Age‐ and sex‐dependent differences in cognitive decline in rat models of Alzheimer’s disease

Abstract

AbstractBackgroundMemory loss has been a central focus of Alzheimer’s disease (AD) research but executive dysfunction may be one of the earliest indicators of AD (Baudic et al., 2006). Executive function refers to a group of cognitive processes that are required for goal directed behaviours, such as working memory and cognitive flexibility. Amyloid‐β (Aβ) plaques and neurofibrillary tangles are considered the pathological hallmarks of AD, but evidence suggests that these are not the earliest pathologies to appear in the AD brain (Sperling et al., 2011). This highlights the importance of assessing both the prodromal and more advanced phases of AD in preclinical modelling. This study aimed to characterize age‐ and sex‐related changes in executive function, learning, and memory across normal aging in rats as well as in two aging transgenic rat strains of AD: TgAPP21 (Aβ plaque‐negative) and TgAPP/PS1 (Aβ plaque‐positive).MethodMale and female wildtype Fischer 344, TgAPP21, and TgAPP/PS1 rats were used in this study. The TgAPP21 rat overexpresses the mutant human amyloid precursor protein but does not spontaneously develop Aβ plaques, serving as an important model of prodromal AD. The TgAPP/PS1 rat overexpresses mutant human forms of both the amyloid precursor protein and Presenilin‐1 and does develop age‐dependent Aβ plaques. These strains allowed us to assess cognition under three conditions (i) normal aging, (ii) increased Aβ without plaque deposition, and (iii) age‐dependent Aβ plaque deposition. At 3, 9, or 15 months of age the rats were tested for spatial learning and memory, working memory, and cognitive flexibility using the Morris water maze, the 8‐arm radial water maze, and a T‐maze set‐shifting task.ResultAge‐dependent cognitive decline was observed across all genotypes but was exacerbated in both transgenic models. Effects of age, sex, and genotype varied across the cognitive tasks, emphasizing the importance of assessing multiple cognitive domains.ConclusionThese findings expand our understanding of the roles of sex, age and Aβ plaque‐positive/negative environments in cognitive decline in preclinical rat strains of AD. Overall, this work supports further investigation into the pathologies driving these cognitive changes and potential biomarkers for earlier detection.