The Role of Glutamatergic Signaling in Central Noradrenergic Neurons in Respiratory Control

Abstract

Central noradrenergic (NA) neurons are key constituents of the respiratory homeostatic network. NA dysfunction is implicated in several developmental respiratory disorders such as the fatal Sudden Infant Death Syndrome (SIDS) and Rett Syndrome, in which abnormal chemosensory function is thought to play a role. However, which NA populations modulate respiratory chemoreflexes and the underlying mechanisms are still not fully understood. Histological evidence suggests that glutamate is co‐transmitted in subsets of brainstem NA neurons, some of which may contribute to regulating chemoreflexes. However, the extent of glutamate co‐transmission in the central NA system remains uncharacterized. Further, it remains unclear what role NA‐based glutamatergic signaling plays in various aspects of respiratory homeostasis.To anatomically map potential glutamate‐expressing NA neurons, we characterized the expression profile of all three known of Vesicular Glutamate Transporters (Vglut1, Vglut2 and Vglut3) in NA neurons by intersectional genetic fate mapping. For each Vglut1/2/3 transporter, acorresponding Cre knock‐in recombinase line was combined with DBH‐p2a_Flpomice. These Vglut1/2/3_Cre; DBH‐p2a_Flpocompound lines were crossed with the RC::F_TdTomato_P_GFPintersectional reporter mice. In each of the three intersectional reporter crosses, NA neurons co‐expressing either Vglut1, Vglut2, or Vglut3 are labeled by green fluorescent protein (GFP) while NA neurons without any Vglut1/2/3 expression are labelled by red fluorescent protein (tdTomato). Our preliminary fate maps, which reflect the cumulative expression profiles of glutamate markers in NA neurons throughout the development and lifetime of the mouse, found that about 80% NA neurons express Vglut2 at some point during their development and posterior medullary NA neurons express Vglut3 as well.Prior studies suggest that Vglut2‐based glutamatergic signaling may play a role in respiratory control. To determine what physiological role, if any, Vglut2‐based glutamatergic signaling may play in adult respiratory homeostasis, we conditionally ablated Vglut2 in central NA neurons by crossing DBH‐Cre/+with Vglut2flox/flox mice. Mutants and sibling controls (6‐8 weeks) were assessed for respiratory function by whole‐body barometric plethysmography. Ventilation and VO2 were assessed under room air (21%O2,79%N2), hypercapnia (21%O2, 74/72/69%N2, 5/7/10%CO2) and hypoxia (10% O2, 90% N2). Our preliminary data indicates that loss of Vglut2 in NA neurons does not significantly impact breathing under room air, hypercapnia, or hypoxia. Thus, our data suggests that Vglut2‐based glutamatergic signaling within the central NA system is dispensable for normal baseline breathing and hypercapnic, and hypoxic chemosensory reflexes.