Tissue Inhibitor of Metalloproteinases-2 (TIMP-2) Suppresses TKR-Growth Factor Signaling Independent of Metalloproteinase Inhibition*

Susan E. Hoegy, Hae-Ryong Oh, Marta L. CorcoranDagger, and William G. Stetler-Stevenson§

From the Extracellular Matrix Pathology Section, Laboratory of Pathology, Division of Clinical Sciences, NCI, National Institutes of Health, Bethesda, Maryland 20892-1500

Received for publication, September 6, 2000, and in revised form, October 16, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The tissue inhibitors of metalloproteinases (TIMPs) block matrix metalloproteinase (MMP)-mediated increases in cell proliferation, migration, and invasion that are associated with extracellular matrix (ECM) turnover. Here we demonstrate a direct role for TIMP-2 in regulating tyrosine kinase-type growth factor receptor activation. We show that TIMP-2 suppresses the mitogenic response to tyrosine kinase-type receptor growth factors in a fashion that is independent of MMP inhibition. The TIMP-2 suppression of mitogenesis is reversed by the adenylate cyclase inhibitor SQ22536, and implicates cAMP as the second messenger in these effects. TIMP-2 neither altered the release of transforming growth factor alpha  from the cell surface, nor epidermal growth factor (EGF) binding to the cognate receptor, EGFR. TIMP-2 binds to the surface of A549 cells in a specific and saturable fashion (Kd = 147 pM), that is not competed by the synthetic MMP inhibitor BB-94 and is independent of MT-1-MMP. TIMP-2 induces a decrease in phosphorylation of EGFR and a concomitant reduction in Grb-2 association. TIMP-2 prevents SH2-protein-tyrosine phosphatase-1 (SHP-1) dissociation from immunoprecipitable EGFR complex and a selective increase in total SHP-1 activity. These studies represent a new functional paradigm for TIMP-2 in which TIMP suppresses EGF-mediated mitogenic signaling by short-circuiting EGFR activation.



    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In mature normal tissues, the structure and composition of the extracellular matrix (ECM)1 functions to maintain tissue homeostasis and cellular quiescence. These anti-proliferative and differentiation promoting effects of the ECM are attributable both to its composition and three-dimensional spatial organization, as well as the presence of soluble growth inhibitors, such as TGF-beta (1-4). Compelling evidence for these effects also comes from transgenic animal studies in which altered ECM expression or organization, disruption of ECM attachments, or proteolytic modification of ECM integrity results in altered developmental and disease-related phenotypes (5-7). The matrix metalloproteinases (MMPs) are a major determinant of ECM turnover in tissue morphogenesis. Altered expression of MMP activity is associated with a variety of pathologic conditions, including tumor progression and cancer invasion (5-8).

In addition to disrupting the structural organization of the ECM, MMP proteolysis of ECM can result in release and/or activation of sequestered growth factors (1, 3). In addition, MMP activity may expose cryptic sites in the ECM or directly modify cell surface receptors or ligands involved in both cell-matrix, as well as cell-cell adhesion (1, 3, 9). The endogenous metalloproteinase inhibitors, tissue inhibitors of MMPs (TIMPs), negatively regulate the proteolytic activity of MMPs during ECM turnover. Reduction or ablation of TIMP gene expression results in enhanced ECM proteolysis concomitant with up-regulation of cell invasive activity of nontransformed differentiated cells (10, 11). In comparison, TIMP overexpression results in decreased invasion of endothelial and tumor cells both in vitro and in vivo (12, 13). Recent transgenic animal studies have demonstrated that alteration of the MMP/TIMP balance in vivo in favor of TIMP-1 activity can block neoplastic proliferation in the SV40 T antigen-induced model of murine hepatocellular carcinoma (14). The mechanism of this TIMP-1 effect was mediated by direct inhibition of MMP processing of insulin-like growth factor-binding protein-3 (IGFBP-3), thereby preventing the release of insulin-like growth factor II and thus suppressing mitogenic activity. These and other studies demonstrate that, through inhibition of MMP activity and prevention of ECM turnover, TIMPs can suppress cell proliferation, invasion and reduce metastasis formation, i.e. TIMPs act as tumor suppressors. As a result of such studies, targeting MMP activity with synthetic MMP inhibitors has become an attractive strategy for therapeutic intervention in cancer progression (15). However, recent studies suggest that TIMPs may also directly modulate cell growth in an MMP-independent fashion, although many of these studies lack detailed mechanistic insight (16-20). Thus, in addition to their action as inhibitors of metalloproteinases, it is important to investigate whether TIMPs function to directly modulate cell growth and the potential mechanisms for these effects.

Epidermal growth factor receptor (EGFR) is highly expressed in human cancers and is detectable at low levels in many normal tissues (21). Overexpression of EGFR has been observed in a variety of human tumors, and EGF-related growth factors play a role in human cancer growth through autocrine and paracrine mechanisms (22). Overexpression of EGFR (23) or structural alterations in the receptor protein, such as truncation of the cytoplasmic domain, may elicit ligand-independent signaling and autonomous cell growth (24). Ligand binding to EGFR initiates receptor dimerization, autophosphorylation of tyrosyl residues on the cytoplasmic domain of EGFR, and subsequently Src-mediated activation of the extracellular signal-regulated kinase mitogen-activated protein (MAP) kinase pathway (25). Mitogenic signaling of the EGFR seems to critically depend on activation of the extracellular signal-regulated kinase/mitogen-activated kinase cascade.

Here we study the role of TIMP-2 in the regulation of cell growth in response to tyrosine kinase-type receptor (TKR) growth factor stimulation. In addition to soluble ligand binding, membrane-anchored ligands can also stimulate TKR-mediated mitogenic responses at high cell densities or following proteolytic processing from the cell surface. Examples are the membrane-anchored EGFR ligands, which include heparin-bound epidermal growth factor, amphiregulin, transforming growth factor-alpha (TGF-alpha ), and betacellulin, which are shed from the plasma membrane by proteolytic cleavage resulting in autocrine activation of the receptor (26, 27). Synthetic metalloproteinase inhibitors, such as BB-94 (Batimastat), reduce cell proliferation in the human mammary epithelial cell line 184A1 by blocking TGF-alpha release (26). BB94 also inhibits EGFR trans-activation by G-protein-coupled receptors that occurs via a metalloproteinase directed cleavage of pro-heparin-bound EGF (27). These findings suggest that the metalloproteinase inhibitors prevent the release of membrane-anchored EGFR ligands (e.g. TGF-alpha , pro-heparin-bound EGF), thereby inhibiting autocrine activation of the receptor protein (26). However, if soluble ligands that do not require metalloproteinase processing (e.g. EGF) are present, BB-94 did not inhibit the mitogenic response in these experiments (26). Thus we have focused our experiments on TIMP inhibition of cellular responses to soluble mitogenic factors, in particular EGF.

We have examined the direct modulation of TKR growth factor-stimulated proliferation of human, A549 lung carcinoma, MCF7 mammary carcinoma, HT1080 fibrosarcoma, and Hs68 dermal fibroblast cells using both wild type TIMP-2 (wt-TIMP-2) and a null-inhibitor form of TIMP-2, Ala+TIMP-2. Both forms of TIMP-2 abrogate the TKR-mediated mitogenic responses in these cells. We also investigated the mechanism of the diminished mitogenic response following TIMP-2 pretreatment prior to growth factor stimulation. The results demonstrate that these suppressive effects are mediated by disruption of TKR activation proximal to the extracellular signal-regulated kinase pathway. To our knowledge this is the first demonstration that TIMP-2 can directly suppress activation of a mitogenic response through suppression of TKR activation in an MMP-independent fashion.


    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Reagents-- Recombinant human EGF, PDGF, and bFGF were obtained from R&D Systems, Minneapolis, MN. The following commercially available antibodies were obtained: human anti-EGFR, clone 528, mouse, monoclonal IgG2a (Santa Cruz Biotechnology, Santa Cruz, CA); human anti-phosphotyrosine, clone PY-20, mouse IgG2b, monoclonal, (Transduction Labs, Lexington, KY); human anti-MT-1-MMP, clone 113-5B7 or 114-6G6 (catalytic), mouse, monoclonal (Chemicon International, Temecula, CA), human anti-Grb2, clone C-23, rabbit, polyclonal, (Santa Cruz, Santa Cruz, CA); human anti-SH-PTP1, clone C-19, rabbit, polyclonal (Santa Cruz Biotechnology); human anti-SH-PTP2, clone C-18, rabbit, polyclonal (Santa Cruz Biotechnology); mouse and rabbit IgG-horseradish peroxidase conjugate, (Santa Cruz); and goat anti-mouse IgG (H+L) (Kirkegaard & Perry, Gaithersburg, MD). MMP synthetic hydroxamate inhibitor, BB-94, was a gift from British Biotechnology, Ltd. (Oxford, United Kingdom). Adenylate cyclase inhibitor, SQ22536, and PKA inhibitor, H89 were purchased from Calbiochem (La Jolla, CA). The recombinant MT-1-MMP catalytic domain (150 units/mg) was purchased from Chemicon International and metalloproteinase activity was determined by the thiopeptolide assay as described previously (28). RIPA buffer consists of 50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 1% Nonidet P-40, 0.5% sodium deoxycholate, and 0.1% SDS.

The rTIMP-2 protein was expressed using a vaccinia virus expression system and purified as described (29). TIMP-2 was also expressed in Escherichia coli with the authentic sequence (wt) or with an alanine residue appended to the amino-terminal cysteine (Ala+TIMP-2) as described previously (28). TIMP-2 and Ala+TIMP-2 were purified by gel filtration in 4 M guanidine HCl, folded, and oxidized, and then purified by gel filtration under native conditions. Recombinant TIMP-1 was isolated from the conditioned medium of EPA-transfected Chinese hamster ovary cells (8/8 2G EPA2) (Genetics Institute, Cambridge, MA) as described (30), and then purified by high performance liquid chromatography gel permeation chromatography using 50 mM Tris-HCl, 150 mM NaCl, pH 7.5. All TIMP preparations were endotoxin tested using the Limulus amoebocyte lysis assay and found to contain less than 2 EU/mg of protein.

Cell Culture Conditions-- Human lung adenocarcinoma cells (A549; ATCC CCL 185), human fibrosarcoma cells (HT1080; ATCC CCL 121), human breast adenocarcinoma (MCF7; ATCC HTB 22), and human dermal fibroblasts (Hs68; ATCC CRL 1635) were obtained from American Tissue Culture Collection (Manassas, VA). Cells were grown to 80% confluence in Dulbecco's modified Eagle's media (DMEM; Life Technologies Inc.) containing 4500 mg/liter of D-glucose, D-glutamine, sodium pyruvate, 100 units/ml penicillin-G, 100 µg/ml streptomycin sulfate, and 10% heat-inactivated fetal bovine serum, unless otherwise indicated. Cells were trypsinized using trypsin-EDTA (Life Technologies, Inc., Bethesda, MD).

Cell Growth Assays-- A549, Hs68, HT1080, and MCF7 cells were plated at 5 × 105 cells/well on a 96-well Costar plate for 18 h in DMEM with 10% fetal bovine serum. The cells were then starved for 18 h in DMEM without serum to synchronize cells in G1 (or G0) phase of the cell cycle. Fresh serum-free DMEM was added to the wells prior to treatment with TIMP-2. Cells were routinely incubated with TIMP-2 at the indicated concentrations for 30 min, followed by incubation in DMEM with or without EGF (100 ng/ml, R & D Systems), bFGF (50 ng/ml, R & D Systems), or PDGF (50 ng/ml, R & D Systems) and incubated for 24 h. TIMP-2 pretreatment could be reduced to 1 min prior to addition of growth factor without loss of an effect on growth factor stimulation. Following growth factor stimulation, the cells were incubated for 1 h with the CellTiter 96TM AQueous One Solution reagent (Promega, Madison, WI) containing 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfo-phenyl)-2H-tetrazolium, inner salt, and phenazine ethosulfate. The quantity of formazan product was determined by the 490 nm absorbance, and was directly proportional to the number of living cells in culture. The mean and S.D. for triplicate determinations were recorded for all incubation conditions.

Alternatively, the mitogenic response to growth factor stimulation with and without TIMP-2 pretreatment was quantitated by [3H]thymidine incorporation assays. Cells were synchronized in serum-free conditions and treated with TIMP-2 and growth factors as described above. Following growth factor treatment [3H]thymidine (0.1 µCi/ml; Amersham Pharmacia Biotech) was added and incubated for 2 h at 37 °C. The percentage of thymidine incorporated in a 2-h pulse correlated in a linear fashion with the cell number. The culture medium was subsequently discarded, the wells were washed twice with phosphate-buffered saline (PBS), and the cells were fixed in methanol:glacial acetic acid (3:1). The incorporated [3H]thymidine was extracted as described previously and quantitated by liquid scintillation counting (31). The mean and S.D. of triplicate assays were determined for all incubation conditions. SQ22536 or 9-(tetrahydro-2-furyl)adenine (Calbiochem/Novabiochem) was solubilized in sterile deionized H2O and added to cells at a final concentration of 100 µM (32). H-89 was dissolved in sterile, deionized H2O and added to give a final concentration of 0.1 µM (33).

The results of the growth assays are presented as the percentage of maximal growth factor response for the mitogen being tested after correcting for nonstimulated growth in basal medium. This allows comparison of the effects of TIMP-2 or Ala+TIMP-2 on the mitogenic response to various growth factors, as well as between cell lines.

Immunoprecipitation and Western Blotting-- HT1080, Hs68, A549, or MCF7 cells were grown in a 6-well Costar plate, pretreated with TIMP-2 or Ala+TIMP, followed by growth factors (described above). Following incubation with growth factor for 5 min, 37 °C, cells were washed with PBS and treated for 10 min at 4 °C with RIPA lysis buffer containing freshly added protease inhibitors (10 µg/ml aprotinin, 30 µg/ml 4-(2-aminoethyl)benzenesulfonyl fluoride, and 100 µM sodium orthovanadate). Cells were disrupted by repeated aspiration through a 21-gauge needle. Cell lysates were pre-cleared with normal mouse-IgG and Protein A/G (Pierce, Rockford, IL), and the supernatants were then incubated with anti-EGFR monoclonal antibodies (clone LA22, Upstate Biotech, Lake Placid, New York) at 4 °C, 1 h. Immune complexes were precipitated with Protein A/G-agarose and washed extensively with RIPA buffer, 4 °C. Immunoprecipitated EGFR was resolved by polyacrylamide gel electrophoresis and transferred to a polyvinylidene difluoride membrane (NOVEX, San Diego, CA) using a blotting apparatus (Bio-Rad). Tyrosine phosphorylation of the EGFR was visualized by incubating the membrane with anti-phosphotyrosine antibodies (primary), followed by anti-mouse IgG horseradish peroxidase antibodies (secondary), and detection using the ECL system (DuPont Renaissance, PerkinElmer Life Science, Boston, MA). Total EGFR (loading control) or Grb2 was visualized by incubating the membrane with stripping buffer (2% SDS, 62.5 mM Tris-HCl, pH 7.4, 100 mM beta -mercaptoethanol) for 2 h, 23 °C, followed by extensive washing (0.05% Tween 20 in PBS) and blocking (0.25% nonfat milk, 0.12% Tween 20, SSC). The membrane was incubated with anti-EGFR (primary), or anti-GRB-2 (primary) antibody, followed by horseradish peroxidase-conjugated secondary antibody and ECL development, as above.

125I-EGF Binding Assay-- A549 cell monolayers were washed with PBS, trypsinized off the tissue culture, and resuspended in DMEM to give a suspension of 1 × 106 cells/ml. Cells were equilibrated in DMEM containing 10% fetal calf serum for 1 h, 23 °C, followed by washing with PBS (3 times). TIMP-2, Ala+TIMP-2 ± EGF (unlabeled) was added to cell suspensions, in binding buffer (Amersham Pharmacia Biotech), followed by addition of 125I-EGF (100 µCi/ml, >75 Ci/mmol, Amersham Pharmacia Biotech) and incubated for 3 h, 4 °C. The cells were diluted in ice-cold binding buffer, collected by gentle centrifugation (<1000 × g), and washed three times with cold PBS. EGF bound to the A549 cells was determined by gamma  counting (cpm) on a Packard, Cobra auto-gamma -counter (Canberra Co., Downes Grove, IL).

Fluorescent Labeling and TIMP-2 Binding Assay-- TIMP-2 and Ala+TIMP-2 were labeled with BODIPY-Fl by addition of three molar equivalents (total) of BODIPY-Fl (Molecular Probes) in three batches over 2 h, 23 °C. This labeling reaction was protected from light by covering the reaction vessel with aluminum foil. The reaction was quenched by addition of 1.5 M Tris-HCl, pH 7.5, to give a final concentration of 50 mM Tris-HCl. The crude reaction mixture was then passed over a Superose 6 (Amersham Pharmacia Biotech) gel filtration column using 50 mM Tris-HCl, pH 7.5, 100 mM NaCl as eluate. The BODIPY-labeled TIMP-2 or Ala+TIMP-2 containing peaks were collected and the degree of labeling was calculated by determining the ratio of absorbance at 450 nm/280 nm. An optimum value between 0.3 and 0.7 was obtained for these labeling reactions.

Binding assays of BODIPY-labeled TIMP-2 to A549 and MCF7 cells were performed in triplicate as follows. Cells were grown to 80% confluence in DMEM containing 10% fetal calf serum, in white-walled, clear-bottom 96-well Costar plates. Cells were washed with PBS and pretreated to dissociate preformed ligand-receptor complexes with 3 M glycine buffer in 0.9% saline, pH 3.0, for 3 min. The cells were again washed in PBS prior to addition of TIMP-2-BODIPY in PBS containing 0.1% bovine serum albumin for 1 h, 37 °C. The supernatant was removed from cells and placed into empty wells for determination of unbound TIMP-2-BODIPY. Cell monolayers were washed three times with ice-cold (4 °C) PBS containing 0.1% bovine serum albumin. Amounts of bound TIMP-2-BODIPY were analyzed using a plate reader (PerkinElmer Life Sciences HTS7000), and measuring fluorescence from each well (lambda  excitation = 494 nm and lambda  emission = 520 nm). Specific binding was calculated as the difference between bound BODIPY-TIMP-2 in the presence or absence of excess (100-fold) unlabeled ligand. Scatchard analysis of TIMP-2 binding was performed as previously reported (35).

Confocal Fluorescent Microscopy-- A549 and MCF7 cells were plated at a range of 1-3 × 105 cells/ml in a Lab-Tek chambered glass slide (Nalgene). The growth medium was discarded and cells were washed with PBS. Nonspecific binding was blocked using 1 mg/ml bovine serum albumin (fatty acid-free), for 1 h. Cell were washed with PBS 3 times and incubated with BODIPY-labeled TIMP-2 or Ala+TIMP-2, for 30 min, 37 °C. Following incubation with BODIPY-labeled TIMP-2, the cells were washed with PBS 5 times and fixed in paraformaldehyde. For double staining experiments cells were first incubated with BODIPY-labeled TIMP-2, washed, and fixed as described above. These cells were then incubated with the appropriate primary antibody for 1 h, followed by washing with PBS, prior to incubation with secondary rhodamine-conjugated antibody for 45 min, 23 °C. Following this secondary antibody incubation the cells were washed three times with PBS and fixed as before. Two drops of Vectashield Mounting Medium (Vector Laboratories, Burlingame, CA) containing DAPI (for nuclear counter staining) were added prior to coverslipping. Cell associated BODIPY-labeled TIMP-2 or Ala+TIMP-2, as well as anti-MT-1-MMP antibody staining was localized using confocal laser microscopy. All preparations were examined with a Leica confocal microscope, model TCS4D/DMIRBE, equipped with argon and argon-krypton lasers. Cells were originally photographed at × 80 magnification.

Protein-tyrosine Phosphatase Assays-- Protein-tyrosine phosphatase activities were assayed following immunoprecipitation of either SHP-1 (clone C-19, Santa Cruz Biotechnology) or SHP-2 (clone N-16, Santa Cruz Biotechnology) utilizing selective antibodies. Phosphotyrosine phosphatase activity of the immunoprecipitates was measured as the amount of phosphotyrosine content remaining after addition of known amounts of phosphotyrosine-containing peptide substrates, (Roche Molecular Biochemicals). Hs68 or A549 cells were plated on 75-cm2 Nunc flasks (2 × 106/flask). Cells were preincubated with TIMP-2, followed by stimulation with growth factor (described above). Cells were harvested in lysis buffer containing 10 mM MOPS, pH 6, 5 mM EDTA, 10% glycerol, 1% Triton X-100, 10 mM NaF, 25 mM glycerol phosphate, 10 µg/ml 4-(2-aminoethyl)benzenesulfonyl fluoride, and 30 µg/ml aprotinin at 4 °C for 10 min. The relative protein concentrations were determined using the BCA assay (Pierce). Equal amount of protein (200 µg) were immunoprecipitated with anti-SHP-1 or SHP-2 antibodies (Transduction Labs) at 4 °C for 1 h, followed by incubation with anti-mouse agarose beads (Cappel) for 1 h. The beads were subsequently washed 3 times with lysis buffer (without orthovanadate), and 3 times with phosphatase assay buffer. The immunoprecipitates were resuspended in assay buffer and the reaction initiated by addition of phosphotyrosine peptides (Roche Molecular Biochemicals). The optical densities were measured at 405 nm. Data was normalized to blank assay values and plotted as relative OD units of phosphotyrosine. Enhanced phosphatase activity is represented by a decrease in phosphotyrosine levels.


    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

TIMP-2 Suppresses Tyrosine Kinase Growth Factor-stimulated Cell Proliferation-- Previous reports have shown that TIMP-2 and Ala+TIMP-2 can stimulate the growth of quiescent (serum starved) cells in culture (28, 34). However, this system does not represent a physiologic setting in which multiple stimuli, both positive and negative, are integrated to determine the cellular response. The effects of TIMP-2 on the mitogenic response to TKR growth factors in several cells lines, including Hs68, HT1080, A549, and MCF7 cells were examined in vitro. Treatment of these quiescent cells with a variety of TKR growth factors, including EGF, bFGF, and PDGF, results in approximately a 2-fold stimulation of cell growth. A representative example of this growth stimulation is presented in the inset in Fig. 1A. Preincubation of quiescent A549, HT1080, HS68, or MCF7 cells with increasing TIMP-2 concentrations followed by addition of a TKR growth factor, such as EGF, results in dose-dependent inhibition of the mitogenic response (Fig. 1A). Preincubation of cells with TIMP-2, prior to addition of growth factor, was routinely performed for 30 min at 37 °C, but identical effects were obtained with preincubation periods as short as 1 min, as previously reported (28). This suppressive effect on growth factor stimulation was not observed if TIMP-2 was added concurrent with EGF stimulation or after treatment of the cells with EGF (data not shown).



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Fig. 1.   TIMP-2 and Ala+TIMP-2 inhibit EGF, bFGF, and PDGF-induced proliferation of A549, HT1080, Hs68, and MCF7 cells. A, A549, MCF7, or HT1080 cells were seeded onto gelatin (10 µg/ml)-coated 96-well plates and were serum starved to quiescence, followed by treatment with TIMP-2 (0-200 nM) for 30 min, stimulated with EGF (200 ng/ml), and incubated for 24 h. Proliferation of viable cells was determined by the change in absorbance at 490 nm on reduction of 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium salt or [3H]thymidine incorporation. Results shown are the percentage of maximum proliferation obtained by stimulation of cells with EGF alone (100%), after correction for basal rate of proliferation in serum-free conditions. Each data point represents the average ± S.D. of six determinations. B, A549 and Hs68 cells were treated with ±Ala+TIMP-2 (50 nM) for 30 min, followed by stimulation with various growth factors (*GF) (bFGF (50 ng/ml with 1.13 units/mg of heparin), EGF (200 ng/ml), PDGF (50 ng/ml)), or with TIMP-2 (50 nM) alone (absence of growth factors or serum). C, A549 and Hs68 cells were treated with Ala+TIMP-2 (0-50 nM), followed by stimulation with EGF (200 ng/ml).

The observed effects of TIMP-2 on mitogenic response are not specific for A549 cells. The effects of TIMP-2 on the EGF-stimulated responses of HT1080 human fibrosarcoma and MCF7 human mammary carcinoma cells are essentially identical to those observed with the A549 cells (Fig. 1A). TIMP-2 maximally inhibited (student t test, p < 0.01) the mitogenic response in all cell lines tested to 50-60% of the level achieved following EGF stimulation alone (Fig. 1A). Similarly, TIMP-2 reduced the mitogenic response to bFGF and PDGF in these cell lines (data not shown). The effects of TIMP-2 on the mitogenic responses were observed at low nanomolar concentrations (<10 nM) with the maximal suppression of growth factor-mediated proliferation obtained at 20-50 nM TIMP-2.

TIMP-2 Effect on Mitogenic Response Is Not Dependent on MMP Inhibition-- To determine whether the effect of TIMP-2 on growth factor mitogenic response in these cells was dependent on inhibition of MMP activity, we examined the effect of other MMP inhibitors on the mitogenic response. We utilized the endogenous MMP-inhibitor, TIMP-1, a synthetic MMP inhibitor (BB-94, Batimastat), and Ala+TIMP-2, a form of TIMP-2 that lacks MMP inhibitor activity. Neither TIMP-1 nor the synthetic hydroxamate inhibitor, BB-94, demonstrated any modulating effects on mitogenic stimulation in any of the cell lines tested (data not shown, see below). However, Ala+TIMP-2 was effective at inhibiting the proliferative response stimulated by EGF, bFGF, and PDGF treatment of A549 and Hs68 cells (Fig. 1). Pretreatment with 50 nM Ala+TIMP-2 prior to exposure to bFGF or PDGF suppressed the growth factor-mediated mitogenic response of Hs68 and A549 cells (Fig. 1B). Ala+TIMP-2 suppressed cell growth to the levels observed with TIMP-2 stimulation alone, without addition of growth factors (Fig. 1B). The suppressive effect of Ala+TIMP-2 also demonstrated a dose dependence (Fig. 1C), however, Ala+TIMP-2 suppressed the mitogenic response to lower levels than those achieved with TIMP-2.

TIMP-2 Inhibition of Growth Factor Response Requires Adenylate Cyclase Activity-- We previously reported that the mitogenic effects of TIMP-2 on quiescent Hs68 or HT1080 cell proliferation were dependent on activation of a heterotrimeric G protein, and a subsequent increase in cytosolic cAMP (34). In the present study, we examined the effects of an adenylate cyclase inhibitor (SQ22536) on TIMP-2 suppression of EGF-stimulated cell proliferation. Pretreatment of A549 cells with SQ22536 (100 µM), followed by TIMP-2 (50 nM) and then EGF, ablated the suppressive effect of TIMP-2, and restored the EGF-stimulated mitogenesis to levels observed in the absence of TIMP-2 (Fig. 2). In addition, the suppressive effects of TIMP-2 on mitogenesis were mimicked in these cells by use of nonhydrolyzable cAMP analogues, such as dibutryl-cAMP or Sp-cAMP (100 µM). Treatment of cells with cAMP analogues prior to stimulation with EGF suppressed the proliferative response in these cells to similar levels as observed with TIMP-2 or Ala+TIMP-2 (data not shown). These results are identical to our previous study (28) on the effect of TIMP-2 on the growth of serum-starved quiescent fibroblasts and suggest that G protein activation and stimulation of adenylate cyclase are common mechanisms for both effects.



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Fig. 2.   Adenylate cyclase inhibitor (SQ22536) abrogates the suppressive effects of TIMP-2 on EGF-stimulated A549 growth. Cells were pretreated with SQ22536 (100 µM) for 30 min, prior to treatment with TIMP-2 (100 nM) for 30 min, and stimulation with EGF (200 ng/ml), for 24 h. Preincubation with SQ22536 prior to addition of TIMP-2 results in proliferation levels comparable to EGF alone, i.e. reversing the suppressive effect of TIMP-2. SQ22536 did not alter the proliferation in response to EGF.

TIMP-2 Does Not Compete for EGF Binding but Binds to the Cell Membrane Independent of MT-1-MMP-- The mechanisms of the TIMP-2 mediated effects on stimulated mitogenesis were examined using A549 cells. Among possible mechanisms for the observed effects of TIMP-2 on cell growth are the inhibition of protease-mediated release of cell surface-bound EGF ligands or competition and displacement of exogenous EGF from its cognate receptor. An alternative possibility is the direct binding of TIMP-2 to the cell surface and activation of adenylate cyclase activity required for inhibition of growth factor stimulation.

The effect of TIMP-2 on shedding of TGF-alpha from the surface of A549 cells was examined by enzyme-linked immunosorbent assay measurement of TGF-alpha released from A549 cells. Incubation of A549 cells with 10-100 nM TIMP-2 resulted in no detectable decrease in soluble TGF-alpha concentration (<2.5 pg/ml). Whereas addition of 1-10 nM active gelatinase-A (MMP-2) resulted in an increase in soluble TGF-alpha (>8 pg/ml) released from A549 cells. Thus, TIMP-2 did not mediate growth suppressive effects by interfering with MMP-dependent proteolytic cleavage of membrane-anchored EGF ligands.

Next, we examined the effects of TIMP-2 on cell surface binding of EGF. Experiments with 125I-EGF showed that TIMP-2 does not directly compete with EGF binding to the EGFR (Fig. 3). Incubation of A549 cells with TIMP-2 or Ala+TIMP-2 (100 nM), followed by addition of 125I-EGF (0.2 nM), did not interfere with the binding of 125I-EGF to the EGFR protein. 25I-EGF binding was competed by addition of nonlabeled EGF, as expected (Student's t test, p < 0.01). Addition of TIMP-2 or Ala+TIMP-2 did not alter the competition of EGF for 125I-EGF bound to EGFR (Fig. 3). These results definitively demonstrate that TIMP-2 or Ala+TIMP-2 do not alter the mitogenic response in the cells tested by interfering with the binding of EGF to its cognate receptor.



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Fig. 3.   TIMP-2 and Ala+TIMP-2 do not compete for 125I-EGF ligand binding to EGFR. A549 cells were treated with 0.2 nM 125I-EGF and ± unlabeled EGF (500 nM), ± TIMP-2 (100 nM), or ± Ala+ TIMP-2 (100 nM), allowed to bind to cells for 90 min. After washing, the cell amount of bound 125I-EGF was measured in a gamma -counter. Each bar graph represents six individual determinations ± S.D. Treatment with unlabeled EGF provided a statistically significant (Student's t test, p < 0.001) reduction in binding, compared with control. Treatment with TIMP-2 and Ala+TIMP-2 alone, or in the presence of excess unlabeled EGF did not have a statistically significant effect on the binding of 125I-EGF to EGFR on the surface of A549 cells.

The direct binding of TIMP-2 to the surface of A549 and MCF7 cells was quantified by use of a direct, fluorescent binding assay. Previous reports from several laboratories have shown that TIMP-2 can bind to the membrane-type matrix metalloproteinase-1 (MT-1-MMP) (8, 35-38). This interaction is mediated predominately through interaction of the NH2-terminal inhibitory domain of TIMP-2 with the catalytic active site of MT-1-MMP. In our study of TIMP-2 binding to the surface of A549 cells we have utilized both TIMP-2 and the null inhibitor form Ala+TIMP-2. Data shown in Fig. 4A demonstrate that Ala+TIMP-2 does not inhibit the ability of MT-1-MMP to degrade synthetic peptide substrate, compared with the potent inhibitory activity of TIMP-2. These results are similar to our previous report that TIMP-2 inhibits MMP-2 activity, while Ala+TIMP-2 does not (28).



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Fig. 4.   TIMP-2 and Ala+TIMP-2 activity against MT-1-MMP catalytic domain and cell binding experiments. A, measurement of Ala+TIMP-2 suppressive activity against MT-1-MMP. TIMP-2 and Ala+TIMP-2 inhibition of MT-1-MMP activity were determined using the thiopeptolide assays as described previously (28). These assays were performed in 50 mM MOPS, 150 mM NaCl, 1 mM CaCl2, and 1 mM 5,5'-dithiobis-(2-nitrobenzoic acid) at pH 7.0. Concentrations of the catalytic domain of MT-1-MMP and thiopeptolide were 20 nM and 50 µM, respectively. TIMP-2 effectively inhibits MT-1-MMP activity, but Ala+TIMP-2 does not, as indicated by no decrease in Vi over the range of added Ala+TIMP-2 concentrations. B, measurement of Kd and number of receptors per cell was determined for TIMP-2-BODIPY binding to A549 cells by a 96-well plate binding assay. A549 cells were seeded onto 96-well plates and treated with TIMP-2-BODIPY (0-100 nM) for 30 min, 37 °C. Supernatant was transferred to new wells and measured as the amount of unbound TIMP-2-BODIPY. Cells were washed with PBS and the amount of TIMP-2-BODIPY was measured as the amount of fluorescence remaining on the A549 cell surface. Concentration of bound TIMP-2-BODIPY was determined with a standard curve (TIMP-2-BODIPY concentration versus fluorescence units) and plotted against Bound/Free, to give the resulting Scatchard plot. Scatchard analysis was performed as described previously (35). Unlabeled TIMP-2 was added to cells to determine specific binding from total and nonspecific binding. C, a 10-fold excess of Ala+TIMP-2 (unlabeled) was added to cells, resulting in a reduction of bound fluorescence (Student's t test, p < 0.01), whereas addition of BB94 (0.5 µM) did not result in any significant change. However, addition of 10 µg/ml anti-MT1-MMP (clone 114-6G6) resulted in a reduction in bound TIMP-2-BODIPY fluorescence (Student's t test, p < 0.05).

In the binding experiments, TIMP-2-BODIPY was added to a monolayer of cells, grown to 80-90% confluence, and the amount of bound (B) versus free (F) fluorescent TIMP-2-BODIPY was determined by quantitation of fluorescence (Fig. 4B). The concentration dependence of BODIPY-TIMP-2 binding was determined at each concentration in six replicate measurements in the presence (nonspecific binding) and absence (total binding) of unlabeled TIMP-2. The data were plotted as the amount of bound TIMP-2-BODIPY versus bound/free for Scatchard analysis (Fig. 4B). TIMP-2 bound to A549 cells in a specific and saturable fashion with a subnanomolar dissociation constant, Kd = 147 pM, and 115,00 receptors per cell. For comparative purposes the binding parameters for BODIPY-TIMP-2 interaction with MCF7 cells was also determined. For these cells the dissociation constant was low nanomolar Kd = 1.90 nM with 38,000 sites per cell. The data for TIMP-2 binding to MCF7 cells was in excellent agreement with data previously published by others (36, 38, 39), as well as our own laboratory (35), using 125I-TIMP-2 for determination of cell binding parameters. These findings suggest that our fluorescent-based method for determination of TIMP-2 binding was comparable in sensitivity and specificity to methods described previously.

The addition of a 10-fold excess of unlabeled Ala+TIMP-2 to A549 cells treated with TIMP-2-BODIPY leads to a statistically significant (Student's t test, p < 0.001) reduction in binding of TIMP-2 to the cell surface. Ala+TIMP-2 competition results in a 65% decrease in BODIPY-TIMP-2 binding to A549 cells suggesting that it competes for binding to most, but not all, TIMP-2-binding sites (Fig. 4B). In contrast, addition of a broad spectrum, hydroxamate MMP inhibitor, BB-94 (0.5 µM), did not significantly compete for binding of BODIPY-TIMP-2 to the cell surface (Fig. 4B). This failure of BB-94 to compete with TIMP-2 cell surface binding was in contrast to the effects of synthetic hydroxamate MMP inhibitors which have been shown to inhibit the binding of TIMP-2 to MT-1-MMP (36, 38). Western blot analysis of A549 cell membranes demonstrated that these cells have low but detectable levels of MT-1-MMP compared with well characterized cell lines such as HT1080 (data not shown). However, addition of an MT1-MMP antibody, specific for the catalytic domain, maximally reduced the binding of TIMP-2 to cells by 35% (Fig. 4B). Together these data suggest that TIMP-2 binds to the cell surface and that this interaction may consist of at least two binding sites, an interpretation consistent with the Scatchard analysis shown in Fig. 4A, as well as previous reports (36).

Confocal, laser fluorescent microscopy was utilized to examine the localization of TIMP-2 on the cell surface and colocalization with MT-1-MMP. Confocal fluorescent microscopy demonstrated fluorescent-labeled (BODIPY) TIMP-2 or Ala+TIMP-2 bound to the surface of A549 cells (Fig. 5A). Analysis of Nemarsky optic images of A549 cells with or without TIMP-2 or Ala+TIMP-2 treatment revealed no significant morphologic changes following short term (30 min) exposure to TIMP-2 (Fig. 5, A, top and middle left panels; B, top two panels). Fluorescence localization of BODIPY-TIMP-2 or Ala+TIMP-2 demonstrates a linear, punctate pattern consistent with cell surface localization (Fig. 5, A, lower panels, B, second panels from top). xz-axis analysis of the confocal images (Fig. 5A, bottom panel) confirms that TIMP-2 binding occurs on the surface of A549 cells. By fluorescent antibody staining the cells with rhodamine anti-MT-1-MMP antibody complexes, the majority of TIMP-2 binds to the surface of A549 cells independent of MT1-MMP localization (Fig. 5B, bottom panel right, and arrowheads). A minor component of the TIMP-2 on the cell surface colocalized with MT-1-MMP (Fig. 5B, bottom panel, and arrows). The MT-1-MMP colocalization was markedly less apparent when the binding of Ala+TIMP-2 was examined (Fig. 5B, bottom panel, left). Ala+TIMP-2 colocalization with MT1-MMP (Fig. 5, bottom panel, left, and arrows) was reduced compared with that observed with wtTIMP-2 (Fig. 5, bottom panel, right, and arrows). These findings are consistent with our in vitro observations that the Ala+TIMP-2 mutant does not inhibit MT-1-MMP activity (Fig. 4A) (i.e. Ala+TIMP-2 does not bind to the MT-1-MMP active site).



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Fig. 5.   TIMP-2 and Ala+TIMP-2 binding to A549 cell surface proteins and co-localization with MT-1-MMP. A, A549 cells were treated with 3 M glycine, 0.9% NaCl, pH 3, to dissociate complexes, washed with PBS, blocked with 1% bovine serum albumin, and treated with Ala+TIMP-2-BODIPY (100 nM) for 30 min, fixed with paraformaldehyde and stained for 4,6-diamidino-2-phenylindole. Ala+TIMP-2 cell surface binding is shown in green, and nuclei are shown in blue. B, cells were treated with TIMP-2 or Ala+TIMP-2 (100 nM) and incubated with anti-MT1-MMP antibody (clone 113-5B7), followed by IgG-tetramethylrhodamine B isothiocyanate. MT1-MMP is shown in red and areas of colocalization with TIMP-2 appears yellow (white arrows). Although some colocalization with MT-1-MMP was observed, TIMP-2 binding without MT-1-MMP was readily apparent (arrowheads). The TIMP-2 cell surface localization-independent of MT-1-MMP was even more apparent when BODIPY-Ala+TIMP-2 was utilized in these experiments (arrowheads, lower left panel).

TIMP-2 Disrupts EGFR Phosphorylation and Grb-2 Association-- From these studies so far, we have shown that TIMP-2 suppresses EGF mitogenisis without the requirement for MMP inhibition. TIMP-2 binds to the plasma membrane thereby activating an adenylate cyclase signaling pathway. This binding is independent of MT1-MMP, and does not compete for EGF ligand binding to the EGFR. These findings suggest that the effect of TIMP-2 on mitogenic stimulation should be rapid and proximal in the EGF signaling pathway. To further study the mechanism of TIMP-2 effects on the mitogenic response, we have examined the activation status of the EGFR receptor (phosphorylation status, Grb-2 association), as well as phosphatase activity that influences the state of EGFR activation.

Ligand binding induced activation of the EGFR initiates autophosphorylation of the receptor on the cytoplasmic, SH2 domain. The amount of phosphorylated EGFR was measured by Western blot analysis of EGFR immunoprecipitates prepared from equivalent numbers of A549 lung adenocarcinoma or HT1080 fibrosarcoma cells. The total quantity of immunoprecipitable EGFR did not change in response to treatment with TIMP-2 or Ala+TIMP-2 and therefore served as a loading control for these experiments (Fig. 6A, lower gel panel). This finding also demonstrates that the effect of TIMP-2 or Ala+TIMP-2 occurs in the absence and/or prior to any change in the level of EGFR on the cell surface (i.e. EGFR internalization and/or turnover). TIMP-2 pretreatment prior to EGF stimulation of HT1080 cells results in a dose-dependent decrease in EGFR-associated tyrosine phosphorylation (Fig. 6A). At the highest concentration of TIMP-2 tested (200 nM) in these experiments, the level of EGFR phosphorylation approached that of basal levels under serum-free conditions. It should be noted that under basal conditions the level of EGFR phosphorylation in these HT1080 cells was low but significantly increased (greater than 10-fold) following EGF stimulation of cell growth. TIMP-2 and Ala+TIMP-2 also showed a dose-dependent inhibition of EGFR phosphorylation in MCF7 and A549 cells stimulated with EGF (data not shown). Inhibition of EGFR tyrosine phosphorylation was not observed following treatment with BB-94, or TIMP-1 prior to stimulation with EGF (Fig. 6B). This finding supports the conclusion that TIMP-2 exhibits an early and immediate effect on EGFR activation by a mechanism independent of MMP-inhibition.



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Fig. 6.   TIMP-2 reduces tyrosyl phosphorylation of EGFR and association of Grb-2 protein with EGFR. A, HT1080 cells were serum-starved to quiescence, followed by treatment with TIMP-2 (0-200 nM) for 30 min, and EGF (200 ng/ml) for 5 min. Cells were lysed with RIPA buffer, EGFR immunoprecipitates were prepared, and PVDF membranes were probed with phosphotyrosine (PY-20) antibody or EGFR antibody. Bands of interest were integrated for mean pixel density using NIH Image. Data is presented as the percentage of maximum phosphorylated EGFR, as from EGF treatment alone (100%). Amount of EGFR did not change with increasing TIMP-2 concentration, and was therefore used as an internal loading control. B, A549 cells were treated with BB94 (0.5 µM), TIMP-1 (100 nM), TIMP-2 (100 nM), or Ala+TIMP-2 (100 nM), and amounts of phosphorylated EGFR were determined by Western blot. Each data point represents the average of three determinations ± S.D. C, quiescent, serum-starved MCF7 cells were treated with TIMP-2 (100 nM) followed by stimulation with EGF, and EGFR immunoprecipitates were prepared as before. PVDF membranes of EGFR immunoprecipitates were probed for Grb-2 antibody. Treatment of cells with EGF enhanced the mean density of Grb-2 bound to EGFR, whereas TIMP-2 treatment resulted in a statistically significant reduction (Student's t test, p < 0.01) in Grb-2 association.

We also examined the effects of an adenylate cyclase inhibitor, SQ22536, on phosphorylation of EGFR tyrosyl residues. Preincubation of A549 cells with SQ22536 (100 µM), followed by TIMP-2 (100 nM), and then stimulation with EGF, blocks the TIMP-2 suppressive effects on EGFR phosphorylation (data not shown). When cells were preincubated with SQ22536, the amount of phosphorylated EGFR remains similar to levels obtained with EGF stimulation alone. Thus, the effect of TIMP-2 on EGFR phosphorylation, like the growth suppressive effect reported in Fig. 2 depends on activation of adenylate cyclase.

Following ligand-induced dimerization and autophosphorylation of EGFR, there is specific recruitment of Grb-2 to phosphorylated EGFR (40). Therefore, we determined the level of Grb-2 associated with EGFR to confirm the effects of TIMP-2 on EGFR phosphorylation. Cells were pretreated with TIMP-2 or Ala+TIMP-2 for 30 min, followed by incubation with EGF for 5 min at 37 °C. Cells were lysed using RIPA buffer and EGFR immunoprecipitates were prepared as before. The amount of 25-kDa Grb-2 bound to EGFR was determined by Western blot for anti-Grb-2, of EGFR immunoprecipitates. Addition of exogenous TIMP-2 prior to EGF stimulation of MCF7 cells results in a decreased association of Grb-2 with EGFR (Fig. 6C). The decrease in amount of Grb-2 associated with EGFR correlated with the decreased EGFR phosphorylation observed following TIMP-2 pretreatment. The results demonstrate that TIMP-2 and Ala+TIMP-2 pretreatment results in a rapid (within 5 min of EGF treatment) reduction in EGFR phosphorylation, that in turn results in decreased Grb-2 association with EGFR.

Role of PKA in TIMP-2 Effects on TKR-stimulated Proliferation and EGFR Phosphorylation-- Pretreatment of A549 cells with the PKA inhibitor, H89 (0.1 µM), prior to EGF stimulation results in a 60% reduction of the mitogenic response that is unchanged by the addition of TIMP-2 prior to EGF stimulation (Fig. 7A). Although H89 did not appear to reverse the suppressive effect of TIMP-2 on EGF-stimulated growth, the reduction in the EGF-induced mitogenic response by H89 alone prevents exclusion of a role for PKA in mediating the TIMP-2 suppression of EGF stimulated growth.



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Fig. 7.   Inhibition of PKA activity reduces EGF-stimulated proliferation of A549 cells and only partially reverses TIMP-2 reduction of EGFR phosphorylation. A, cells were pretreated with H-89 (0.1 µM) for 30 min, prior to treatment with TIMP-2 (100 nM) for 30 min, and stimulation with EGF (200 ng/ml), for 24 h, 37 °C. Proliferation was measured as described under "Experimental Procedures." B, serum-starved A549 cells were treated ± H89 (0.1 µM) for 30 min, followed by ± TIMP-2 (50 nM), 30 min, and then EGF (200 ng/ml), 5 min EGFR immunoprecipitates were prepared as described in the legend to Fig. 6. Each data point represents the average of three replicate measurements ± S.D.

H89 was also used to investigate the possible role of PKA in the TIMP-2 reduction in EGFR phosphorylation observed following EGF stimulation. The direct serine phosphorylation of the EGFR receptor by PKA catalytic subunit reportedly results in down-regulation of EGFR mitogenic signaling (41). We speculated that if PKA is required for the TIMP-2 down-regulation of EGFR tyrosine phosphorylation, that H89 would reverse the effect of TIMP-2 in reducing EGFR phosphorylation. Fig. 7B presents the results of these experiments. The data showed that the effects of H89 on reversal of TIMP-2 reduction in EGFR phosphorylation are at best only partial. The data from the two experiments on cell proliferation and EGFR phosphorylation using the PKA inhibitor H89 do not definitively demonstrate a clear-cut requirement for PKA activity in the growth suppressive effects of TIMP-2. However, the data suggest that an alternative pathway that is not dependent on PKA activation may also function to mediate the effects of TIMP-2 on cell growth and EGFR phosphorylation.

TIMP-2 Induces SH2 Protein Phosphatase-1 (SH-PTP1) Activity and Association with EGFR-- The level of phosphorylation of activated growth factor receptors with endogenous tyrosine kinase activity depends upon the net result of both tyrosine specific autophosphorylation and rapid dephosphorylation by phosphotyrosine phosphatases (PTPs). Receptor dephosphorylation attenuates signaling downstream from the activated receptor. The SH2-domain containing PTPs (SH2-PTPs) have been shown to interact with multiple growth factor receptors, including EGFR (42-44). Generally, SHP-1 (also known as SH2-PTP-1 and PTP-1C) negatively regulates receptor signaling, while SHP-2 (also known as SH2-PTP-1 and PTP-1D) reportedly enhances positive signaling, although negative modulation of receptor signaling by SHP-2 has also been reported (42-44).

In this experiment, we determined if SHP-1 or SHP-2 was bound to EGFR by immunoprecipitation of the EGFR complex by Western blot. The effects of TIMP-2 on PTP association with this receptor complex were examined. Cells (A549 or HT1080) were preincubated with and without TIMP-2 (100 nM), and stimulated with EGF as above. Analysis of SH2-PTPs associated with EGFR immunoprecipitates demonstrates that, compared with EGF treatment alone, TIMP-2 pretreatment preserves the association of SHP-1 with EGFR immunoprecipitates to levels that are essentially identical with those observed in the basal state. The levels of SHP-1 associated with EGFR complexes were inversely correlated with the level of EGFR phosphorylation previously observed (Figs. 6A, and 8, A and B). In contrast, the association of SHP-2 with EGFR complex remains unchanged following either TIMP-2 pretreatment or EGF stimulation of cells (Fig. 8, A and B). We also assayed total cytoplasmic SHP-1 and SHP-2 activity utilizing an in vitro tyrosine phosphatase assay following selective immunoprecipitation of total SHP-1 and SHP-2. The results of these experiments demonstrate a significant (Student's t test, p < 0.01) increase in total SHP-1 activity in cells pretreated with TIMP-2 prior to EGF stimulation (Fig. 8C, decrease in optical density for phosphotyrosine staining reflects enhanced phosphotyrosine activity). No increase in SHP-2 activity was observed following TIMP-2 preincubation. In fact, EGF stimulation alone results in a significant induction of SHP-2 activity and a slight inhibition of SHP-2 activity was noted following TIMP-2 pretreatment (Fig. 8C). These results demonstrate that TIMP-2 supression of EGFR activation was mediated, at least in part, through persistent association of SHP-1 with EGFR and a selective increase total SHP-1 activity.



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Fig. 8.   TIMP-2 enhances binding of SH2 protein-tyrosine phosphatase-1 (SH-PTP1), but not phosphatase-2 (SH-PTP2) to EGFR. A, A549 cells were serum starved to quiescence and treated with TIMP-2 (100 nM) followed by EGF (200 ng/ml) for 5 min. EGFR immunoprecipitates were prepared, and polyvinylidene difluoride membranes were probed for SH-PTP1 or SH-PTP2. B, treatment of cells with EGF reduced SH-PTP1 association, but TIMP-2 restored levels to that seen without EGF stimulation. Amounts of SH-PTP2 were not significantly altered on treatment with EGF or TIMP-2. C, cells were plated on 75-cm2 Nunc flasks 2 × 106 cells per flask and following attachment were incubated in serum-free DMEM for 2 h then in serum-free DMEM for an additional 24 h. TIMP-2 (24 nM) was preincubated for 5 min prior to a 10-min stimulation with growth factor (EGF, 100 ng/ml). The cells were harvested in lysing buffer containing vanadate. Equal amounts of protein from the lysates (200 µg) were immunoprecipitated with anti-SHP-1 or SHP-2 antibodies (Transduction Labs) at 4 °C for 60 min followed by 60 min incubation with anti-mouse agarose beads (Cappel). The beads were subsequently washed three times in lysing buffer without orthovanadate and 3 times more with phoshatase assay buffer. These immunoprecipitates were resuspended in assay buffer, transferred to 96-well plates, and the reaction initiated by adding a phosphotyrosine peptide. After 10 min at 30 °C, the reaction was stopped by addition of 100 µM orthrovanadate. The relative levels of phosphatase activity in these immunprecipitates was determined utilizing a phosphopeptide by enzyme-linked immunosorbent assay as described by manufacturer's instruction (Roche Molecular Biochemicals). Enzyme-linked immunosorbent assay results were determined in a Molecular Devices microplate reader. A decrease in optical density is indicative of enhanced phosphatase activity against the phosphopeptide containing substrate.



    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The tissue microenvironment is known to exert a profound influence on cell proliferation and differentiation (45-47). Cell fate is the net result of cellular integration of multiple signals derived from soluble factors and adhesive interactions present in the microenvironment (48-50). Evidence for the influence of this integrative process on cell behavior is derived from studies using reconstituted ECM, as well as alteration in the expression of cell adhesion molecules, or the introduction of proteases to disrupt the structure and/or composition of the microenvironment (3, 6, 46, 49). ECM turnover is a critical event in development, morphogenesis, and tissue remodeling (3, 6, 46, 49). Enhanced MMP activity results in altered neonatal development and progression of pathologic conditions (6, 49). Vis à vis their ability to inhibit MMP activity, TIMPs can suppress ECM turnover associated with either embryonic development or pathologic conditions (2, 9, 51), resulting indirectly in suppression of cell growth and/or direct inhibition of cellular invasion initiated by ECM remodeling (12-14, 52).

However, studies demonstrate that TIMPs also directly alter in vitro cell growth and/or survival of a variety of cell types (16, 17, 18, 19, 31, 34, 53-57). These effects are independent of TIMP-mediated MMP inhibitory activity. TIMP-3 overexpression induces apoptosis (58, 59), an effect variably reproduced by synthetic MMP inhibitors and possibly related to stabilization of TNF-alpha receptors or inhibition of TNF-alpha converting enzyme (60).

In the present report we examine how TIMP-2 induction of intracellular signaling is integrated with TKR growth factor induction of mitogenic signals. TIMP-2 abrogates the mitogenic response of a variety of cell types to several different TKR-type growth factors. The TIMP-2 inhibition of growth factor-stimulated mitogenesis occurs in a concentration range identical to that observed for the maximal effect on stimulation of growth in quiescent, dermal fibroblasts (28, 34). These TIMP-2 concentrations are only slightly lower than reported for the growth suppressive effect of TIMP-2 on bFGF-stimulated endothelial cells (31). Mitogenic stimulation of various cell lines at subnanomolar concentrations of TIMPs has also been reported (19, 53, 55). The differences in effective TIMP-2 concentrations between these reports are possibly due to variation in the innate sensitivity of the cell lines tested, or, alternatively, different TIMP preparations may have altered potency or contaminants (e.g. endotoxin). All of the TIMP-2 preparations in this study are known to be free of significant endotoxin contamination (see "Experimental Procedures"). It is also possible that differences in the levels of active MMPs produced by the cell lines may influence responsiveness to the growth modulating activity of TIMP-2. This is because high concentrations of available MMP active sites could sequester TIMP-2 and prevent it from binding to the cell surface.

The suppressive effect of TIMP-2 on growth factor-stimulated mitogenesis is specific and independent of MMP inhibition. No effects on stimulated cell growth are observed with TIMP-1 or BB-94. Ala+TIMP-2, lacking MMP inhibitor activity, remains active in abrogating the TKR-stimulated response. No evidence of cell death or apoptosis was observed in these experiments, and the cells remained viable following exposure to TIMP-2 or Ala+TIMP-2 alone. In fact, TIMP-2 or Ala+TIMP-2 treatment without growth factor stimulation reproduces the modest mitogenic stimulation of quiescent cells as previously reported (28, 34). Ala+TIMP-2 shows a somewhat more potent effect on inhibiting EGF-stimulated growth compared with the wild type protein. This is specific for EGF-stimulated growth and is not observed with the other growth factors utilized in this study. Possible explanations for this observation include intrinsic differences in the growth factor-specific responses and/or greater availability of Ala+TIMP-2, which did not bind effectively to the MT-1-MMP active sites (see below).

TIMP-2 regulation of TKR-induced mitogenesis occurs immediately downstream of receptor-ligand interaction during receptor activation. Previous reports demonstrate that metalloproteinases contribute to shedding of EGFR ligands, such as TGF-alpha , as well as EGFR (61). TIMP-2 treatment did not alter EGFR levels, compete for EGF binding to EGFR, or alter TGF-alpha release. These findings are again consistent with TIMP-2 growth modulation that is independent of inhibition of MMP activity required for either ligand or receptor processing.

TIMP-2 binds directly to the cell surface (19, 34, 36, 55). However, the identification of cell surface binding proteins for TIMP-2 is complicated by the presence of MT-MMPs. These integral membrane proteins contain a transmembrane domain and catalytic site that is oriented toward the ECM (8, 37). Binding of TIMP-2 to MT-1-MMP involves interaction of the NH2-terminal of TIMP-2 with the catalytic site of MT-1-MMP (38), and is reportedly sensitive to synthetic, hydroxamate MMP inhibitor (36). Our in vitro analysis confirms that Ala+TIMP-2 does not inhibit MT-1-MMP activity, as we have previously reported for MMP-2 (28). This finding suggests that Ala+TIMP-2 will not bind to the MT-1-MMP catalytic site on the cell surface.

We demonstrate specific and saturable binding of TIMP-2 and Ala+TIMP-2 to the surface of A549 and MCF7 cells. Cell surface binding of TIMP-2 to A549 cells was not competed by TIMP-1 or BB-94. Anti-MT-1-MMP catalytic domain antibodies reduce TIMP-2 binding by only 35%, compared with the 65% reduction following addition of excess unlabeled Ala+TIMP-2. In fluorescence confocal microscopy experiments, minor colocalization of TIMP-2 and MT-1-MMP in A549 cells is observed, but is essentially absent when Ala+TIMP-2 and MT-1-MMP are visualized. Collectively our studies on TIMP-2 binding and fluorescence co-localization confirm the presence of a high affinity, TIMP-2-binding site on A549 cells that is independent of MT-1-MMP. This is a principal binding site for TIMP-2 in A549 cells that is specifically competed by Ala+TIMP-2, but is not blocked by synthetic hydroxamate MMP inhibitors nor anti-MT-1-MMP antibody. The presence of such sites has been suggested in previous studies that demonstrated TIMP-2 binding in the presence of synthetic MMP inhibitor (36), but such sites have remained poorly characterized. From these studies we conclude that TIMP-2 binds to the cell surface and this interaction may consist of at least two binding sites, one MT-1-MMP independent, as well as a MT-1-MMP site. This interpretation is consistent with Scatchard analysis, as well as previous reports of multiple TIMP-2-binding sites (36). TIMP-2 binding to the MT-1-MMP-independent, high affinity site presumably results in activation of adenylate cyclase that is required for TIMP-2 inhibition of TKR-stimulated cell growth. TIMP-2 binding results in heterotrimeric G protein activation and an increase in cytosolic cAMP level (34).

Activation of downstream signaling cascades by TKR(s) is dependent on the net level of receptor phosphorylation. Net phosphorylation is dependent on the level of autophosphorylation induced by ligand binding and the level of associated protein-tyrosine phosphatase activity (62, 63). Cells treated with TIMP-2 or Ala+TIMP-2, prior to EGF, down-regulate the level of EGFR autophosphorylation in a dose-dependent fashion. This effect is again specific for TIMP-2 and is not observed with synthetic, hydroxamate MMP inhibitor, BB94, or TIMP-1. Furthermore, the decrease in EGFR phosphorylation is confirmed by a concomitant decrease in Grb-2 association with EGFR. This effect of TIMP-2 on EGFR autophosphorylation is dependent upon adenylate cyclase activity, but is not completely reversed by the PKA inhibitor, H89. The lack of PKA inhibitor to reverse the TIMP-2 effect on cell growth or EGFR phosphorylation is in contrast to the direct role of PKA in TIMP-2 mitogenic stimulation of quiescent cells previously reported (34). Also, the positive effect of TIMP-2 on the growth of quiescent cells is reversed at higher TIMP-2 concentrations, this is not observed in the TIMP-2 suppression of stimulated growth or EGFR down-regulation (34). These differences suggest that, although similar in requirement for adenylate cyclase activity, these actions of TIMP-2 are mechanistically distinct from one another. Direct phosphorylation of EGFR by the serine kinase activity of PKA is observed in vitro with purified, recombinant catalytic subunit of PKA and in cells following administration of cAMP analogues (41). The failure of H89 to completely reverse TIMP-2-mediated reduction in EGFR phosphorylation is consistent with a TIMP-2 action that is immediately downstream to receptor-ligand interaction and TKR activation. To our knowledge this is the first demonstration that TIMP-2 directly interferes with receptor signal transduction at the level of TKR phosphorylation.

Activated, TKR(s) are rapidly dephosphorylated resulting in down-regulation of their signaling activity (62, 63). The SH2-PTPs are known to interact with multiple receptor systems, including the erythropoietin receptor and interleukin-3 receptor in hematopoietic cells, as well as the EGFR and vascular endothelial growth factor (VEGF) receptor (Flt, KDR) in epithelial and endothelial cells, respectively (42-44). The SH2-PTP, SHP-1, is involved in receptor dephosphorylation and negative regulation of receptor signaling. SHP-2 has little effect on receptor phosphorylation and positively mediates receptor signaling via mechanisms that are not well understood. The direct interaction of SHP-1 with the EGFR receptor has been demonstrated in vitro (42-44). The catalytic domain of SHP-1 is important for EGFR dephosphorylation and cannot be substituted by the catalytic domain in SHP-2 (43). It is not known if SHP-1 displays selectivity with respect to dephosphorylation of individual phosphotyrosine residues on EGFR (43). Also, EGFR dephosphorylation does not absolutely correlate with SHP-1 binding (43). This has been interpreted to suggest that the SHP-1 active site may be sterically hindered with respect to some phosphotyrosine sites on EGFR, and/or not all SHP-1 activity is directly bound to EGFR in vivo. SHP-1 may also associate with the EGFR complex via an intermediary docking protein.

In our experiments TIMP-2 prevents dissociation and/or promotes association of SHP-1 with the EGFR complex in a fashion that correlates with the decrease in EGFR phosphorylation. These findings are confirmed by direct measurement of phosphatase activity in SHP-1 and SHP-2 immunoprecipitates prepared from whole cell lysates. Comparison of the results of SHP-1 levels associated with EGFR in the basal and TIMP-2-treated cells with the direct assay of SHP-1 activity is consistent with previous reports that suggest not all SHP-1 activity is bound to EGFR (43). Alternatively there may be a selective increase in the specific activity of the SHP-1 associated with EGFR following TIMP-2 treatment. The observed increase in SHP-2 activity with EGF treatment is consistent with the reported positive modulation of EGFR signaling reported for this PTP (44). Our findings are consistent with previous reports demonstrating that SHP-1 can negatively modulate EGFR activation and prevent downstream signal propagation from this receptor (43, 44). Also, TIMP-2 may induce a selective increase in SHP-1 activity that is not directly bound to EGFR, but may require some auxiliary docking protein that is as yet unidentified. Little is known about regulation of SHP-1 levels or activity, but one report does suggest that a cAMP-regulated pathway involving phosphorylation of SHP-1 may function to regulate this activity (64).

In summary, TIMP-2 suppresses the mitogenic response to TKR growth factor stimulation. TIMP-2 binds to the surface of A549 cells independently of MT-1-MMP. TIMP-2 binding to the cell surface results in activation of adenylate cyclase and increased cAMP levels in the cytosol, presumably secondary to receptor-mediated activation of the GTP-binding protein Galpha s. TIMP-2 modulates the phosphorylation of the EGFR following growth factor stimulation and this effect is mediated by SHP-1. These effects of TIMP-2 on the mitogenic response are observed with several different growth factors (EGF, bFGF, and PDGF) and in multiple cell types (including neoplastic cells as well as dermal fibroblasts). Based on these findings, we propose TIMP-2 functions to suppress inappropriate growth factor stimulation of cells in G1/G0 phase of the cell cycle, as well as to inhibit MMP-mediated ECM turnover. Consistent with our observation that TIMP-2 needs to be available prior to growth factor stimulation, and the proximal inhibition or down-regulation of EGFR activation (phosphorylation), TIMP-2 must function during early G1 prior to entry in the restriction point late in G1. Both this G1 regulator-type and protease inhibitor functions of TIMP promote tissue homeostasis. The G1 regulator-type function may be a feedback mechanism that informs cells that MMP-mediated remodeling of the ECM is complete. In this proposal TIMP-2 would not function to suppress mitogenesis until ECM remodeling is shutdown by inhibition of MMP activity. Saturation of available MMP active sites in the remodeling matrix and/or on the cell surface would block ECM turnover, only then would excess free TIMP-2 begin to suppress cell responsiveness to residual growth factor stimulation. Our proposal is consistent with the recent finding that timp-2-deficient mice display no abnormalities in fertility or development (65, 66). As a G1 cell cycle phase regulator, one would expect that TIMP-2 would be a nonessential gene and that elimination from the germ line would not necessarily result in disruption of fetal development (67). The results of the present study demonstrate that TIMP-2 is multifunctional in suppressing growth factor stimulation, modulating MT-1-MMP activation of pro-MMP-2, in addition to the well established role of MMP inhibition, which prevents ECM remodeling. The growth suppression and MMP inhibitor functions both act to preserve tissue homeostasis. The control and integration of these TIMP-2 functions is poorly understood and warrants further investigation.


    ACKNOWLEDGEMENTS

We thank Dr. Larry Wahl for the Lumulus amoebocyte lysis (LAL) analysis, as well as Drs. Kazuyo Takeda and Zu-Xi Yu for technical support and assistance with the confocal mircoscopy. We also thank Drs. Liliana Gudez and David Roberts for helpful discussions.


    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger Current address: IGEN International Inc., 16020 Industrial Dr., Gaithersburg, MD 20877.

§ To whom correspondence should be addressed: Laboratory of Pathology, Div. of Clinical Sciences, NCI, National Institutes of Health, Bldg. 10, Room 2A33, MSC 1500, Bethesda, MD 20892-1500. Tel.: 301-496-2687; Fax: 301-402-2628; E-mail: sstevenw@mail.nih.gov.

Published, JBC Papers in Press, October 19, 2000, DOI 10.1074/jbc.M008157200


    ABBREVIATIONS

The abbreviations used are: ECM, extracellular matrix; TIMP, tissue inhibitor of matrix metalloproteinases; MMP, matrix metalloproteinase; Ala+TIMP-2, amino-terminal alanine appended TIMP-2; TKR, tyrosine kinase-type receptor; bFGF, basic fibroblast growth factor; EGF, epidermal growth factor; EGFR, epidermal growth factor receptor; TGF-alpha , transforming growth factor alpha ; PDGF, platelet-derived growth factor; ERK, extracellular regulated kinase; PTP, protein-tyrosine phosphatase; DMEM, Dulbecco's modified Eagle's medium; PBS, phosphate-buffered saline solution; MT-1-MMP, membrane-type matrix metalloproteinase-1; MOPS, 4-morpholinepropanesulfonic acid.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES


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