APPsα Rescues Tau-Induced Synaptic Pathology

Alzheimer's disease (AD) is histopathologically characterized by A beta plaques and the accumulation of hyperphosphorylated Tau species, the latter also constituting key hallmarks of primary tauopathies. Whereas A beta is produced by amyloidogenic APP processing, APP processing along the competing nonamyloidogenic pathway results in the secretion of neurotrophic and synaptotrophic APPs alpha. Recently, we demonstrated that APPs alpha has therapeutic effects in transgenic AD model mice and rescues A beta-dependent impairments. Here, we examined the potential of APPs alpha to mitigate Tau-induced synaptic deficits in P301S mice (both sexes), a widely used mouse model of tauopathy. Analysis of synaptic plasticity revealed an aberrantly increased LTP in P301S mice that could be normalized by acute application of nanomolar amounts of APPs alpha to hippocampal slices, indicating a homeostatic function of APPs alpha on a rapid time scale. Further, AAV-mediated in vivo expression of APPs alpha restored normal spine density of CA1 neurons even at stages of advanced Tau pathology not only in P301S mice, but also in independent THY-Tau22 mice. Strikingly, when searching for the mechanism underlying aberrantly increased LTP in P301S mice, we identified an early and progressive loss of major GABAergic interneuron subtypes in the hippocampus of P301S mice, which may lead to reduced GABAergic inhibition of principal cells. Interneuron loss was paralleled by deficits in nest building, an innate behavior highly sensitive to hippocampal impairments. Together, our findings indicate that APPs alpha has therapeutic potential for Tau-mediated synaptic dysfunction and suggest that loss of interneurons leads to disturbed neuronal circuits that compromise synaptic plasticity as well as behavior.

Automated summary

The study reveals the therapeutic potential of APPs alpha in mitigating Tau-induced synaptic deficits. Additionally, loss of interneurons leads to disrupted neuronal circuits, compromising synaptic plasticity and behavior.