In the present study, the effects of chronic hypoxia on the expression and localization of angiotensin II (Ang II) receptors are investigated by semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) and by immunohistochemistry. The effect of chronic hypoxia on the carotid body chemoreceptor activity was also examined by in vitro electrophysiology. Results from RT-PCR revealed that chronic hypoxia exhibited differential effects on the gene expression of Ang II receptors, namely AT 1 and AT 2 , in the carotid body. The mRNA expression for subtypes of the AT 1 receptor, AT 1a and AT 1b , was significantly increased in the carotid body with chronic hypoxia. To further investigate the localization of the AT 1 receptor, an immunohistochemical study was performed. The results showed that AT 1 receptor immunoreactivity was found in lobules of glomus cells in the carotid body and the immunoreactivity was more intense in chronic hypoxia than in normoxic controls. In vitro electrophysiological studies consistently demonstrated that chronic hypoxia enhanced the AT 1 receptor-mediated excitation of carotid body chemoreceptor activity. These data suggest that chronic hypoxia upregulates the transcriptional and post-transcriptional expression of AT 1 receptors in the rat carotid body. The upregulation of the expression also enhances AT 1 receptor-mediated excitation of the carotid body afferent activity. This might be important in the modulation of cardiorespiratory functions as well as fluid and electrolyte homeostasis during chronic hypoxia.
In acute hypoxia, the release of nitric oxide (NO) produced in rat carotid body is unclear. The concentration of NO was measured electrochemically with a Pt/Nafion/Pd-IrOx/POAP-modified electrode placed on the surface of isolated carotid bodies superfused with bicarbonate-buffer saline at 35 degrees C. In hypoxia, the concentration of NO in the carotid body was increased by 17+/-2 nM. The amount of NO release during hypoxia was augmented by increasing the number of carotid bodies surrounding the electrode and also in the presence of L-arginine. In addition, the hypoxia-induced elevation of NO was abolished by pretreatment with a nitric oxide synthase (NOS) inhibitor, L-N(G)-nitroarginine methylester (L-NAME). The results suggest that endogenous NO production in the carotid body increases during hypoxia. Electrophysiological measurement of single fiber activity in the sinus nerve revealed that L-NAME treatment enhances the afferent discharge in response to hypoxia. This confirms that the hypoxia-induced elevation of NO suppresses the carotid chemoreceptor response to hypoxia. Taken together, it is concluded that acute hypoxia increases NO generation in the rat carotid body, and that the elevated levels of NO suppress carotid chemoreceptor activity during hypoxia. Hence, NO may play an active inhibitory role in the control of carotid chemoreceptor activity during hypoxia.
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