AUTHOR=Mouradian Gary C. , Liu Pengyuan , Nakagawa Pablo , Duffy Erin , Gomez Vargas Javier , Balapattabi Kirthikaa , Grobe Justin L. , Sigmund Curt D. , Hodges Matthew R. 

TITLE=Patch-to-Seq and Transcriptomic Analyses Yield Molecular Markers of Functionally Distinct Brainstem Serotonin Neurons

JOURNAL=Frontiers in Synaptic Neuroscience

VOLUME=14

YEAR=2022

URL=https://www.frontiersin.org/journals/synaptic-neuroscience/articles/10.3389/fnsyn.2022.910820

DOI=10.3389/fnsyn.2022.910820

ISSN=1663-3563

ABSTRACT=<p>Acute regulation of CO<sub>2</sub> and pH homeostasis requires sensory feedback from peripheral (carotid body) and central (central) CO<sub>2</sub>/pH sensitive cells – so called respiratory chemoreceptors. Subsets of brainstem serotonin (5-HT) neurons in the medullary raphe are CO<sub>2</sub> sensitive or insensitive based on differences in embryonic origin, suggesting these functionally distinct subpopulations may have unique transcriptional profiles. Here, we used Patch-to-Seq to determine if the CO<sub>2</sub> responses in brainstem 5-HT neurons could be correlated to unique transcriptional profiles and/or unique molecular markers and pathways. First, firing rate changes with hypercapnic acidosis were measured in fluorescently labeled 5-HT neurons in acute brainstem slices from transgenic, Dahl SS (SSMcwi) rats expressing T2/ePet-eGFP transgene in Pet-1 expressing (serotonin) neurons (SS<sup><italic>ePet</italic>1–eGFP</sup> rats). Subsequently, the transcriptomic and pathway profiles of CO<sub>2</sub> sensitive and insensitive 5-HT neurons were determined and compared by single cell RNA (scRNAseq) and bioinformatic analyses. Low baseline firing rates were a distinguishing feature of CO<sub>2</sub> sensitive 5-HT neurons. scRNAseq of these recorded neurons revealed 166 differentially expressed genes among CO<sub>2</sub> sensitive and insensitive 5-HT neurons. Pathway analyses yielded novel predicted upstream regulators, including the transcription factor <italic>Egr2</italic> and <italic>Leptin</italic>. Additional bioinformatic analyses identified 6 candidate gene markers of CO<sub>2</sub> sensitive 5-HT neurons, and 2 selected candidate genes (<italic>CD46</italic> and <italic>Iba57</italic>) were both expressed in 5-HT neurons determined via <italic>in situ</italic> mRNA hybridization. Together, these data provide novel insights into the transcriptional control of cellular chemoreception and provide unbiased candidate gene markers of CO<sub>2</sub> sensitive 5-HT neurons. Methodologically, these data highlight the utility of the patch-to-seq technique in enabling the linkage of gene expression to specific functions, like CO<sub>2</sub> chemoreception, in a single cell to identify potential mechanisms underlying functional differences in otherwise similar cell types.</p>