Hyperexcitability of Nucleus Tractus Solitarii Neurons in the Streptozotocin‐Induced Model of Alzheimer's Disease

Abstract

Besides the stereotypical problems of memory and cognition in patients with Alzheimer's Disease (AD), another highly prevalent symptom is of respiratory origin. We have repeatedly shown blunted respiratory responses to hypoxia in the streptozotocin (STZ) -induced AD model, which is similar to sleep disordered breathing found in nearly 80% of AD patients. Our current study focuses on the electrophysiological changes within the nucleus tractus solitarii (nTS), a brainstem area known to control respiratory function. Using male Sprague-Dawley rats (n = 15 rats, 240±8 g), we induced AD symptoms with microinjections of 2 mg/kg Streptozotocin (STZ) into the lateral cerebral ventricles. Control animals received 0.9 mM citrate buffer as vehicle control (CTL). The disease model was verified using the Morris water maze to test for memory dysfunction. We recorded nTS neuronal responses via whole cell patch clamp. Action potential (AP) discharge upon current-stimulation was higher in STZ-AD when compared to control. Also, spontaneous spike activity (no stimulation) was elevated. These data corroborate earlier results using a higher (2x1.5 mg) STZ dosage. Spontaneous post-synaptic currents in the absence of stimulation resemble nTS network activity. The number of spontaneous events in nTS neurons of the STZ-AD group was surprisingly similar to CTL in the current study. On the other hand, network activity mirrors the hyperexcitability seen from our current injection when using the higher STZ dosage. While there was no appreciable change in resting membrane potential, AP threshold of STZ-AD nTS cells shifted towards a more negative membrane potential, overall contributing to increased excitability in these cells. AP phase plane plots in STZ-AD had a significantly smaller overshoot with a reduced velocity of up and down stroke, possibly indicating altered function of voltage-gated sodium channels. Analysis of transient K+ currents (A-type) revealed a slight shift to higher activation voltages (from -20 mV [CTL] to 0 mV [STZ-AD]) in STZ-AD. This shift favors AP generation and may contribute to a lower spike threshold in STZ-AD. There were no changes in the steady state K+ currents between groups. In summary, nTS cells of the STZ-AD group showed increased excitability that may involve gating properties of voltage-gated sodium channels and A-type potassium channels. The observed neurophysiological changes in the nTS may be part of the neuronal correlate for increased breathing frequency and blunted (ceiling effect) respiratory responses to hypoxia in the STZ-AD model.