Intrinsic pH chemosensitivity of acutely dissociated medullary serotonergic and retrotrapezoid neurones

Abstract

Central respiratory chemoreceptors (CRCs) are critically important for maintaining normal systemic levels of pH and PCO ₂ . Their specific identity has been controversial. It is widely acknowledged that CRCs must respond to small changes in pH via cell‐autonomous (intrinsic) mechanisms. However most studies designed to identify CRCs have only blocked a limited subset of synaptic mechanisms. Here we used patch‐clamp recordings to compare chemosensitivity of two candidates for CRCs: (1) Phox2b ‐expressing neurones of the retrotrapezoid nucleus (RTN) and (2) serotonin (5‐HT)‐producing neurones of the medullary raphe nuclei. We used acute dissociation to ensure responses were intrinsic. In response to a change in CO ₂ from 5% to 9% (pH 7.4 to ≈7.2) 48% of medullary 5‐HT neurones ( n  = 118) increased their firing rate by more than 20% with a mean increase of 139%, whereas 16% of RTN neurones ( n  = 93) increased their firing rate by more than 20% with a mean increase of 46%. RTN neurones that expressed Neuromedin B ( Nmb ) (a proposed biomarker of RTN CRCs) were not more likely to have a larger pH response. After 3 days in culture many RTN neurones began to receive excitatory synaptic drive from 5‐HT neurones and also responded to acidosis. These results support the conclusion that a subset of medullary 5‐HT neurones are CRCs. Many RTN neurones may play a role in integration and relay of pH information from 5‐HT neurones and other chemoreceptor sites but contribute less to direct pH sensation. image