Selective dysfunction of fast-spiking inhibitory interneurons and disruption of perineuronal nets in a tauopathy mouse model.

In Alzheimer's disease (AD), network hyperexcitability is frequently observed and associated with subsequent cognitive impairment. Dysfunction of inhibitory interneurons (INs) is thought to be one of the key biological mechanisms of hyperexcitability. However, it is still unknown how INs are functionally affected in tau pathology, which is a major pathology in AD. To clarify this, we evaluated the neuronal activity of cortical INs in 6-month-old rTg4510 mice, a model of tauopathy. Calcium imaging with mDlx enhancer-driven labeling revealed that neuronal activity in INs was decreased in rTg4510 mice. In the patch clamp recording, the firing properties of fast-spiking INs were altered so as to reduce their activity in rTg4510 mice. In parallel with microglial activation, perineuronal nets around parvalbumin-positive INs were partially disrupted in rTg4510 mice. Taken together, our data indicate that the excitability of cortical fast-spiking INs is decreased, possibly because of the disruption of perineuronal nets.

A quantitative in vivo imaging platform for tracking pathological tau depositions and resultant neuronal death in a mouse model.

PURPOSE: Depositions of tau fibrils are implicated in diverse neurodegenerative disorders, including Alzheimer's disease, and precise assessments of tau pathologies and their impacts on neuronal survival are crucial for pursuing the neurodegenerative tau pathogenesis with and without potential therapies. We aimed to establish an in vivo imaging system to quantify tau accumulations with positron emission tomography (PET) and brain atrophy with volumetric MRI in rTg4510 transgenic mice modeling neurodegenerative tauopathies. METHODS: A total of 91 rTg4510 and non-transgenic control mice underwent PET with a tau radiotracer, 18F-PM-PBB3, and MRI at various ages (1.8-12.3 months). Using the cerebellum as reference, the radiotracer binding in target regions was estimated as standardized uptake value ratio (SUVR) and distribution volume ratio (DVR). Histopathological staining of brain sections derived from scanned animals was also conducted to investigate the imaging-neuropathology correlations. RESULTS: 18F-PM-PBB3 SUVR at 40-60 min in the neocortex, hippocampus, and striatum of rTg4510 mice agreed with DVR, became significantly different from control values around 4-5 months of age, and progressively and negatively correlated with age and local volumes, respectively. Neocortical SUVR also correlated with the abundance of tau inclusions labeled with PM-PBB3 fluorescence, Gallyas-Braak silver impregnation, and anti-phospho-tau antibodies in postmortem assays. The in vivo and ex vivo 18F-PM-PBB3 binding was blocked by non-radioactive PM-PBB3. 18F-PM-PBB3 yielded a 1.6-fold greater dynamic range for tau imaging than its ancestor, 11C-PBB3. CONCLUSION: Our imaging platform has enabled the quantification of tau depositions and consequent neuronal loss and is potentially applicable to the evaluation of candidate anti-tau and neuroprotective drugs.

MRS-measured glutamate versus GABA reflects excitatory versus inhibitory neural activities in awake mice.

To assess if magnetic resonance spectroscopy (MRS)-measured Glutamate (Glu) and GABA reflect excitatory and inhibitory neural activities, respectively, we conducted MRS measurements along with two-photon mesoscopic imaging of calcium signals in excitatory and inhibitory neurons of living, unanesthetized mice. For monitoring stimulus-driven activations of a brain region, MRS signals and mesoscopic neural activities were measured during two consecutive sessions of 15-min prolonged sensory stimulations. In the first session, putative excitatory neuronal activities were increased, while inhibitory neuronal activities remained at the baseline level. In the second half, while excitatory neuronal activities remained elevated, inhibitory neuronal activities were significantly enhanced. We assessed regional neurochemical statuses by measuring MRS signals, which were overall in accordance with the neural activities, and neuronal activities and neurochemical statuses in a mouse model of Dravet syndrome under resting condition. Mesoscopic assessments showed that activities of inhibitory neurons in the cortex were diminished relative to wild-type mice in contrast to spared activities of excitatory neurons. Consistent with these observations, the Dravet model exhibited lower concentrations of GABA than wild-type controls. Collectively, the current investigations demonstrate that MRS-measured Glu and GABA can reflect spontaneous and stimulated activities of neurons producing and releasing these neurotransmitters in an awake condition.