|
- 积分
- 0
- 威望
- 0
- 包包
- 0
|
作者:Masao Kakoki, Hyung-Suk Kim, Cora-Jean S. Edgell, Nobuyo Maeda, Oliver Smithies, and David L. Mattson作者单位:1 Department of Pathology and Laboratory Medicine, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina; and 2 Department of Physiology, Medical College of Wisconsin, Milwaukee, Wisconsin
% `9 E0 i# M5 `0 S9 p. Q6 V1 O! T; @
! T' F1 K* c( G' i. ` % p/ V; A9 x$ D+ z
. c# w3 g6 ~% T! }/ [/ d
. y9 i! _% {3 |0 x 6 t U* h9 [( m
; X/ w0 T) [( u( G, d
$ X; g- z" f; f5 [$ t7 u0 \
4 ^2 S8 s& U+ h7 R1 O/ X; W ! X& b. A' l5 p8 s* S3 G! k
: X+ i2 t0 m9 @# E/ u/ L& Q9 ^ 4 p& m" {" q1 I$ M' ]
2 C: V0 t1 }8 R; s 【摘要】
G* U- o! X. q4 ~8 u5 ^, s p To examine the mechanisms whereby amino acids modulate nitric oxide (NO) production and blood flow in the renal vasculature, chemiluminescence techniques were used to quantify NO in the renal venous effluent of the isolated, perfused rat kidney as different amino acids were added to the perfusate. The addition of 10 -4 or 10 -3 M cationic amino acids ( L -ornithine, L -lysine, or L -homoarginine) or neutral amino acids ( L -glutamine, L -leucine, or L -serine) to the perfusate decreased NO and increased renal vascular resistance. Perfusion with anionic amino acids ( L -glutamate or L -aspartate) had no effect on either parameter. The effects of the cationic and neutral amino acids were reversed with 10 -3 M L -arginine and prevented by deendothelialization or NO synthase inhibition. The effects of the neutral amino acids but not the cationic amino acids were dependent on extracellular sodium. Cationic and neutral amino acids also decreased calcimycin-induced NO, as assessed by DAF-FM-T fluorescence, in cultured EA.hy926 endothelial cells. Inhibition of system y or y L by siRNA for the cationic amino acid transporter 1 or the CD98/4F2 heavy chain diminished the NO-depleting effects of these amino acids. Finally, transport studies in cultured cells demonstrated that cationic or neutral amino acids in the extracellular space stimulate efflux of L -arginine out of the cell. Thus the present experiments demonstrate that cationic and neutral amino acids can modulate NO production in endothelial cells by altering cellular L -arginine transport through y and y L transport mechanisms. 8 X2 Z' e2 F+ Y0 M8 _8 n- G
【关键词】 kidney L arginine flow cytometry7 I- W$ T2 i3 {' R: a& u4 \" B
A LARGE BODY OF EVIDENCE indicates that the endogenous production of nitric oxide (NO) by nitric oxide synthase (NOS) in the kidney is partially dependent on the cellular uptake of NOS substrate L -arginine ( L -Arg). Both in vitro and in vivo studies demonstrated that increasing extracellular L -Arg concentration can alter NO-dependent vasorelaxation in the kidney ( 9, 33 ). Cellular L -Arg uptake also appears necessary for NO-mediated effects in renal epithelial cells ( 20, 21, 30, 39, 41 ). Consistent with vasodilatory and/or natriuretic effects mediated by L -Arg uptake, supplementation of L -Arg increased sodium excretion ( 27, 28 ) and prevented or reversed the elevation of arterial blood pressure in a genetic rat model of sodium-sensitive hypertension ( 4, 18 ). Cellular L -Arg transport mechanisms therefore appear to be important to mediate NO-dependent function in the kidney.
% `) d& O; E6 P! `0 A X
: {( ] J' d* \1 uCationic amino acids, including L -Arg, are transported into cells by a number of differentially expressed transport systems (y , b o, , B o, , y L) ( 10, 25 ). A y transport mechanism mediates cellular L -Arg uptake in renal epithelial cells ( 20, 21, 39, 41 ), whereas L -Arg uptake in endothelial cells is mediated by both y and y L transport mechanisms ( 7, 35, 37 ). System y is a family of cationic amino acid transporters represented predominantly in the kidney by the CAT1 gene product ( 20, 41 ). System y L mediates the cellular uptake of both cationic and neutral amino acids. The cellular uptake of cationic amino acids by y and y L transporters is sodium independent, and uptake of neutral amino acids by the y L transporter is sodium dependent. The y L mechanism observed in endothelial cells has been identified to be associated with CD98/4F2 heavy chain (hc) ( 7, 35, 37 ). Both the y and y L systems demonstrate competitive inhibition as well as trans -stimulation (exchange) ( 3, 5 - 7, 10, 35, 40 ). As such, it would be predicted that both cationic and neutral amino acids could influence intracellular L -Arg levels by decreasing cellular L -Arg uptake and/or by stimulating efflux of L -Arg from cells.; y3 w* M* C3 ?9 Q$ g# h* i
9 k, Z+ D+ z0 u. R
Cellular L -Arg uptake, mediated by a y mechanism, influences NO production in renal epithelial cells ( 20, 21, 39, 41 ). The importance of y and/or y L-mediated L -Arg uptake mechanisms in the regulation of NO production in the renal vasculature and the regulation of renal vascular resistance has not been examined. In the present study, we tested the hypothesis that both cationic and neutral amino acids modulate NO and NO-dependent function in the renal vasculature through y and/or y L-mediated L -Arg transport. Experiments were performed in the isolated, perfused rat kidney and in cultured endothelial cells to determine the importance of L -Arg transport in the regulation of NO production and vascular resistance.
5 }, l5 G: @0 c: V& O0 l ^) K W8 i& F# Z7 \/ D( G
MATERIALS AND METHODS7 k5 B- Q! W5 d/ t1 K7 q
) v6 |8 @2 p/ @( x6 J
Animals: z. t1 Y! u" ?( O2 y2 E' W, X0 _
8 b' V& Y$ W, \) u3 J' w6 ^3 {2 v
Male Sprague-Dawley rats were used in this study. The animals were obtained from Harlan Sprague Dawley (Madison, WI) and housed in the Animal Resource Center at the Medical College of Wisconsin. Food and water were available ad libitum. All experiments were conducted in accordance with the Medical College of Wisconsin Institutional Animal Care and Use Committee's guidelines.4 Q% x/ d' J" W
( G# z1 S; j$ }9 ^# z2 v5 D" m, Y
Isolated, Perfused Kidney
: t y8 s. r6 h1 n+ [8 X8 n) M! I/ }
Rats were anesthetized with pentobarbital sodium (50 mg/kg ip) and the right kidney was isolated and perfused as described previously ( 19, 23 ). The renal artery was cannulated via the aorta to ensure constant perfusion. The kidneys were perfused with Krebs-Henseleit buffer (118 mM NaCl, 4.7 mM KCl, 2.5 mM CaCl 2, 1.2 mM MgSO 4, 1.2 mM KH 2 PO 4, 25.0 mM NaHCO 3, and 10 mM glucose) saturated with 95% O 2 -5% CO 2. The buffer contained phenylephrine (10 -7 M) to maintain renal perfusion pressure (RPP) at 100 mmHg with a constant perfusion rate of 5 ml/min using a roller pump. The renal venous effluent was collected continuously (2 ml/min), mixed with a chemiluminescence probe (0.5 ml/min; 2 mM H 2 O 2, 18 µM luminol, 2 mM potassium carbonate, and 150 mM desferrioxamine), and forwarded into a flow-cell type chemiluminescence analyzer (CL-1525, JASCO, Tokyo, Japan) to quantify NO in the effluent. The experimental protocols were performed following a 60-min equilibration period.
- ^- X8 A# w7 ?9 J
$ w* ~; G2 U5 R/ nValidation experiments demonstrated that this system responded with a decrease in renal vascular resistance and an increase in chemiluminescent signal when acetylcholine was added to the perfusate (10 -7 -10 -6 M). Endothelial disruption was performed by serial introduction of seven individual air boli (0.5 ml) into the renal arterial perfusate. The functional absence of the endothelium was confirmed by the lack of the vascular response to 10 -7 M acetylcholine.
6 N8 w( v8 k) {# g3 J, h! j
+ j6 v, ?) p2 {, J, ?Cell Culture Experiments
1 G. O5 p! P3 n0 s' G" D1 S
0 b4 T) l K1 D2 I. n! U& E+ R$ E& ^The EA.hy926 human vascular endothelial cell line was used in the present study; these cells were established from human umbilical vein endothelial cells as a continuous cell line ( 11 ). The cells were grown in DMEM supplemented with 10% heat-inactivated fetal bovine serum and 2 mM L -glutamine./ ~2 Q- H( x! n( B
; @1 V6 z6 _0 U7 AFor flow cytometry analysis, the EA.hy926 cells were trypsinized and resuspended in Locke's solution (154 mM NaCl, 5.6 mM KCl, 2 mM CaCl 2, 1 mM MgSO 4, 10 mM HEPES, 3.6 mM NaHCO 3, and 5.6 mM glucose). After a 60-min equilibration period, calcimycin (10 µM) and amino acids (100 µM) were added and the cells were incubated for 60 min at 37°C in a CO 2 incubator. The cells were then incubated for 30 min with 2 µM DAF-FM diacetate (Molecular Probes). Flow cytometry for the fluorescence of the benzotriazole derivative of DAF-FM (DAF-FM-T) was performed with a FACScan Cytometer equipped with an argon laser for excitation at 488 nm and a 530/30-nm bandpass filter (Becton Dickinson). We observed in preliminary experiments that the DAF-fluorescence was very low in the absence of calcimycin, and no differences were detected between the cells with vehicle and those treated with 1-mM concentrations of cationic amino acids, neutral amino acids, or L -NAME; the NO response to calcimycin stimulation was therefore compared when the cells were treated with different amino acids. A minimum of 2,500 events was collected for each analysis. Data acquisition and analysis were made with Summit 3.1 software (DakoCytomation).; x, P1 y6 N4 {1 |/ |6 _
, u/ ]4 I0 V4 Z. ], G: Z5 W
Generation and Transfection of Small Interference RNA2 |9 |1 ^. i, Y: o
; G# a+ i6 `2 D5 f1 NSmall interference RNAs (siRNAs) ( 12 ) for CAT1 and CD98/4F2hc were prepared with a Dicer siRNA Generation Kit (Gene Therapy Systems) according to the manufacturer's instructions. The sequences of the T7 promoter (lower case)-tagged primers used for RT-PCR are 5'-GCGtaatacgactcactatagggagaGTTGGTCTTACGGTACCAGC-3' (CAT1 Fwd; Genbank gi 4507046), 5'-GCGtaatacgactcactatagggagaTGCAGTGAGGGTGTGGACG-3' (CAT1 Rev), 5'-GCGtaatacgactcactatagggagaTCTCCACGACCGTCCTGTG-3' (CD98 Fwd; Genbank gi 21361343), and 5'-GCGtaatacgactcactatagggagaCCACTCTGCAAACCCTAAGG-3' (CD98 Rev). The delivery of siRNAs into the cells was confirmed using siRNAs labeled with Cy3 using Silencer siRNA Labeling Kit (Ambion). The siRNA (100 nmol) was transfected into 50% confluent EA.hy926 cells with Oligofectamine Reagent (Invitrogen), and the cells were harvested 48 h after the beginning of the 3-h incubation.3 Y' t2 s2 e9 R z3 \2 T4 ]3 H
6 V0 h+ c0 P3 p" a+ y, h7 M, X
Immunoblot Analysis
, D7 K. m. T) v5 b# ?
0 X# _4 m( P9 M/ W+ _3 dCells were lysed with 3 vol of lysis buffer containing 10 mM Tris (pH 7.5), 10 mM NaCl, 1 mM MgCl 2, 0.5% Nonidet P40, and 1 mM phenylmethylsulfonyl fluoride ( 16 ). Following a 10-min low-speed centrifugation (800 g ), the supernatant was treated with N -glycosidase F (10 U/100 µg protein) for 1 h at 37°C. Protein samples (100 µg/lane) were separated under reducing conditions on a 4-20% gradient sodium dodecyl sulfate-polyacrylamide gel and transferred to a polyvinyl difluoride membrane by wet blotting. The membranes were incubated with a rabbit polyclonal anti-CAT1 antibody (1:1,000) or mouse monoclonal anti-hCD98 antibody (1:50; Cymbus/Chemicon) as the primary antibody and with horseradish peroxidase-conjugated goat anti-rabbit or anti-mouse IgG antibody (1:5,000; DakoCytomation) as the secondary antibody. Visualization of the bands was performed by chemiluminescence (Amersham).
6 \9 h* E) M; _5 P+ S
( T) n8 W4 D+ s+ y" ]L -Arg Efflux; t. W6 }7 A5 U1 {- T. B
, I x: n1 [) v. u' X% m# e5 qTransport experiments were performed using the cluster-tray method for the measurement of solute flux in adherent cells ( 13 ). The serum-depleted (60 min) EA.hy926 cells were incubated with Locke's buffer with or without 1 mM N -ethylmaleimide (NEM) containing 0.5 µCi/ml of [ 14 C] L -Arg for 60 min. After the incubation, the cells were washed twice and incubated with the buffer with L -amino acids (100 µM). Arginine efflux was determined by the ratio [Rsup/(Rsup Rcell)] where Rsup is the radioactivity in the supernatant and Rcell is the radioactivity in the cells. Cell extracts were obtained by incubating the cells with 10% (wt/vol) trichloroacetic acid for 60 min. The radioactivity was determined by liquid scintillation counting.; w9 B5 [: n8 ]
7 w1 ~7 w8 X1 v+ m7 j) O0 gExperimental Protocols
5 J7 ]+ ~8 @9 G. M) q% S; e' k3 R; {3 F$ x; G1 W9 y
Protocol 1: influence of cationic, neutral, and anionic amino acids on vascular resistance and NO release in the isolated, perfused rat kidney. The isolated, perfused rat kidney was prepared as described above. The changes in renal vascular resistance and renal venous NO were measured during a 30-min control period and during two 30-min experimental periods in which 10 -4 and 10 -3 M concentrations of the following amino acids were successively added to the perfusate: L -ornithine ( L -Orn), L -lysine ( L -Lys), L -homoarginine ( L -Harg), L -glutamine ( L -Gln), L -leucine ( L -Leu), L -serine ( L -Ser), L -glutamate ( L -Glu), and L -aspartate ( L -Asp). The control and experimental periods were each 30 min in duration.
2 o* u* A& k1 x4 K: I5 D7 Q
3 d5 h4 [( Q3 ~" u0 E3 G8 S( x, nProtocol 2: influence of L -NAME, L -Arg, sodium substitution, or endothelial cell disruption on renal vascular resistance and NO release in isolated, perfused rat kidneys administered cationic or neutral amino acids. The isolated, perfused rat kidney was prepared as described above. Throughout the control and experimental portion of the experiment, the following substances were included in the perfusate: vehicle, 10 -4 M L -NAME, or 10 -4 M L -Arg. Additional experiments were performed in kidneys in which the endothelial cell layer was damaged by injection of air bubbles into the arterial perfusate until the renal vasculature no longer dilated in response to 10 -7 M acetylcholine. A final group of kidneys was studied in which NaCl in the perfusate was replaced with N -methyl-glucamine (NMG). The changes in renal vascular resistance and chemiluminescent signal in each of these groups were measured during a 30-min control period and during a 30-min period following the addition of 10 -4 M of the following amino acids to the perfusate: L -Orn, L -Lys, L -Harg, L -Gln, L -Leu, and L -Ser.
; g/ l2 Y( P! j$ g& E
/ p" |0 n' \8 U7 oProtocol 3: influence of cationic, neutral, and anionic amino acids on NO in cultured endothelial cells. Experiments were performed to determine whether cationic, neutral, and anionic amino acids influenced NO, as measured by DAF fluorescence, in calcimycin-stimulated EA.hy926 cells. The cells were prepared as described above and incubated with vehicle plus 10 -4 M L -Arg, L -NAME, L -Orn, L -Lys, L -Harg, L -Gln, L -Ser, L -Glu, or L -Asp. Additional experiments were performed in which the cells were incubated with excess L -Arg (10 -3 M) along with 10 -4 M of each of the cationic or neutral amino acids.
- E; N- ^' l' I3 b' O# Q# B+ l. x m$ T! Y
Protocol 4: influence of siRNA for CAT1 or CD98/4F2hc on NO release in cultured endothelial cells treated with cationic or neutral amino acids. Experiments in this protocol were performed to determine the role of the y transporter CAT1 and the y L transporter CD98/4F2hc in the NO-suppressive response to cationic or neutral amino acids in cultured cells. Cells were treated with siRNA for either CAT1 or CD98/4F2hc for 48 h. Control cells were transfected with siRNA for green fluorescent protein (GFP). The NO response to calcimycin stimulation during the incubation with the cationic amino acid L -Orn or the neutral amino acid L -Gln was then examined in the absence of extracellular L -Arg in control and siRNA-treated cells.& e# O4 T1 E4 C# @
* H5 M+ S) D- o6 m) c
Protocol 5: influence of cationic, neutral, and anionic amino acids on L -Arg efflux from cultured endothelial cells. Transport experiments were performed to quantify L -Arg efflux from cultured cells as described above in untreated cells and those incubated with 10 -4 M L -Arg, L -Orn, L -Lys, L -Harg, L -Ser, L -Gln, L -Leu, L -Glu, or L -Asp ( n = 4/group). L -Arg efflux was determined at 5, 10, 20, and 40 min after the incubation was begun. Experiments were performed in the presence and absence of 1 mM N -ethyl-maleimide (NEM), an agent which inhibits y but not y L transport.) v: d. k7 a2 E- K
0 n$ {5 t4 g0 Y, J: cRESULTS
R. `' s# a/ ]& r6 n! }
, R7 V1 |$ ?6 D4 j5 `+ ]' ZProtocol 1: Influence of Cationic, Neutral, and Anionic Amino Acids on NO Release and Vascular Resistance in the Isolated, Perfused Rat Kidney, L: I9 q0 p, S# R1 j
. E/ Y$ l. ^9 g* \
The effects of cationic, neutral, and anionic amino acids on vascular resistance and NO release in the effluent of the isolated, perfused kidney are illustrated in Fig. 1 ( n = 4/group). The addition of 10 -4 and 10 -3 M of the cationic amino acids L -Orn, L -Lys, or L -Harg led to a significant decrease in NO release in the venous effluent with an accompanying increase in renal vascular resistance. These vasoconstrictive responses took 10 min to reach a stable level. The addition of the neutral amino acids L -Gln, L -Leu, or L -Ser to the perfusate also led to a decrease in NO and an elevation of vascular resistance in the isolated, perfused kidney. Neither the 10 -4 or 10 -3 M concentration of the anionic amino acids L -Glu or L -Asp altered NO or vascular resistance in this preparation. The addition of 10 -4 M L -NAME, the NOS inhibitor, decreased the NO in the perfusate and increased vascular resistance; the L -NAME data ( n = 8) were obtained following the amino acid infusion from the kidneys perfused with L -Glu or L -Asp.
8 v) A# M0 `- e" s L: c0 o! g7 ^+ {, C" w) |
Fig. 1. Influence of L -ornithine ( L -Orn), L -lysine ( L -Lys), L -homoarginine ( L -Harg), L -glutamine ( L -Gln), L -leucine ( L -Leu), L -serine ( L -Ser), L -aspartate ( L -Asp), L -glutamate ( L -Glu), and N w -nitro- L -arginine methyl ester ( L -NAME) on vascular resistance and nitric oxide (NO) release from the isolated, perfused rat kidney. * P & d8 P6 l% c' U% X5 z
7 c& m6 H9 E- E. G5 ~9 m9 t2 iProtocol 2: Influence of L -NAME, L -Arg, Sodium Substitution, or Endothelial Cell Disruption on Renal Vascular Resistance and NO Release in Isolated, Perfused Rat Kidneys Administered Cationic or Neutral Amino Acids ]6 @; M/ A1 S( y7 i0 _: Z& d6 G
5 P3 q' j* c# i, H2 W
A summary of data from experiments to examine the mechanism of the changes in vascular resistance and NO release in kidneys in which cationic or neutral amino acids were added to the perfusate is illustrated in Fig. 2; each bar represents the value from an individual group ( n = 4/group). The addition of 10 -4 M of each cationic or neutral amino acid led to a significant decrease in NO in the renal venous effluent and an increase in renal vascular resistance. None of the amino acids affected vascular resistance or NO release in kidneys in which air boli were used to disrupt the endothelium or in kidneys pretreated with L -NAME. These experiments indicated that the effects of the cationic and neutral amino acids are endothelium dependent and NOS dependent. The addition of 10 -4 M L -Arg to the perfusate in addition to the 10 -4 M concentration of each amino acid significantly blunted the increase in renal vascular resistance and the decrease in NO in the renal venous effluent, indicating that the effects of the cationic and neutral amino acids are mediated through competition for L -Arg uptake. Finally, to test whether the effects of the amino acids are sodium dependent, NaCl in the perfusate was replaced with NMG. The substitution for NaCl with NMG did not affect the change in NO or vascular resistance associated with infusion of the cationic amino acids L -Orn, L -Lys, or L -Harg. The addition of NMG did, however, significantly blunt the changes in vascular resistance and NO in the groups administered the neutral amino acids L -Gln, L -Leu, and L -Ser. These results indicate that the effects of the cationic amino acids are sodium independent, whereas the effects of the neutral amino acids are sodium dependent.
" x2 M& s8 O* ]0 M S3 M: W0 n3 a! ~$ V: M/ X8 x' T
Fig. 2. Influence of 10 -4 M L -Orn, L -Lys, L -Harg, L -Gln, L -Leu, and L -Ser on vascular resistance and NO release from the isolated, perfused rat kidney. Experiments were performed on groups of vehicle-treated control kidneys or those in which 10 -4 M L -NAME or L -arginine ( L -Arg) was added to the perfusate throughout the control and experimental portion of the experiment. Additional experiments were performed in kidneys in which the endothelial layer was damaged (endo-) by continuous injection of air until the renal vasculature no longer dilated to 10 -7 M acetylcholine. A final group of kidneys was studied for each amino acid in which the NaCl in the perfusate was replaced with N -methyl- D -glucamine (NMG). * P
/ p8 i% Y0 s- \) ~" [8 r- B! U
; T" g* I9 Y6 R UProtocol 3: Influence of Cationic, Neutral, and Anionic Amino Acids on NO in Cultured Endothelial Cells
8 K2 v8 g. q8 ^3 s
8 V$ h6 @ u3 c2 j) m- VTo elucidate the mechanisms through which both cationic and neutral amino acids can decrease NO release and increase renal vascular resistance, further experiments were performed in cultured endothelial cells (EA.hy926). The NO production in calcimycin-stimulated cells subjected to various treatments was assessed by DAF fluorescence ( Fig. 3 1,000 cells/group). Compared with vehicle-treated cells, 10 -4 M L -Arg increased DAF fluorescence while the NOS inhibitor L -NAME significantly decreased calcimycin-stimulated NO in the cultured cell preparation. The addition of 10 -4 M of the cationic amino acids L -Orn, L -Lys, and L -Harg or the neutral amino acids L -Gln and L -Ser led to a significant blunting of NO production in the cells compared with vehicle-treated cells. The reduction in the NO signal was attenuated when excess L -Arg (10 -3 M) was added along with the cationic or neutral amino acids. Consistent with the observation in the isolated, perfused kidney, neither of the anionic amino acids, L -Glu or L -Asp, altered calcimycin-stimulated DAF fluorescence in the cultured cells. The changes in NO observed in the calcimycin-stimulated endothelial cells are therefore similar to those observed in the isolated, perfused kidney. p* p1 `/ |: B
; m+ H1 n4 D) eFig. 3. Intensity of calcimycin-stimulated DAF-FM-T fluorescence in cultured human EA.hy926 endothelial cells incubated with 10 -4 M L -Arg, L -NAME, L -Orn, L -Lys, L -Harg, L -Gln, L -Ser, L -Glu, or L -Asp. Additional experiments were performed in which excess L -Arg (10 -3 M) was added in addition to the cationic and neutral amino acids. * P
) c+ H# v& V& M+ G- s
8 q# q+ `! s$ E; s8 z9 TProtocol 4: Influence of siRNA for CAT1 or CD98/4F2hc on NO Release in Cultured Endothelial Cells Treated with Cationic or Neutral Amino Acids
$ t; g+ l2 @& i! j
; v6 Z; {- ^# jTo determine the role of the y transporter CAT1 and the y L transporter CD98/4F2hc in the NO-suppressive response to cationic amino acids in cultured EA.hy926 cells, cells were treated with siRNA inhibition before stimulation with calcimycin. Photomicrographs demonstrating the fluorescence of Cy3-labeled siRNA for GFP or CAT1 48 h after the transfection in cultured human EA.hy926 endothelial cells indicate that the siRNA is taken up by most cells and located mainly in the perinuclear cytoplasm ( Fig. 4 ). Representative immunoblots for CAT1 or CD98/4F2hc in the cells incubated with the siRNAs for GFP (negative control) or with those for CAT1 or CD98/4F2hc demonstrate a reduction of the siRNA-targeted protein. Densitometric analysis indicated that CAT1-immunoreactive protein was significantly reduced by greater than 80% by CAT1 siRNA treatment compared with cells treated with nonspecific siRNA for GFP ( n = 4). Similarly, siRNA for CD98/4F2hc protein significantly reduced CD98/4F2hc protein by greater than 90% ( n = 4)./ f; [) [/ \1 b- o5 l
, X" p, M* W6 F- f X* q0 s) x
Fig. 4. Photomicrographs of the fluorescence of Cy3-labeled small interference RNAs (siRNAs) for cationic amino acid transporter 1 (CAT1) 48 h after the transfection in cultured human EA.hy926 endothelial cells. The siRNA is located mainly in the perinuclear cytoplasm. A : phase contrast. B : Cy3 fluorescence. C and D : immunoblot for CAT1 ( C ) or CD98/4F2hc ( D ) in the cells incubated with the siRNAs for green fluorescence protein (GFP; negative control) or with those for CAT1 or CD98/4F2hc.; r! H6 F+ P% k: a! U- V
" G8 Y9 b \: b9 v/ I
Experiments were performed in calcimycin-stimulated cells to examine the influence of L -Orn and L -Gln on NO production in control cells and cells with siRNA inhibition of CAT-1 or CD98/4F2hc. Compared with control cells incubated with 10 -4 M L -Orn, calcimycin-stimulated cells subjected to siRNA inhibition of CAT-1 or CD98/4F2hc had a significantly greater NO than observed in the control cells ( Fig. 5, top ). These results indicate that both the y and y L mechanisms are important for the L -Orn-mediated reduction in NO in these cultured cells.2 i& h4 K$ l/ x% W% _( u
9 b B: z- e1 T- f. `( ?
Fig. 5. Intensity of calcimycin-stimulated DAF-FM-T fluorescence in cultured human EA.hy926 endothelial cells treated with vehicle, CAT1 siRNA, or CD98/4F2hc siRNA. Fluorescence was measured under control conditions or following addition of 10 -4 M L -Orn or L -Gln. * P
: [4 }! S; {! a; l" h" z7 O0 T- Y- d" T) \
Further experiments examined the NO responses in calcimycin-stimulated cells incubated with the neutral amino acid L -Gln ( Fig. 5, bottom ). The siRNA inhibition of CAT-1 did not affect NO production in cells incubated with 10 -4 M L -Gln compared with NO production in control cells exposed to L -Gln. In contrast, calcimycin-stimulated NO production during incubation with L -Gln was significantly greater in cells in which CD98/4F2hc was inhibited when compared with control cells. These results demonstrate that the effects of L -Gln are not mediated by a y mechanism, but the y L mechanism is important in the reduction of NO in response to this neutral amino acid.
5 Q* X K- ^/ N8 F) P0 D
; T) |( Q7 v& g( fProtocol 5: Influence of Cationic, Neutral, and Anionic Amino Acids on L -Arg Efflux from Cultured Endothelial Cells
( A# y' x j4 Y+ n. D( h2 R5 ?7 {! y, @* z4 u% O8 G F1 y* V
To test whether cationic and neutral amino acids lead to trans -stimulation of L -Arg, the influence of different amino acids ( n = 4/group) on efflux of 14 C- L -Arg from cultured endothelial cells was determined. Radiolabeled L -Arg moved out of cells subjected to each treatment during the 40-min experiment. Compared with untreated cells, the addition of the cationic amino acids ( L -Arg, L -Orn, L -Lys, and L -Harg) increased L -Arg efflux ( Fig. 6 A ). The addition of the neutral amino acids L -Ser, L -Gln, and L -Leu also stimulated L -Arg efflux from the cultured cells ( Fig. 6 B ). Incubation of the cells with the anionic amino acids L -Glu and L -Asp did not affect L -Arg movement from the cells compared with the untreated group of cells ( Fig. 6 C ). There were no significant differences in L -Arg efflux between the cells treated with the four different cationic amino acids, between the cells incubated with the three different neutral amino acids, or between the cells treated with the two different anionic amino acids. For purposes of statistical comparison, the data from the different cationic amino acids ( n = 16), neutral amino acids ( n = 12), and anionic amino acids ( n = 8) were combined. Although both cationic and neutral amino acids stimulated L -Arg movement out of the cultured endothelial cells, the cationic amino acids had a significantly greater stimulatory effect on L -Arg efflux than the neutral amino acids. Compared with control, the anionic amino acids did not stimulate L -Arg efflux from the cells.
9 h+ A; Y( G N: I: Z
1 S3 A% k. ?1 `7 T" T. t" R3 XFig. 6. Efflux of intracellular L -Arg from EA.hy926 cells. Data are expressed as the ratio of the [ 14 C] L -Arg in the supernatant (R sup ) to the total radioactivity in the well (R tot ). A : L -Arg efflux in control cells (Blank) and cells incubated with 10 -4 M of the cationic amino acids L -Arg, L -Orn, L -Lys, or L -Harg. B : L -Arg efflux in control cells (Blank) and cells incubated with 10 -4 M of the neutral amino acids L -Ser, L -Gln, or L -Leu. C : L -Arg efflux in control cells (Blank) and cells incubated with 10 -4 M of the anionic amino acids L -Glu or L -Asp. D : pooled effects of the cationic and neutral amino acids on L -Arg efflux; L -Arg efflux after 10 min was compared in the presence and absence of 1 mM N -ethyl-maleimide (NEM). * P / e2 C; o0 p8 Z0 z4 J
. J. p2 C# ~& `! d3 B4 i; d
The effects of the cationic and neutral amino acids on L -Arg efflux following 10 min of incubation in control cells and in cells treated with NEM, a blocker of y transport, are illustrated in Fig. 6 D. Both cationic and neutral amino acids stimulated L -Arg efflux, although the cationic amino acids had a significantly greater effect than the neutral amino acids. The addition of NEM did not alter the efflux of L -Arg in the control cells or in those treated with neutral amino acids. In contrast, the addition of NEM significantly decreased cationic amino acid-mediated L -Arg efflux by 40% to a level not significantly different from that observed with neutral amino acids. The addition of NEM did not alter the efflux of L -Arg in control cells or in those incubated with neutral amino acids.9 d7 e) [# ~/ w7 k: o9 @
4 R# C2 ^* G8 @$ q
DISCUSSION
1 y% A1 \) b+ l' I: x) \$ T
" K8 c( R% m4 s2 _The present experiments demonstrate that the cationic amino acids L -Orn, L -Lys, and L -Harg and the neutral amino acids L -Gln, L -Leu, and L -Ser decrease NO and increase renal vascular resistance in the isolated, perfused kidney. The effects of both the cationic and neutral amino acids are endothelium dependent, NOS dependent, and reversed by coadministration of excess NOS substrate. Moreover, the effects of the cationic amino acids are sodium independent, the effects of the neutral amino acids are sodium dependent, and the anionic amino acids have no influence on vascular resistance or NO release. Further studies in cultured cells confirmed the effects of the cationic, neutral, and anionic amino acids on NO production. It was also demonstrated that siRNA inhibition of the y transporter CAT-1 attenuated the NO-depleting influence of the cationic amino acid L -Orn, whereas siRNA inhibition of the y L transporter CD98/4F2hc attenuated the NO-depleting effects of L -Orn and the neutral amino acid L -Gln in cultured cells. Finally, transport studies in cultured cells demonstrated that cationic or neutral amino acids in the extracellular space can lead to a depletion of cellular L -Arg. Together, these data are consistent with the hypothesis that y and y L transporters are present in the endothelial layer of the rat renal vasculature and that manipulation of L -Arg transport by either mechanism can alter NO and renal vascular resistance.
" ?! G$ g' d: T7 m; Z, p, D# u2 E2 E- Z/ G4 s
These experiments demonstrate that a number of cationic and neutral amino acids can have a potent influence on L -Arg efflux, NO production, and vascular resistance. Although the in vitro nature of these studies necessitates a limited interpretation of these data, the concentrations of the amino acids used in the present study (10 -4 -10 -3 M) are in the range of the physiological concentrations of these amino acids in the extracellular fluid ( 15 ). Moreover, increasing extracellular L -Arg concentration increases NO-dependent vasorelaxation in the renal and systemic vasculature ( 1, 9, 33 ); and cellular L -Arg uptake appears necessary for NO-mediated effects in the thick ascending loop of Henle ( 30 ), the macula densa ( 39 ), and the inner medullary collecting duct ( 41 ). In addition, physiological concentrations of L -Gln, but not L -Glu, markedly impaired endothelium-dependent vasorelaxation in the thoracic rat aorta and decreased intracellular concentration of L -Arg in cultured vascular endothelial cells ( 36 ). The manipulation of cellular L -Arg uptake can therefore have a potent effect on vascular NO and NO-dependent function.
& W, r) i1 \0 z" \ n" ^0 K% b
- G1 D3 r g: K' ~' v- g, ~Results of the present experiments are consistent with both competitive inhibition and trans -stimulation mechanisms influencing L -Arg in the renal vasculature. The observations that L -Arg increased NO in the cultured cells while excess or equimolar amounts of L -Arg blocked the NO-depleting effects of the cationic and neutral amino acids in the cultured cells or the isolated, perfused kidney are consistent with competitive inhibition. The other cationic amino acids and the neutral amino acids thus compete with L -Arg for cellular uptake, likely through y and y L mechanisms. Interestingly, addition of the cationic and neutral amino acids to the perfusate, in the absence of L -Arg, also led to a decrease in NO in the isolated, perfused kidney. This observation is consistent with trans -stimulation of systems y and y L which mediates the transmembrane exchange of extracellular and intracellular amino acids ( 3, 5 - 7, 10, 35, 40 ). This is a well-described mechanism whereby cationic or neutral amino acids in the extracellular fluid stimulate the efflux of L -Arg from the cells. As evidence of trans -stimulation, we observed that the addition of cationic or neutral amino acids, but not anionic amino acids, to the extracellular fluid enhanced the efflux of L -Arg from the cultured cells. The present data therefore indicate that cationic or neutral amino acids in the extracellular space can lead to a decrease in intracellular NOS substrate by both decreasing the amount of L -Arg taken into cells and also by increasing the movement of L -Arg out of endothelial cells.
3 C/ B0 b( n1 {
2 m" U0 m& a, D5 \The present data may help explain the discrepancy, known as the "arginine paradox," between the results of in vivo and in vitro studies which examined extracellular L -Arg and NO production. Because intracellular L -Arg (100-3,800 µM) ( 2 ) is much greater than the K m of NOS for L -Arg (
+ x c% J' q1 V! r+ w& v
; B7 }& T( R# B+ ]0 P5 ZA number of explanations have been proposed for the arginine paradox. One possibility is that endogenous inhibitors of NOS, such as N G -monomethyl- L -arginine and asymmetric N G, N G -dimethyl- L -arginine, increase the functional K m of L -Arg in vivo ( 38 ). Another potential explanation is spatial sequestration of L -Arg in intracellular pools, some of which are inaccessible to eNOS ( 37 ). In addition, the immunolocalization of CAT1 with endothelial NOS ( 26 ) suggests that the close association of the L -Arg transporter and NOS could lead to L -Arg uptake-dependent NO production. The present results, which indicate that cationic and neutral amino acids are competitors of L -Arg for cellular uptake and can also lead to L -Arg depletion, are consistent with each of these possibilities. The cellular and molecular mechanisms which mediate the observed dependence of NO on L -Arg transport remain to be fully resolved.
" a7 B/ P% |) K2 b/ W# B
9 H1 a# n; `0 x1 X+ eIn summary, the present experiments indicate that renal vascular NO and resistance can be modulated by manipulation of cellular y and y L amino acid transport mechanisms. Physiological levels of several different cationic and neutral amino acids decreased endothelium-derived NO and increased vascular resistance in the isolated, perfused kidney. Further studies in cultured cells indicated that cationic and neutral amino acids can modulate NO production in endothelial cells by depletion of intracellular L -Arg through a combination of competitive inhibition which decreased cellular L -Arg uptake and trans -stimulation which increased the efflux of L -Arg. Further study will be required to determine the importance of these mechanisms in the physiological control of vascular resistance and to determine whether abnormalities in y or y L transport in the endothelium or whether an imbalance between L -Arg and other amino acids in the extracellular fluid are important in disease.
7 ]$ E: P/ S/ G2 d& s
8 e }% E! }6 {. S( p% xGRANTS9 e- [- j" c& |3 _
S4 y9 y6 g+ \% y4 a8 j5 z! ^This work was partially supported by National Institutes of Health Grants HL-29587 and DK-62803 to D. Mattson and a fellowship program of the Japanese Heart Foundation and of Sankyo Life Science Foundation to M. Kakoki.2 U6 @" E9 `6 d; `' D! S
【参考文献】 ~' x9 j' v5 F! j7 a3 e" p
Aisaka K, Gross SS, Griffith OW, and Levi R. L -Arg availability determines the duration of acetylcholine-induced systemic vasodilation in vivo. Biochem Biophys Res Commun 163: 710-717, 1989., w2 ^/ x5 h# t
2 w* z2 k# p3 F A
& f7 ~9 S( |# P ^ q: q( o8 N* ?" |+ @: l9 U; I7 G8 D* s, \
Baydoun AR, Emery PW, Pearson JD, and Mann GE. Substrate-dependent regulation of intracellular amino acid concentrations in cultured bovine aortic endothelial cells. Biochem Biophys Res Commun 173: 940-948, 1990.7 ~4 k/ v% ]1 F9 a( s+ Y. S
1 J# H/ J1 l5 C6 M. [9 K$ S" L5 ]- q: A! B* e# r
- n) U! R% y2 ?6 Z5 BBröer A, Wagner CA, Lang F, and Bröer S. The heterodimeric amino acid transporter 4F2hc/y LAT2 mediates arginine efflux in exchange with glutamine. Biochem J 349: 787-795, 2000." h6 ^* e! d. I8 w
1 f; Y3 R' _; @ D- P3 [* l
6 @# F f7 F7 [
$ t$ k7 I6 h$ f+ a' v6 S' A& ]3 V6 q
Chen PY and Sanders PW. L -Arginine abrogates salt-sensitive hypertension in Dahl/Rapp rats. J Clin Invest 88: 1559-1567, 1991.
' q7 p$ \# ?0 g% p6 v8 N, {1 Q0 [8 D* X5 l
4 ]2 H: G; T. K
+ s4 V# O' m5 w4 S4 hCloss EI, Albritton LM, Kim JW, and Cunningham JM. Identification of a low affinity, high capacity transporter of cationic amino acids in mouse liver. J Biol Chem 268: 7538-7544, 1993.: `( I, |$ _+ w+ {! ]9 B
: K: M/ H5 r$ {4 b9 \
( l- P u8 [' H, h. m
+ ~5 Z) [# H6 eCloss EI, Gräf P, Habermeier A, Cunningham JM, and Förstermann U. Human cationic amino acid transporters hCAT-1, hCAT-2A, and hCAT-2B: three related carriers with distinct transport properties. Biochemistry 36: 6462-6468, 1997.
/ D; v$ s* J& d9 x2 n7 y
2 _. z& Y! |3 Y( t: Z
: s0 ?" y* B5 I0 v3 v( F
. E" V; ^4 \6 z7 N4 JCloss EI, Scheld JS, Sharafi M, and Förstermann U. Substrate supply for nitric oxide synthase in macrophages and endothelial cells: role of cationic amino acid transporters. Mol Pharmacol 57: 68-74, 2000.
; e/ h J& w) \: P. j/ L2 Q( \% h4 j2 ?- U1 L2 O: _0 o! \
& d9 b8 R2 T6 N
. }$ k" w( \# }5 P- K! s+ ^Cooke JP, Andon NA, Girerd XJ, Hirsch AT, and Creager MA. Arginine restores cholinergic relaxation of hypercholesterolemic rabbit thoracic aorta. Circulation 83: 1057-1062, 1991.
8 z# L. R3 Z4 i" r5 R
H2 H5 }" B, ?3 i$ N8 L7 N1 X' z9 I9 @8 x
7 S( F- b4 O* W; G' \5 o/ {5 EDeng X, Welch WJ, and Wilcox CS. Renal vasodilation with L -arginine. Effects of dietary salt. Hypertension 26: 256-262, 1995.
* y6 z% X0 a* g. v J" G
* j0 |+ ^( ~# l
/ Z# G! n |# [( ~. A
0 x5 Y, ]; `, B& X( bDevés R and Boyd CAR. Transporters for cationic amino acids in animal cells: discovery, structure, and function. Physiol Rev 78: 487-545, 1998.
, J- I) s0 J0 ?- `, I* G! u0 a, x/ Z: G: k3 n
" c0 v6 l3 U3 ?" S# n7 _
# R& ^/ Q! \4 FEdgell CJ, McDonald CC, and Graham JB. Permanent cell line expressing human factor VIII-related antigen established by hybridization. Proc Natl Acad Sci USA 80: 3734-3737, 1983.
6 V; T3 c$ T, I$ d
1 ~+ F4 ~* p0 s) V: b. D+ i: Z' @ w& r, Y' T6 \0 P
- `) F+ O( T# n" f3 X, t0 H. @
Elbashir SM, Harborth J, Lendeckel W, Yalcin A, Weber K, and Tuschl T. Duplexes of 21-nucleotide RNAs mediate RNA interference in cultured mammalian cells. Nature 411: 494-498, 2001./ N" {. V& _7 x, V9 O- _/ |" C
4 {3 z4 R7 y; l8 b, B0 ~( ]% L5 R; {, @. ^3 O# v
- y4 Y% m: C5 w7 _* J4 S6 v0 k7 Q9 Y
Gazzola GC, Dall'Asta V, Franchi-Gazzola R, and White MF. The cluster-tray method for rapid measurement of solute fluxes in adherent cultured cells. Anal Biochem 115: 368-374, 1981.9 S1 K5 J" K$ T# Y* _
8 _) R! e. b# M( J7 F$ \, v
. Y% ?/ z5 u" V8 f V: U3 \7 E$ ?
O3 w! }. k+ _% n2 iGräf P, Förstermann U, and Closs EI. The transport activity of the human cationic amino acid transporter hCAT-1 is downregulated by activation of protein kinase C. Br J Pharmacol 132: 1193-1200, 2001.4 a/ q: Z( U1 A* A1 D3 E: B
, N" ?" J4 N @! A( c: x6 m) C
5 Y0 [' C8 j# ~
! _4 g7 q* w9 _" R5 g: iGross KL, Hartman WJ, Ronnenberg A, and Prior RL. Arginine-deficient diets alter plasma and tissue amino acids in young and aged rats. J Nutr 121: 1591-1599, 1991.- }" Z% H- L/ r2 Z
) M. S D$ e# y3 K; a0 v5 T0 `7 f$ z6 D+ r5 u% o: u
# D# x, {7 b' @, r; W) @
Habermeier A, Wolf S, Martine U, Graf P, and Closs EI. Two amino acid residues determine the low substrate affinity of human cationic amino acid transporter-2A. J Biol Chem 278: 19492-19499, 2003.+ `0 A8 O# A4 R0 O# q, w
2 p, [, e; J+ h' \: \1 Z; D
|5 _' V( _0 b# i8 a
" l( |5 x1 P9 M1 @4 d' }- tHayakawa H, Hirata Y, Suzuki E, Kimura K, Kikuchi K, Nagano T, Hirobe M, and Omata M. Long-term administration of L -arginine improves nitric oxide release from kidney in deoxycorticosterone acetate-salt hypertensive rats. Hypertension 23: 752-756, 1994.% E& d0 R+ B$ F# ^4 v* q
* s# A& p; d$ v6 Z6 |; d6 M
* F4 u( N. K6 \, ^( l& m w( J
0 E4 J3 Q- Y! G& P2 GHu L and Manning RDJ. Role of nitric oxide in regulation of long-term pressure-natriuresis relationship in Dahl-rats. Am J Physiol Heart Circ Physiol 268: H2375-H2383, 1995.
- i% O; Z( s0 V5 F* e+ s6 W- J) n! K+ O! q! J; s9 F
6 u3 q- D# r+ z& M
1 b. X5 I' I7 ]9 {8 \
Kakoki M, Hirata Y, Hayakawa H, Tojo A, Nagata D, Suzuki E, Kimura K, Goto A, Kikuchi K, Nagano T, and Omata M. Effects of hypertension, diabetes mellitus, and hypercholesterolemia on endothelin type B receptor-mediated nitric oxide release from rat kidney. Circulation 99: 1242-1248, 1999.6 T4 J: l) d( [2 e6 O q) D
& B! m6 h# `5 |* i _/ I+ @; Z
; U0 `% ]# n6 t* v7 [1 q; l4 G7 [7 Q* G% w8 S' U i
Kakoki M, Kim HS, Arendshorst W, and Mattson DL. L -Arginine uptake affects nitric oxide production and blood flow in the renal medulla. Am J Physiol Regul Integr Comp Physiol 287: R1478-R1485, 2004.# }* R$ ] u9 Z! n7 r4 q$ Q
9 K* m m3 \7 \% }* Q
, N( m" w0 ?$ a# I! z2 _- u( s. l8 @$ b7 V0 t7 \0 Y
Kakoki M, Wang W, and Mattson DL. Cationic amino acid transport in the renal medulla and blood pressure regulation. Hypertension 39: 287-292, 2002.. ` U/ V. \8 w& t! V$ S
+ j8 A3 Y2 {: R; e* |$ P0 H! E0 M
; u! F% K( t; d, a; J1 k
3 e! P# ?% G! Q
Kamada Y, Nagaretani H, Tamura S, Ohama T, Maruyama T, Hiraoka H, Yamashita S, Yamada A, Kiso S, Inui Y, Ito N, Kayanoki Y, Kawata S, and Matsuzawa Y. Vascular endothelial dysfunction resulting from L -arginine deficiency in a patient with lysinuric protein intolerance. J Clin Invest 108: 717-724, 2001.
- j5 a4 j/ @* V0 M I1 ~/ z+ I6 K! w8 C& Y8 l& A2 [1 m
D6 [3 \' C. t: O$ ~9 U& s( i7 }( `1 |- f$ w
Kikuchi K, Nagano T, Hayakawa H, Hirata Y, and Hirobe M. Real time measurement of nitric oxide produced ex vivo by luminol-H 2 O 2 chemiluminescence method. J Biol Chem 268: 23106-23110, 1993.% C5 k. G/ [$ `( v0 U9 L
( v! h! _. |9 r2 i
7 Y2 H# D* [/ k9 T2 b9 t3 Q8 Y8 ^$ }, _' t3 T9 b; }9 A: j* x
Lekakis JP, Papathanassiou S, Papaioannou TG, Papamichael CM, Zakopoulos N, Kotsis V, Dagre AG, Stamatelopoulos K, Protogerou A, and Stamatelopoulos SF. Oral L -arginine improves endothelial dysfunction in patients with essential hypertension. Int J Cardiol 86: 317-323, 2002.
! ~. d% V$ n$ T8 X! T2 R& x$ [6 X! x7 f0 G6 ~- z, S n8 a
2 Y) u. g: P( j9 i. u. k
6 G6 V0 s [8 [: i' ~1 [4 w
Malandro MS and Kilberg MS. Molecular biology of mammalian amino acid transporters. Annu Rev Biochem 65: 305-336, 1996." c3 C, \) X4 A6 n- A: T
4 c ?# j; g1 \" l& Y _
8 ^; s3 x! E" f
+ b8 g s! l( Q) ?; o4 w5 AMcDonald KK, Zharikov S, Block ER, and Kilberg MS. A caveolar complex between the cationic amino acid transporter 1 and endothelial nitric oxide synthase may explain the "arginine paradox". J Biol Chem 272: 31213-31216, 1997.
# I; X! }/ `6 c3 n0 d+ k0 \& ~ S/ r6 |( N. H% |$ m2 p7 x4 @
" u# y F0 g! Q, l2 W
( Z0 F' Y- {% f! [# F# U) ]# U* ^8 GPatel A, Layne S, Watts D, and Kirchner KA. L -Arginine administration normalizes pressure natriuresis in hypertensive Dahl rats. Hypertension 22: 863-869, 1993.
- e6 g: N% b3 W6 I4 a
, D" @1 Z) \0 w# c* Q) f
0 Q1 x) s, l4 _4 G y5 b. {+ i9 o- ~- R
Patel AR, Granger JP, and Kirchner KA. L -Arginine improves transmission of perfusion pressure to the renal interstitium in Dahl salt-sensitive rats. Am J Physiol Regul Integr Comp Physiol 266: R1730-R1735, 1994.$ o: Z4 N" `# ]! q8 A/ U% F
* X+ _& f( k3 m" b- o
+ U5 G: `, @, Z4 r7 J* V
8 {8 q+ h% D9 n0 gPieper GM and Peltier BA. Amelioration by L -arginine of a dysfunctional arginine/nitric oxide pathway in diabetic endothelium. J Cardiovasc Pharmacol 25: 397-403, 1995.
, }/ Q7 E5 ?' K! S. \7 y
" G5 \% @3 d, a, g% ?5 x
8 l. N8 p Z4 n
9 N# A1 L4 {/ J- O. R! ^7 BPlato CF, Stoos BA, Wang D, and Garvin J. Endogenous nitric oxide inhibits chloride transport in the thick ascending limb. Am J Physiol Renal Physiol 276: F159-F163, 1999.
" e! w2 b9 }9 R" r! X4 [' S
4 `8 D7 [ D; [$ R0 r8 V9 Z7 D. x) w; ?
- A2 K8 K5 ~7 z2 G" b4 UPollock JS, Förstermann U, Mitchell JA, Warner TD, Schmidt HHHW, Nakane M, and Murad F. Purification and characterization of particulate endothelium-derived relaxing factor synthase from cultured and native bovine aortic endothelial cells. Proc Natl Acad Sci USA 87: 8612-8616, 1990.
* E3 f/ Z; A3 `" n4 u" O6 ^, D* j) K5 Z6 h f% J
( T H1 G% c' y# E8 m* A
& O9 h; U+ W4 L4 U$ L& k( j7 W7 J( E
Quyyumi AA, Dakak N, Diodati JG, Gilligan DM, Panza JA, and Cannon RO. Effect of L -arginine on human coronary endothelium-dependent and physiologic vasodilation. J Am Coll Cardiol 30: 1220-1227, 1997.
# H3 S& e; ^/ K0 S$ {
% R7 j5 J. l+ I# c# s* I, a* L
* X' g h- l& j0 b7 ]! V
% S) I+ T9 z2 ]& _Radermacher J, Klanke B, Kastner S, Haake G, Schurek HJ, Stolte HF, and Frolich JC. Effect of arginine depletion on glomerular and tubular kidney function: studies in isolated perfused rat kidneys. Am J Physiol Renal Fluid Electrolyte Physiol 261: F779-F786, 1991.
3 E9 M2 |, n7 r1 o5 T# L2 v5 {- l. ?- @8 s( S2 p- L+ J/ c) V/ e
5 v I5 D4 T9 E6 y9 }# A
8 U6 V1 n0 x1 p$ w% Z# F
Rossitch E Jr, Alexander E III, Black PM, and Cooke JP. L -Arginine normalizes endothelial function in cerebral vessels from hypercholesterolemic rabbits. J Clin Invest 87: 1295-1299, 1991.
$ s; X& ]% g& C* a2 d6 K5 x. Z6 T5 g, h. _4 \5 ~4 v
' t& I. f- @/ C- c
- G6 Q& ^) ^5 S, ]Sala R, Rotoli BM, Colla E, Visigalli R, Parolari A, Bussolati O, Gazzola GC, and Dall'asta V. Two-way arginine transport in human endothelial cells: TNF- stimulation is restricted to system y . Am J Physiol Cell Physiol 282: C134-C143, 2002.3 m. ^, Y$ H! M3 A
1 R% P& E! P) x6 P, M2 Z
* W5 a: h6 J/ @" T$ I
) T- r; W' N" G- `& \: PSessa WC, Hecker M, Mitchell JA, and Vane JR. The metabolism of L -arginine and its significance for the biosynthesis of endothelium-derived relaxing factor: L -glutamine inhibits the generation of L -arginine by cultured endothelial cells. Proc Natl Acad Sci USA 87: 8607-8611, 1990.
8 t9 U8 K$ r/ ?4 V3 |5 n
; O+ x3 O q) P- m
2 C& }. z" s, ~, }3 D( p# a2 ~4 S0 s8 S$ Q5 V1 u- j8 P
Simon A, Plies L, Habermeier A, Martiné U, Reining M, and Closs EI. Role of neutral amino acid transport and protein breakdown for substrate supply of nitric oxide synthase in human endothelial cells. Circ Res 93: 813-820, 2003.* A% ` k( S( o0 K: h, f2 M s
" {" u; l3 a6 r4 D! a/ c1 E0 {
4 z0 t0 C6 F7 C4 _" y2 A p
& H. R) s7 h* \Vallance P, Leone A, Calver A, Collier J, and Moncada S. Accumulation of an endogenous inhibitor of nitric oxide synthesis in chronic renal failure. Lancet 339: 572-575, 1992., m; J2 Z2 k4 o( S
\5 B- K8 O2 ^" |( x O; y; u5 g3 L
6 L* b; j/ v5 }& K9 P4 U- T6 QWelch WJ and Wilcox CS. Macula densa arginine delivery and uptake in the rat regulates glomerular capillary pressure. Effects of salt intake. J Clin Invest 100: 2235-2242, 1997.
# [7 S4 c; a+ j/ I; v9 R" j( ]* q% @1 W4 E% ]$ O+ B
" J5 j' B+ N6 U3 h
; l- F+ ]3 T2 V2 n" [6 b5 hWhite MF and Christensen HN. The two-way flux of cationic amino acids across the plasma membrane of mammalian cells is largely explained by a single transport system. J Biol Chem 257: 10069-10080, 1982.1 u, L' a0 Z8 c' C0 m X Y9 {; Y
: W9 s6 ~ V8 O' r* h
3 _( z8 Z4 w( n
6 R. `1 w, P/ g$ p2 H2 Q
Wu F, Cholewa BC, and Mattson DL. Characterization of L -arginine transporters in rat renal inner medullary collecting ducts. Am J Physiol Regul Integr Comp Physiol 278: R1506-R1512, 2000. |
|
发表于 2009-4-22 08:39
