Cholecystokinin (CCK) down regulates PGE2 and PGI2 release in inflamed Guinea pig gallbladder smooth muscle cell cultures.

This study examines the hypothesis that cholecystitis down-regulates Guinea pig gallbladder (GPGB) smooth muscle cholecystokinin (CCK)-stimulated prostaglandin (PG) release. Guinea pig gallbladder from Control and 48 h bile duct ligated (BDL) animals were placed in cell culture and grown to confluence. The cultures underwent Western Blot analysis for smooth muscle cell content of COX-1, COX-2, Prostacyclin Synthase (PS), or were incubated with CCK at 10(-8)M or 10(-6)M with and without indomethacin for 1h and analyzed for release of 6-keto-PGF1alpha, PGE2 and TxB2 by EIA. BDL increased Guinea pig gallbladder cell culture basal PGE2 and PGI2 release which was in part due to increased COX-2 content. CCK incubation down-regulated BDL Guinea pig gallbladder cell culture release of 6-keto-PGF1alpha and PGE2 and down-regulated COX-2 content but did not alter the Control group. The decrease in CCK-mediated BDL cell Guinea pig gallbladder release may be an endogenous mechanism to limit physiologic derangements induced by increased endogenous gallbladder PG synthesis during early acute cholecystitis.

Iodinated contrast induced renal vasoconstriction is due in part to the downregulation of renal cortical and medullary nitric oxide synthesis.

OBJECTIVES: The loss of renal function continues to be a frequent complication of the iodinated contrast agents used to perform diagnostic angiography and endovascular procedures. This study examined the hypothesis that contrast-induced renal injury is partly due to a decrease in cortical and medullary microvascular blood flow after the downregulation of endogenous renal cortical and medullary nitric oxide (NO) synthesis. METHODS: Anesthetized male Sprague-Dawley rats (300 g) had microdialysis probes or laser Doppler fibers inserted into the renal cortex to a depth of 2 mm and into the renal medulla to a depth of 4 mm. Laser Doppler blood flow was continuously monitored, and the microdialysis probes were connected to a syringe pump and perfused in vivo at 3 muL/min with lactated Ringer's solution. Dialysate fluid was collected at time zero (basal) and 60 minutes after infusion of either saline or Conray 400 (6 mL/kg). Both groups were treated with saline carrier, N(omega)-nitro-L-arginine methyl ester hydrochloride (L-NAME, 30 mg/kg), L-arginine (400 mg/kg), or superoxide dismutase (10,000 U/kg), an oxygen-derived free radical scavenger. Dialysate was analyzed for total NO and eicosanoid synthesis. The renal cortex and medulla were analyzed for inducible NO synthase (iNOS), cyclooxygenase-2 (COX2), prostacyclin synthase, and prostaglandin E(2) (PGE(2)) synthase content by Western blot analysis. RESULTS: Conray caused a marked decrease in cortical and medullary blood flow with a concomitant decrease in endogenous cortical NO, PGE(2), and medullary NO synthesis. The addition of L-NAME to the Conray further decreased cortical and medullary blood flow and NO synthesis, which were restored toward control by L-arginine. Neither L-NAME nor L-arginine (added to the Conray) altered cortical or medullary eicosanoids release. Medullary PGE(2) synthesis decreased when superoxide dismutase was added to the Conray treatment, suggesting that oxygen-derived free radicals had a protective role in maintaining endogenous medullary PGE(2) synthesis after Conray treatment. Conray did not significantly alter iNOS, COX-2, prostacyclin synthase, or PGE(2) synthase content. CONCLUSIONS: These findings suggest that the downregulation of renal cortical and medullary NO synthesis contributes to the contrast-induced loss of renal cortical and medullary microvascular blood flow. Preservation of normal levels of renal cortical and medullary NO synthesis may help prevent or lessen contrast-induced renal vasoconstriction and lessen contrast-induced renal injury found after diagnostic and therapeutic endovascular procedures.

Oxygen-radical regulation of renal blood flow following suprarenal aortic clamping.

OBJECTIVE: Renal insufficiency continues to be complication that can affect patients after treatment for suprarenal aneurysms and renal artery occlusive disease. One proposed mechanism of renal injury after suprarenal aortic clamping (above the superior mesenteric artery) and reperfusion (SMA-SRACR) is the loss of microvascular renal blood flow with subsequent loss of renal function. This study examines the hypothesis that the loss of medullary and cortical microvascular blood flow following SMA-SRACR is due to oxygen-derived free radical down-regulation of endogenous medullary and cortical nitric oxide synthesis. METHODS: Anesthetized male Sprague-Dawley rats (about 350 g) either had microdialysis probes or laser Doppler fibers inserted into the renal cortex (depth of 2 mm) and into the renal medulla (depth of 4 mm). Laser Doppler blood flow was continuously monitored. The microdialysis probes were connected to a syringe pump and perfused in vivo at 3 microL/min with lactated Ringer's solution. The animals were subjected to SMA-SRACR (or sham) for 30 minutes, followed by 60 minutes of reperfusion. Laser Doppler blood flow after the 30 minutes of SMA-SRACR followed by 60 minutes of reperfusion was compared with the time zero (basal) and with the corresponding sham group and reported as percent change compared with the time zero baseline. The microdialysis fluid was collected at time zero (basal) and compared with the dialysis fluid collected after 30 minutes of SMA-SRACR followed by 60 minutes of reperfusion as well as the corresponding sham group. The microdialysis dialysate was analyzed for total nitric oxide (microM) and prostaglandin E2 (PGE2), 6-keto-PGF(1alpha) (PGI2 metabolite), and thromboxane B2 synthesis. The data are reported as percent change compared with the baseline time zero. The laser Doppler blood flow and microdialysis groups were treated with either saline carrier, N(omega)-nitro-L-arginine methyl ester hydrochloride (L-NAME) (30 mg/kg, nitric oxide synthesis inhibitor), L-arginine (400 mg/kg, nitric oxide precursor), superoxide dismutase (SOD, 10,000 U/kg, oxygen-derived free radical scavenger), L-NAME + SOD, or L-arginine + SOD. SOD was given 30 minutes before the reperfusion, and the other drugs were given 15 minutes before reperfusion. The renal cortex and medulla were separated and analyzed for inducible nitric oxide synthase (iNOS), cyclooxygenase-2, prostacyclin synthase, and PGE2 synthase content by Western blot. RESULTS: Superior mesenteric artery-SRACR caused a marked decrease in medullary and cortical blood flow with a concomitant decrease in endogenous medullary and cortical nitric oxide synthesis. These changes were further accentuated by L-NAME treatment but restored toward sham levels by L-arginine treatment after SMA-SRACR. The kidney appeared to compensate for these changes by increasing cortical and medullary PGE2 synthesis and release. SOD treatment restored renal cortical and medullary nitric oxide synthesis and blood flow in the ischemia-reperfusion group and in the ischemia-reperfusion group treated with L-NAME. CONCLUSIONS: These data show that nitric oxide is important in maintaining renal cortical and medullary blood flow and nitric oxide synthesis. These data also support the hypothesis that the loss of medullary and cortical microvascular blood flow following SRACR is due in part to oxygen-derived free radical downregulation of endogenous medullary and cortical nitric oxide synthesis.

Suprarenal aortic clamping and reperfusion decreases medullary and cortical blood flow by decreased endogenous renal nitric oxide and PGE2 synthesis.

OBJECTIVE: This study examined the hypothesis that clamping the aorta above the superior mesenteric artery (SMA) followed by suprarenal aortic clamping and reperfusion (SRACR) decreases microvascular blood flow by loss of endogenous medullary and cortical nitric oxide (NO) and prostaglandin (PG) E(2) synthesis. STUDY DESIGN: Anesthetized male Sprague-Dawley rats (350 g) had either microdialysis probes or laser Doppler fibers inserted into the renal cortex to a depth of 2 mm and into the renal medulla at 4 mm. Laser Doppler blood flow was continuously monitored (data reported as percentage of change compared to basal), and the microdialysis probes were connected to a syringe pump and perfused in vivo at 3 microL/min with lactated Ringer solution. Dialysate fluid was collected at basal time zero, following 30 minutes of suprarenal aortic clamping (ischemia) followed by 60 minutes of reperfusion and compared to a sham operation. Both groups were treated with saline carrier, indomethacin (INDO) (10 mg/kg, a cyclooxygenase [COX] inhibitor), N(G)-nitro-L-arginine methyl ester (L-NAME) (20 mg/kg, a NO synthase [NOS] inhibitor), or L-arginine (200 mg/kg, an NO precursor). Dialysate was analyzed for total NO (muM) and PGE(2) (pg/mL) synthesis. The renal cortex and medulla were analyzed for inducible NOS (iNOS) and COX-2 content by Western blot. All data are reported as mean +/- SEM, N > 5 and analyzed by analysis of variance. RESULTS: SRACR caused a marked decrease in medullary and cortical blood flow with a concomitant decrease in endogenous medullary and cortical NO synthesis. Treatment with L-NAME further decreased blood flow and NO synthesis in the medulla and cortex. L-Arginine restored medullary and cortical NO synthesis and blood flow in the cortex but not the medulla. SRACR did not alter renal medullary or cortical PGE(2); however, addition of INDO, COX inhibitor, caused a concomitant decrease in medullary and cortical PGE(2) synthesis and blood flow. CONCLUSIONS: NO is an important endogenous renal vasodilator that, when maintained can help preserve cortical blood flow following SRACR. These data also suggest that avoidance of COX-2 inhibitors can help maintain endogenous renal cortical and medullary PGE(2) synthesis and thus contribute to maintaining normal blood flow. CLINICAL RELEVANCE: This study is the first to combine in vivo physiologic assays to simultaneously identify clinically relevant intrarenal vasodilators (cortical and medullary) that are required to maintain microvascular blood flow. Identification of endogenous renal cortical and medullary vasodilators responsible for maintaining renal microvascular blood flow will allow development of treatment strategies to preserve these vasodilators following SRACR. Successful preservation of endogenous intrarenal vasodilators will help maintain renal microvascular blood flow and renal function in the treatment of complex aortic pathology that requires SRACR.