluate intrinsic excitability of neurons within the DG and CA1 of 14m old mice with cognitive deficits compared to age matched controls; their cellular contents, including the nucleus, were collected after each recording to characterize the transcriptome.ResultComparison of the intrinsic properties of DG and CA1 neurons of hippocampal slices from 5XFAD mice and their non‐transgenic (Ntg) counterparts revealed that DG granule cells from 5XFAD mice have a lower input resistance and an increased sag ratio in response to hyperpolarizing current injections. Pyramidal neurons from the CA1 of 5xFAD mice exhibit significantly more depolarized action potential thresholds, a significant increase in the medium afterhyperpolarization (mAHP) and sag ratio compared to Ntg controls. While these intrinsic properties are proxy measures for neuronal excitability, we did not observe a significant effect of genotype on firing rate in response to 1s and 15s depolarizing current steps.ConclusionOur findings newly demonstrate disease related changes to intrinsic firing properties of DG granule cells at 14mo indicating that these neurons may be hypoexcitable. Also found, CA1 neurons from AD mice exhibit an increased mAHP and changes to sag ratio and AP threshold, indicating they too become less excitable. Future work will add additional AD‐BXD strains characterized as resilient or susceptible to the AD transgene to discover changes in intrinsic properties that could underlie resilience. We will also use an integrated analysis of transcriptomic and electrophysiological data to identify relevant functional targets for validation.