Abstract
Amyloid precursor protein (APP) is the precursor to Aβ plaques. The cytoplasmic domain of APP mediates attachment of vesicles to molecular motors for axonal transport. In APP-KO mice, transport of Mn2+ is decreased. In old transgenic mice expressing mutated human (APPSwInd) linked to Familial Alzheimer’s Disease, with both expression of APPSwInd and plaques, the rate and destination of Mn2+ axonal transport is altered, as detected by time-lapse manganese-enhanced magnetic resonance imaging (MEMRI) of the brain in living mice. To determine the relative contribution of expression of APPSwInd versus plaque on transport dynamics, we developed a Tet-off system to decouple expression of APPSwInd from plaque, and then studied hippocampal to forebrain transport by MEMRI. Three groups of mice were compared to wild-type (WT): Mice with plaque and APPSwInd expression; mice with plaque but suppression of APPSwInd expression; and mice with APPSwInd suppressed from mating until 2 weeks before imaging with no plaque. MR images were captured before at successive time points after stereotactic injection of Mn2+ (3–5 nL) into CA3 of the hippocampus. Mice were returned to their home cage between imaging sessions so that transport would occur in the awake freely moving animal. Images of multiple mice from the three groups (suppressed or expressed) together with C57/B6J WT were aligned and processed with our automated computational pipeline, and voxel-wise statistical parametric mapping (SPM) performed. At the conclusion of MR imaging, brains were harvested for biochemistry or histopathology. Paired T-tests within-group between time points (p = 0.01 FDR corrected) support the impression that both plaque alone and APPSwInd expression alone alter transport rates and destination of Mn2+ accumulation. Expression of APPSwInd in the absence of plaque or detectable Aβ also resulted in transport defects as well as pathology of hippocampus and medial septum, suggesting two sources of pathology occur in familial Alzheimer’s disease, from toxic mutant protein as well as plaque. Alternatively mice with plaque without APPSwInd expression resemble the human condition of sporadic Alzheimer’s, and had better transport. Thus, these mice with APPSwInd expression suppressed after plaque formation will be most useful in preclinical trials.
Highlights
Alzheimer’s disease (AD), a progressive, debilitating illness, ends in death
We examined five mice from each of our four groups of transcription activator (tTA)/APPSwInd double transgenic, Group A, Group B, Group C, and Group D for expression of the APPSwInd transgene by Western blot, the presence of Aβ by dot blot, and presence of plaques by histochemistry (Figures 2B,C)
We show by live, longitudinal MRI of the whole brain, differences in axonal transport dynamics with and without plaque in mouse models of Alzheimer’s disease
Summary
Alzheimer’s disease (AD), a progressive, debilitating illness, ends in death. No cure or even any effective treatment is yet available. We use manganese-enhanced magnetic resonance imaging (MEMRI) to study axonal transport in the living brain (Bearer et al, 2007a,b, 2009a,b, 2018; Zhang et al, 2010; Gallagher et al, 2012, 2013). Distal accumulation of Mn2+, giving hyper-intense T1-weighted signal, can be identified in MRI images using statistical parametric mapping (Friston, 1996), revealing the anatomy of projections and rates of transport. Using this technique, we recently reported that in aging mice expressing a FAD-associated mutant APP, APPSwInd, and dense plaques, transport is significantly decreased and terminal destinations are altered (Bearer et al, 2018)
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