Vagus Nerve Sensory Neurons Respond Distinctly to Specific Inflammatory Mediators

Abstract

The peripheral nervous system communicates with the immune system in response to injury or infection. In the case of inflammation, sensory signals travel up to the brain via the vagus nerve, which is a major pathway for neuro‐immune communication. While previous work from our group showed that cytokines administered systemically were associated with specific patterns of vagus nerve activity, we did not know how individual vagal sensory neurons encoded this immune information.Here, we use in vivo calcium imaging to monitor the neural activity of individual vagal sensory neurons in response to specific inflammatory mediators. Using mice that express the calcium sensor GCaMP6f in glutamatergic neurons, we imaged neurons of the nodose ganglion in situ using a 1‐photon miniature microscope (Miniscope). During imaging, the inflammatory mediators tumor necrosis factor (TNF) and interleukin 1β (IL‐1β) were applied directly to the vagus nerve. The raw fluorescence data was analyzed with a Python‐based calcium imaging analysis (CaImAn) software and a customized pipelines to output the neural activity (change in fluorescence: ∆F) of individually detected neurons. An average of 69±16.3 neurons were recorded per 1 hour imaging session.Our results reveal that specific vagal sensory neurons respond to differentially to specific immune mediators. The average amplitude, integral, and delay of TNF‐responsive neurons was significantly higher than IL‐1β‐responsive cells (TNF vs IL‐1β, p < 0.01). This result suggests that TNF application triggers responses later and with higher firing rates in responsive neurons compared to IL‐1β. Neuronal responses to IL‐1β had a significantly higher number of peaks when compared to TNF responses (IL‐1β vs TNF, p < 0.05). When compared to responses for the TRPV1‐specific agonist capsaicin, the cytokine responses were found to have significantly lower number of peaks (capsaicin vs IL‐1β, p < 0.05), which suggests that immune mediators produce different neural activity than canonical activators. Taken together, our findings demonstrate that individual vagal sensory neurons encode information about distinct inflammatory stimuli and provide insight into the neural sensing of inflammation. Further investigation into this type of neuro‐immune signaling may identify novel neural targets for the treatment of inflammatory disorders.