Specific small-molecule inhibition of PLD1 prevents ADRD-like memory deficits by preserving dendritic spine integrity driven by amyloidogenic proteins.

Abstract

Phosphatidyl choline phospholipase D (PC-PLD), a lipolytic enzyme that breaks down membrane phospholipids via two isoforms - a constitutively expressed PLD2 and an inducible PLD1 isoform - are also involved in developmentally important signaling mechanisms that regulate synaptic function. We were the first to propose and present a systematic study that established PLD1 as the aberrantly elevated isoform in AD and related dementia using human clinical samples and provided functional proof using mouse models to demonstrate the underlying synaptic dysfunction and memory deficits. Synaptosomal Western blot analysis on 12 month 3xTg-AD mice hippocampi were used to investigate neuronal PLD1 expression and function. Long term potentiation of PLD1 dependent changes using pharmacological approaches in ex vivo slice preparations from wildtype and transgenic mouse models were used to assess synaptic perturbations that were first studied using the novel object recognition memory (NOR) and fear conditioning (FC) paradigms. Chronic PLD1 small molecule inhibitor treatment was assessed to ascertain the efficacy against Aβ and tau-driven AD-like memory deficit progression. Lastly, brain tissues from these animals were subjected to Western Blot analyses, Golgi analysis, immunohistochemical analysis to ascertain the potential signaling mechanism(s) that is/are perturbed/altered by overexpression of PLD1 in such diseased states. Chronic PLD1 inhibition ameliorates the synaptic dysfunction and underlying memory deficits in the 3xTg-AD mouse model by specific action on preserving mushroom spine dendritic spine integrity. Further analysis using Western Blots revealed an underlying mechanism. Using chronic administration of a well-tolerated halopemide derivative of the specific PLD1 isoform inhibitor in the preclinical mouse models of synaptic dysfunction and memory deficits associated with amyloidogenic effects of Aβ and tau, we demonstrated neuroprotective aspects involving changes in the dendritic spine integrity that contributes to the preservation of memory.