Brain vasculature influences local tau accumulation in the human inferior temporal gyrus

Abstract

AbstractBackgroundAlzheimer’s disease (AD) is a neurodegenerative disease that involves the accumulation of pathological tau protein. While the mechanisms behind tau accumulation are not well understood, they are pivotal to understanding the pathogenesis of AD. Because protein clearance in the brain is mediated in part by vasculature, we hypothesize that vasculature may direct the accumulation and distribution of tau pathology. In this study, we analyzed the spatial relationship between tau distribution and vasculature to elucidate vasculature’s role in tau clearance.MethodPost‐mortem human tissue samples (∼1 cm3) from the inferior temporal gyrus of 6 AD and 6 control donors were sliced at thicknesses of 500 µm to 1 mm. Tissue slices were prepared with tissue clearing. Cleared samples were stained with antibodies for tau (AT8), vasculature (GLUT1), nuclei (DAPI), and neurons (HUD). Images were collected using confocal fluorescence microscopy. A virtual reality tracing method was developed to segment individual blood vessels across large tissue volumes and 12‐21 individual vessels were isolated in each sample. Novel MATLAB scripts were developed to calculate the intensity of tau as a function of distance from the blood vessels’ surfaces.ResultIn AD samples, tau intensity varied along the length of the blood vessel and with distance from the blood vessel surface. Regions with high tau accumulation on the blood vessel surface exhibited elevated tau accumulation in the surrounding tissue. In regions with low tau accumulation on the blood vessel surface, tau intensity was observed to decrease near the vessel. The influence of blood vessels on tau intensity dissipated as distance from the vessel surface increased, where tau intensity approached the bulk value (average tau intensity across the entire image). Compared to AD samples, control tissue showed little AT8+ tau labeling and the relationship between tau and distance from blood vessels was not apparent.ConclusionThese results indicate that pathological tau accumulation is spatially related to blood vessels in AD. In addition, these data imply that blood vessels contribute to tau clearance and that vascular tau clearance is disrupted in regions with high tau accumulation.