Integrin {alpha}2 and Extracellular Signal-regulated Kinase Are Functionally Linked in Highly Malignant Autocrine Transforming Growth Factor-{alpha}-driven Colon Cancer Cells*

Rajinder S. Sawhney {ddagger}, Bhavya Sharma, Lisa E. Humphrey and Michael G. Brattain §

From the Department of Pharmacology and Therapeutics, Roswell Park Cancer Institute, Buffalo, New York 14263

Received for publication, December 26, 2002 , and in revised form, March 19, 2003.
    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Recently, we have shown that autocrine transforming growth factor-{alpha} (TGF-{alpha}) controls the expression of integrin {alpha}2, cell adhesion to collagen IV and motility in highly progressed HCT116 colon cancer cells (Sawhney, R. S., Zhou, G-H. K., Humphrey, L. E., Ghosh, P., Kreisberg, J. I., and Brattain, M. G. (2002) J. Biol. Chem. 277, 75–86). We now report that expression of basal integrin {alpha}2 and its biological effects are controlled by constitutive activation of the extracellular signal-regulated/mitogen-activated protein kinase (ERK/MAPK) pathway. Treatment of cells with selective mitogen-activated protein kinase kinase (MEK) inhibitors PD098059 and U0126 showed that integrin {alpha}2 expression, cell adhesion, and activation of ERK are inhibited in a parallel concentration-dependent fashion. Moreover, autocrine TGF-{alpha}-mediated epidermal growth factor receptor activation was shown to control the constitutive activation of the ERK/MAPK pathway, since neutralizing antibody to the epidermal growth factor receptor was able to block basal ERK activity. TGF-{alpha} antisense-transfected cells also showed attenuated activation of ERK. Using a real time electric cell impedance sensing technique, it was shown that ERK-dependent integrin {alpha}2-mediated cell micromotion signaling is controlled by autocrine TGF-{alpha}. Thus, this study implicates ERK/MAPK signaling activated by endogenous TGF-{alpha} as one of the mechanistic features controlling metastatic spread.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Epidermal growth factor receptor (EGFr)1 activation is known to control cancer cell growth as a result of autocrine and/or paracrine stimulation. We have recently shown that constitutive endogenous activation of the EGFr by TGF-{alpha} provides a critical growth and survival advantage to colon cancer cells (1, 2). Similarly, it is conceivable that human colon cancer cells involved in metastasis may derive an advantage in cell motility from a strong autocrine TGF-{alpha} loop, because the initial number of cells contributing to metastatic behavior is small. Recently, we showed that in HCT116 cells, the DNA synthesis response is saturated by a relatively low EGFr occupation resulting from autocrine TGF-{alpha} (3). The expression level of integrin {alpha}2 and its functions, on the other hand, show a much wider window of response, increasing from low EGFr occupation by autocrine TGF-{alpha} to saturation by complete receptor occupation with exogenous EGF. The initiation of this response at low level receptor occupation was shown by its attenuation with treatment by an EGFr blocking antibody that inhibits basal EGFr activation resulting from autocrine TGF-{alpha} as well as by stable transfection with a TGF-{alpha} antisense cDNA to inhibit basal EGFr activation in HCT116 cells. We also observed that the addition of exogenous EGF results in further EGFr activation, which is associated with higher expression of integrin {alpha}2, enhanced cell adhesion, and micromotility. Thus, there is a difference in response windows based on the extent of EGFr activation. While the activation of EGFr was demonstrated to be critical to {alpha}2 integrin-mediated adhesion and motility, the EGFr-mediated downstream mechanism(s) and the intracellular pathways that control autocrine TGF-{alpha}-mediated cell adhesion and motility remain unclear.

In the present study, selective pharmacological inhibitors of signaling intermediates have been used to link cell signaling to integrin {alpha}2 expression, cell adhesion, and motility in HCT116 colon cancer cells. This cell line has been shown to generate liver metastases when implanted orthotopically in athymic nude mice (4, 5, 6). The link between metastases and motility suggests that endogenous TGF-{alpha} also has a role in the control of metastatic tumor formation.

The binding of a growth factor to its receptor may result in the activation of multiple signaling pathways, including the superfamily of mitogen-activated protein kinases (MAPKs)/extracellular signal-regulated kinases (ERK) (7, 8). Our work shows that in highly malignant growth factor-independent, metastatic HCT116 colon cancer cells, ERK plays an important role mediating endogenous cellular control of integrin {alpha}2 expression, cell adhesion, and motility. This study implicates ERK activated by endogenous TGF-{alpha} as one of the mechanistic features controlling metastatic spread.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Materials—Collagen type IV (CN IV), 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), and bovine serum albumin (BSA) were purchased from Sigma. Polyclonal antibodies specific for integrin {alpha}2 subunit (Ab 1936), integrin {alpha}1 subunit (Ab 1934), and functional monoclonal antibody specific for anti-human integrin {alpha}2 (clone P1E6) were procured from Chemicon International Inc. (Temecula, CA). The mouse IgG1 isotype control was purchased from R&D Systems (Minneapolis, MN), and the secondary fluorescein isothiocyanate AffiniPure goat anti-mouse IgG (H + L) antibody was from Jackson ImmunoResearch (West Grove, PA). EGFr monoclonal blocking antibody, mAb 528, was obtained from Oncogene Science (Manhasset, NY), whereas MEK inhibitors, PD098059 (2-(2'-amino-3'-methoxyphenyl)oxanaphthalen-4-one) and U0126 (1,4-diamino-2,3-dicyano-1,4-bis(2-aminophenylthio)butadiene) were purchased from Calbiochem and Promega, respectively. The phosphatidylinositol 3-kinase (PI3K) inhibitor LY 294002 (2-(4-morpholinyl)-8-phenyl-4H-1-benzopyran-4-one) was purchased from Calbiochem. Polyclonal anti-actin antibody was purchased from Sigma. Anti-ERK antibody was purchased from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA). McCoy's 5A medium, transferrin, and insulin were obtained from Sigma, whereas EGF was purchased from R&D Systems. Arrays of gold film-coated electrodes for cell motility experiments were purchased from Applied Biophysics Inc. (Troy, NY). NHS-LC-Biotin was purchased from Pierce, whereas streptavidin-agarose and Trizol reagent were procured from Calbiochem and Invitrogen, respectively.

Cell Culture and Adhesion Assay—These experiments were performed as described previously (3). HCT 116 cells were maintained at 37 °C in a humidified incubator with 5% CO2 in chemically defined serum-free medium consisting of McCoy's 5A medium supplemented with 4 µg/ml transferrin and 20 µg/ml insulin either in the absence or presence of EGF (10 ng/ml) depending upon experimental conditions.

For adhesion assays, 96-well tissue culture plates were coated overnight at room temperature with CN IV at concentrations of 0–0.25 µg/ml, blocked with 3% BSA in PBS for 3 h, and then rinsed once with PBS. Subsequently, the colorimetric MTT procedure was followed as described previously (3, 9).

After trypsinization, cells were incubated at 37 °C with inhibitors for 3 h to determine autocrine TGF-{alpha}- or exogenous EGF-mediated cell adhesion functions. Cells were plated at 6 x 104 cells/well on CN IV-coated plates and incubated for 90 min in the absence or presence of MEK inhibitors PD098059 and U0126. Nonadherent cells were removed by washing three times with serum-free medium. The relative number of attached cells was determined by the MTT method. All inhibitors were dissolved in Me2SO as stock solutions and diluted at the time of experiment.

Cell Lysates, Biotinylation, and Immunoblotting—The procedures were the same as described previously (3). Briefly, subconfluent cultures of HCT116 cells were treated either with Joklik's EDTA for 8 min or trypsinized for 3 min at room temperature, and subsequently cells were scraped and pelleted by centrifugation in a clinical centrifuge for 3 min at 800 x g. The pellet was washed twice with cold PBS, and cells were biotinylated in suspension with NHS-LC-Biotin (Pierce), 0.1 mg/ml in Me2SO at room temperature for 1 h. The biotinylated cells for integrins were washed with PBS and lysed in buffer (50 mM Tris, pH 7.5, 150 mM NaCl, 1 mM CaCl2, 1 mM MgCl2, 1% Nonidet P-40, and a mixture of protease inhibitors) by shearing them through a 26-gauge needle and centrifuging at 16,000 x g for 20 min at 4 °C in a microcentrifuge. Equal amounts of protein from treated and untreated (control) cell lysates were incubated with streptavidin-agarose for 90 min at 4 °C. Agarose beads were pelleted by centrifugation at 4 °C and subsequently washed five times with lysis buffer containing phenylmethylsulfonyl fluoride. The beads were boiled in 2x Laemmli buffer containing 4% {beta}-mercaptoethanol for 8 min, and supernatant was filtered through Bio-Rad columns and analyzed by 7.5% SDS-PAGE. The proteins were transferred to nitrocellulose membranes (Hybond), and the membrane was blocked for 2–3 h with 5% nonfat dry milk in Triton Tris-buffered saline and subsequently incubated overnight at 4 °C with primary antibody. After washing the membrane three times with Triton Tris-buffered saline, it was incubated for 1 h at room temperature with horseradish peroxidase-conjugated rabbit or mouse secondary antibody. The membrane was washed twice, and detection of specific protein was achieved by using enhanced chemiluminescence reagent (PerkinElmer Life Sciences). For Western blot analysis of cell signaling proteins, biotinylation of cells was omitted, and proteins were separated by either 7.5 or 10% SDS-PAGE.

Transfection of TGF-{alpha} Antisense Cells with Activated ERK1 DNA— TGF-{alpha} antisense cells were transfected with ERK1 DNA using Fu-GENE 6 transfection reagent (Roche Applied Science) according to the manufacturer's protocol. Briefly, ~1 x 106 cells were seeded in 100-mm tissue culture plates in chemically defined serum-free medium 3 days before transfection and changed to serum-free medium devoid of EGF on the third day. The cells were transfected with activated MEK1 DNA, a gift of Drs. Weber and Slack-Davis (10) at a 4:1 ratio of FuGENE to plasmid DNA. Forty-eight hours after transfection, the medium was replaced. Sixty-two hours after transfection, cells were harvested and cell lysates were prepared as described earlier. The cell lysates were analyzed for ERK activation and integrin {alpha}2 protein expression by Western blot.

RNase Protection Assay—Total cellular RNA was isolated from control or treated HCT116 cells by lysing cells with the Trizol reagent following the supplier's protocol (11). Equivalent amounts of RNA samples (40 µg) were used in RNase protection assays. The {alpha}2 subunit template was constructed by subcloning a 292-base pair ECoR V-Hinc II fragment of the human {alpha}2 subunit cDNA into plasmid PBSK (-). A high specific activity {alpha}2 subunit riboprobe was synthesized by T7 RNA polymerase, whereas actin antisense probe was prepared by S{rho}6-RNA polymerase in the presence of [32P]UTP (3000 Ci/mmol; Amersham Biosciences). Normalization of sample loading was assessed as previously described (3).

Determination of Cell Surface Integrin {alpha}2 by Fluorescence-activated Cell Sorter Analysis—HCT116 cells either were treated with Me2SO, PD098059 (25 µM), or U0126 (10 µM) for 48h. The cells were harvested with Joklik's EDTA and washed once in culture medium. For each experimental condition, ~1 x 106 cells were pelleted and fixed in 2% formaldehyde at 4 °C overnight. The cells were washed twice with a cold 1% BSA in PBS solution. Cells were resuspended in 0.25 ml of cold 0.1% BSA in PBS and incubated with the primary antibody (IgG1 and P1E6; 1:50 dilution) for 45 min at 4 °C. Cells were washed three times with 1% BSA in PBS, resuspended in 0.1% BSA in PBS, and incubated with a secondary fluorescein isothiocyanate antibody (1:100 dilution) for 45 min on ice in the dark. The cells were washed twice with 1% BSA in PBS, resuspended in PBS, and maintained on ice. Cells were analyzed on a Becton-Dickinson FACScan Analyzer using CellQuest and WinList software.

Cell Motility Measurements by the Electrical Cell Impedance Sensor (ECIS) Technique—These experiments were performed as described previously (3). Briefly, to determine cell motion, HCT116 cells were plated at 4 x 104 cells/well on small active gold electrodes (diameter, 250 µm) at the bottom of tissue culture wells (area, 0.5 cm2) (12, 13, 14). Four hundred microliters of medium, which served as an electrolyte, were used per well. Depending on the experimental design, arrays consisting of either five or eight individual small electrodes were used. In these measurements, a 1-µA, 4-kHz AC signal from a constant current source was applied between the small electrode and a much larger counter electrode (0.15 cm2). This signal was too weak to disturb the cells or to change cell behavior (12). The voltage of the system was monitored by a lock-in amplifier, which can detect both magnitude and phase of the voltage appearing across the sample. The in-phase and out-of-phase voltages across the electrode were recorded by the lock-in amplifier once every second for measuring micromotion. The ECIS software (Applied BioPhysics, Troy, NY) calculated the impedance (resistance and capacitance) values of the electrode over a designated period of time. The movement of the cells on the active electrode interfered with the flow of the current, resulting in fluctuations in the electrode impedance. These real time cellular movements were called micromotion (13) and were a measure of the motile ability of the cells under investigation. As the cells moved on the gold electrode, the sensitive nature of the lock-in amplifier detected the fluctuations in the resistance and capacitance values of impedance (14). These fluctuations were then statistically analyzed by the ECIS software, thus revealing the percentage variation in resistance, which in turn was a reflection of cellular micromotion on the electrode (14). The technique is real time, quantitative, and completely automated.


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
ERK/MAPK Activity Is Induced by Endogenous and Exogenous EGFr Ligands—Since ERK/MAPK is a downstream effector of EGFr-mediated signaling, cells were suspended and then incubated at 37 °C for 20 min in the absence or presence of exogenous EGF. Both ERK-1 (44 kDa) and ERK-2 (42 kDa) activities were enhanced by endogenous and exogenous ligands as determined by Western blot analyses using a mAb against the active phosphorylated ERK (p-ERK). In the upper panel (Fig. 1A), a Western blot of ERK using anti-phospho antibodies is shown, whereas the lower panel shows total ERK. Densitometric quantitation showed that endogenous ligand increased ERK activation about 80%, whereas exogenous EGF enhanced ERK activation about 230%, as compared with the control (Fig. 1B).



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FIG. 1.
A, effect of EGF on activation of ERK. HCT116 cells were maintained in the absence of exogenous EGF. Lane 1, basal level of ERK activation at 4 °C; lane 2, increase in activation of ERK when cells were incubated for 20 min at 37 °C in the absence of exogenous EGF; lane 3, shows further enhancement in activation of ERK when cells were incubated for 20 min at 37 °C in the presence of exogenous EGF. Proteins were analyzed by Western blot analysis using mAb against the active phosphorylated ERK (upper panel). The lower panel shows total ERK. B, densitometry quantitation in percentage activation of ERK by endogenous and exogenous ligands.

 

Constitutive ERK Activation through Endogenous TGF-{alpha}-mediated EGFr Activation—Previously, we showed that mAb 528 inhibited autocrine TGF-{alpha}-mediated EGFr activation and cell adhesion in HCT116 cells (3). To further define the role of activated ERK as a downstream event of EGFr activation, HCT116 cells were treated with EGFr-blocking mAb 528, and its effect on ERK levels was observed by Western blot analysis. The anti-EGFr antibody mAb 528 was effective in blocking activation of ERK in cells maintained in the absence of EGF. Fig. 2A shows that mAb 528 inhibited phosphorylation of ERK as compared with control HCT116 cells. The antibody did not have any effect on total ERK. The results indicate that autocrine TGF-{alpha} contributes to ERK/MAPK signaling.



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FIG. 2.
A, inhibitory effect of mAb 528 on ERK activation. Cells maintained in the absence of EGF were treated with 10 µg/ml EGFr blocking mAb 528 or with mouse IgG for 48 h. Cells were lysed, and equal amounts of protein were analyzed by Western blot as described under "Experimental Procedures." Total ERK was used as a loading control. B, inhibition of ERK in TGF-{alpha} antisense cells. HCT116 and HCT116 TGF-{alpha} antisense transfected cells were maintained in the absence of EGF. Lane 1, basal level of ERK activation in HCT116 cells; lane 2, basal level of ERK activation in TGF-{alpha} antisense cells; lane 3, increased activation of ERK when antisense cells were incubated for 20 min at 37 °C in the presence of exogenous EGF. Cells were lysed, and equal amounts of protein were analyzed by Western blot analysis as described under "Experimental Procedures," using antibodies either against phosphorylated ERK (upper panel) or total ERK (lower panel). C, effect of MEK1 transfection on ERK activation and integrin {alpha}2 protein expression in TGF-{alpha} antisense cells. Upper panel, comparison of activation of ERK in control TGF-{alpha} antisense cells (lane 1) and activated MEK1-transfected cells (lane 2). Total ERK was used as a loading control. Lower panel, comparison of integrin {alpha}2 protein expression in control TGF-{alpha} antisense cells (lane 1) and activated MEK1-transfected cells (lane 2). Actin was used as a loading control. The TGF-{alpha} antisense cells were transfected with activated MEK1 DNA as described under "Experimental Procedures."

 

If TGF-{alpha} were acting in an autocrine manner to effect ERK activation, it would be expected that anti-TGF-{alpha} antisense-transfected cells would block activation of ERK relative to parental HCT116 cells. We have previously used well characterized HCT116 cells stably transfected with a full-length antisense TGF-{alpha} cDNA to show that the TGF-{alpha} antisense mRNA can be detected in these stably transfected cells (15, 16). The antisense mRNA forms duplexes with the sense TGF-{alpha} mRNA, which results in the reduced steady state of TGF-{alpha} mRNA but not of other genes (16). All of these effects as well as the biological effects (loss of tumorigenicity, gain of dependence on exogenous EGFr ligand for DNA synthesis, and cell proliferation) are reversed when the antisense mRNA is lost by revertant transfected cells or by the addition of exogenous ligand. Similarly, we have previously shown that exogenous EGFr ligand rescues the effects of TGF-{alpha} antisense transfection on basal steady state integrin {alpha}2 expression as well on the subsequent steady state cell adhesion and micromotility properties (3).

The TGF-{alpha} antisense transfected cells were used to characterize autocrine TGF-{alpha} effects on ERK. Fig. 2B (lane 1) shows activation of ERK in parental HCT116 cells in the absence of exogenous EGF, whereas lane 2 exhibits attenuation of ERK activation in HCT116 TGF-{alpha} antisense transfected cells showing that ERK activation is sensitive to TGF-{alpha} antisense expression. Furthermore, the decreased activation of ERK was rescued by treating TGF-{alpha} antisense cells with exogenous EGF, showing that reactivation of EGFr rescues the antisense effect. However, levels of total ERK were not altered. These results are consistent with the effects of EGFr blocking mAb 528 on ERK phosphorylation in HCT116 cells.

To demonstrate that the decrease in integrin {alpha}2 expression in TGF-{alpha} antisense cells can be rescued by overexpressing ERK, we transfected TGF-{alpha} antisense cells with constitutively activated MEK1 (10). The activation of ERK and expression of integrin {alpha}2 was analyzed by immunoblotting. Fig. 2C shows that by constitutively overexpressing ERK in TGF-{alpha} antisense transfected cells, inhibition of integrin {alpha}2 is rescued. Fig. 2C (upper panel) shows activation of ERK in antisense cells (lane 1), whereas lane 2 shows activation of ERK in MEK1-transfected cells. Fig. 2C (lower panel) shows expression of integrin {alpha}2 in TGF-{alpha} antisense cells (lane 1), whereas lane 2 shows expression of integrin {alpha}2 in MEK1-transfected antisense cells.

PD098059 and U0126 Inhibit Cell Adhesion, Integrin {alpha}2 Expression, and ERK Activation in a Parallel Fashion—Because ERK can be activated by EGFr signaling, we determined whether autocrine TGF-{alpha} contributes to cell adhesion functions via ERK activation in HCT116 cells. We utilized highly selective MEK inhibitors to further define the role of the MAPK pathway in the control of integrin {alpha}2 and its functions (17, 18). Treatment with PD098059 or U0126 selectively inhibits MEK activity, which is responsible for phosphorylation and activation of ERK. PD098059 inhibits MEK1, whereas U0126 is an inhibitor of MEK1 and -2. Both inhibitors were effective for inhibition of cell adhesion (Fig. 3). The effect of PD098059 on CN IV-mediated adhesion in the absence of exogenous EGF on cell adhesion was characterized. Inhibition of adhesion (35–67%) by different concentrations of the drug indicated that basal control of cell adhesion on CN IV is mediated by endogenous MAPK activation (Fig. 3A). HCT116 cells showed 33–67% inhibition of cell adhesion to CN IV (in the absence of exogenous EGF) when incubated with MEK inhibitor U0126 relative to Me2SO-treated controls under identical conditions (Fig. 3B). The inhibitory effect of MEK inhibitors on cell adhesion was directly correlated with reduced expression of integrin {alpha}2, both at the protein and mRNA levels, as shown by Western blot analysis (Fig. 4A) and by an RNase protection assay (Fig. 4B).



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FIG. 3.
A, dose-response effect of PD098059 on adhesion of HCT116 cells. Shown is a comparison of the adhesion to CN IV of HCT116 control and HCT116 cells treated with 0–50 µM concentrations of PD098059. Substrates were prepared by coating tissue culture 96-well plates with CN IV at a concentration of 0.25 µg/ml overnight at room temperature. Cells in the absence of EGF were seeded at 6 x 104 cells/well onto coated plates and incubated for 90 min at 37 °C. The relative number of attached cells was determined by an MTT assay as described under "Experimental Procedures." B, effect of U0126 on adhesion of HCT116 cells. Shown is a comparison of adhesion of HCT116 control and U0126-treated cells to CN IV. Substrates were prepared by coating tissue culture 96-well plates with CN IV at concentrations of 0, 0.1, and 0.25 µg/ml overnight at room temperature. Cells were seeded at 6 x 104 cells/well onto coated plates and incubated for 90 min at 37 °C. The relative number of attached cells was determined by MTT assay as described under "Experimental Procedures." DMSO, Me2SO.

 


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FIG. 4.
A (left panel), effect of MEK inhibitors on expression of integrin {alpha}2. HCT116 cells were treated with different concentrations of PD098059 and U0126 for 48 h. Cells were lysed, and equal amounts of protein were analyzed by Western blot analysis using specific antibody against integrin {alpha}2 as described under "Experimental Procedures." Actin was used as a loading control. A (right panel), effect of MEK inhibitors on expression of integrin {alpha}1. HCT116 cells were treated with PD098059 (25 µM) and U0126 (10 µM) for 48 h. Cells were lysed, and equal amounts of protein were analyzed by Western blot analysis using specific antibody against integrin {alpha}1 (Ab 1934) (upper panel) as described under "Experimental Procedures." Actin was used as a loading control (lower panel). B, effect of PD098059 and U0126 on the expression of integrin {alpha}2 mRNA. Total RNA (40 µg) isolated from control, PD098059 (10, 25, and 50 µM), and U0126 (5 and 10 µM)-treated cells was hybridized with 32P-labeled RNA probe of the integrin {alpha}2 subunit (0.5 x 106 cpm) and actin (8500 cpm) simultaneously according to the details given under "Experimental Procedures." The sizes of the protected fragments on urea-polyacrylamide gel electrophoresis are indicated by the arrows. Lane 1, a mixture of probes; lane 2, a negative control yeast tRNA; lanes 3–8, expression of integrin {alpha}2 mRNA after treating cells with either Me2SO (DMSO) or with the appropriate MEK inhibitor, as shown. Actin mRNA levels are shown for normalization of sample loading. C, fluorescence-activated cell sorter analysis of HCT116 cells treated with MEK inhibitors. a, control cells (Me2SO-treated) stained with anti-{alpha}2 integrin antibody (P1E6); b, cells treated with PD098059 (25 µM) for 48 h, stained with anti-{alpha}2 integrin antibody (P1E6); c, cells treated with U0126 (10 µM) for 48 h, stained with anti-{alpha}2 integrin antibody (P1E6). As a point reference, the dotted lines indicate mean fluorescence intensity (MFI) of control cells. The mean fluorescence intensity and percentage of integrin {alpha}2-positive cells are indicated. D, effect of LY 294002 on the expression of integrin {alpha}2 protein. HCT116 cells were treated with different concentrations (0–40 µM) of LY 294002. Cells were biotinylated and lysed, and equal amounts of protein were analyzed by Western blot analysis. The upper panel shows the effect of LY 294002 on the expression of integrin {alpha}2, whereas the lower panel shows levels of actin as a loading control. E, dose-response effect of LY 294002 on adhesion of HCT116 cells. A comparison of the adhesion to CN IV of HCT116 control and HCT116 cells treated with 20 and 40 µM concentrations of LY 294002. Substrates were prepared by coating tissue culture 96-well plates with CN IV at a concentration of 0.025 µg/ml overnight at room temperature. Cells were seeded at 6 x 104 cells/well onto coated plates and incubated for 90 min at 37 °C. The relative number of attached cells was determined by MTT assay as described under "Experimental Procedures."

 

To determine the effect of MEK inhibitors on functional cell surface integrin {alpha}2 expression, cells were treated with MEK inhibitors (U0126 and PD098059) or with the Me2SO vehicle alone. The effect of the inhibitors was analyzed by fluorescence-activated cell sorter analysis with integrin {alpha}2-specific (P1E6) functional antibodies. Fig. 4C shows that both MEK inhibitors induce a loss of cell surface integrin {alpha}2 expression.

To confirm that MEK activation was directly related to ERK activation under these conditions, cells were incubated with MEK inhibitors, and cell lysates were analyzed for ERK activation by Western blot analysis. The constitutive activation of ERK is inhibited by MEK inhibitors in a concentration-dependent fashion (Fig. 5, A and B). Inhibition of activation of ERK by a MEK inhibitor in the absence of EGF shows endogenous control of integrin functions via ERK. The inhibitors did not affect levels of nonphosphorylated ERK. Similarly, inhibition of activation of ERK by MEK inhibitors was also observed in the presence of exogenous EGF (Fig. 5B). Our results demonstrate that inhibition of cellular adhesion functions parallels the inhibition of activation of ERK by MEK inhibitors.



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FIG. 5.
A, effect of MEK inhibitors on ERK in the absence of EGF. Cells in the absence of EGF were treated with different concentrations of PD098059 (10, 25, and 50 µM; upper panel) and U0126 (5 and 10 µM; lower panel) for 48 h. Cells were lysed, and equal amounts of protein were analyzed by Western blot analysis as described under "Experimental Procedures," using antibodies either against phosphorylated ERK or total ERK as shown. B, effect of MEK inhibitors on ERK in the presence of EGF. Cells in the presence of EGF were treated with different concentrations of U0126 (5 and 10 µM) for 48 h. Cells were lysed and equal amounts of protein were analyzed by Western blot analysis as described under "Experimental Procedures," using antibodies either against phosphorylated ERK (upper panel) or total ERK (lower panel). DMSO, Me2SO.

 

LY 294002 Does Not Inhibit Integrin {alpha}2 Protein Expression and Cell Adhesion—To determine the role of PI3K signaling in cell adhesion and integrin {alpha}2 expression, HCT116 cells were treated with various concentrations (0–40 µM) of LY 294002, a selective inhibitor of PI3K, and the expression of integrin {alpha}2 was analyzed by immunoblotting (Fig. 4D). We did not observe any decrease in the expression of integrin {alpha}2 protein by the PI3K inhibitor. Similarly, the adhesion assay, after treating cells with LY 294002, did not show any inhibition in cell adhesion (Fig. 4E). These results show that the EGFr-mediated expression of integrin {alpha}2 protein and its function are not under the control of the PI3K signaling pathway in HCT116 cells.

PD098059 Inhibits Basal Cell Micro motion in a Concentration-dependent Fashion—The real time ECIS technique was used to quantitate cell motility. Using this technique, cell motion may be measured at a nanometer level and is, therefore, called micromotion (13). Micromotion detected by the ECIS technique is directly related to conventional cell motility (19). Drugs that inhibit cell migration and cell motility in cultured cells, such as cytochalasin B, also inhibit micromotion (14, 20). Micromotion detected by the ECIS technique has been used to detect cell motility, cell morphology, and cell-ECM interactions in different systems (20, 21). More recently, ECIS has been used to establish the metastatic behavior of cells in culture (22). Cell motility is one of the salient features of invasive tumors, enabling tumor cells to migrate and metastasize into other tissues. Our results are consistent with recent findings that EGFr-mediated aberrant motility may lead to metastatic and invasive behavior in cancer cells (23).

In the ECIS technique, a small AC signal is applied across the gold electrode on which cells are plated, while the resistance and the capacitance of the electrode are measured over time (3). To determine the role of autocrine TGF-{alpha} in cell locomotion, cells (4 x 104) were grown on electrodes precoated with CN IV, in EGF-free medium. The subconfluent cultures were treated with 10 and 25 µM of PD098059 for 48 h, and the micromotion was recorded. Fig. 6A shows that in the control HCT116 cells, the percentage variation in resistance was found to be 2.421% (Me2SO; DMSO, upper panel). Treatment of the cells with PD098059 (10 µM; middle panel) decreased the fluctuations, indicating a decrease in cell motility, such that the percentage variation in resistance was now 1.580%. When cells were treated with higher concentrations of PD098059 (25 µM), we observed a further decrease in basal levels of cell micromotion (percentage variation in resistance was 0.743%), thus demonstrating that the inhibitory effect of PD098059 on cell micromotion was concentration-dependent. These results show that the basal levels of HCT116 cell micromotion are selectively under the control of endogenous ERK/MAPK signaling mediated by autocrine activation of TGF-{alpha}.



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FIG. 6.
A, PD098059 inhibits basal levels of cell micromotion in a dose-response fashion in the absence of EGF. Electrode arrays after precoating with CN IV (5 µg/ml) were used. HCT116 cells (4 x 104) were plated in medium devoid of EGF. Subconfluent cultures were either treated with Me2SO (DMSO; upper panel), PD098059 10 µM (middle panel), or 25 µM (bottom panel) for 48 h. Cells growing on CN IV-coated gold electrodes were monitored for micromotion. B, EGF enhances cell micromotion, whereas PD098059 abrogates EGF effect. Electrode arrays after precoating with CN IV (5 µg/ml) were used in these experiments. HCT116 cells were cultured in the absence of EGF. Subconfluent (70–80%) cultures were either not treated (upper panel) or treated with EGF (10 ng/ml) (middle panel) and treated with EGF plus PD098059 (50 µM)(bottom panel). Cells growing on collagen-coated gold electrodes were monitored for micromotion.

 

EGF Enhances CN IV-induced Cell Motility, whereas MEK Inhibitor PD098059 Abrogates EGF Effects—Following cell attachment and spreading, the micromotion of cells was studied as shown in Fig. 6B. In untreated HCT116 cells, the percentage variation in resistance was found to be 2.703 (Fig. 6B, upper panel). The addition of EGF (10 ng/ml) to the cell medium increased the fluctuations, indicating an increase in cell motility, such that the percentage variation in resistance was now 7.818 (Fig. 6B, middle panel). This indicated that the increase in cell micromotion may have been due to the activation of ERK by EGF. To determine whether this effect of EGF was indeed via MAPK signaling, we then treated these cells with PD098059 (25 µM). The addition of PD098059 to the EGF-stimulated cells abrogated the increase in cell motility caused by EGF (percentage variation in resistance was 3.050; Fig. 6B, bottom panel). This demonstrated that, in addition to cell adhesion, cell micromotion is also mediated by ERK/MAPK signaling.


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
We have previously reported that in HCT116 cells, the biological responses of EGFr-mediated functions including DNA synthesis, integrin {alpha}2 expression, cell adhesion, and cell micromotion depend upon autocrine EGFr activation at the basal state as well as response to exogenous ligand (3). To further elucidate the mechanism(s) of EGFr-mediated integrin {alpha}2 expression and its biological functions in HCT116 cells, we have examined downstream signaling of basal and stimulated EGFr activation. Fig. 1 showed that ERK was endogenously activated in HCT116 cells, and incubation of cells in the presence of exogenous growth factor further activated ERK. These results are supported by our earlier observations that endogenous TGF-{alpha} does not fully activate EGFr and further incubation of HCT116 cells with exogenous EGF or TGF-{alpha} fully saturates unoccupied EGFr (3). We have now shown that the endogenous phosphorylation of ERK is due to autocrine TGF-{alpha}. Autocrine TGF-{alpha} was demonstrated to be responsible for ERK activation via EGFr signaling by two approaches. These included the use of mAb 528 and the use of TGF-{alpha} antisense-transfected cells. These results were further supported by our earlier observations that TGF-{alpha} antisense transfected cells showed reduced expression of integrin {alpha}2, cell adhesion, and micromotion (3). The decrease in ERK activation in TGF-{alpha} antisense cells as compared with parental HCT116 cells (Fig. 2B) may be critical in inhibiting cell adhesion and integrin {alpha}2 expression (3). Our MEK1 DNA transient transfection experiments (Fig. 2C) suggest that ERK/MAPK pathway is sufficient to mediate autocrine TGF-{alpha}-induced control of integrin {alpha}2. TGF-{alpha} autocrine loops have been reported in many cancer cells including colon carcinoma cells in which it has been demonstrated that malignancy is dependent upon TGF-{alpha} autocrine activity (1, 24, 25, 26, 27).

In addition to the above experiments, selective inhibitors of MEK (PD098059 and U0126) also inhibited activation of ERK in HCT116 cells. Both inhibitors significantly inhibited the activation of ERK, in a dose-dependent fashion, both in the absence and presence of exogenous EGF. This showed that the activation of ERK is under MEK control. We further provide evidence that ERK activation in HCT116 cells is linked with cell adhesion. The inhibitory effect of MEK inhibitors on cell adhesion was concentration-dependent. To determine whether the inhibitory effect of MEK inhibitors on cell adhesion was mediated by expression of integrin {alpha}2, we treated cells with different concentrations of PD098059 and U0126. The inhibitors down-regulated the expression of integrin {alpha}2, both at protein and mRNA levels. To demonstrate the selectivity of inhibition of integrin {alpha}2 expression by ERK/MAPK signaling pathway, HCT116 cells were treated with selective MEK inhibitors (PD098059 and U0126), and expression of integrin {alpha}1 protein was determined by immunoblotting. The results show that HCT116 cells express the integrin {alpha}1 subunit; however, the levels of integrin {alpha}1 protein do not alter by either MEK inhibitor (Fig. 4A, right panel). These results show that MEK inhibitors selectively inhibit integrin {alpha}2 expression in HCT116 cells.

We observed the down-regulatory effect of MEK inhibitors on cell surface integrin {alpha}2 at two levels. First, the total number of cells expressing integrin {alpha}2 was reduced. In addition, inhibitors caused a marked decrease in overall surface density of integrin {alpha}2 at the individual cell level. Taken together, these results provide an explanation for the decrease in cell adhesion by MEK inhibitors. These data are consistent with the concept that a threshold level of cell surface integrin {alpha}2 is required to support optimal adhesion. The inhibitory effect of MEK inhibitors on cell adhesion and integrin {alpha}2 expression indicates that ERK activation is critical in "inside-out" signaling in HCT116 cells. Other studies have shown that ERK is critical mediator of "outside-in" signaling as well. For example, it has been shown that active ERK is present in focal adhesions formed by ECM-integrin interaction (28). The activation of ERK2/MAPK by serum or growth factors has been shown to depend strongly on cell adhesion to ECM proteins (29). Integrin-mediated cell adhesion to the ECM allows efficient EGFr-mediated activation of ERK. Lai et al. (30) have shown that ERK is important for osteoblast adhesion and integrin expression. ERK/MAPK signaling has previously been shown to be involved in expression of integrins (31, 32). Our experiments provide direct evidence linking endogenous ERK activation to integrin {alpha}2 expression and its biological functions.

In addition to mitogens, integrin ligation can also trigger ERK/MAPK signaling (33, 34, 35, 36). Miyamoto et al. (36) have shown that integrin aggregation with or without ligand occupancy can initiate activation of the ERK signal transduction pathway. Aplin et al. (37) have shown that integrin {alpha}2-mediated ERK activation was via focal adhesion kinase activation, whereas growth factors respond via Shc signaling, suggesting important differences in the activation of ERK/MAPK signaling by different ligands. Further, the adaptor protein Shc was not involved in integrin and growth factor collaborative signaling.

A second important target of EGFr-mediated downstream signaling is via PI3K. This kinase is widely involved in a variety of signal transduction pathways including cell adhesion and cell survival (38). We have investigated the potential role of PI3K signaling in integrin {alpha}2 functions in HCT116 cells. Treatment of HCT116 cells with LY 294002, a selective inhibitor of PI3K signaling, did not significantly affect integrin {alpha}2 protein expression (Fig. 4D) or cell adhesion (Fig. 4E). Our results show that ERK/MAPK signaling and not PI3K signaling has a key role in the EGFr-mediated control of integrin {alpha}2 function in autocrine TGF-{alpha}-driven HCT116 cells. Recently, it was reported that the integrin {alpha}2{beta}1 does not interact effectively with the PI3K/Akt pathway, whereas integrin {alpha}5{beta}1 promptly activates this pathway in intestinal cells (39). However, the precise mechanism(s) underlying integrin-specific activation of the PI3K remains elusive.

To investigate whether EGFr-mediated cell motility is linked with ERK/MAPK signaling, we examined the effect of PD098059 on cell motion. To determine cell motion, a real time quantitative and very sensitive technique, ECIS, was used (13). Further, to determine whether autocrine TGF-{alpha} controls micromotion via ERK/MAPK signaling, experiments were performed in the absence of exogenous growth factor. Treatment of cells with PD098059 resulted in the inhibition of endogenous cell micromotion in a concentration-dependent fashion (Fig. 6A). These results demonstrate that autocrine TGF-{alpha} not only controls cell adhesion and integrin {alpha}2 expression but also cell micromotion via ERK/MAPK signaling. Treatment of cells with exogenous EGF also dramatically enhanced cell locomotion (Fig. 6B, middle panel). The increase in percentage variation in resistance caused by EGF was abrogated by treating cells with the MEK inhibitor PD098059, thus showing that the EGFr-mediated cell micromotion, in addition to cell adhesion and integrin {alpha}2 expression, is also under the control of ERK/MAPK signaling. Autocrine growth factor-mediated signaling is believed to play an important role in cell biology. However, it is still not well understood whether autocrine effects on cell functions are different from the effects of ligand in the exogenous mode. Maheshwari et al. (40) have elegantly shown that in human mammary epithelial cells, autocrine EGF provides a directional motility signal involved in tissue organization that is not provided by exogenous ligand.

Cell micromotion may have a significant role to play in cancer metastasis, which is a complex process that includes changes in cell adhesion, allowing cancer cells to invade and migrate through the ECM. Some of these changes occur in focal adhesions that are formed due to ECM-integrin interaction when cells attach to the ECM. Cell motility is dependent on cell-substrate attachment at the leading edge of the cell coordinated with cell-substrate detachment at the rear of the cell. The attachment in the leading edge of the cell is associated with the formation of focal adhesion complexes, whereas detachment at the rear of the cell is associated with the disassembly of focal adhesion complexes and the proteolytic cleavage of the proteins that make up the focal adhesion complexes (23).

Since in HCT116 cells, growth factors EGF and TGF-{alpha} enhance integrin {alpha}2 expression irrespective of mitogenecity, integrin {alpha}2 may play a role in metastatic behavior. This observation is consistent with reports indicating a relationship between integrin-mediated cell adhesion and motility on CNIV that is controlled by ECM density, integrin expression, and integrin affinity (41, 42, 43, 44). Since integrin {alpha}2 is a receptor for CNIV, which is the major component of the basement membrane, this integrin may enhance metastasis and invasiveness. Thus, constitutive enhancement of motility by autocrine growth factors via ERK/MAPK signaling in malignant cells may be an important contributory factor to invasive and metastatic properties exhibited by HCT116 cells.


    FOOTNOTES
 
* This work was supported in part by National Institutes of Health Grants CA 54807, 34432, and 50457 and by the Shelby Rae Tengg Foundation. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

{ddagger} To whom correspondence may be addressed. E-mail: rajinder.sawhney{at}roswellpark.org. § To whom correspondence may be addressed. Dept. of Pharmacology & Therapeutics, Roswell Park Cancer Institute, Elm and Carlton Sts., Buffalo, NY 14263. Tel.: 716-845-3044; Fax: 716-845-8857; E-mail: michael.brattain{at}roswellpark.org.

1 The abbreviations used are: EGFr, epidermal growth factor receptor; EGF, epidermal growth factor; CN IV, collagen IV; ECM, extracellular matrix; ERK, extracellular signal-regulated kinase; Ab, antibody; mAb, monoclonal antibody; MAPK, mitogen-activated protein kinase; MEK, mitogen-activated protein kinase kinase; PBS, phosphate-buffered saline; PI3K, phosphatidylinositol 3-kinase; TGF-{alpha}, transforming growth factor-{alpha}; MTT, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide; BSA, bovine serum albumin; ECIS, electrical cell impedance sensor; PD098059, 2-(2'-amino-3'-methoxyphenyl)oxanaphthalen-4-one; U0126, 1,4-diamino-2,3-dicyano-1,4-bis(2-aminophenylthio)butadiene; LY 294002, 2-(4-morpholinyl)-8-phenyl-4H-1-benzopyran-4-one. Back


    ACKNOWLEDGMENTS
 
We thank Dr. Charles Keese and Dr. Ivar Giaever for providing the ECIS facility.



    REFERENCES
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 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
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