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Optogenetic activation of enkephalinergic neurons reveals excitatory effects in the respiratory rhythm generating network

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The primary cause of death during opioid overdose is respiratory depression. Opioid-induced respiratory depression (OIRD) is characterized by a pronounced decrease in the frequency and regularity of inspiratory efforts. This… Click to show full abstract

The primary cause of death during opioid overdose is respiratory depression. Opioid-induced respiratory depression (OIRD) is characterized by a pronounced decrease in the frequency and regularity of inspiratory efforts. This rhythm suppression is caused, in part, by activation of mu-opioid receptors (MORs) in the preBötzinger Compex (preBötC), a region in the ventral medulla that generates respiratory rhythm. In response to exogenous opioids, MOR-expressing preBötC neurons undergo modest hyperpolarization and glutamatergic synaptic transmission is suppressed via effects on presynaptic release. While MOR activation often leads to [LG1] destabilization and cessation of the inspiratory rhythm, under conditions of elevated network excitability it can also stabilize rhythm generation. In addition to MOR-expressing neurons, the preBötC also contains neurons that express enkephalin, an endogenous ligand for the MOR encoded by the Penk gene. Yet, little is known about how enkephalinergic neurons and endogenous MOR signaling affect respiratory rhythm generation. We hypothesized that activation of Penk neurons in the preBötC would suppress rhythm generation which under conditions of high excitability stabilizes network activity. To test this hypothesis, we optogenetically stimulated enkephalinergic preBötC neurons while recording respiratory activityin brainstem slices from PenkCre; Rosa26Chr2:YFP neonatal mice. To our surprise, optogenetic activation of Penk neurons strongly excited, rather than suppressed, the preBötC network. Specifically, brief 200-ms light pulses evoked inspiratory bursts with a high probability and low latency, consistent with the effects of activating glutamatergic preBötC neurons. Further, prolonged 30-Hz or continuous stimulations of Penk neurons increased the frequency of the inspiratory rhythm and these effects persisted following blockade of MORs with Naloxone. Based on the initial results, we predict that Penk neurons predominantly affect preBötC activity through glutamatergic signaling. The co-release of enkephalin may serve as a negative feedback mechanism that regulates the presynaptic release of glutamate to protect against network over-excitation. Understanding the role of endogenous MOR signaling in this vital respiratory network may inspire strategies to prevent respiratory depression during administration of exogenous opioids. R00 HL145004 (Baertsch) 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.

Keywords: network; respiratory rhythm; mor; physiology; activation

Journal Title: Physiology
Year Published: 2023

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