MrgprC11+ Jugular Neurons Control Airway Hyperresponsiveness in Allergic Airway Inflammation

Role of specialized sensory neuron subtypes in modulating peripheral immune responses

The immune and sensory nervous systems detect diverse threats, from tissue damage to infection, and coordinate protective responses to restore homeostasis. Like immune cells, sensory neurons exhibit remarkable heterogeneity, with advanced genetic models revealing that distinct subsets differentially regulate immune responses. Here, we review how various immune signals engage distinct subtypes of sensory neurons to mediate inflammatory pain, itch, relief, protective behavioral adaptations, and autonomic reflexes. We also highlight how specialized sensory neuron populations modulate immune function through the release of neuropeptides, neurokines, or glutamate. This functional specialization enables precise immunomodulation adapted to the kinetics and nature of immune responses, positioning sensory neurons as key regulators of host defense and tissue homeostasis.

Vagal sensory circuits of the lower airway in respiratory physiology: Insights from neuronal diversity

Sensory neurons innervating the lower airway provide essential feedback information that regulates respiratory physiology. These neurons synapse with second-order neurons in the central nervous system, which project directly or indirectly to the respiratory and autonomic centers. Both primary sensory neurons and second-order neurons within these circuits exhibit significant heterogeneity, and the precise roles of individual neuronal subtypes in coding the airway's internal states and modulating respiratory and autonomic outputs remain incompletely understood. In this review, we summarize recent advances in understanding the neuronal diversity along sensory circuits of the lower airway and their physiological functions. We also highlight the challenges in elucidating the roles of specific neuronal subtypes due to the extensive molecular and anatomical diversity among these neurons. Improving targeting specificity for neuronal manipulation, combined with the development of a comprehensive connectivity map, will be critical for revealing the coding and wiring logics that underlie the precise control of respiratory physiology.