Changes in tyrosine hydroxylase and substance P immunoreactivity in the cat carotid body following chronic hypoxia and denervation.

Long-term hypoxia elicits functional changes in the cat carotid body which are manifest as altered chemosensitivity in response to hypoxia. Previous studies have suggested that these functional adjustments may be mediated by changes in neurotransmitter levels in chemosensory type I cells. Neurotransmitter metabolism in the carotid body has also been shown to be regulated by the neural innervation to the organ. The present study using the cat carotid body demonstrates profound changes in the levels of immunoreactivity of the catecholamine-synthesizing enzyme, tyrosine hydroxylase, and the neuropeptide, substance P, in response to a two-week exposure to hypoxia (10% O2 in 90% N2). Furthermore, these changes were modulated both by sensory and sympathetic denervation of the organ. For TH, the intensity of immunostaining in type I cells was markedly increased by long-term hypoxia in both normal and chronic carotid sinus nerve-denervated carotid bodies, but this effect was blocked following chronic sympathectomy. Substance P immunoreactivity in type I cells was dramatically attenuated by hypoxia in both intact and chronic carotid sinus nerve-denervated preparations, but this effect was reduced following chronic sympathectomy. Tyrosine hydroxylase- and substance P-positive axon terminals were observed to innervate type I cells. These axons were also present in chronically sympathectomized preparations, but they disappeared following chronic carotid sinus nerve-denervation suggesting that they very likely arise from sensory neurons in the petrosal ganglion. Our data indicate that chronic chemoreceptor stimulation by hypoxia elicits multiple neurochemical adjustments in the cat carotid body. These changes suggest that catecholaminergic enzymes and neuropeptides play a significant role in the adaptive mechanisms of chemoreceptor function which occur in response to chronic physiological stimulation. Furthermore, the data suggest that neurotrophic mechanisms may influence neurotransmitter metabolism in chemosensory type I cells.