Subiculum fiber degeneration within the fornix white matter tract in 5xFAD mice

Abstract

AbstractBackgroundAlzheimer’s disease (AD) is a progressive neurodegenerative disease that affects all components of the neurovascular unit. The hallmark pathology of AD, amyloid plaques and tau neurofibrillary tangles, aggregate within gray matter areas and spread across neural networks. Although AD pathology is scarce within white matter brain regions, white matter abnormalities have been observed in AD patients using diffusion tensor imaging (DTI; Sachdev et al 2013) and white matter tracts are putative therapeutic targets for deep brain stimulation (Lam et al 2020). Particularly, the fornix is a white matter tract which connects the hippocampus to brain regions of the classic Papez circuit and Default Mode Network (DMN). A recent whole brain analysis using transgenic 5xFAD/Thy1‐GFP mouse (Zhang et al 2020) found evidence of fornix degeneration and dystrophic axon terminals within the mammillary body (a major SUB target) occurring as early as 2 months of age. However, due to the broad expression of GFP under the Thy1 promotor, it is difficult to determine the origin of axon fibers and further characterize if other SUB pathways are also affected.MethodTo investigate white matter changes in AD and further characterize SUB axon degeneration, we performed triple anterograde tract‐tracing of SUB axon fibers and post‐mortem DTI tractography imaging within the same 8‐9 mo. old 5xFAD mice.ResultDTI imaging revealed a significant decrease in fiber density of the fornix white matter tract in 5xFAD mice. Quantification of tracer‐labeled fluorescent fiber density in the 5xFAD mice vs control mice also revealed significant degeneration of SUB fibers within the fornix white matter as well as downstream SUB targets including mammillary body, retrosplenial cortex, and anterior thalamus. Furthermore, SUB axon terminals in 5xFAD mice appeared dystrophic and terminal field topography was disrupted.ConclusionDTI imaging and anatomical tract tracing approaches reveal white matter degeneration in 5xFAD mice and the fornix/SUB fibers are particularly vulnerable in AD. Diminished SUB input to brain regions of the Papez circuit/DMN likely leads to neural network dysfunction. Whether amyloid pathology, neurovascular dysfunction, or inflammatory response in the 5xFAD mouse contributes to white matter degeneration remains to be determined by future studies.