Ligand-Independent Activation of the EGFR by Lipid Raft Disruption

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Ligand-Independent Activation of the EGFR by Lipid Raft Disruption Sylviane Lambert, Dina Vind-Kezunovic, Susanna Karvinen, Robert Gniadecki  Journal of Investigative Dermatology  Volume 126, Issue 5, Pages 954-962 (May 2006) DOI: 10.1038/sj.jid.5700168 Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 1 Clustering of EGFR after cholesterol depletion. (a) Cultured HaCaT cells were incubated with 1% MβCD or DMEM (control) for 30minutes at 37°C, fixed in paraformaldehyde, and stained with the mouse E30 anti-EGFR antibody followed by anti-mouse Texas red secondary antibody (red) and CTx-FITC (green). Comparable results were obtained in experiments where the E30 antibody was substituted with LA1 antibody (not shown). (b) The cells were labeled with EGF-Alexa 555 (red channel) for 30minutes at 4°C, washed, and incubated in 1% MβCD or DMEM (control) for 30minutes. The cells were acetone fixed and counterstained with CTx-FITC (green channel). EGFR clustering was also seen when MβCD-treated cells were stained with EGF-Alexa 555 and CTx-FITC after acetone fixation. (c) The cells were treated as in (b) and scanned in confocal microscope to obtain linear intensity histograms representing the fluorescence of EGF-Alexa 555 (red curve) and CTx-FITC (green curve). The X-axis represents the distance along which the measurement was taken. In the control cells, the high-intensity green fluorescence denotes CTxbright lipid raft aggregates (LRA). Note that in control cells, the green and red fluorescence intensities are spatially correlated and that after MβCD treatment, the large LRA disappear and the intensity of EGF-Alexa 555 increases also in the regions poorly labeled with CTx (vertical arrows). (d) Cells were treated with 1% MβCD for 30minutes as described above, scanned after staining with EGF-Alexa 555 (left) or anti-EGFR LA1 antibody (right), and the images were reconstructed in the Z-plane. The Left lower image represents reconstruction along the magenta line at the level of the basal membrane. Images in the right column represent Z-axis reconstruction of the whole cell. Note that the bright red clusters representing EGFR (arrows) do not colocalize with CTx-FITC (green) and are present either at the margins of CTxbright regions or in the regions unlabeled by CTx. (e) Adherent cells were stained with E30 anti-EGFR followed by a secondary anti-mouse FITC conjugate and scanned immediately by laser scanning cytometry to determine the membrane expression of EGFR. The red line represents control, untreated cells and the black line cells treated with 1% MβCD for 30minutes, as in (a). Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 2 Lateral movement of EGFR in cholesterol-depleted cells. Cells were stained with CTx-FITC (green) and EGF-Alexa 555 (red) and imaged in confocal microscope. Subsequently, a 1.2-μm-wide strip was photobleached through the CTxbright and CTxdim regions of the membrane and fluorescence recovery was calculated as described in Materials and Methods. Images in (a) (upper row) show an MβCD-treated cell before photobleaching, immediately after (0second), and 370seconds after photobleaching. The lower row shows lack of FRAP of single EGFR clusters in MβCD-treated cells. (b) Fluorescence recovery (mean±SEM, n=6) for CTx and EGFR in control cells and after MβCD treatment. Note that EGF-Alexa 555 and CTx-FITC fluorescence recoveries are significantly lower in the CTxbright than in the CTxdim areas, both in the control cells and the MβCD-treated cells (P<0.05, t-test). MβCD treatment causes a further decrease in recovery (*P<0.05, t-test). (c) Time-resolved fluorescence recovery curves for EGF-Alexa 555 in the CTxbright regions in control cells (○), MβCD-treated cells (▵), and for single EGFR clusters in control (□) and MβCD-treated cells (◊). There is a significant difference at P<0.0001 between any pair of curves (F-test) except for ◊ and □. All symbols show mean values (n=6 cells) with SD. Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 3 Activation of EGFR–ERK2 signaling in MβCD-treated cells. (a) Confocal images of the cells prelabeled with EGF-Alexa 555 (red channel) and subsequently treated with 1% MβCD as in Figure 1a. After acetone fixation, the cells were stained with rabbit anti-pEGFR followed by the secondary anti-rabbit FITC-conjugated antibody (green channel). Note colocalization of the EGFR clusters and pEGFR. A reverse experiment where cells were treated with 1% MβCD, acetone fixed, and stained with anti-pEGFR antibody and EGF-Alexa 555 yielded an identical result (not shown). (b) Staining of MβCD-treated and acetone-fixed cells with anti-pEGFR revealing spatial separation between pEGFR clusters (Texas red staining, red) and CTx-labeled areas (green). (c) Extracts from control and MβCD-treated cells were analyzed by Western blot. Each membrane was cut along the 70kDa line; the upper part was probed with the antibody against pEGFR and anti-EGFR (E30 antibody), whereas the lower part with the antibodies recognizing activated ERK1/2 (monoclonal mouse anti-pERK1/2) and total ERK (polyclonal, rabbit). The experiment was repeated at least four times with a similar result. (d) The amount of phosphorylated ERK1 and ERK2 was calculated from the Western blot shown in (c) as a fraction of the total form and expressed as percent of the control (Ctl 1hour, cells incubated for 1hour in DMEM). Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 4 Cholesterol depletion activates ERK2 in an EGFR-dependent manner. Cells were pretreated with the specific EGFR tyrosine kinase inhibitor AG1478 (1μm, 15minutes) and incubated with 1% MβCD (a) or 2μg/ml filipin III (b) for 1 or 1.5hours in the presence of the inhibitor. Cell lysates were analyzed by Western blot as in Figure 3c. Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 5 Moderate cholesterol depletion stimulates cell growth via EGFR but impairs the mitogenic response to EGF. (A–C) Cells were incubated with 0–2% MβCD for 2–24hours and pulse-labeled with BrdU for 30minutes at the end of the incubation. The contribution of the BrdU+ cells (shown in the insets as red events on the dot-plot charts) is highlighted in red on the DNA histograms in (a) (control cells, 0% MβCD, 4hours) and (b) (0.5% MβCD, 4hours). The proportion of BrdU+ cells after treatment with different concentrations of MβCD for different periods (n=3, mean±SD) is shown in (c). *Significant increase in the proportion of BrdU+ cells compared to cells not treated with MβCD (P<0.01, t-test). (d) Cells were pretreated for 15minutes with the specific EGFR tyrosine kinase inhibitor AG1478 (1μm), the specific mitogen-activated protein kinase/ERK kinase inhibitor PD98059 (2μm), or the vehicle (0.1% DMSO) and treated with the indicated concentrations of MβCD in the presence of the inhibitor or vehicle for additional 4hours. Cells were washed and cultured for a total of 24hours. Cell number was assessed by staining with methylene blue and expressed in absorbance units. The values represent mean percent of change +SD compared to control cells treated with the relevant kinase inhibitor (or DMSO) but without MβCD (values >100% mean stimulation of growth). MβCD caused a statistically significant increase in cell number at concentrations 0.1 and 0.5% (*P<0.01, t-test), but caused cell death at the concentration of 1% (⧫ P<0.01, t-test). Cell numbers in the groups treated with MβCD with PD98059 or AG1478 were lower (#P<0.001, t-test) than in the corresponding MβCD-treated cells that had not been pretreated with these blockers. (e) Cells were incubated with the indicated concentrations of MβCD (0–0.5%) for 1hour before the addition of EGF for 4hours. Absorbance was measured 24hours after MβCD treatment as in (d) and the results are expressed as percent of the values obtained for cells not stimulated with EGF. Bars show mean values with SD from three independent experiments. Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 6 pERK1/2 is translocated into the nucleus after MβCD treatment. Control (a) and MβCD (1%, 1hour)-treated cells (b) were fixed and stained with mouse anti-pERK1/2 antibody followed by anti-mouse Texas red-labeled secondary antibody. Fluorescence intensities were calculated from confocal images of the MβCD-treated cells, the control, untreated cells (Con), and the EGF-treated cells (positive control, 5ng/ml EGF for 1hour) for the cytoplasmic and nuclear regions (n=9 cells for each group) and shown in (c) as means+SD. *P<0.05 t-test. Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions

Figure 7 EGFR activation by MβCD is ligand independent. Cells were preincubated with the neutralizing anti-EGFR antibody (clone LA1), and treated with 1 or 2% MβCD for 1hour. The negative controls were incubated with the serum-free DMEM, whereas the positive control cells were treated with 5ng/ml of EGF for the same period of time. Cell extracts were analyzed by Western blot with the antibodies recognizing pEGFR, pERK1/2, or ERK1/2, as in Figure 3c. Journal of Investigative Dermatology 2006 126, 954-962DOI: (10.1038/sj.jid.5700168) Copyright © 2006 The Society for Investigative Dermatology, Inc Terms and Conditions