Centrally derived gasotransmitter modulation of hypoglossal motoneuron activity

Airway obstruction during inspiration is a hallmark trait of sleep apnea (SA). In mice, genetic elimination of the CO producing enzyme, heme oxygenase-2 (HO-2), leads to a SA phenotype predominately associated with recurrent airway obstruction. This phenotype is mitigated by either inhibition or genetic ablation of the H2S producing enzyme, cystathionine g-lysase (CSE). While these observations indicate that mutual interactions between HO-2/CO and CSE/H2S are important for regulating airway clearance, the extent of contribution from these interaction in the central nervous system to airway tone are unclear. Here, we determine how HO-2/CO and CSE/H2S impact inspiratory output from the hypoglossal nucleus (XIIn) in the isolated rhythmic brainstem slice preparation. We hypothesize that these enzymes and their respective gasotransmitter products locally interact in the inspiratory circuit to modulate the input-output (I/O) relationship between preBötC and XIIn. Electrophysiological studies conducted in brainstem slices from mice (P5-12) showed that HO-2 dysregulation, using either in wildtype slices exposed to Cr (III) Mesoporphyrin IX chloride or in slices from HO-2 null mice, increased transmission failure from preBötC to XIIn and altered the I/O relationship between the rhythm generating network and XIIn. HO-2 dysregulation also increased subnetwork activity in the preBötC that was associated with a decrease in amplitude regularity. While many transmission failures to the XIIn were associated with preBötC subnetwork activity, simultaneous recordings from the preBötC, premotor area, and the XIIn revealed that preBötC subnetwork activity was reliably transmitted to the premotor field but not to the XIIn. Dual extracellular and intracellular recordings from the preBötC and individual XIIn neurons under disinhibited conditions revealed that HO-2 dysregulation reduced inspiratory drive currents received by XIIn neurons, decreased the intrinsic excitability of XIIn neurons while also reducing the amount of preBötC subnetwork activity. Additionally, targeted inhibition of CSE/H2S activity using L-PAG or by genetic elimination of CSE in HO-2 null mice mitigated these effects of HO-2 dysregulation. Thus, the mutual interactions HO-2/CSE and CSE/H2S in the medullary brainstem appear to modulate XIIn output by: (1) causing a E/I imbalance that promotes preBötC subnetwork activity; (2) suppressing inspiratory drive received in XIIn; and (3) suppressing intrinsic excitability of XIIn neurons. These findings may be key to understanding the action by which central gasotransmitters actions contribute to upper airway muscle regulation. This work was supported by NIH: P01-HL-44454; R01NS107421. This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.