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【摘要】 Nitric oxide (NO) produced by endothelial cells diffuses to vascular smooth muscle cells to cause dilatation of the renal vasculature and other vessels. Although it is generally assumed that NO moves from cell to cell by free diffusion, we recently showed that aquaporin-1 (AQP-1) transports NO across cell membranes. AQP-1 is expressed in endothelial and vascular smooth muscle cells. We hypothesized that diffusion of NO into vascular smooth muscle cells and out of endothelial cells is facilitated by AQP-1, and transport of NO by AQP-1 is involved in endothelium-dependent relaxation. In intact aortic rings from AQP-1 -/- mice, vasorelaxation induced by acetylcholine (which increases endogenous NO) was reduced ( P < 0.0001 vs. control). No differences were found in the relaxation caused by intracellular delivery of NO or intracellular cGMP between strains. In endothelium-denuded aortic rings from AQP-1 -/- mice, the vasorelaxant capability of NO released in the extracellular space was reduced ( P < 0.0001 vs. control). Influx of NO (5 µM) into vascular smooth muscle cells was 0.17 ± 0.02 f.u./s for control and 0.07 ± 0.01 f.u./s for AQP-1 -/- mice, 62% lower ( P < 0.002). NO released by endothelial cells in response to 1 µM acetylcholine was 96.2 ± 17.7 pmol NO/mg for control and 41.9 ± 13.4 pmol NO/mg for AQP-1 -/- mice, 56% reduction ( P < 0.04). NOS3 expression was 1.33 ± 0.29 O.D. units for control and 3.84 ± 0.76 O.D. units for AQP-1 -/- mice, 188% increase ( P < 0.01). We conclude that 1 ) AQP-1 facilitates NO influx into vascular smooth muscle cells, 2 ) AQP-1 facilitates NO diffusion out of endothelial cells, and 3 ) transport of NO by AQP-1 is required for full expression of endothelium-dependent relaxation.
【关键词】 aquaporin nitric oxide transport relaxation aquaporin knockout
AQUAPORINS ARE A family of transmembrane proteins that transport water across cell membranes ( 3 ). Eleven aquaporins have been identified to date (0-10) ( 1, 32, 33, 36 ). Aquaporin-1 (AQP-1), the first identified member of the family ( 2 ), is expressed in cells characterized by high rates of net water transport such as the proximal tubule, thin descending limb, and red blood cells ( 38, 49, 50, 55 ). However, AQP-1 is often expressed in cells where net water flux does not appear to be important, such as endothelial ( 18, 45, 51, 65 ) and vascular smooth muscle cells ( 18, 19, 56 ). The physiological role of AQP-1 in these cells remains unclear.
Nitric oxide (NO) is a gas that plays a crucial role in the regulation of blood pressure. NO dilates the arterial blood vessels and lowers total peripheral resistance ( 47 ). Within the kidney, NO helps maintain the low vascular resistance characteristic of this organ by dilating the preglomerular arteries ( 7, 61 ). It also plays an important role in mediating pressure natriuresis, attenuating tubuloglomerular feedback, and inhibiting nephron transport ( 25, 39 - 41, 54 ). In the preglomerular vasculature, NO produced by endothelial NO synthase (eNOS or NOS3) is released from the endothelial cells, diffuses to adjacent vascular smooth muscle cells, enters these cells, and binds soluble guanylate cyclase to cause vasorelaxation ( 16, 17 ). Free diffusion has historically been assumed to be the main mechanism whereby NO exits and enters cells. Thus NO is thought to cause dilatation without need for a specific transporter. This assumption was based on the partition coefficient of NO between lipids and water ( 42, 46 ) rather than direct measurements of NO diffusion across the cell membrane. We recently showed that AQP-1 transports NO across cell membranes and that the cell membrane is a significant barrier to NO diffusion, based on measurements of NO fluxes across reconstituted lipid vesicles and transfected cultured cells ( 24 ). However, it is still not known whether transport of NO by AQP-1 has any physiological consequence. We hypothesized that AQP-1 mediates the transport of NO out of endothelial cells and into vascular smooth muscle cells of blood vessels, and therefore, transport of NO by AQP-1 is required for full expression of endothelium-dependent relaxation. To test our hypothesis, we used thoracic aortas isolated from control (CD1) and AQP-1 -/- mice.
MATERIALS AND METHODS
Materials. Cell culture reagents were all from GIBCO-Invitrogen (Carlsbad, CA). Unless otherwise specified, all other reagents were from Sigma (St. Louis, MO).
Animals. Breeding pairs of AQP-1 -/- mice were a gift from Dr. H. Brooks at the University of Arizona (Tucson, AZ). They were bred in the animal facility of Henry Ford Hospital by the Transgenic Mouse Core of the Division of Hypertension and Vascular Research. Their respective controls, CD1 mice ( 37 ), were obtained from Charles River (Kalamazoo, MI). C57Bl/6J mice were obtained from Jackson (Bar Harbor, ME). Only animals weighing 24-28 g on the day of the experiment were used. All protocols were carried out in accord with the guidelines of the Institutional Animal Care and Use Committee.
Aortic relaxation in response to acetylcholine, spermine NONOate, sodium nitroprusside, and phosphodiesterase 5 inhibition. Male AQP-1 -/- and CD1 control mice were anesthetized with ketamine (100 mg/kg body wt ip) and xylazine (20 mg/kg body wt ip). Thoracic aortas were removed, cleared of adhering connecting tissue, and cut into rings 2 mm in length. When necessary, the endothelium was removed by passing a piece of 5-cm 4.0 surgical suture through the lumen of the vessel six times. Aortic rings were mounted in a vessel myograph (Multi Myograph System-610M, Danish Myo Technology, Aarhus, Denmark) and bathed with buffer containing (in mM): 120 NaCl, 25 NaHCO 3, 4.7 KCl, 1.18 KH 2 PO 4, 1.18 MgSO 4, 2.5 CaCl 2, 0.026 ethylenediaminetetraacetic acid (EDTA) disodium salt, and 5.5 glucose, pH 7.4, at 37°C gassed with 95% O 2 -5% CO 2. Resting force was set at 6.9 mN (700 mg). Active force was recorded isometrically. Preparations were allowed to equilibrate for 1 h, replacing the buffer at 20-min intervals. The rings were constricted twice with 100 mM KCl (using the above buffer, except that 100 mM KCl was achieved by equimolar substitution of NaCl). After removal of KCl, preparations were allowed to reach equilibrium for 40 min, replacing the buffer at 20-min intervals. When the NOS inhibitor N G -nitro- L -arginine methyl ester ( L -NAME; 1 mM) or the superoxide scavenger (Tempol, 100 µM) was used, these drugs were added to the bath 20 min before phenylephrine. The vessels were constricted by adding a concentration of phenylephrine that caused 80% constriction. When a plateau was reached, we obtained concentration-response curves for relaxation induced by either acetylcholine (to stimulate NO production by endothelial cells), spermine NONOate (an NO donor that spontaneously releases NO into the bath; Cayman Chemicals, Ann Arbor, MI), sodium nitroprusside (an NO donor that releases NO intracellularly), or the PDE5 inhibitor 4-{[3',4'-(methylenedioxy)benzyl]amino}-6-methoxyquinazoline (that increases endogenous cGMP levels; Calbiochem, San Diego, CA). Complete endothelium removal was tested by adding 1 µmol/l acetylcholine when appropriate. The degree of relaxation was calculated as a percentage of PE tension.
Primary cultures of mouse endothelial and vascular smooth muscle cells. Endothelial and vascular smooth muscle cells from mouse thoracic aortas were isolated according to the methods of Kobayashi et al. ( 34 ) and Ray et al. ( 53 ) with some modifications. Briefly, mice were anesthetized with xylazine (20 mg/kg body wt) and ketamine (100 mg/kg body wt). The thorax was opened and the abdominal aorta was cut at the middle and perfused from the left ventricle with 1 ml PBS (140 mM NaCl, 10 mM phosphate buffer, and 3 mM KCl, pH 7.4) containing 1,000 U/ml heparin. The thoracic aorta was then dissected, and fat and connective tissue were removed from both ends. Five-centimeter PE-50 tubing was inserted into the proximal portion of the aorta. The inside of the lumen was washed with serum-free medium, using a 3-ml syringe and a sterile 25-gauge needle. The distal end of the aorta was closed with 6.0 surgical suture and the lumen filled with collagenase type 2 solution (Worthington, Lakewood, NJ, 2 mg/ml dissolved in serum-free DMEM). The outside of the vessel was rinsed by passing it through sterile medium three times and transferred to a clean plastic dish containing serum-free medium without collagenase. After incubation for 30 min at 37°C, endothelial cells were removed from the aorta by flushing it with 5 ml DMEM containing 20% heat-inactivated FBS. Cells were collected by centrifugation at 300 g for 5 min, resuspended with 2 ml 20% FBS-DMEM, and cultured in 35-mm collagen type I-coated inserts (0.4 µm, 4.7-cm 2 area, Corning Costar, Cambridge, MA). After 2 h, medium was replaced by DMEM plus 20% FBS, 100 U/ml penicillin, 100 µg/ml streptomycin, 2 mM L -glutamine, 1 x nonessential amino acids (GIBCO cat. no. 11140-050), 1 mM sodium pyruvate, 100 µg/ml heparin, and 100 µg/ml endothelial cell growth supplements. Two mice were necessary to obtain a single plate of confluent endothelial cells after 1 wk of incubation.
After endothelial cells were removed, the adventitia was removed. The aorta was cut into 1- to 2-mm pieces, transferred to a small tissue culture tube containing 1 ml collagenase (1.3 mg/ml) in serum-free DMEM, and digested at 37°C for 3.5 h in an incubator with 5% CO 2. Tissue was disturbed every 30 min by pipetting up and down. Cells were collected by centrifugation at 300 g for 5 min at room temperature and rinsed with 5 ml DMEM high glucose supplemented with 10% bovine serum, 100 U/ml penicillin, and 100 µg/ml streptomycin. Then, they were resuspended, plated in two wells of a 24-well plate containing a round glass coverslip 13 mm in diameter, and used 5 days later.
To make sure our primary cultures were not contaminated with other cell types, endothelial and vascular smooth muscle cells isolated from CD1 aortas were plated on glass coverslips until confluency. For endothelial cells, laminin- and fibronectin-treated coverslips were used. Cells were fixed in ice-cold 4% paraformaldehyde for 30 min. After incubation for 30 min in 5% albumin/Tris-buffered saline (TBS; 20 mM tris base, 137 mM NaCl, pH 7.6) 0.1% Tween, endothelial cells were incubated with a 1:200 dilution of a NOS3 monoclonal antibody (BD Biosciences, San Diego, CA) and vascular smooth muscle cells with 1:200 of monoclonal vascular smooth muscle cells -actin antibody (Dako, Carpenteria, CA). Cells were washed twice for 5 min with TBS-T, incubated for 30 min with 1:500 Alexa Fluor 488 goat anti-mouse antibody (Molecular Probes-Invitrogen, Carlsbad, CA), then rewashed twice for 5 min with TBS-T, and mounted using Fluormount-G (Southern Biotech, Birmingham, AL). Cells were visualized under a x 100 oil objective and the secondary antibody was excited with an argon/krypton laser at 488 nm. Emitted fluorescence was visualized with a scanning laser confocal microscope (Noran Instruments, Middleton, WI). Primary cultures of endothelial cells were 98% pure. Primary cultures of vascular smooth muscle cells were 96% pure.
Western blot. Western blotting was performed as routinely done in our laboratory ( 23, 26 ). For detection of AQP-1, 15 µg endothelial cells and 5 µg vascular smooth muscle homogenates were loaded onto the same 12% polyacrylamide gel, electrophoresed, and transferred. Membranes were incubated for 1 h with 1:1,000 dilution of AQP-1 polyclonal antibody (Alpha Diagnostics, San Antonio, TX). To make sure the AQP-1 antibody was specific, we used purified AQP-1 as a positive control for our Western blots. We observed the expected molecular weight bands for AQP-1 by either Silver stain or Western blot. Additionally, we used two different antibodies raised against different epitopes of AQP-1 (Alpha Diagnostics and BD Biosciences), and both antibodies gave us the expected molecular weight bands for AQP-1 by Western blot. For detection of vascular smooth muscle cell -actin, 1:200 of monoclonal antibody was used (Dako). For detection of NOS3, 2 µg endothelial cells homogenates were loaded onto a 8% polyacrylamide gel and a 1:1,000 dilution of a NOS3 monoclonal antibody was used (BD Biosciences). Membranes were incubated for 1 h using a 1:1,000 dilution of the appropriate secondary antibody. Quantification of the bands was performed by densitometry. When a different amount of protein was loaded, densitometric values were corrected accordingly and expressed as O.D. units per 10 µg of protein.
Measurements of NO influx. Primary cultures of vascular smooth muscle cells were grown on glass coverslips until 60% confluence and placed in a temperature-regulated chamber at 37°C. The flow rate of the bath was 0.4 ml/min [HEPES-buffered physiological saline: (in mM) 130 NaCl, 2.5 NaH 2 PO 4, 4 KCl, 1.2 MgSO 4, 6 alanine, 1 Na 3 citrate, 5.5 glucose, 2 Ca (lactate) 2, 10 HEPES at pH 7.4]. Cells were loaded by adding 4 µM DAF-2 DA to the medium for 30 min and then washed with physiological saline for 30 min. The dye was excited at 488 nm with an argon/krypton laser, and fluorescence was emitted by NO-bound dye was measured with a scanning laser confocal microscope (Noran Instruments). After stable baseline fluorescence was established, the NO donor spermine NONOate [500 µM, which releases 5 µM NO as measured by a precalibrated NO-selective sensor ( 24 )] was added to the bath. The increase in fluorescence, representing the increase in intracellular NO, was measured once every 5 s for 50 s. Rates of NO influx were calculated from the slope of the initial rates of increases in fluorescence. Results were expressed in fluorescence units/second.
Measurements of NO release. NO release was measured as routinely done in our laboratory ( 22, 24 ). Briefly, confluent primary cultures of endothelial cells were transferred to a temperature-regulated system and maintained at 37°C. The atmosphere contained 95% O 2 -5% CO 2. A precalibrated NO selective sensor (amiNO-Flat, Harvard Apparatus, Holliston, MA) was placed on top of the cells. Once a baseline was obtained, 1 µM acetylcholine and 250 µM L -arginine (the substrate for NOS) were added to the apical side of the cells and NO release was measured continuously for 5 min ( 26 ). At the end of the experiment, cells were rinsed three times with ice-cold PBS and lysed in a buffer containing 20 mM HEPES, pH 7.4, 2 mM EDTA, 0.3 M sucrose, 1.0% NP-40, 0.1% sodium dodecyl sulfate, 5 µg/ml antipain, 10 µg/ml aprotinin, 5 µg/ml leupeptin, 4 mM benzamidine, 5 µg/ml chymostatin, 5 µg/ml pepstatin A, and 0.105 M 4(2-aminoethyl)-benzene sulfonyl fluoride. Total protein was determined using Coomassie Plus reagent (Pierce, Rockford, IL), based on Bradford's colorimetric method. Results were expressed in picomoles of NO per milligram of protein after 2-min stimulation.
Statistics. Data are reported as means ± SE. They were evaluated by t -test or exact nonparametric Wilcox two-sample test as appropriate. To compare the relaxation-response curves, a four parametric logistic model was fit to the dose-response curves. All statistical analyses were performed by the Biostatistics Department at Henry Ford Hospital. P < 0.05 was considered significant.
RESULTS
To make sure the mouse thoracic aorta is a valid model to test our hypothesis, we first investigated whether AQP-1 is expressed in both endothelial and vascular smooth muscle cells of these vessels by Western blot. Using whole cell homogenates, we found that both endothelial cells and vascular smooth muscle cells isolated from thoracic aortas of control mice expressed AQP-1. However, its relative abundance was 20.3 ± 2.6 times higher in vascular smooth muscle cells compared with endothelial cells ( P < 0.0005; n = 4; Fig. 1 ). The presence of AQP-1 detected in endothelial cells was not due to contamination with vascular smooth muscle cells since vascular smooth muscle cell -actin was only detected in isolated vascular smooth muscle cells and not endothelial cells. In addition, NOS3 was only detected in isolated endothelial cells but not vascular smooth muscle cells ( Fig. 1 ). These data indicate that AQP-1 is present in both cell types in the mouse thoracic aorta, and thus this vessel is a valid model to test our hypothesis.
Fig. 1. Top : representative Western blot showing the relative abundance of aquaporin-1 (AQP-1) in endothelial cells (EC) and vascular smooth muscle cells (VSMC) isolated from the thoracic aorta of CD1 mice. As control for cell purity, the same membrane was blotted for NOS3 (as a specific marker for EC) and for VSMC -actin (as a specific marker for VSMC). Bottom : mean densitometric data for AQP-1 expression. Densitometric values were factored for the amount of protein loaded for each sample. P < 0.005 vs. CD1; n = 4.
To investigate whether transport of NO by AQP-1 plays a role in endothelium-dependent relaxation, we first studied the ability of NO released by endothelial cells to relax intact aortic rings. NO release by endothelial cells was stimulated by adding increasing concentrations of acetylcholine to the bath. We found that the relaxant effect of acetylcholine was diminished in aortic rings isolated from AQP-1 -/- mice compared with controls at all concentration tested (10 -9 -3 x 10 -6 M) being the maximum relaxation reduced by 30% in aortas from AQP-1 -/- compared with control mice ( P < 0.05; n = 5-7; Fig. 2 ). However, the EC 50 values were similar between both curves (2.48 ± 0.13 x 10 -8 for CD1 and 4.05 ± 0.12 x 10 -8 M for AQP-1 -/-; not significant). These data suggest that in the mouse thoracic aorta, the ability of acetylcholine to induce endothelium-dependent relaxation is impaired by the absence of AQP-1.
Fig. 2. Relaxant effect of acetylcholine (Ach) on intact aortic rings from control (CD1) and aquaporin-1 knockout mice (AQP-1 -/-). P < 0.0001 indicates that the curves are different. The maximum relaxation to the highest dose of Ach was reduced by 30% in AQP-1 -/- ( P < 0.05 vs. CD1; n = 5-7). The EC 50 values for Ach were 2.48 ± 0.13 x 10 -8 for CD1 and 4.05 ± 0.12 x 10 -8 M for AQP-1 -/- (not significant).
The ability of acetylcholine to cause relaxation of the thoracic aorta is mainly attributed to stimulation of NO release by endothelial cells. However, in certain blood vessels other mechanisms have been shown to be the mediators of acetylcholine-induced relaxation such as cytochrome P -450 epoxygenase products ( 15, 66 ) and endothelium-dependent hyperpolarizing factor. To make sure that in our experiments all the effects of acetylcholine were mediated by NO, we tested the effect of the NOS inhibitor L -NAME on acetylcholine-induced relaxation. L -NAME (1 mM) completely abolished the relaxation induced by acetylcholine (10 -9 -10 -6 M) in aortic rings from both control and AQP-1 -/- mice (maximum relaxation induced by 1 µM acetylcholine was -4.3 ± 2.5 and 5.4 ± 2.7% for AQP-1 -/- and CD1 mice, respectively). Thus the mechanism whereby acetylcholine relaxes aortic rings is exclusively NO dependent.
The genetic background of AQP-1 -/- mice is primarily CD1 with a small percentage of C57Bl/6J mixed in. To make sure our results were not due to strain differences in the response to acetylcholine, we measured endothelium-dependent relaxation in aortic rings from CD1 and C57Bl/6J mice. We found that maximum relaxation occurred at 3 µM acetylcholine for both CD1 (17.2 ± 1.1%) and C57Bl/6J (11.5 ± 6.2%; n = 3). Additionally, we found no differences in the EC 50 for the concentration-response curve to acetylcholine between strains. Because there were no differences and, the AQP-1 -/- are mostly on a CD1 background, we used CD1 as controls.
NO released by endothelial cells must enter the vascular smooth muscle cells to activate soluble guanylate cyclase and cause relaxation. The impaired endothelium-dependent relaxation found in aortic rings from AQP-1 -/- mice may be due to 1 ) alterations in the signaling cascade beyond NO, 2 ) diminished NO influx into vascular smooth muscle cells, and/or 3 ) reduced NO efflux out of endothelial cells.
To investigate whether the differences we found in the ability of endogenous NO to relax aortic rings isolated from AQP-1 -/- mice were due to an impairment of the signaling cascade beyond NO, we next investigated the ability of intracellular NO and cGMP to cause vasorelaxation. NO was delivered intracellularly using the NO donor sodium nitroprusside (10 -10 -3 x 10 -7 M). This donor needs to be metabolized by the cells to release NO ( 4, 20, 44 ). In endothelium-denuded aortic rings, the relaxation responses induced by intracellular delivery of NO did not differ between AQP-1 -/- and controls ( n = 6; Fig. 3 ). Next, we studied the ability of intracellular cGMP to cause vasorelaxation. Intracellular levels of cGMP were increased by treating rings with the phosphodiesterase 5 (PDE5) inhibitor 4-{[3',4'-(methylenedioxy)benzyl] amino}-6-methoxyquinazoline (10 -7 -3 x 10 -5 M). In endothelium-denuded aortic rings, the relaxation responses induced by intracellular cGMP did not differ between AQP-1 -/- and controls ( n = 4; Fig. 3 ). These data suggest that the ability of a given amount of intracellular NO and intracellular cGMP to activate the signaling cascade leading to relaxation is intact in the thoracic aorta of AQP-1 -/- mice. Thus the impaired endothelium-dependent relaxation in AQP-1 -/- mice is not due to alterations in the signaling cascade beyond NO.
Fig. 3. Relaxant effects of intracellular nitric oxide (NO; top ) and intracellular cGMP ( bottom ) on endothelium-denuded aortic rings from control (CD1) and AQP-1 -/- mice. SNP, sodium nitroprusside (an NO donor that releases NO intracellularly); PDE5 inh, a phosphodiesterase 5 inhibitor (utilized to diminish degradation of cGMP by PDE5; n = 6 for SNP and 4 for PDE5 inh).
Because vascular smooth muscle cells express 20 times more AQP-1 than endothelial cells, we next investigated whether reduced NO influx into vascular smooth muscle cells could account for the impaired endothelium-dependent relaxation in aortas isolated from AQP-1 -/- mice. For this, we studied the ability of exogenous NO to relax endothelium-denuded aortic rings. NO was added to the bath using increasing concentrations of the NO donor spermine NONOate (3 x 10 -8 -3 x 10 -5 M), which spontaneously releases NO primarily into the extracellular environment ( 31, 58 ). We found that in endothelium-denuded rings, the cumulative relaxation-response curve to extracellular NO was shifted to the right in thoracic aortas isolated from AQP-1 -/- mice compared with controls ( P < 0.0001, n = 5-6). The maximum relaxation response to NO was the same in both strains ( Fig. 4 ). The EC 50 for NO was higher for aortic rings isolated from AQP-1 -/- compared with controls (6.30 ± 0.08 x 10 -7 vs. 1.47 ± 0.02 x 10 -7 M; P < 0.05). These data suggest that in the endothelium-denuded mouse thoracic aorta, the ability of extracellular NO to cause relaxation is diminished by the absence of AQP-1.
Fig. 4. Relaxant effect of extracellular NO on endothelium-denuded aortic rings from control (CD1) and AQP-1 -/- mice. SPM, spermine NONOate (an NO donor that spontaneously releases NO into the bath). P < 0.0001 indicates that the curves are different. The EC 50 values for SPM were 1.47 ± 0.02 x 10 -7 for CD1 vs. 6.30 ± 0.08 x 10 -7 for AQP-1 -/- ( P < 0.05; n = 5-6).
To investigate whether the reduced ability of spermine NONOate to relax aortic rings from AQP-1 -/- mice is due to reduced NO transport, we directly measured the rate of NO influx into isolated vascular smooth muscle cells from mouse thoracic aortas using fluorescence microscopy. NO influx was initiated by generating a 5-µM NO concentration gradient using the NO donor spermine NONOate. In isolated vascular smooth muscle cells, the rate of NO influx was 0.17 ± 0.02 fluorescence units/s for cells from controls and 0.07 ± 0.01 fluorescent units/s for cells from AQP-1 -/-, 60% lower ( P < 0.0002; n = 6-8; Fig. 5 ). These data suggest that reduced AQP-1-dependent NO transport into vascular smooth muscle cells accounts, at least in part, for the diminished ability of extracellular NO to cause relaxation in AQP-1 -/-.
Fig. 5. NO influx by VSMC isolated from thoracic aortas of control (CD1) and AQP-1 -/- mice. Top : representative traces of NO influx. The initial rate of increase in fluorescence (typically 50-100 s) was used to calculate the rate of NO influx. The line plotted through the data represents the initial rates. Bottom : mean data for initial rates of NO influx ( P < 0.0002 vs. CD1; n = 6-8).
To investigate whether reduced NO transport out of endothelial cells could account, at least in part, for the impaired endothelium-dependent relaxation observed in AQP-1 -/-, we measured NO release by primary cultures of endothelial cells isolated from the thoracic aorta. In response to 1 µM acetylcholine, NO released by confluent endothelial cells from control mice was 96.2 ± 17.7 pmol NO/mg protein after 2 min. In contrast, NO released by endothelial cells from AQP-1 -/- was 41.9 ± 13.4 pmol NO/mg protein, 56% less ( P < 0.04; n = 5; Fig. 6 ). These data suggest that reduced AQP-1-dependent NO transport out of endothelial cells could partially account for the impaired endothelium-dependent relaxation in the AQP-1 -/-.
Fig. 6. Effect of 1 µM acetylcholine on NO release in confluent endothelial cells isolated from thoracic aortas of control (CD1) and AQP-1 -/- mice ( P < 0.04 vs. CD1; n = 5).
Impaired NO efflux in endothelial cells from AQP-1 -/- could be due to reduced NOS3 expression. Thus we measured NOS3 expression by endothelial cells isolated from both control and AQP-1 -/- mice by Western blot. We found that NOS3 was 1.33 ± 0.29 O.D. units for controls and 3.84 ± 0.76 O.D. units for AQP-1 -/-, a 188% increase ( P < 0.01; n = 6; Fig. 7 ). These data suggest that the ability of endothelial cells to produce NO is enhanced in thoracic aortas of AQP-1 -/-. Thus reduced NO production is not likely to account for impaired endothelium-dependent relaxation in AQP-1 -/- mice.
Fig. 7. Mean data and representative Western blot showing NOS3 expression by endothelial cells isolated from thoracic aortas of control (CD1) and AQP-1 -/- mice. P < 0.01 vs. CD1; n = 6.
Since NOS3 is increased in endothelial cells of AQP-1 -/- mice, we next investigated whether superoxide production as a result of NOS3 uncoupling could account for the reduced ability of endogenous NO to cause relaxation. To do this, we tested whether superoxide scavenging could reverse the reduced ability of acetylcholine to cause relaxation in the AQP-1 -/- mice. We found that, in the presence of the superoxide scavenger Tempol (100 µM), the relaxant effect of acetylcholine was diminished in aortic rings isolated from AQP-1 -/- mice compared with controls at all concentration tested (10 -9 -3 x 10 -6 M) being the maximum relaxation reduced by 36% in aortas from AQP-1 -/- compared with controls ( P < 0.02; n = 4; Fig. 8 ). Thus NOS3 uncoupling does not account for the impaired endothelium-dependent relaxation in AQP-1 -/-.
Fig. 8. Effect of the superoxide scavenger Tempol (100 µM) on Ach-induced relaxation of intact aortic rings from control (CD1) and AQP-1 -/- mice. P < 0.05 indicates that the curves are different. The maximum relaxation to the highest dose of Ach was reduced by 36% in AQP-1 -/- ( P < 0.02 vs. CD1; n = 4).
DISCUSSION
We believe our data demonstrate for the first time a physiological role for AQP-1-dependent transport of NO. We found that NO transport into vascular smooth muscle cells and out of endothelial cells is diminished in cells lacking AQP-1. As a result, NO-dependent relaxation is impaired in thoracic aortas from AQP-1 -/- mice. We conclude that transport of NO via AQP-1 is essential for full expression of endothelium-dependent relaxation.
Since we demonstrated that in transfected cultured cells and reconstituted lipid vesicles AQP-1 transports NO across the lipid bilayer ( 24 ), we questioned whether transport of NO by AQP-1 plays a physiological role. For this, we first investigated the ability of NO produced by endothelial cells to relax aortic rings isolated from AQP-1 -/- mice. At almost all concentrations tested, the relaxant effects of acetylcholine were decreased in AQP-1 -/- ( Fig. 2 ). The maximum relaxation to acetylcholine was diminished by 30%. Since acetylcholine stimulates the production of NO by NOS3 in endothelial cells ( 9, 14, 60 ) and it has to reach the vascular smooth muscle cells to cause relaxation ( 6, 9, 17, 28 ), our data from the AQP-1 -/- mice might be explained if in this strain 1 ) the signaling cascade beyond NO is altered, 2 ) NO influx into vascular smooth muscle cells is decreased, and/or 3 ) NO efflux out of endothelial cells is diminished.
We first investigated whether alterations in the signaling cascade beyond NO in vascular smooth muscle cells accounted for the impaired endothelium-dependent relaxation in the AQP-1 -/- mice. To do this, we tested the ability of intracellular NO to relax endothelium-denuded aortic rings. We used sodium nitroprusside because this NO donor needs to be metabolized by the cells to release NO ( 4, 20, 44 ). We found no differences in the relaxant effects of sodium nitroprusside between wild-type and AQP-1 -/- at all concentrations tested, indicating that the ability of NO to activate guanylate cyclase and generate cGMP is intact in the knockouts. We also tested the ability of cGMP to cause relaxation. We found no differences in the relaxation caused by a PDE5 inhibitor between wild-type and AQP-1 -/- mice, indicating that the ability of a given amount of cGMP to activate the signaling cascade leading to vasorelaxation is intact in the knockouts. Thus the reduced ability of NO to cause vasorelaxation in the absence of AQP-1 is not due to alterations in the signaling cascade beyond NO in AQP-1 -/-.
To investigate whether reduced NO transport into vascular smooth muscle cells could contribute to the reduced ability of acetylcholine to cause relaxation, we tested the ability of NO to relax endothelium-denuded aortic rings isolated from wild-type and AQP-1 -/- mice. To increase extracellular NO levels, we used the NO donor spermine NONOate, which spontaneously releases NO into the bath ( 31, 58 ), thus enhancing NO concentrations in the extracellular space. At almost all concentrations tested, the relaxant effects of spermine NONOate were decreased in AQP-1 -/- as evidenced by a shift of the cumulative dose-response curve to the right. These data suggest that the ability of extracellular NO to relax vascular smooth muscle cells is diminished in the absence of AQP-1.
To investigate whether AQP-1 transports NO into vascular smooth muscle cells, we directly measured NO influx into vascular smooth muscle cells of wild-type and AQP-1 -/- mice. We used 5 µM NO to initiate influx because we previously showed that transport of NO by AQP-1 saturates at 3 µM NO ( 24 ); therefore, by using 5 µM, we were sure we were measuring the maximum rate of NO transport by AQP-1. We found that the rate of NO influx was diminished by 62% in vascular smooth muscle cells isolated from AQP-1 -/-, indicating that AQP-1 transports NO into vascular smooth muscle cells. Our data suggest that reduced transport of NO into vascular smooth muscle cells could account, at least in part, for the reduced ability of acetylcholine-stimulated NO production by endothelial cells to relax aortic rings isolated from AQP-1 -/- mice. However, reduced release of NO out of endothelial cells could also account for our data.
To investigate whether AQP-1-dependent NO transport out of endothelial cells could account for the reduced ability of acetylcholine to relax intact aortic rings from AQP-1 -/- mice, we measured NO released by endothelial cells upon stimulation with 1 µM acetylcholine. We chose this concentration because it produced the maximum relaxant effect in aortic rings from both wild-type and AQP-1 -/-. Our data indicate that in response to equal amounts of acetylcholine, NO released by endothelial cells isolated from AQP-1 -/- is reduced by 56%. Thus this could be at least partly responsible for the impaired endothelium-dependent relaxation in AQP-1 -/-. However, it is important to note that while it appears that release of NO from endothelial cells is also impaired in AQP-1 -/- and that this could account for the 30% blunting of maximum endothelium-dependent relaxation, several other possible explanations exist. These include a decrease in acetylcholine receptors, a decrease in G protein expression, and/or G protein activation. Exhaustive testing of all such possibilities is clearly beyond the scope of this manuscript. It appears unlikely that the effects are due to changes in NOS3, because we found that NOS3 expression was increased by 188% in endothelial cells isolated from AQP-1 -/- compared with wild-type. The fact that endothelial cells from AQP-1 -/- exhibited higher levels of NOS3 may be due to an adaptive mechanism developed by these animals to compensate for the diminished effects of NO within the vasculature caused by systemic lack of AQP-1.
The concept that NO freely diffuses across lipid bilayers was originally based on the partition coefficient of NO between hydrophobic phases and water. The partition coefficient of NO in 1-octanol and liposomes relative to water was found to be 6.5 ( 42 ) and 4.4 ( 46 ). It has been assumed that because solubility of NO is higher in hydrophobic phases, NO freely diffuses across cell membranes. However, partition coefficients are measured at equilibrium and do not provide any information concerning the rate at which equilibrium is achieved. Additionally, due to the higher solubility of NO in lipids, it is energetically unfavorable for NO to leave the membrane. Thus one cannot predict transmembrane rates of NO flux based on partition coefficients.
In 1996, Subczynski et al. ( 59 ) calculated the permeability coefficient for NO across membranes based on profiles of local NO diffusion concentration products in synthetic phospholipid bilayers using lipid-soluble NO spin labels and electron paramagnetic resonance. They reported that the lipid bilayer represents no barrier to the diffusion of NO. However, several approximations and assumptions entered into their calculations. Thus the apparent permeability values they obtained are not likely to reflect the real permeability of NO across cell membranes. For instance, the diffusion coefficient of NO in the lipid bilayer was not measured. Instead, the authors assumed that the diffusion coefficient for NO in the lipid phase was the same as in water. However, the diffusion coefficient of NO is reportedly five times lower in lipids with respect to water when measured by fluorescence quenching of derivatives incorporated at different positions in the membrane ( 12, 62 ). Such a difference on its own could cause a significant overestimation of the permeability coefficient. Similarly, it was assumed that the polar heads of phospholipids offer no resistance to the permeability of NO ( 13 ), and thus their calculation would reflect permeability of NO "within" but not "across" the membrane. Finally, experimental measurements of the NO diffusion concentration product were performed under nonphysiological conditions. The concentration of NO was 2 mM, at least 1,000 times that produced by endothelial cells; the experiments were carried out at 25°C, a temperature below the transition phase of cell membranes; and the measurements were done in synthetic lipid bilayers. Under physiological situations, the protein content of cell membranes would decrease the partition coefficient of NO into the lipid bilayer ( 57 ). In contrast to calculated NO permeabilities, we recently demonstrated directly that the cell membrane is a significant barrier to NO diffusion and that AQP-1 facilitates NO transport ( 24 ).
Our data indicate that AQP-1 facilitates diffusion of NO across the mammalian cell membrane. However, free diffusion of NO driven by NO concentration gradients across cell membranes would still be expected to occur, although at lower rates ( 24 ). This raises the question of why, even at the higher levels of NO induced by the highest doses of acetylcholine, free diffusion of NO is not sufficient to completely relax aortic rings from AQP-1 -/- mice. Because NO undergoes rapid degradation ( 42 ), intracellular NOS3-derived NO concentrations may not build up enough to reach the vascular smooth muscle cells by simply equilibrating across cell membranes. As a result, the amount of NO that crosses the cell membrane by free diffusion is not sufficient to cause full relaxation. In contrast, in the presence of AQP-1, NO produced by the cell is rapidly extruded via this channel; consequently, less degradation would occur, and more NO could cross the cell membrane. Given that there was a 30% reduction in response to acetylcholine in AQP-1 -/-, one might well ask why this difference was not seen in the experiments involving spermine NONOate. The most likely explanation is that spermine NONOate produces a higher concentration of NO and that the concentration of NO is constant for a longer period of time ( 31, 58 ) than when the NO is produced by endothelial cells. Thus the fraction of the total amount of NO produced that is degraded is smaller and diffusion of NO can occur rapidly enough to produce maximum relaxation.
NO is an important regulator of blood pressure. In peripheral blood vessels, NO dilates blood vessels and lowers total peripheral resistance. Additionally, NO helps maintain the low renal vascular resistance characteristic of the kidney by dilating preglomerular arterioles. It also regulates ion and solute transport along the nephron, mediates pressure-natriuresis, and modulates tubuloglomerular feedback ( 7, 25, 30, 35, 39 - 41, 43, 54, 61 ). This raises the question of whether deletion of AQP-1 alters blood pressure. Interestingly, AQP-1 -/- mice are not hypertensive; if anything, mean blood pressure is slightly reduced (unpublished data from this laboratory). Several possibilities can explain this. First, these mice are polyuric due to disruption of the countercurrent multiplication mechanism, which in turn is attributable to the lack of AQP-1 in the thin descending limb and descending vasa recta within the kidney ( 10, 37, 52 ). The antihypertensive effects of polyuria would be expected to overwhelm the increased vascular tone resulting from the reduced effects of NO in the vasculature. Second, the rapid scavenging of NO by its reaction with hemoglobin would be expected to be reduced in the knockouts because of the lack of AQP-1 in the membrane of red blood cells. This would result in enhanced NO concentrations, which in turn would increase diffusion, thus enhancing the effects of NO in vascular smooth muscle cells. Third, other modulators of vascular tone, such as prostaglandins ( 5, 11, 21, 63 ), carbon monoxide (CO) ( 8, 29, 67, 68 ), cytochrome P -450 epoxygenase products ( 15, 27, 66 ), and endothelium-dependent hyperpolarizing factor ( 48, 64 ), could be upregulated in the knockouts, mitigating the reduced vasodilator effect of NO in the vasculature. Finally, other aquaporins may compensate for the lack of AQP-1 within the vasculature.
We conclude that 1 ) AQP-1 transports NO into vascular smooth muscle cells, 2 ) AQP-1 transports NO out of endothelial cells, 3 ) the membrane of mammalian cells is a significant barrier to diffusion of NO, 4 ) transport of NO by AQP-1 into vascular smooth muscle cells and out of endothelial cells is essential for full expression of endothelium-dependent relaxation, and 5 ) transport of NO by AQP-1 enhances its physiological effects.
GRANTS
This work was supported in part by National Heart, Lung, and Blood Institute Grants HL-28982 and HL-70985 (to J. L. Garvin) and a predoctoral fellowship from American Heart Association 0415404Z (to M. Herrera).
【参考文献】
Agre P, King LS, Yasui M, Guggino WB, Ottersen OP, Fujiyoshi Y, Engel A, Nielsen S. Aquaporin water channels-from atomic structure to clinical medicine. J Physiol 542: 3-16, 2002.
Agre P, Preston GM, Smith BL, Jung JS, Raina S, Moon C, Guggino WB, Nielsen S. Aquaporin CHIP: the archetypal molecular water channel. Am J Physiol Renal Fluid Electrolyte Physiol 265: F463-F476, 1993.
Agre P, Smith BL, Preston GM. ABH and Colton blood group antigens on aquaporin-1, the human red cell water channel protein. Transfus Clin Biol 2: 303-308, 1995.
Al Sa'doni H, Ferro A. S-nitrosothiols: a class of nitric oxide-donor drugs. Clin Sci (Lond) 98: 507-520, 2000.
Arima S, Ren Y, Juncos LA, Carretero OA, Ito S. Glomerular prostaglandins modulate vascular reactivity of the downstream efferent arterioles. Kidney Int 45: 650-658, 1994.
Arnold WP, Mittal CK, Katsuki S, Murad F. Nitric oxide activates guanylate cyclase and increases guanosine 3':5'-cyclic monophosphate levels in various tissue preparations. Proc Natl Acad Sci USA 74: 3203-3207, 1977.
Beierwaltes WH, Sigmon DH, Carretero OA. Endothelium modulates renal blood flow but not autoregulation. Am J Physiol Renal Fluid Electrolyte Physiol 262: F943-F949, 1992.
Botros FT, Navar LG. Interaction between endogenously produced carbon monoxide and nitric oxide in regulation of renal afferent arterioles. Am J Physiol Heart Circ Physiol 291: H2772-H2778, 2006.
Busse R, Trogisch G, Bassenge E. The role of endothelium in the control of vascular tone. Basic Res Cardiol 80: 475-490, 1985.
Chou CL, Knepper MA, Hoek AN, Brown D, Yang B, Ma T, Verkman AS. Reduced water permeability and altered ultrastructure in thin descending limb of Henle in aquaporin-1 null mice. J Clin Invest 103: 491-496, 1999.
Danielson LA, Conrad KP. Prostaglandins maintain renal vasodilation and hyperfiltration during chronic nitric oxide synthase blockade in conscious pregnant rats. Circ Res 79: 1161-1166, 1996.
Denicola A, Souza JM, Radi R, Lissi E. Nitric oxide diffusion in membranes determined by fluorescence quenching. Arch Biochem Biophys 328: 208-212, 1996.
Dix JA, Kivelson D, Diamond JM. Molecular motion of small nonelectrolyte molecules in lecithin bilayers. J Membr Biol 40: 315-342, 1978.
Fleming I, Busse R. NO: the primary EDRF. J Mol Cell Cardiol 31: 5-14, 1999.
Fleming I, Busse R. Endothelium-derived epoxyeicosatrienoic acids and vascular function. Hypertension 47: 629-633, 2006.
Furchgott RF. The 1989 Ulf von Euler lecture. Studies on endothelium-dependent vasodilation and the endothelium-derived relaxing factor. Acta Physiol Scand 139: 257-270, 1990.
Furchgott RF, Zawadzki JV. The obligatory role of endothelial cells in the relaxation of arterial smooth muscle by acetylcholine. Nature 288: 373-376, 1980.
Gannon BJ, Carati CJ. Endothelial distribution of the membrane water channel molecule aquaporin-1: implications for tissue and lymph fluid physiology? Lymphat Res Biol 1: 55-66, 2003.
Gannon BJ, Warnes GM, Carati CJ, Verco CJ. Aquaporin-1 expression in visceral smooth muscle cells of female rat reproductive tract. J Smooth Muscle Res 36: 155-167, 2000.
Gruetter CA, Barry BK, McNamara DB, Gruetter DY, Kadowitz PJ, Ignarro L. Relaxation of bovine coronary artery and activation of coronary arterial guanylate cyclase by nitric oxide, nitroprusside and a carcinogenic nitrosoamine. J Cyclic Nucleotide Res 5: 211-224, 1979.
Gryglewski RJ, Botting RM, Vane JR. Mediators produced by the endothelial cell. Hypertension 12: 530-548, 1988.
Herrera M, Garvin JL. Endothelin stimulates endothelial nitric oxide synthase expression in the thick ascending limb. Am J Physiol Renal Physiol 287: F231-F235, 2004.
Herrera M, Garvin JL. A high-salt diet stimulates thick ascending limb eNOS expression by raising medullary osmolality and increasing release of endothelin-1. Am J Physiol Renal Physiol 288: F58-F64, 2005.
Herrera M, Hong NJ, Garvin J. Aquaporin-1 transports NO across cell membranes. Hypertension 48: 157-164, 2006.
Herrera M, Ortiz PA, Garvin JL. Regulation of thick ascending limb transport: role of nitric oxide. Am J Physiol Renal Physiol 290: F1279-F1284, 2006.
Herrera M, Silva G, Garvin JL. A high-salt diet dissociates NO synthase-3 expression and NO production by the thick ascending limb. Hypertension 47: 95-101, 2006.
Imig JD, Navar LG, Roman RJ, Reddy KK, Falck JR. Actions of epoxygenase metabolites on the preglomerular vasculature. J Am Soc Nephrol 7: 2364-2370, 1996.
Johns RA, Peach MJ, Linden J, Tichotsky A. N G -monomethyl L -arginine inhibits endothelium-derived relaxing factor-stimulated cyclic GMP accumulation in cocultures of endothelial and vascular smooth muscle cells by an action specific to the endothelial cell. Circ Res 67: 979-985, 1990.
Johnson FK, Teran FJ, Prieto-Carrasquero M, Johnson RA. Vascular effects of a heme oxygenase inhibitor are enhanced in the absence of nitric oxide. Am J Hypertens 15: 1074-1080, 2002.
Juncos LA, Garvin J, Carretero OA, Ito S. Flow modulates myogenic responses in isolated microperfused rabbit afferent arterioles via endothelium-derived nitric oxide. J Clin Invest 95: 2741-2748, 1995.
Keefer LK, Nims RW, Davies KM, Wink DA. "NONOates" (1-substituted diazen-1-ium-1,2-diolates) as nitric oxide donors: convenient nitric oxide dosage forms. Methods Enzymol 268: 281-293, 1996.
King LS, Kozono D, Agre P. From structure to disease: the evolving tale of aquaporin biology. Nat Rev Mol Cell Biol 5: 687-698, 2004.
Knepper MA. The aquaporin family of molecular water channels. Proc Natl Acad Sci USA 91: 6255-6258, 1994.
Kobayashi M, Inoue K, Warabi E, Minami T, Kodama T. A simple method of isolating mouse aortic endothelial cells. J Atheroscler Thromb 12: 138-142, 2005.
Kone BC, Baylis C. Biosynthesis and homeostatic roles of nitric oxide in the normal kidney. Am J Physiol Renal Physiol 272: F561-F578, 1997.
Lee MD, King LS, Agre P. The aquaporin family of water channel proteins in clinical medicine. Medicine (Baltimore) 76: 141-156, 1997.
Ma T, Yang B, Gillespie A, Carlson EJ, Epstein CJ, Verkman AS. Severely impaired urinary concentrating ability in transgenic mice lacking aquaporin-1 water channels. J Biol Chem 273: 4296-4299, 1998.
Maeda Y, Smith BL, Agre P, Knepper MA. Quantification of Aquaporin-CHIP water channel protein in microdissected renal tubules by fluorescence-based ELISA. J Clin Invest 95: 422-428, 1995.
Majid DS, Navar LG. Nitric oxide in the mediation of pressure natriuresis. Clin Exp Pharmacol Physiol 24: 595-599, 1997.
Majid DS, Navar LG. Nitric oxide in the control of renal hemodynamics and excretory function. Am J Hypertens 14: 74S-82S, 2001.
Majid DS, Williams A, Navar LG. Inhibition of nitric oxide synthesis attenuates pressure-induced natriuretic responses in anesthetized dogs. Am J Physiol Renal Fluid Electrolyte Physiol 264: F79-F87, 1993.
Malinski T, Taha Z, Grunfeld S, Patton S, Kapturczak M, Tomboulian P. Diffusion of nitric oxide in the aorta wall monitored in situ by porphyrinic microsensors. Biochem Biophys Res Commun 193: 1076-1082, 1993.
Manning RD Jr, Hu L. Nitric oxide regulates renal hemodynamics and urinary sodium excretion in dogs. Hypertension 23: 619-625, 1994.
Marks GS, McLaughlin BE, Brown LB, Beaton DE, Booth BP, Nakatsu K, Brien JF. Interaction of glyceryl trinitrate and sodium nitroprusside with bovine pulmonary vein homogenate and 10,000 x g supernatant: biotransformation and nitric oxide formation. Can J Physiol Pharmacol 69: 889-892, 1991.
Matsuzaki T, Tajika Y, Ablimit A, Aoki T, Hagiwara H, Takata K. Aquaporins in the digestive system. Med Electron Microsc 37: 71-80, 2004.
Moller M, Botti H, Batthyany C, Rubbo H, Radi R, Denicola A. Direct measurement of nitric oxide and oxygen partitioning into liposomes and low density lipoprotein. J Biol Chem 280: 8850-8854, 2005.
Moncada S, Palmer RM, Higgs EA. Nitric oxide: physiology, pathophysiology, and pharmacology. Pharmacol Rev 43: 109-142, 1991.
Mori Y, Ohyanagi M, Koida S, Ueda A, Ishiko K, Iwasaki T. Effects of endothelium-derived hyperpolarizing factor and nitric oxide on endothelial function in femoral resistance arteries of spontaneously hypertensive rats. Hypertens Res 29: 187-195, 2006.
Nielsen S, Frokiaer J, Marples D, Kwon TH, Agre P, Knepper MA. Aquaporins in the kidney: from molecules to medicine. Physiol Rev 82: 205-244, 2002.
Nielsen S, Pallone T, Smith BL, Christensen EI, Agre P, Maunsbach AB. Aquaporin-1 water channels in short and long loop descending thin limbs and in descending vasa recta in rat kidney. Am J Physiol Renal Fluid Electrolyte Physiol 268: F1023-F1037, 1995.
Nielsen S, Smith BL, Christensen EI, Agre P. Distribution of the aquaporin CHIP in secretory and resorptive epithelia and capillary endothelia. Proc Natl Acad Sci USA 90: 7275-7279, 1993.
Pallone TL, Edwards A, Ma T, Silldorff EP, Verkman AS. Requirement of aquaporin-1 for NaCl-driven water transport across descending vasa recta. J Clin Invest 105: 215-222, 2000.
Ray JL, Leach R, Herbert JM, Benson M. Isolation of vascular smooth muscle cells from a single murine aorta. Methods Cell Sci 23: 185-188, 2001.
Ren YL, Garvin JL, Ito S, Carretero OA. Role of neuronal nitric oxide synthase in the macula densa. Kidney Int 60: 1676-1683, 2001.
Sabolic I, Valenti G, Verbavatz JM, Van Hoek AN, Verkman AS, Ausiello DA, Brown D. Localization of the CHIP28 water channel in rat kidney. Am J Physiol Cell Physiol 263: C1225-C1233, 1992.
Shanahan CM, Connolly DL, Tyson KL, Cary NR, Osbourn JK, Agre P, Weissberg PL. Aquaporin-1 is expressed by vascular smooth muscle cells and mediates rapid water transport across vascular cell membranes. J Vasc Res 36: 353-362, 1999.
Simon SA, Gutknecht J. Solubility of carbon dioxide in lipid bilayer membranes and organic solvents. Biochim Biophys Acta 596: 352-358, 1980.
Smith DJ, Chakravarthy D, Pulfer S, Simmons ML, Hrabie JA, Citro ML, Saavedra JE, Davies KM, Hutsell TC, Mooradian DL, Hanson SR, Keefer LK. Nitric oxide-releasing polymers containing the [N(O)NO] group. J Med Chem 39: 1148-1156, 1996.
Subczynski WK, Lomnicka M, Hyde JS. Permeability of nitric oxide through lipid bilayer membranes. Free Radic Res 24: 343-349, 1996.
Thom SA, Hughes AD, Martin GN, Sever PS. The release of the endothelium derived relaxing factor from isolated human arteries. J Hypertens Suppl 3: S97-S99, 1985.
Tolins JP, Palmer RM, Moncada S, Raij L. Role of endothelium-derived relaxing factor in regulation of renal hemodynamic responses. Am J Physiol Heart Circ Physiol 258: H655-H662, 1990.
Vanderkooi JM, Wright WW, Erecinska M. Nitric oxide diffusion coefficients in solutions, proteins and membranes determined by phosphorescence. Biochim Biophys Acta 1207: 249-254, 1994.
Villa E, Garcia-Robles R, Haas J, Romero JC. Comparative effect of PGE 2 and PGI 2 on renal function. Hypertension 30: 664-666, 1997.
Villar IC, Francis S, Webb A, Hobbs AJ, Ahluwalia A. Novel aspects of endothelium-dependent regulation of vascular tone. Kidney Int 70: 840-853, 2006.
Wang D, An SJ, Wang WH, McGiff JC, Ferreri NR. CaR-mediated COX-2 expression in primary cultured mTAL cells. Am J Physiol Renal Physiol 281: F658-F664, 2001.
Wang H, Garvin JL, Falck JR, Ren Y, Sankey SS, Carretero OA. Glomerular cytochrome P -450 and cyclooxygenase metabolites regulate efferent arteriole resistance. Hypertension 46: 1175-1179, 2005.
Zhang F, Kaide J, Wei Y, Jiang H, Yu C, Balazy M, Abraham NG, Wang W, Nasjletti A. Carbon monoxide produced by isolated arterioles attenuates pressure-induced vasoconstriction. Am J Physiol Heart Circ Physiol 281: H350-H358, 2001.
Zhang F, Kaide JI, Rodriguez-Mulero F, Abraham NG, Nasjletti A. Vasoregulatory function of the heme-heme oxygenase-carbon monoxide system. Am J Hypertens 14: 62S-67S, 2001.
作者单位:1 Henry Ford Hospital and 2 Department of Physiology, Division of Hypertension and Vascular Research, Wayne State University, Detroit, Michigan