|
- 积分
- 0
- 威望
- 0
- 包包
- 0
|
作者:Hongye Li and Edward P. Nord作者单位:Division of Nephrology, Department of Medicine, School of Medicine,State University of New York at Stony Brook, Stony Brook, New York 11794
- G0 o: z: f* g( }
5 F/ [" Y4 R3 ~' i0 O, z
0 w, w" F: }, l- z
6 j1 x8 S; H k9 ^1 y7 @ 9 N, K2 e6 y6 q8 R, x" v& D
0 C7 O" p% D, `! m
4 l. i5 k; \% k a" t3 K
- U! X6 z4 o" N8 K3 l
: M) e% J! K3 E+ y ) [% t$ I! f2 C
# t$ |- U. ~0 v- M
( C- q& H# M7 ^
! A0 |' ]1 Z* L) K 【摘要】
! ?* l% W; p1 |- t The role of caveolae in CD40/CD154 activation of proinflammatory chemokines and their potential role in renal inflammatory disease were explored in primary cultures of human renal proximal tubule epithelial cells. With the use of a cell fractionation assay, caveolin-1 (Cav-1), the defining structural protein of caveolae, was detected exclusively in the cell membrane (detergent insoluble) component of resting and CD40-activated cells. In the unstimulated condition, CD40 was associated with Cav-1, and with activation of the receptor by its cognate ligand CD154, CD40 disassociated from Cav-1. Other previously identified components of the CD40 signaling pathway, namely, SAPK/JNK, p38, and ERK1/2 MAPKs, but not tumor necrosis factor receptor-associated factor 6 (TRAF-6), were also present within caveolae and dissociated from this structure with ligation of the CD40 receptor. Disruption of caveolae with filipin diminished CD40-mediated MAPK activation and blunted downstream monocyte chemoattractant protein-1 (MCP-1) and IL-8 production. Similarly, dislodgment of signaling proteins from their scaffolding with a peptide targeted to the Cav-1 scaffolding domain (CSD) resulted in blunted MAPK activation and augmented IL-8 and MCP-1 production. In contrast, epidermal growth factor (EGF)-mediated tyrosine phosphorylation of the EGF receptor and activation of ERK1/2 were not interrupted by the peptide. We conclude that in human renal proximal tubule epithelial cells, CD40 and its downstream MAPK signaling proteins are located in membrane rafts and that disruption of caveolae or dislodgment of signaling proteins from the CSD diminishes MAPK activation and IL-8 and MCP-1 production in these cells. # p: h5 U4 q. e g
【关键词】 caveolin scaffolding domain mitogenactivated protein kinases monocyte chemoattractant protein interleukin interstitial inflammation0 |' [3 a. `1 B8 k: S/ ], M. L
RECENT WORK FROM this laboratory identified the CD40 receptor on primary cultures of human renal proximal tubule epithelial cells (PTCs) ( 10 ). Engagement of CD40 by CD154 stimulated monocyte chemoattractant protein-1 (MCP-1) and IL-8 production, which proceeded via receptor activation of the ERK1/2, SAPK/JNK, and MAPK pathways. An early event in this cascade was CD40 engagement of tumor necrosis factor receptor-associated factor 6 (TRAF6). With the use of immunocytochemistry, confocal microscopy, and a cell fractionation assay, CD40 and TRAF6 were shown to reside in separate low-density detergent-insoluble membrane microdomains, and with activation they translocated and associated with one another probably via zinc finger domains in the soluble or cytoplasmic compartment.$ J% U0 u3 R/ i1 Y( b
- e2 h- F" ^# D% t8 @- Y. y2 D5 h7 g& u
The outer leaflet of the plasma membrane contains specialized lipid microdomains or rafts that are principally composed of sphingolipids and cholesterol, rendering that segment of the outer leaf less fluid and thicker than the surrounding environment composed of glycerophospholipids ( 4 ). Similar rafts are thought to exist in the inner leaflet (cytosolic surface) of the plasma membrane but their lipid composition is largely unknown ( 23 ). Caveolae are a specialized form of lipid rafts that appear on both sides of the plasma membrane and appear as flask-shape invaginations of the plasma and are coated with caveolin, the defining protein component of caveolae membrane ( 4, 14, 18 ). Currently, three caveolin genes are known to exist; caveolin-1 (Cav-1) and caveolin-2 are ubiquitously expressed, whereas caveolin-3 appears to be muscle specific ( 16, 21 ).
- C: g8 s- G) F0 E. f3 ?
6 h: A) J8 t8 [) LBased on our earlier observation that the CD40 receptor resides in low-density detergent-insoluble membrane microdomains ( 10 ), we sought to explore whether caveolae are involved in CD40 signaling in human renal PTCs. In this study, we demonstrate that in the unstimulated condition CD40 and its key downstream signaling intermediates, SAPK/JNK, p38, and ERK1/2 MAPKs, are present in caveolae and dissociate from this structure with ligation of the receptor. Furthermore, disruption of caveolae, or dislodgment of signaling proteins from their scaffolding domain on Cav-1, diminishes CD40-mediated MAPK activity and blunts subsequent MCP-1 and IL-8 production.
- i0 [0 M9 |8 O( j% S$ J) E( z. |
+ v F1 q6 ]$ G% q0 }9 iMATERIALS AND METHODS: L% E8 K$ F% ^4 M$ t6 h
( A. Z& j$ m6 N1 R- `, n/ t" b
Cell culture. All experiments were carried out on primary cultures of human PTCs. Normal renal tissue was obtained from nephrectomy specimens during the course of cancer surgery ( 2 ), and verification of proximal tubule origin was performed as previously described ( 13 ). Cultures were maintained in a defined medium composed of 1:1 (vol/vol) mixture of DMEM and Ham's F-12 medium supplemented with insulin (5 µg/ml), transferrin (5.5 µg/ml), hydrocortisone (50 nM), triiodoithyronine (5 pM), and sodium selenate (10 nM), and to which 50 IU/ml penicillin and 50 µg/ml streptomycin were added. Cells were usually grown in 25-cm 2 tissue culture flasks but occasionally in 100-cm 2 tissue culture flasks (cell fractionation) or in 24-well plates (ELISA) and perpetuated in a humidified incubator at 37°C in 95% air-5% CO 2 (culture medium pH 7.3). Media were exchanged at 48- to 72-h intervals, and cells were propagated through passages 8 - 10.7 N' n8 D) b4 M- J7 C: W
. h- }, @- f9 l ]! a' aCell fractionation. In experiments where detergent-soluble and detergent-insoluble fractions were required, vehicle and CD154-stimulated cells [recombinant human soluble (rhs) CD154 100 ng/ml 1 µg/ml enhancer] were lysed in 1% Brij 58 (Pierce, Rockford, IL) for 5 min at 4°C as previously described ( 10 ). Lysates were centrifuged at 8,600 g (5 min, 4°C), and after the supernatants were collected, the insoluble pellets were resuspended and sonicated for 15 s in 100 µl of lysis solution that contained 0.5% SDS. The protein concentrations in the supernatants and in the insoluble pellets were detected by BCA Protein Assay Reagent. Equal aliquots of detergent-soluble and detergent-insoluble material were subjected to SDS-PAGE and immunoblotting as described below.
4 p9 B8 @; y+ C/ a0 ?" o2 L- V6 Y6 x" Q6 G) t
Immunoprecipitation and immunoblotting. Immunoprecipitation and Western blot analysis were performed using protocols previously described by this laboratory ( 1, 10 ). Unless otherwise stated, monolayers were challenged with rhs CD154 or vehicle (control) for the time periods indicated, washed extensively with PBS (4°C), and then lysed in a previously described buffer. After a 5-min incubation period in lysis buffer, samples were transferred to Eppendorf microcentrifuge tubes, and the insoluble material was removed by centrifugation. Samples were next exposed to the antibody of interest, which had been preincubated with protein A-Sepharose CL-4B beads swollen in 50 mM Tris (pH 7.0). Immunoprecipitation proceeded overnight at 4°C on a rocker. Immunoprecipitates were washed, suspended in sample buffer, and heated to 95°C for 5 min. Matched aliquots were subjected to SDS-PAGE in 10% gels, transferred to membranes, and blocked with 5% nonfat dry milk suspended in 143 mM NaCl, 0.1% Tween 20, and 20 mM Tris base (pH 7.6, room temperature, 1 h). Filters were probed with the antibody of interest (1:1,000, overnight at 4°C), washed three times with TBS containing 0.1% Tween 20, and subsequently incubated with peroxidase-linked goat anti-rabbit IgG in blocking buffer (1 h, room temperature). After additional washes (3 x ), antibody-bound proteins were detected using an enhanced chemiluminescence (ECL) system according to the manufacturer's instructions (Pierce), and membranes were exposed to Hyperfilm ECL (Amersham Pharmacia Biotech, Buckinghamshire, UK). Molecular weight markers were used to determine the size of the detected band. Where required, relative densities of the protein bands were determined with a GS-670 imaging densitometer and Molecular Analyst PC software program (Bio-Rad, Richmond, CA). Antibodies were obtained from commercial sources and are detailed in Materials.; F5 e o q- N9 F, x; x- N
- e+ p- ], ~3 p' o
Immunoblotting was performed as previously described ( 1 ). Briefly, following extensive washes with PBS (4°C), cells were lysed in 100 µl of SDS sample buffer ( 1 ), scraped, and the extract was transferred to a microcentrifuge tube for sonication (10-15 s) to reduce sample viscosity. Samples were heated to 95°C for 5 min, and matched aliquots were subjected to SDS-PAGE in 10% gels as described above. Immunoblotting was performed as outlined earlier., W8 i7 P6 u0 v4 z- m1 i7 y B
4 {( n" F/ g5 l* h" W/ w: @Immunocytochemistry and confocal microscopy. Immunocytochemical staining of cultured proximal tubule cells for CD40 and Cav-1 was carried out on 3.7% paraformaldehyde-fixed cells permeabilized with 0.1% Triton X-100 as previously described by this laboratory ( 1, 2, 10 ). Optimal dilutions of the first antibody, determined by checkerboard titration, were incubated with the monolayer at room temperature for 60 min followed by three rinses in buffered saline at 3-5°C. An Alexa Fluor-coupled secondary antibody was then applied for 30 min under identical conditions. Nonspecific binding of secondary antibody was determined by omitting the primary antibody (vehicle only) from the initial incubate. An irrelevant antibody ensured specificity. In double-labeled experiments, the rabbit anti-human anti-CD40 polyclonal primary antibody was detected by anti-rabbit IgG-labeled Alexa Fluor 594 (red), and the anti-Cav-1 monoclonal primary antibody was detected by anti-mouse IgG-labeled Alexa Flour 488 (green). Alexa Fluor 594 and Alexa Fluor 488 (Molecular Probes, Eugene, OR) were detected by fluorescent confocal microscopy (Bio-Rad Radrance 2000), using a Nikon Eclipre E800, 60 x 1.4 numerical aperture oil-immersion objective lens, the appropriate excitation wavelength, a dichroic mirror, and a barrier filter. Images were captured with a digital camera and stored for further processing and evaluation. All studies were blinded.7 Z# @. D5 T* Y9 a p$ X7 ^* h
8 [( Y7 s2 o: G# h
Detergent-free purification of caveolin-rich membrane fragments. Vehicle-treated or rhs CD154 (100 ng/ml 1 µg/ml enhancer, 10 min)-challenged monolayers were washed (2 x ) with ice-cold PBS, scraped, and suspended into 0.85 ml of 0.5 M sodium carbonate, pH 11.0 ( 20 ). Lysates from five 100-cm 2 tissue culture flasks were pooled for each experimental point. All subsequent steps were carried out at 4°C. Cell membranes were disrupted with a loose-fitting Dounce homogenizer (10 strokes) followed by three 10-s bursts with a Polytron tissue grinder and three 20-s bursts with a sonicator to further homogenize the samples. Homogenates were adjusted to 40% sucrose by adding an equal volume of 80% sucrose prepared in Mes-buffered saline (MBS; 25 mM Mes, pH 6.5, and 0.15 M NaCl) and placed on the bottom of an ultracentrifugation tube. A 5 to 35% discontinuous sucrose gradient was formed above the sample by using 1 ml of 5% sucrose and 1.3 ml of 35% sucrose, both in MBS containing 250 mM sodium carbonate. Ultracentrifugation proceeded for 18 h at 50,000 rpm using a model SW65 rotor (Beckman Instruments, Palo Alto, CA). For profiles, 0.3-ml fractions starting at the top of each gradient were collected to yield a total of 13 fractions. Twenty microliters of each fraction were dissolved in equal volumes of 2 x SDS sample buffer for Western blot analysis. In separate experiments, the light-scattering band confined to the 5 to 35% interface ( fractions 4 and 5 ), which contains caveolae but excludes most other cellular structures, was diluted threefold with MBS and centrifuged at 30,000 rpm for 1 h in the above mentioned rotor to pellet caveolae. The caveolae were then solubilized with SDS sample buffer and subjected to Western blot analysis as described.$ U3 R" V- u7 K; n6 x; K
) I: M' q, ~, V8 U2 W; `' I6 I+ |ELISA. MCP-1 and IL-8 production by proximal tubule cells were measured by the quantitative sandwich enzyme immunoassay technique according to the manufacturer's instructions (Quantikine, R&D Systems, Minneapolis, MN) and as previously reported by this laboratory ( 10 ). Proximal tubule cells were grown in 24-well culture plates and the experimental maneuver was performed by adding agonist/vehicle/inhibitor to the supernatant, which was assayed for chemokine production. Optical density of each microtiter plate was read at 450 nm on a Biomed microplate reader. Recombinant MCP-1 and IL-8 standards from 0 to 2,000 pg were used to generate standard curves. Quadruplicate determinations in three to four different series of experiments were performed. Data are presented as means ± SE as the index of dispersion. Analysis of variance was used to compare group means, and the null hypothesis was rejected when P $ j+ l' \$ ^& x( l3 | J
4 d. x/ J+ O: z& N/ N% W
Peptide synthesis and introduction into cells. A peptide corresponding to the scaffolding domain of Cav-1 (amino acids 82-101: DGIWKASFTTFTVTKYWFYR; accession number: Q03135 ) was synthesized as a fusion peptide to the COOH terminus of the Drosophila antennapedia homeodomain-derived carrier peptide (RQIKIWFQNRRMKWKK) (purification 95%) by Biosynthesis (Lewisville, TX). Biotin was linked to the peptide through an aminohexanoic acid spacer at the NH 2 terminus. Confluent monolayers grown on 25-cm 2 tissue culture flasks or 24-well plates were incubated with 1, 10, or 100 µM Cav-1 peptide for 6 h before stimulation with vehicle, CD154 (100 ng/ml 1 µg/ml enhancer), or epidermal growth factor (EGF; 100 ng/ml, 10 min). Lysates were subjected to SDS-PAGE and immunoblotted with the phospho or nonphospho antibody as described. MCP-1 and IL-8 production were measured by ELISA. To validate internalization of the peptide by proximal tubule cells, monolayers grown on glass coverslips were incubated with 1, 10, or 100 µM Cav-1 peptide for 6 h. Cell fixation and permeabilization proceeded as described in Immunocytochemistry and confocal microscopy. Cells were subsequently incubated with streptavidin-fluorescein following blocking by 10% goat serum in PBS. Internalization of the peptide was detected by fluorescent microscopy.& g0 j, Q( F7 J) f+ @& x
% t( r s( J+ ~. ^8 }5 r
Materials. DMEM, Ham's F-12 medium, RPMI 1640, and the penicillin-streptomycin solution were purchased from GIBCO Laboratories (Grand Island, NY) and newborn calf serum was from Sigma (St. Louis, MO). Rabbit anti-human CD40 polyclonal antibody, mouse anti-human TRAF6 monoclonal antibody, rabbit anti-human TRAF6 polyclonal antibody, mouse anti-human TRAF2 monoclonal antibody, rabbit anti-human TRAF2 polyclonal antibody, rabbit anti-human Cav-1 polyclonal antibody, and goat anti-human phospho-EGF receptor polyclonal antibody were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Mouse anti-human Cav-1 monoclonal antibody was purchased from BD Transduction Laboratories (San Diego, CA). Rabbit anti-p44/42 MAP kinase and phospho-p44/42 MAP kinase antibody, rabbit anti-SAPK/JNK and rabbit anti-phospho-SAPK/JNK antibody, rabbit anti-p38-MAP kinase and phospho-p38-MAP kinase antibody were purchased from Cell Signaling Technology (Beverly, MA). rhs CD40 ligand or CD154 and enhancer (an antibody that binds CD154 trimers and has the effect of multimerizing the CD40 receptor) were purchased from Alexis (San Diego, CA). Filipin was purchased from Sigma. Electrophoretic grade reagents used for SDS-PAGE were obtained from Bio-Rad Laboratories (Melville, NY). All standard chemicals used were purchased at the highest commercial grade available.
* ^3 R# _5 k/ H1 ?3 q! r3 Z& x& u- |
RESULTS; L! Y1 { T6 n
, y& B1 D, n9 R7 ~0 s/ Z
Expression of Cav-1 by human proximal tubule cells. Cav-1 expression by primary cultures of human proximal tubule cells was first examined in detergent-soluble and detergent-insoluble cell fractions using Western blot analysis. It was deemed important to take the approach of cell fractions because we recently demonstrated that the activated CD40 receptor translocates from the cell membrane (detergent insoluble) to the cytosolic compartment (detergent soluble) ( 10 ). Accordingly, quiescent monolayers were either treated with vehicle or challenged with rhs CD154 (100 ng/ml 1 µg/ml enhancer) for 5 or 10 min as indicated ( Fig. 1 ) and then lysed with a buffer that contained 1% Brij 58 as detailed under MATERIALS AND METHODS. The insoluble pellet was dissolved in 0.5% SDS and then subjected to SDS-PAGE/Western blot analysis using the anti-Cav-1 antibody. The soluble pellet was analyzed independently by SDS-PAGE/Western blot analysis. As depicted in Fig. 1, all the Cav-1 was present in the detergent-insoluble fraction both in unstimulated and stimulated cells. In parallel experiments, immunocytochemical staining of intact monolayers detected Cav-1 primarily in the cell membrane of unchallenged cells ( Fig. 2 B, left ), and the membrane-staining pattern persisted through 7 min of CD154 stimulation. Taken together, these observations suggest that Cav-1 is present in a component of the cell membrane of both stimulated and unstimulated proximal tubule cells.) `( u- m, O9 C
' M- B$ b, B! K. |3 b
Fig. 1. Subcellular localization of caveolin-1 (Cav-1) in human proximal tubule cells. Western blot of detergent-insoluble and detergent-soluble (Brij 58) fractions of Cav-1 in control (0 min) and recombinant human soluble (rhs) CD154 (100 ng/ml 1 µg/ml enhancer)-treated cells (5 and 10 min). One of 3 similar experiments is shown./ @+ g: a9 H0 T
# g( i- f" _2 c; g3 H& b6 i: k: Q
Fig. 2. Association between CD40 and Cav-1 in human proximal tubule cells. A : coimmunoprecipitation of CD40 and Cav-1 ( top ) and Cav-1 and tumor necrosis factor receptor-activated factor 6 (TRAF6) ( bottom ). Monolayers were either challenged with rhs CD154 (100 ng/ml 1 µg/ml enhancer) for 5 or 10 min as indicated or left untreated (0 min). Lysates were subjected to immunoprecipitation (IP) using the anti-CD40 or anti-Cav-1 antibody as shown, and following SDS-PAGE they were immunoblotted (IB) with either the anti-Cav-1 or TRAF6 antibody as delineated. B : confocal photomicrographs of rhs CD154-challenged cells. Cells were examined before (baseline) and 2 and 7 min after challenge with rhs CD154 (100 ng/ml 1 µg/ml enhancer). The rabbit anti-human anti-CD40 polyclonal primary antibody was tagged by an anti-rabbit IgG-labeled Alexa Fluor 594 (red) and the anti-Cav-1 monoclonal primary antibody was tagged by an anti-mouse IgG-labeled Alexa Fluor 488 (green). Colocalization (overlay) is shown in yellow. One of 3 to 4 similar experiments is shown.
4 G- [" u' r: r9 c& K7 s2 @. T7 X: I& Y' t
Association between CD40 and Cav-1 in human proximal tubule cells. An early event in CD40 signaling is engagement by the cytoplasmic domain of the receptor of TRAF proteins ( 7, 9, 10, 15 ). We recently demonstrated that CD40 and TRAF6 reside in separate detergent-insoluble membrane microdomains, or rafts, and on activation of CD40 by its cognate ligand, the two proteins associate with one another probably via zinc finger domains in the soluble or cytoplasmic compartment ( 10 ). To explore whether Cav-1 is involved in CD40 signaling in human proximal tubule cells, coimmunoprecipitation experiments were performed where CD40 immunoprecipitates were subjected to Western blot analysis with an anti-Cav-1 antibody under unstimulated and rhs CD154-activated (100 ng/ml 1 µg/ml enhancer) conditions. The results are depicted in Fig. 2 A. In the unstimulated condition, CD40 coimmunoprecipitated with Cav-1, but at 5 and 10 min following CD154 stimulation, Cav-1 could barely be detected in CD40 immunoprecipitates. In contrast, Cav-1 coimmunoprecipitated weakly with TRAF6 in the unstimulated state, but the association between Cav-1 and TRAF6 was enhanced as a function of time following CD154 stimulation. These data suggest that under resting conditions CD40 is located within caveolae, and with activation the receptor rapidly dissociates from the scaffold protein, Cav-1. Cav-1, in turn, associates more strongly with TRAF6 following CD40 activation. The consequences of these interactions will be analyzed in further detail.
+ ~7 P, p7 w: d2 Q5 @: B" k8 v+ ~, x
In parallel experiments, quiescent monolayers were incubated with rhs CD154 (100 ng/ml 1 µg/ml enhancer) for the time periods detailed in Fig. 2 B, and the Alexa Fluor-tagged Cav-1 and CD40 antibodies were tracked by confocal microscopy. As indicated earlier, under unstimulated (baseline) conditions the anti-Cav-1 antibody tagged by Alexa Fluor 488 (green) was localized primarily to the cell membrane and cytoplasm immediately adjacent to the cell membrane, and the anti-CD40 antibody tagged by Alexa Fluor 594 (red) was localized primarily to the cell membrane as previously reported by this laboratory ( 10 ). Colocalization of these two proteins as depicted in the overlay photomicrograph (colocalization in yellow) is evident in the unstimulated or baseline condition. In rhs CD154-stimulated cells (2 min), the anti-Cav-1-tagged Alexa Fluor 488 (green) antibody could still be detected in the cell membrane with some cytosolic distribution. This pattern persisted through 7 min with increased nonspecific localization to the cell nucleus. The anti-CD40-tagged Alexa Fluor 594 (red) antibody was less evident in the cell membrane and distributed throughout the cell as previously reported ( 10 ). Of greater significance is the observation that at 2 min poststimulation, colocalization (yellow) of these two proteins markedly diminished and could barely be detected at 7 min ( Fig. 2 B, right ), in keeping with the coimmunoprecipitation experiments described above. These observations argue that in unstimulated human proximal tubule cells, the CD40 receptor is configured in caveolae.
& j2 T+ }! f7 Y+ c* L7 Z
+ Y6 H3 R$ {: i3 c$ {, SEvaluation of the role of Cav-1 in CD40 signaling in human proximal tubule cells. To explore whether caveolae form a scaffolding for components of the CD40 signal transduction pathways previously described in proximal tubule cells ( 10 ), we examined the subcellular localization of Cav-1, a major structural protein in caveolae, in further detail, using the sucrose gradient method ( 20 ). Equal aliquots from each of 13 sucrose gradients were subjected to SDS-PAGE/Western blot analysis using the anti-Cav-1 antibody described above. In the unstimulated condition, Cav-1 was detected in fractions 4 and 5 and 8 - 13 ( Fig. 3, top row ). After rhs CD154 treatment (100 ng/ml 1 µg/ml enhancer, 10 min), increased amounts of Cav-1 were detected in fractions 4 and 5 and also appeared in fractions 6 and 7 ( Fig. 3, second row ). Differences in Cav-1 content of fractions 8 - 13 were difficult to quantify because of the large amount of Cav-1 detected in these fractions. The key observations are 1 ) that Cav-1 was detected in the lower-density fractions ( 4 and 5 ) as described by others ( 20 ), and 2 ) that following activation of CD40 by its cognate ligand, increased amounts of Cav-1 were detected in fractions 4 and 5. These findings are indicative of the presence of Cav-1 in lipid-associated membrane fragments ( 4 and 5 ), a characteristic feature of caveolae ( 20 ).3 z3 j$ s! V! n4 l9 {5 ~
) b; G" @% P; m4 ]' bFig. 3. Subcellular localization of Cav-1 and CD40 in fractions from human proximal tubule cells. Vehicle (CD154 -) or rhs CD154 (100 ng/ml 1 µg/ml enhancer, 10 min)-challenged monolayers (CD154 ) were disrupted and applied to a discontinuous sucrose gradient as described in MATERIALS AND METHODS. Equal aliquots from each of 13 sucrose gradient fractions were separated by SDS-PAGE followed by immunoblotting with either an anti-Cav-1 or anti-CD40 antibody, as indicated. One of 4 similar experiments is shown.
8 T' \& z0 b) Y# r) J6 e# U8 T& |, m* U1 M. e
If CD40 and Cav-1 are associated in the resting condition and then dissociate from one another following ligation of the receptor, it should be feasible to recapitulate these observations using the sucrose gradient approach. Accordingly, the above-described blots were stripped and reprobed with an anti-CD40 antibody. In the unstimulated condition, CD40 was detected in fractions 3 through 13 with the major bands detected in fractions 3 - 5 ( Fig. 3, third row ). After rhs CD154 treatment (100 ng/ml 1 µg/ml enhancer, 10 min), most of the CD40 protein was detected in fractions 12 and 13, with marked reduction in the amount of protein observed in fractions 3 - 5 and 9 - 12, with virtual disappearance from fractions 6 - 8 ( Fig. 3, bottom row ). These observations are in keeping with the concept that the CD40 receptor is configured in caveolae in unstimulated proximal tubule cells and dissociates from this structure with ligation.
6 z5 N0 R% S4 I. M; Y
4 {$ ?* X! w8 g2 k7 PTo examine whether other components of the CD40 signaling pathway previously identified by this laboratory are also present in the lipid-associated membrane fragments, fragments 4 and 5 of the cell fractionation assay described above were pooled and subjected to SDS-PAGE/Western blot analysis using different specific antibodies. As expected, rhs CD154 stimulation (100 ng/ml 1 µg/ml enhancer, 10 min) increased Cav-1 abundance in the delineated fractions ( Fig. 4 A ). TRAF6 could not be detected in these cell fractions under both unstimulated and stimulated conditions ( Fig. 4 A ). TRAF2 abundance, on the other hand, decreased following CD154 stimulation ( Fig. 4 A ). Under identical experimental conditions, SAPK/JNK, p38, and ERK1/2 MAPK abundance decreased somewhat in the lipid-associated membrane fragments following CD40 ligation ( Fig. 4 B ). In the aggregate, these data argue that in addition to CD40, TRAF2 (but not TRAF6), SAPK/JNK, p38, and ERK1/2 MAPK are all present in caveolae in the unstimulated condition in this cell type. As described previously, TRAF6 resides in a different cell fraction ( 10 ).7 C9 F1 K8 j2 o$ S! h1 J: m" C
8 b0 c# Q+ |* L
Fig. 4. Detection of components of the CD40 signaling pathway in lipid-associated membrane fragments. Pooled aliquots from fragments 4 and 5 of the sucrose gradient depicted in Fig. 3 from vehicle (-) or rhs CD154 (100 ng/ml 1 µg/ml enhancer, 10 min)-challenged monolayers were subjected to SDS-PAGE followed by immunoblotting. Antibodies directed against Cav-1, TRAF2, TRAF6, SAPK/JNK, p38, and ERK1/2 were used as indicated. One of 4 similar experiments is shown.
& t, G& R" _; P$ P/ [2 j. a& P3 T$ Y8 c
Functional relevance of caveolae in CD40-associated signaling in human proximal tubule cells. If the association of Cav-1 with CD40 has functional relevance with regard to MAPK activation, then disruption of caveolae should blunt or diminish CD40-mediated SAPK/JNK, p38, and ERK1/2 MAPK activation. A number of different compounds have been used to disrupt caveolae, of which filipin is possibly the most widely used ( 17 ). Accordingly, monolayers were challenged with rhs CD154 (100 ng/ml 1 µg/ml enhancer, 10 min) and MAPK activity was monitored using the appropriate phospho-activated antibody ( Fig. 5 A ). As previously reported ( 10 ), CD40 ligation stimulates SAPK/JNK, p38, and ERK1/2 MAPK activity in this cell type ( lane 1 vs. 2 ). Filipin (5 µg/ml, 90 min) had no effect on baseline MAPK activity ( lane 3 ). Filipin totally blocked CD40-mediated SAPK/JNK activity and blunted p38 and to a lesser extent ERK1/2 activity ( lane 4 ). A non-phospho-p38 immunoblot is included as a control, which shows that equal quantities of protein were loaded per lane and that the effect of filipin was specific. Because CD40-mediated MCP-1 and IL-8 production are downstream events of MAPK activation in this cell type ( 10 ), disruption of caveolae should also blunt or diminish CD40-mediated chemokine production. CD40 ligation (rhs CD154 100 ng/ml 1 µg/ml enhancer, 24 h) stimulated MCP-1 production from a baseline value of 8,814 ± 239 to 17,689 ± 360 pg/ml ( n = 3, P
- P7 m, A. ?3 d7 T5 E) L( r" R) e( i' T V6 w1 d
Fig. 5. Inhibition of CD40-evoked SAPK/JNK, p38, and ERK1/2 activation, and monocyte chemoattractant protein-1 (MCP-1) and IL-8 production by filipin. Monolayers were incubated with vehicle or filipin (5 µg/ml, 90 min) as indicated, before challenge with vehicle or ligand (rhs CD154 100 ng/ml 1 µg/ml enhancer). A : cell lysates were subjected to SDS-PAGE and immunoblotted with the phospho or nonphospho antibody as shown. B : MCP-1 measured by ELISA. C : IL-8 production measured by ELISA. One of 3 similar experiments for each assay is shown.
- h+ v% G9 v9 C0 W2 F- Z# O7 ^7 q" s, l( m) Q
In a second approach, a peptide corresponding to the scaffolding domain of Cav-1 (fused to a carrier peptide) was introduced into cells as detailed in MATERIALS AND METHODS. We rationalized that the peptide would dislodge the relevant signaling proteins from caveolae and thereby disrupt their function. Accordingly, monolayers were incubated with vehicle or different concentrations of peptide (1, 10, and 100 µM) for 6 h and subsequently challenged with vehicle or rhs CD154 (100 ng/ml 1 µg/ml enhancer) for 30 min. Figure 6 A confirms that the peptide is indeed internalized by the monolayer with fluorescein visualized in 80-90% of cells. MAPK activity was monitored using the appropriate phospho-activated antibody ( Fig. 6 B ). A non-phospho-p38 immunoblot is included as a control, which shows that equal quantities of protein were loaded per lane and that the effect of the peptide was specific. As previously demonstrated, CD40 ligation stimulates SAPK/JNK, p38, and ERK1/2 MAPK activity ( lane 1 vs. 2 ), and 10 µM Cav-1 peptide has little effect on baseline MAPK activity ( lane 3 ). One hundred-micromolar Cav-1 peptide totally abrogated CD40-mediated SAPK/JNK activity and blunted p38 and to a lesser extent ERK1/2 activity ( lane 6 ). One-micromolar Cav-1 peptide was essentially without effect ( lane 5 ), whereas 10 µM Cav-1 peptide had a somewhat intermediary effect ( lane 4 ). MCP-1 ( Fig. 6 C ) and IL-8 ( Fig. 6 D ) production were measured under similar experimental conditions. CD40 ligation (rhs CD154 100 ng/ml 1 µg/ml enhancer, 24 h) stimulated MCP-1 production from a baseline value of 8,098 ± 107 to 16,286 ± 380 pg/ml ( n = 3, P
5 \, K0 j+ I1 p8 E8 B9 _* g
, k' e; ^' M" N' b% f; O/ ]Fig. 6. Peptide (pep) targeting of Cav-1. Confluent monolayers were incubated for 6 h with vehicle or 1, 10, or 100 µM peptide corresponding to the scaffolding domain of Cav-1 detailed in MATERIALS AND METHODS. Monolayers were subsequently challenged with vehicle or rhs CD154 (100 ng/ml 1 µg/ml enhancer). A : photomicrograph of internalized Cav-1 peptide (10 µM) detected with streptavodin-fluorescein as detailed in MATERIALS AND METHODS. B : cell lysates were subjected to SDS-PAGE and immunoblotted with the phospho or nonphospho antibody as indicated. C : MCP-1 measured by ELISA. D : IL-8 production measured by ELISA. One of 3 similar experiments for each assay is shown.
3 a1 X* g2 _% n/ l# M4 u0 n0 w6 F3 C) }! X# l9 r9 b+ G: v$ k
Specificity of peptide targeting of Cav-1. To ensure that the introduced peptide did not disrupt cell function in a nonspecific manner, EGF receptor (EGFR) tyrosine phosphorylation by EGF was examined in parallel experiments. The results are shown in Fig. 7 A. EGF (100 ng/ml, 10 min) markedly increased EGFR tyrosine phosphorylation ( lane 1 vs. 2 ), and Cav-1 peptide (1, 10, and 100 µM for 6 h) had no effect on this response. A non-phospho-p38 immunoblot is included as control, which confirms that equal quantities of protein were loaded per lane. Furthermore, EGF-mediated ERK1/2 activation was not blunted by the presence of the peptide ( Fig. 7 B ). These data provide specificity to the effect of the peptide on CD40-mediated MAPK signaling (see DISCUSSION ) and negate any nonspecific effect that peptide introduction might have on cell function.! M! ^/ F7 x& r% @1 h' e* t
0 h* c( h) _5 j0 R% [8 JFig. 7. Specificity of effect of peptide targeting of Cav-1. Confluent monolayers were incubated for 6 h with vehicle or 1, 10, or 100 µM peptide corresponding to the scaffolding domain of Cav-1 detailed in MATERIALS AND METHODS. Monolayers were subsequently challenged with vehicle or epidermal growth factor (EGF; 100 ng/ml, 10 min). Cell lysates were subjected to SDS-PAGE and immunoblotted with an anti-phospho-EGF receptor antibody ( A ) or an anti-phospho-ERK1/2 antibody ( B ). p38 Immunoblots were included as a control. One of 3 similar experiments for each condition is shown.
- z: F( P0 N" k/ I, q5 D# s
. ?; p7 a, y C* |DISCUSSION
" x1 | J* w9 _+ v6 m4 Q: t' F
! w7 V4 t K9 ]: g& vThe results presented demonstrate that Cav-1 can be detected exclusively in the cell membrane (detergent insoluble) component of resting and CD40-activated human proximal tubule cells ( Fig. 1 ) and that under unstimulated conditions CD40 is located within caveolae (Figs. 2, 3, 4 ). With stimulation by its cognate ligand CD154, CD40 dissociates from Cav-1 (Figs. 2 and 3 ). In addition, CD40, together with other key components of the CD40 signaling pathway (SAPK/JNK, p38, ERK1/2) but not TRAF6, is present in caveolae ( Fig. 4 ). Disruption of caveolae by filipin ( Fig. 5 ) or dislodgment of signaling proteins from their scaffolding ( Fig. 6 ) results in diminished CD40-mediated MAPK activation and MCP-1 and IL-8 production, arguing that there is functional relevance to intact caveolae with regard to CD40-associated downstream events. Finally, dislodgment of CD40-mediated signaling proteins from their scaffolding is specific because EGF-mediated EGFR phosphorylation and ERK1/2 activation proceed uninterrupted in the presence of the peptide ( Fig. 7 ).6 K7 V; M- ^8 \, v
8 ^+ [5 ]" ]% u3 QThe detection of Cav-1 in lipid-associated low-density membrane fragments is indicative of the presence of caveolae ( 20 ). With the use of the sucrose gradient approach described earlier, Cav-1 was detected in fractions 4 and 5 in the unstimulated condition with increased amounts detected following CD40 ligation ( Fig. 3 ). Interestingly, Cav-1 was also detected in large amounts in high-density lipid-insoluble fragments under both conditions. This observation indicates that human PTCs possess large amounts of Cav-1 and that not all Cav-1 is associated with lipid-rich microdomains or rafts. The relevance of this observation will require further work in the future.
4 ?1 |8 R) `: W
& H5 ?! w. ^5 RTo the best of our knowledge, this is the first report demonstrating involvement of caveolae in CD40 signaling in human renal epithelial cells. Indeed, there is a paucity of and somewhat conflicting data implicating lipid rafts in CD40 signaling in other cell types. For example, membrane rafts have been shown to play an integral role in the proximal events of CD40 signaling in human monocyte-derived dendritic cells ( 24 ). On the other hand, CD40 is excluded from the lipid rafts of both mature and immature B cells ( 11 ). Of much interest is a recent publication implicating the transmembranous domain of the CD40 receptor as being crucial both for clustering into lipid rafts and effective CD40 signaling ( 3 ). Because CD45 is known to be excluded from lipid rafts, the investigators constructed a CD40/CD45 chimera. Normal ligand binding was confirmed by flow cytometry. Chimeric CD40/CD45 receptors transfected into T cells failed to cluster and were unable to activate MAPK signaling pathways in contradistinction to the wild-type CD40 receptor. Implicit in this observation, although not stated, is that caveolae were involved. Our approach differed somewhat in that we introduced a peptide corresponding to the scaffolding domain of Cav-1 ( 5, 14 ) known to recognize a diverse group of signal transducer and demonstrate that MAPK activation and downstream IL-8 and MCP-1 production were either obviated or blunted ( Fig. 6 ). Based on these observations, it seems reasonable to conclude that lipid rafts of the caveolae variety are a prerequisite for normal CD40 signaling in human PTCs." q( e W) Z6 ^) f5 u6 g+ [
. G# Q2 w; M( w- x* a' o- ?It might be argued that introduction of the peptide targeting the scaffolding domain of Cav-1 may have a nonspecific effect on cell function. Several lines of evidence would suggest that this indeed is not the case. First, identical amounts of p38 MAPK were detected in all specimens (Figs. 6 B and 7 ). Second, MAPK activities were blunted in a concentration-dependent manner ( Fig. 6 B ). Third, EGF-mediated tyrosine phosphorylation of the EGFR and ERK1/2 proceeded independent of the concentration of peptide introduced into the cell ( Fig. 7, A and B ). In this regard, it has been demonstrated that the EGFR is localized within caveolae along with its downstream signaling molecules ( 5, 12, 19 ). Interestingly, in mesangial cells, endothelin-1 (ET-1)-mediated ERK1/2 transactivation via the EGFR was disrupted by cholesterol depletion using filipin and -cyclodextrin yet EGF-mediated tyrosine phosphorylation of the EGFR was not impacted ( 8 ). In addition, the peptide targeting the Cav-1 scaffolding domain diminished ET-1 transactivation of ERK1/2. EGF-induced tyrosine phosphorylation of the EGFR in this setting was not reported. Along similar lines, in vascular smooth muscle cells, cholesterol depletion significantly inhibited ANG II-mediated EGFR tyrosine phosphorylation and protein kinase B (PKB)/Akt transactivation via the EGFR, yet the identical maneuver had no impact on EGF-mediated EGFR tyrosine phosphorylation and PKB/Akt transactivation, leading the authors to conclude that transactivated EGFRs localize in focal adhesions ( 22 ). Whether EGFRs are located in focal adhesions in PTCs is currently not known, but it was beyond the scope of this investigation.
+ ]2 T2 z; ^1 l) j8 T; \" a2 c4 H, `- ^
Although key CD40 signaling proteins including SAPK/JNK, p38, and ERK1/2 MAPK appear to be present in caveolae in this cell type and dissociate from this structure with ligation of the receptor ( Fig. 4 ), TRAF6 does not appear to be present in this membrane component in both the unchallenged and CD40-stimulated condition. As a control, we examined another protein of this group, namely, TRAF2, which has been shown by others to be involved in CD40 signaling ( 6, 15 ). Similar to the signaling proteins detailed above, and unlike TRAF6, TRAF2 was detected in unchallenged cells in the membrane fragments containing caveolae and dissociated from this fragment with ligation of the receptor ( Fig. 4 ). We have not yet examined in further detail the consequence of CD40 engagement of TRAF2 in human proximal tubule cells. However, the observation that TRAF6 could not be identified in the cell fraction containing caveolae, yet is a necessary prerequisite for the activation of SAPK/JNK and p38 MAPK in this cell model ( 10 ), is in keeping with our previous observation, namely, that CD40 and TRAF6 reside in separate membrane microdomains and on activation translocate and associate with one another in the cytoplasmic compartment ( 10 ).
p0 |5 K( U" A( Y
- \& Y: W" ^; w1 J7 ~" wFigure 8 is a proposed schema for the involvement of caveolae in CD40 signaling in human renal PTCs and summarizes our observations in this regard. CD40 together with SAPK/JNK, p38, and ERK1/2 MAPKs are anchored to Cav-1 in the unstimulated condition. TRAF6 is not located in caveolae but as previously shown ( 10 ) resides in a separate membrane microdomain. With ligation of the receptor, CD40 engages TRAF6. SAPK/JNK, p38, and ERK1/2 MAPKs dissociate from Cav-1. TRAF6 stimulates SAPK/JNK and p38 MAPK activities but is not involved in ERK1/2 MAPK activation (previously shown in Ref. 10 ). Cav-1 and TRAF6 associate with one another, presumably for recycling to their respective membrane microdomains.* z: ]9 Y* y$ `, R. E5 v
" f7 k' G+ T. s
Fig. 8. Schema of proposed involvement of caveolae in CD40 signaling in human renal proximal tubule epithelial cells. In the unstimulated condition, CD40, SAPK/JNK, p38, and ERK1/2 are anchored to Cav-1. TRAF6 resides in a separate membrane domain. With ligation, CD40 engages TRAF6, whereas SAPK/JNK, p38, and ERK1/2 dissociate from Cav-1. Simultaneously, TRAF6 associates with Cav-1 presumably to facilitate recycling into their respective membrane microdomains. SAPK/JNK and p38 are activated by TRAF6, whereas ERK1/2 activation occurs independently of TRAF6 ( 10 ).3 w6 P6 f" d* o/ g) V
) y/ P# O' l, A
ACKNOWLEDGMENTS: V+ c) i( E. o( A" U
$ j* L o& l/ s6 L- dThe expert secretarial assistance of S. Krulik is gratefully acknowledged.3 m2 \# f) d: M) |1 F" C
+ k- \ x: a: _ ]
GRANTS) g) u$ v( L. o6 ~- ~" a
+ c0 Q; v6 b) h- i3 v3 |) G' pThis study was supported by a grant from the Paul Teschan Research Fund (Dialysis Clinics).
2 f1 t- i$ ^' j% [ C9 x$ t4 c# c8 Y 【参考文献】+ a* c& _7 g: S5 q, W
Barnett RL, Ruffini L, Hart D, and Nord EP. Mechanism of endothelin activation of phospholipase A 2 in rat renal medullary interstitial cells. Am J Physiol Renal Fluid Electrolyte Physiol 266: F46-F56, 1994.. ~" T$ `6 M" B i& c/ l* f; \
; f& x: {2 f' [2 o4 k+ K0 H; I2 Y( a% `& u
/ z0 Q, E$ _$ B# _. {! R. }8 k8 f- n
Becker JL, Miller F, Nuovo GJ, Josepovitz C, Schubach W, and Nord EP. Epstein-Barr virus infection of renal proximal tubule cells: possible role in chronic interstitial nephritis. J Clin Invest 104: 1673-1681, 1999.
3 d& ?8 i+ ~8 ^: D5 Z! N& P+ V0 K& j; _5 e3 k
& g4 L L2 t* \* y
% P1 p, [. N: F2 O8 B B% aBock J and Gulbins E. The transmembranous domain of CD40 determines CD40 partitioning into lipid rafts. FEBS Lett 534: 169-174, 2003.
0 ~/ E V. H6 f1 j2 X
2 f# L) W( C5 m. [- w# t* a: k' X' Z
6 U9 s( M# f K3 h
Brown DA and London E. Structure and function of sphingolipid- and cholesterol-rich membrane rafts. J Biol Chem 275: 17221-17224, 2000.
. T3 B. ~' z' P' q
. z7 R1 Z$ Q% P) X* v, O" D8 K1 N9 k- N% I: T
0 s# @/ ]3 y4 i" i3 q* k! @; X( k gCouet J, Li S, Okamoto T, Ikezu T, and Lisanti MP. Identification of peptide and protein ligands for the caveolin-scaffolding domain. J Biol Chem 272: 6525-6533, 1997.% N) ^# r& c3 U" H) G! O0 U
6 `3 g% B, k. m: x$ f6 o, ]' ~# e' q, Z Y0 F+ K0 s. ^& i
& n$ l8 j$ Q8 T/ q5 vHostager BS, Catlett IM, and Bishop GA. Recruitment of CD40 and tumor necrosis factor receptor-associated factors 2 and 3 to membrane microdomains during CD40 signaling. J Biol Chem 275: 15392-15398, 2000." R5 k- x2 G" D% m, Q
{1 s! `! Q$ b8 S- a1 E' s3 o8 Y4 k7 |* a4 C* A# b4 R2 z4 X
6 m. l3 O: i/ }) |& kHu HM, O'Rourke K, Boguski MS, and Dixit VM. A novel RING finger protein interacts with the cytoplasmic domain of CD40. J Biol Chem 269: 30069-30072, 1994.
: {4 ^8 }. O9 ]7 |- y/ k; c; a" V6 w' f# t& `
. w2 h% m% q6 F8 e0 o) Y! |$ s
* I6 S2 c9 J1 H# `, `4 R& Z' F0 R' YHua H, Munk S, and Whiteside CI. Endothelin-1 activates mesangial cell ERK1/2 via EGF-receptor transactivation and caveolin-1 interaction. Am J Physiol Renal Physiol 284: F303-F312, 2003.# R9 O, N3 Z# V# L, ^
( p- m1 q0 e/ \7 E( U1 w1 L) Y3 P( ]
' o, k& N: U0 uIshida T, Mizushima S, Azuma S, Kobayashi N, Tojo T, Suzuki K, Aizawaa S, Watanabe T, Mosialos G, Kieff E, Yamamoto T, and Inoue J. Identification of TRAF6, a novel tumor necrosis factor receptor-associated factor protein that mediates signaling from an amino-terminal domain of the CD40 cytopasmic region. J Biol Chem 271: 28745-28748, 1996.+ B* k* J# h( w" W7 E
) c- Z8 G( W# K$ t. ? O/ K/ s1 B% A# O; B! L" i7 y
4 D( I( \4 a) U% O' m1 [6 k; q
Li H and Nord EP. CD40 ligation stimulates MCP-1 and IL-8 production, TRAF6 recruitment, and MAPK activation in proximal tubule cells. Am J Physiol Renal Physiol 282: F1020-F1033, 2002.- j* e8 Y4 B" a$ L6 D* B3 f/ h6 Q
5 D1 k. |9 @# n0 d/ {' `
3 l7 `9 u8 `2 g* i5 Y" q
. d; R9 m' S2 lMalapati S and Pierce SK. The influence of CD40 on the association of the B cell antigen receptor with lipid rafts in mature and immature cells. Eur J Immunol 31: 3789-3797, 2003. <a href="/cgi/external_ref?access_num=10.1002/1521-4141(200112)31:12
* n! d4 n) }3 q* T# S- `4 b
# ~) N! V# c/ v3 z/ n B
$ r4 f& }( W. E! X' k
0 \( M! W, H7 P0 g5 ]Mineo C, James GL, Smart EJ, and Anderson RGW. Localization of epidermal growth factor-stimulated Ras/Raf-1 interaction to caveolae membrane. J Biol Chem 271: 11930-11935, 1996.. |; [# t$ |/ ?* l8 @* ?6 \
& k" a, D% V# S! n+ `( v
) Q8 C7 }$ X( f9 F D6 u
7 v2 U) }' a; _$ t, c; ~. s) U
Nord EP, Goldfarb D, Mikhail N, Moradeshaghi P, Hafezi A, Vaystub S, Cragoe EJ, and Fine LG. Characteristics of the Na -H antiporter in the intact renal proximal tubular cell. Am J Physiol Renal Fluid Electrolyte Physiol 250: F539-F550, 1986.
. N9 c' G0 x: T1 r4 p/ \# T% G. \. j) O. g
& k* {* b! b4 ~1 I# c& ?
2 g! F! N+ X* i- R h6 R
Okamoto T, Schlegel A, Scherer PE, and Lisanti MP. Caveolins, a family of scaffolding proteins for organizing "preassembled signaling complexes" at the plasma membrane. J Biol Chem 273: 5419-5422, 1998.
) e% ?1 k' M/ M% `- U. y1 R/ v( d: p } N
4 I+ z" u7 Z6 N6 t, \
" C$ s i% E, P* nPullen SS, Miller HG, Everdeen DS, Dang TTA, Crute JJ, and Kehry MR. CD40-tumor necrosis factor receptor-associated factor (TRAF) interactions: regulation of CD40 signaling through multiple TRAF binding sites and TRAF hetero-oligomerization. Biochemistry 37: 11836-11845, 1998.
* V) g$ W0 w9 P6 U; k9 i! `
+ s) b/ Y+ h2 N, h; U6 q" o, H( l4 U* _# @/ L* L* @
; A: t; _" F8 Y
Scherer PE, Lewis RY, Volontes D, Engelman JA, Galbiati F, Couet J, Kohtz S, van Donselaar E, Peters P, and Lisanti MP. Cell-type and tissue-specific expression of caveolin-2. J Biol Chem 272: 29337-29346, 1997.# U0 \, b4 V5 M8 V
* n. ^; p8 q L+ x& ]7 x
3 f5 f+ n' e5 j$ z( W. I3 p1 a2 X! g* U, i+ G; H
Schnitzer JE, Oh P, Pinney E, and Allard J. Filipin-sensitive caveolae-mediated transport in endothelium: reduced transcytosis, scavenger endocytosis, and capillary permeability of select macromolecules. J Cell Biol 127: 1217-1232, 1994.
/ ^! j7 k7 a. ?1 o2 j+ {6 {8 O) o0 S: z! D H
6 ~) M5 ?: m5 I; P2 e) q, y: S! Z4 `) R& i7 U: ?# R
Simons K and Ikonen E. Functional rafts in cell membranes. Nature 387: 569-572, 1997.
6 }. j! b2 s! H+ a R9 O/ m K; L
- G9 Z$ p6 s! P$ H8 ], `7 X
' Q1 t2 r0 `% B5 tSmart EJ, Ying YS, Mineo C, and Anderson RGW. A detergent-free method for purifying caveolae membrane from tissue culture cells. Proc Natl Acad Sci USA 92: 10104-10108, 1995.
, U5 w" q( J& ^8 v6 c6 w* B, Y
4 y2 v# f' G% M& [* N# a9 s" q
$ q4 g$ N' B' _3 J% I: s2 _8 S' x- Z/ R! s0 d, B) E5 ^# E
Song KS, Li S, Okamoto T, Quilliam LA, Sargiacomo M, and Lisanti MP. Co-purification and direct interaction of Ras with Caveolin, an integral membrane protein of caveolae microdomains. J Biol Chem 271: 9690-9697, 1996.
( l9 f2 l* v, w( ^9 r+ h3 ?5 Y
% G- e# L0 [/ o# u5 G* ~' G0 o( e* k; F# ~ E; D9 q; k6 v( G
1 K) z& f6 I# }4 wTang ZL, Scherer PE, Okamoto T, Song K, Chu C, Kohtz DS, Nishimoto I, Lodish HF, and Lisanti MP. Molecular cloning of caveolin-3, a novel member of the caveolin gene family expressed predominatly in muscle. J Biol Chem 271: 2255-2261, 1996.
0 p6 A+ \0 d2 w1 |; f Y% f' K+ J
& Y. L% Y1 L+ w7 N: u% [
7 K0 }' d. ?7 H" r9 i& H$ R
Ushio-Fukai M, Hilenski L, Santanam N, Becker PL, Ma Y, Griendling KK, and Alexander RW. Cholesterol depletion inhibits epidermal growth factor receptor transactivation by angiotensin II in vascular smooth muscle cells. J Biol Chem 276: 48269-48275, 2001.; J* E. K$ d; p. Y3 m4 q
- \. T0 {) L( @1 W9 W
4 E7 l( e- c7 n( M) g
4 P: ^/ Z b( _ V! B: S% n4 N* s0 E6 |
Van Meer G. The different hues of lipid rafts. Science 296: 855-857, 2002.
% m; T6 |2 l) R- e- i
; v$ D( U2 y1 M0 L7 @5 `% ]; J2 m9 n
8 t$ o! n; s' M: V, E
Vidalain PO, Azocar O, Servet-Delprat C, Rabourdin-Cambe C, Gerlier D, and Manie S. CD40 signaling in human dendritic cells is initiated within membrane rafts. EMBO J 19: 3304-3313, 2000. |
|
发表于 2009-4-22 08:15
