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Mapping of the Sensory Innervation of the Mouse Lung by Specific Vagal and Dorsal Root Ganglion Neuronal Subsets

Seol-Hee Kim, Mayur J. Patil, Stephen H. Hadley, Parmvir K. Bahia, Shane G. Butler, Meghana Madaram, Thomas E. Taylor-Clark

2022eNeuro51 citationsDOIOpen Access PDF

Abstract

The airways are densely innervated by sensory afferent nerves, whose activation regulates respiration and triggers defensive reflexes (e.g., cough, bronchospasm). Airway innervation is heterogeneous, and distinct afferent subsets have distinct functional responses. However, little is known of the innervation patterns of subsets within the lung. A neuroanatomical map is critical for understanding afferent activation under physiological and pathophysiological conditions. Here, we quantified the innervation of the mouse lung by vagal and dorsal root ganglion (DRG) sensory subsets defined by the expression of Pirt (all afferents), 5HT 3 (vagal nodose afferents), Tac1 (tachykinergic afferents), and transient receptor potential vanilloid 1 channel (TRPV1; defensive/nociceptive afferents) using Cre-mediated reporter expression. We found that vagal afferents innervate almost all conducting airways and project into the alveolar region, whereas DRG afferents only innervate large airways. Of the two vagal ganglia, only nodose afferents project into the alveolar region, but both nodose and jugular afferents innervate conducting airways throughout the lung. Many afferents that project into the alveolar region express TRPV1. Few DRG afferents expressed TRPV1. Approximately 25% of blood vessels were innervated by vagal afferents (many were Tac11). Approximately 10% of blood vessels had DRG afferents (some were Tac11), but this was restricted to large vessels. Lastly, innervation of neuroepithelial bodies (NEBs) correlated with the cell number within the bodies. In conclusion, functionally distinct sensory subsets have distinct innervation patterns within the conducting airways, alveoli and blood vessels. Physiologic (e.g., stretch) and pathophysiological (e.g., inflammation, edema) stimuli likely vary throughout these regions. Our data provide a neuroanatomical basis for understanding afferent responses in vivo.

Topics & Concepts

Nodose GanglionSensory systemNeuroscienceDorsal root ganglionVagus nerveBiologyAnatomyReflexMechanoreceptorNociceptorSensory neuronSomatosensory systemAfferentSensory nerveChemoreceptorSensory receptorLungTransient receptor potential channelSpinal cordCentral nervous systemTRPV1MedicineFree nerve endingReceptorNeuropeptideRespiratory systemGanglionElectrophysiologyNociceptionSubstance PControl of respirationCapsaicinRespiratory and Cough-Related ResearchAsthma and respiratory diseasesIon Channels and Receptors
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