Evidence of structural and functional plasticity occurring within the intracardiac nervous system of spontaneously hypertensive rats

Plasticity is a fundamental property of neurons in both the central and peripheral nervous systems, enabling rapid changes in neural network function. The intracardiac nervous system (ICNS) is an extensive network of neurons clustered into ganglionated plexi (GP) on the surface of the heart. GP neurons are the final site of neuronal control of heart rhythm, and pathophysiological remodeling of the ICNS is proposed to feature in multiple cardiovascular diseases, including heart failure and atrial fibrillation. To examine the potential role of GP neuron plasticity in atrial arrhythmia and hypertension, we developed whole cell patch clamp recording techniques from GP neurons in isolated ICNS preparations from aged control (Wistar-Kyoto) and spontaneously hypertensive rats (SHRs). Anesthetized SHRs showed frequent premature ventricular contractions and episodes of atrial arrhythmia following carbachol injection, and isolated SHR atrial preparations were susceptible to pacing induced atrial arrhythmia. Whole cell recordings revealed elevated spontaneous postsynaptic current frequency in SHR GP neurons, as well as remodeled electrophysiology, with significant decreases in action potential amplitude and half-width. SHRs also showed a parallel increase in the number of cholinergic neurons and adrenergic glomus cells in cardiac ganglia, a higher proportion of synaptic α7-subunit but not β2-containing nicotinic receptors, and an elevation in the number of synaptic terminals onto GP neurons. Our data show that significant structural and functional plasticity occurs in the intracardiac nervous system and suggest that enhanced excitability through synaptic plasticity, together with remodeling of cardiac neuron electrophysiology, contributes to the substrate for atrial arrhythmia in hypertensive heart disease. We have developed intracardiac neuron whole cell recording techniques in atrial preparations from control and spontaneous hypertensive rats. This has enabled the identification of significant synaptic plasticity in the intracardiac nervous system, including enhanced postsynaptic current frequency, increased synaptic terminal density, and altered postsynaptic receptors. This increased synaptic drive together with altered cardiac neuron electrophysiology could increase intracardiac nervous system excitability and contribute to the substrate for atrial arrhythmia in hypertensive heart disease.