Aortic bodies are arterial chemoreceptors presumed to monitor blood O2 content by unknown mechanisms, in contrast to their well-studied carotid body counterparts, which monitor PO2 and /pH. We recently showed that rat aortic body chemoreceptors (type I cells), located at the left vagus-recurrent laryngeal nerve bifurcation, responded to PO2 and PCO2 /pH in a manner similar to carotid body type I cells. These aortic bodies are uniquely associated with a group of local neurons, which are also sensitive to these stimuli. Here, we hypothesized that these local neurons may contribute to monitoring blood O2 content. During perforated patch recordings, ATP, known to be released from (carotid body) type I cells and red blood cells during hypoxia, induced inward currents and excited ≈ 45% of local neurons (EC50 ≈ 1 μm), mainly via heteromeric P2X2/3 purinoceptors. While ATP also induced a rise in intracellular [Ca(2+)] in a subpopulation of these neurons, almost all of them responded to nicotinic cholinergic agonists. During paired recordings, several juxtaposed neurons showed strong bidirectional electrical coupling, suggesting a local co-ordination of electrical activity. Perfusion with Evans Blue dye resulted in labelling of aortic body paraganglia, suggesting they have ready access to circulatory factors, e.g. ATP released from red blood cells during hypoxia. When combined with confocal immunofluorescence, the dye-labelled regions coincided with areas containing tyrosine hydroxylase-positive type I cell clusters and P2X2-positive nerve endings. We propose a working model whereby local neurons, red blood cells, ATP signalling and low blood flow contribute to the unique ability of the aortic body to monitor blood O2 content.