BACKGROUNDRecent studies showed the central Na+/H+ exchanger type 3 (NHE3) has a close relationship with ventilation control. The objective of the study is to investigate the role of NHE3 in sleep apnea in Sprague-Dawley (SD) rats.

METHODSA sleep study was performed on 20 male SD rats to analyze the correlation between the sleep apneic events and total NHE3 protein content and inactive NHE3(pS552) in the brainstem measured by Western blotting. Another 20 adult male SD rats received 3 days of sleep and respiration monitoring for 6 hours a day, with adaption on the first day, 0.5% DMSO microinjection into the fourth ventricle on the second day, and AVE0657 (specific inhibitor of NHE3) microinjection on the third day. Rats were divided into two groups with injection of 5 µmol/L or 8 µmol/L AVE0657 before the sleep study. The effects of AVE0657 on sleep apnea and sleep structure of rats were analyzed through self-control.

RESULTSThe total post-sigh apnea index (TPSAI) and post-sigh apnea index in non-rapid eye movement (NREM) sleep (NPSAI) and total apnea index (AI) in NREM sleep (NAI) were negatively correlated with NHE3(pS552) protein contents in the brainstem (r = -0.534, -0.547 and -0.505, respectively, P < 0.05). The spontaneous apnea index in REM sleep (RSPAI) was positively correlated with the level of NHE3(pS552) protein expression in the brainstem (r = 0.556, P < 0.05). However, the sleep AI had no relationship with total NHE3 protein. Compared with the blank control and microinjection of 0.5% DMSO, 5 µmol/L AVE0657 significantly reduced the total AI and NPSAI (both P < 0.05) without a significant effect on sleep architecture. In contrast to blank control and microinjection of 0.5% DMSO, injection of 8 µmol/L AVE0657 significantly reduced the AI and PSAI in NREM and REM sleep (all P < 0.05).

CONCLUSIONSThe severity of sleep apnea was negatively correlated with central inactive NHE3. A specific inhibitor of NHE3 decreased the sleep AI. Thus, our results indicate that central NHE3 might be a molecular target for sleep apnea treatment, whose inhibitors may be potential therapeutic drugs for sleep apnea.

Animals ; Male ; Rats ; Rats, Sprague-Dawley ; Sleep Apnea Syndromes ; metabolism ; physiopathology ; Sleep, REM ; physiology ; Sodium-Hydrogen Exchanger 3 ; Sodium-Hydrogen Exchangers ; antagonists & inhibitors ; metabolism

Fructose intake has increased dramatically over the past century and the upward trend has continued until recently. Increasing evidence suggests that the excessive intake of fructose induces salt-sensitive hypertension. While the underlying mechanism is complex, the kidney likely plays a major role. This review will highlight recent advances in the renal mechanisms of fructose-induced salt-sensitive hypertension, including (pro)renin receptor-dependent activation of intrarenal renin-angiotensin system, increased nephron Na transport activity via sodium/hydrogen exchanger 3 and Na/K/2Cl cotransporter, increased renal uric acid production, decreased renal nitric oxide production, and increased renal reactive oxygen species production, and suggest actions based on these mechanisms that have therapeutic implications.
Blood Pressure ; Fructose ; adverse effects ; Humans ; Hypertension ; chemically induced ; physiopathology ; Kidney ; physiopathology ; Nitric Oxide ; metabolism ; Reactive Oxygen Species ; metabolism ; Renin-Angiotensin System ; Sodium Chloride, Dietary ; adverse effects ; Sodium-Hydrogen Exchanger 3 ; metabolism ; Uric Acid ; metabolism