Potato Carboxypeptidase Inhibitor, a T-knot Protein, Is an Epidermal Growth Factor Antagonist That Inhibits Tumor Cell Growth*

Carmen Blanco-AparicioDagger §, Miguel Angel MolinaDagger §, Ester Fernández-SalasDagger , Marsha L. Frazier, José M. Masparallel , Enrique Querolparallel , Francesc X. Avilésparallel **, and Rafael de LlorensDagger

From the Dagger  Unitat de Bioquímica, Departament de Biologia, Facultat de Ciències, Universitat de Girona 17071, Spain, the  Department of Gastrointestinal Medical Oncology and Digestive Diseases, The University of Texas M. D. Anderson Cancer Center, Houston, Texas 77030, and the parallel  Institut de Biologia Fonamental and Departament de Bioquímica i Biologia Molecular, Universitat Autònoma de Barcelona, Bellaterra, 08193 Barcelona, Spain

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

Epidermal growth factor (EGF) and its receptor (EGFR) are involved in many aspects of the development of carcinomas, including tumor cell growth, vascularization, invasiveness, and metastasis. Because EGFR has been found to be overexpressed in many tumors of epithelial origin, it is a potential target for antitumor therapy. Here we report that potato carboxypeptidase inhibitor (PCI), a 39-amino acid protease inhibitor with three disulfide bridges, is an antagonist of human EGF. It competed with EGF for binding to EGFR and inhibited EGFR activation and cell proliferation induced by this growth factor. PCI suppressed the growth of several human pancreatic adenocarcinoma cell lines, both in vitro and in nude mice. PCI has a special disulfide scaffold called a T-knot that is also present in several growth factors including EGF and transforming growth factor alpha . PCI shows structural similarities with these factors, a fact that can explain the antagonistic effect of the former. This is the first reported example of an antagonistic analogue of human EGF.

    INTRODUCTION
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Abstract
Introduction
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Results
Discussion
References

In multicellular organisms peptide factors regulate a variety of cell functions and processes including cell proliferation (1). Epidermal growth factor (EGF)1 is a competence peptide factor that can induce the cells to advance into the G1 phase and is required for differentiation of epidermal tissues (1, 2). It is produced by many normal tissues and is present in serum. Both EGF and transforming growth factor alpha (TGF-alpha ), a growth factor highly homologous to EGF, bind to EGF receptor (EGFR or ErbB-1) (3, 4) and produce similar biological responses. Binding of EGF to EGFR induces receptor dimerization (5) and leads to receptor activation and tyrosine transphosphorylation (6). Ligand-receptor complexes are quickly internalized via coated pits and either recycled or subjected to lysosomal degradation (7).

Most human cancers arise in the epithelial component of organs including the skin, breast, lung, and gastrointestinal and genitourinary tracts. Alterations in growth factor signaling pathways during epithelial neoplasia are common and therefore may be important in the development and maintenance of the neoplastic phenotype (8). EGF, TGF-alpha , and their receptor, EGFR, seem to play a particularly prominent role in epithelial neoplasia (9, 10), and they have been implicated in processes such as tumor cell growth, vascularization, invasiveness, and metastasis (8, 11-13). In many tumors of epithelial origin (carcinomas), EGFR has been found to be overexpressed, and in some cases an autocrine loop involving TGF-alpha has been reported (2, 14). The importance of an autocrine loop activation involving TGF-alpha was first described in pancreatic cancer (15), which has a very poor prognosis. EGFR activation is involved in the genesis and progression of pancreatic neoplasia (16, 17). The increased levels of EGF, TGF-alpha , and EGFR produced by pancreatic tumors may provide tumor cells with a distinct growth advantage that contributes to the clinical aggressiveness of this malignancy.

Given the importance of EGFR in carcinomas, disruption of the activation of EGFR appears to be an excellent target for cancer therapy (2, 13, 18). Cancer cells seem to have lost the normal redundancy in signal transduction pathways and so are preferentially vulnerable to signal interceptors. EGFR activation can be disrupted in several ways, including with EGF antagonists (19), with tyrosine kinase inhibitors (13), and with antibodies directed against the EGFR (20). These three strategies have had various success ratios. Development of EGF/TGF-alpha antagonists by using short synthetic fragments of both growth factors has not been successful (19). The tyrosine kinase inhibitors have been shown to inhibit the development of tumors in animal models but have toxic side effects (13). In contrast, the use of antibodies seems to have some efficiency as antitumor treatment and it is being tested in clinical trials.

In the study presented here, we show that potato carboxypeptidase inhibitor (PCI), a proteinaceous protease inhibitor, is an antagonist of human EGF with antitumor properties. Some protease inhibitors have been reported to serve as cancer-chemopreventive agents, because they can substantially suppress radiation- and chemical-induced malignant transformation in vitro and have strong anticarcinogenic activity in vivo (21-23). However, the mechanisms responsible for this activity are unknown.

PCI is a 39-amino acid protein naturally occurring in potatoes that can form complexes with several metallo-carboxypeptidases, inhibiting them in a strong competitive way with a Ki in the nanomolar range (24). We have developed a procedure to obtain the inhibitor in a recombinant form in Escherichia coli (25-27). Its structure is known in aqueous solution (28) and in crystal complex with carboxypeptidase A (29). The 27-residue globular core of PCI is stabilized by three disulfide bridges. Residues 35-39 form a C-terminal tail that docks on the carboxypeptidase A active center. PCI contains a small cysteine-rich module, called a T-knot scaffold, that is shared by several different protein families, including the EGF family (30-32).

We report here that PCI is an antagonistic analogue of human EGF, the first one described. PCI bound to EGFR and inhibited its activation by EGF. The structural similarities of PCI with this and other growth factors probably account for its properties as EGF antagonist. In addition, PCI inhibited the growth of human pancreatic cell lines and tumors transplanted in nude mice. Our results indicate that these antitumor properties are probably a result of the EGF antagonistic activity of PCI.

    EXPERIMENTAL PROCEDURES
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Materials-- Human recombinant EGF was purchased from R & D Systems (Abingdon, UK), 125I-labeled EGF from ICN (Costa Mesa, CA), human recombinant insulin was from Boehringer Mannheim (Mannheim, Germany), monoclonal antibody against EGFR (clone EGFRI) was from Amersham Pharmacia Biotech (Little Chafont, UK), recombinant anti-phosphotyrosine antibody (RC20) was from Transduction Laboratories (Lexington, KY), protein molecular weight standards were from Bio-Rad (Hercules, CA), and the EZ4U reduction assay kit was from Biomedica Corp. (Vienna, Austria). All other chemicals were purchased from Merck (Darmstadt, Germany) or Sigma Chemical Co. (St. Louis, MO).

PCI was obtained as a recombinant protein. The construction of a synthetic gene for PCI, its expression in E. coli, and a procedure to detect, quantify, and purify recombinant PCI secreted into the culture medium have been previously reported (25-27).

Routine Cell Culture-- Capan-1, Panc-1, A431, and HIT were obtained from the American Type Culture Collection (Rockville, MD). Capan-1, A431, and HIT cells were grown in DMEM supplemented with 10% FBS, 2 mM glutamine, and 20 µg/ml gentamicine unless otherwise indicated. Panc-1 cells were grown in RPMI 1640 supplemented with 10% FBS, 2 mM glutamine, and 20 µg/ml gentamicine.

Cell Proliferation Assays and Growth Curves-- The inhibitory effects of PCI on cell growth were determined with a proliferative assay. To measure proliferation in medium with serum, Capan-1, Panc-1, and HIT tumor cells were seeded at a density of 5 × 103/well in 96-well plates in medium containing 10% FBS. PCI was immediately added at concentrations of 0.1-200 µg/ml. The cells were fed every 4 days with medium containing fresh PCI. Control cells were grown without PCI. After 23 days (for Capan-1) or 10 days (for Panc-1 and HIT), the 2,3-bis(2-methoxi-4-nitro-5-sulfophenyl)-5-phenylaminocarbonyl-2H-tetrazolium-hydroxide (EZ4U) reduction assay was performed to estimate the number of cells according to the manufacturer's instructions.

To measure proliferation in serum free medium, Capan-1 cells were seeded at a density of 5-15 × 103/well in 96-well plates in the presence of DMEM supplemented with 10% FBS. After 72 h, the cells were washed with PBS twice, and serum-free medium (DMEM plus 0.1% of bovine serum albumin without FBS) was added. 24 h later, the serum-starved cells were washed twice with PBS and grown in serum-free medium supplemented with 5 ng/ml sodium selenite and 5 µg/ml transferrin with EGF (10 ng/ml), insulin (5 µg/ml), PCI (50 µg/ml), EGF (10 ng/ml), and PCI (50 µg/ml) or insulin (5 µg/ml) and PCI (50 µg/ml). After 72 h, Capan-1 cells were washed with PBS, and the EZ4U reduction assay was performed to determine the number of cells.

The growth curve of Capan-1 cells was obtained as follows. Capan-1 cells seeded at a density of 1 × 105/well in 6-well plates were treated with 0, 1, or 10 µg/ml PCI. The cells were fed every 4 days with fresh medium. Every day, three replicate wells for each treatment were washed once with PBS, the cells were detached with trypsin, and viable cells were counted by trypan blue dye exclusion.

To obtain the growth curve of Capan-1 cells pretreated with PCI, tumor cells were grown in presence of 50 µg/ml PCI for 3 weeks. The cells were fed every 4 days with medium containing fresh PCI and split 1:10 weekly. Control, untreated cells were grown simultaneously in absence of PCI. After 21 days, the cells were trypsinized, seeded at a density of 2 × 103/well in 96-well plates, and treated with 0, 1, or 50 µg/ml PCI. Control cells were grown in PCI-free medium. Every 3 days, 8 replicate wells for each treatment were submitted to the EZ4U reduction assay to estimate the number of cells.

Tumor Transplantation Experiments-- For injection into nude mice, Capan-1 cells were trypsinized and resuspended in DMEM. 6-week-old female Cd1 nude mice were each injected subcutaneously in the dorsal area with 1 × 107 cells in 0.1 ml of DMEM. 12 days after the injection, when the tumors had reached at least 2 mm in diameter, treatment was started. The tumors were injected daily with 11, 60, or 120 µg of PCI. Control mice were treated with PBS alone. Each group was composed of five mice. The tumors were measured weekly. After 32 days, the animals were killed by CO2 asphyxiation. Their tumor volumes were determined by using the formula [(width)2 × length]/2.

Cell Cycle Analysis-- Logarithmically growing Capan-1 cells were treated with 50 µg/ml PCI for 12 days in a 75-cm2 flask. Adherent cells were collected by trypsinization and combined with cells floating in the medium. After being washed with PBS, the cells were resuspended in 200 µl of PBS, and 2 ml of ethanol 70% at -20 °C was added. After 2 h of fixation, the cells were stained with propidium iodide (50 µg/ml), and RNase (20 µg/ml) was also added. Flow cytometry was performed by exciting the cells with a 488-nm laser (Becton Dickinson and Co., Rutherford, NJ).

PCI Internalization Assays-- RITC labeling of PCI was performed according to Billings et al. (21). The RITC-labeled PCI was used for fluorescence internalization assays. Cells were cultured in chamber slides (Nunc, Kamstrup, Denmark) in DMEM supplemented with 10% serum, and RITC-labeled PCI was added at a concentration of 20 µg/ml. After 30 min, the medium was removed, and the cell monolayers were washed with PBS, fixed with 1:1 methanol:acetic acid, and observed under a fluorescence microscope.

PCI uptake assays were performed by measuring the PCI concentration in Capan-1 culture medium for 24 h. In three separate experiments cells growing logarithmically in a 25-cm2 flask in DMEM supplemented with 10% FBS were treated with PCI at 10, 50, and 200 µg/ml. Samples of 20 µl of medium were taken every 30 min for 24 h. The concentration of PCI was determined by inhibition assays of carboxypeptidase A (24) and enzyme-linked immunosorbent assay using a rabbit polyclonal antibody raised against PCI. Medium without PCI was used as a reference.

Comparison of the Three-dimensional Structures of PCI and EGF-- We developed a computer program (Knot-Match)2 to superimpose the proteins by three-dimensional aligning of their disulfide bridges. The program clusters structures from Protein Data Base proteins by means of a density search algorithm. Molecular graphics and simulations were performed on a Power Indigo 2 from Silicon Graphics. The structures of PCI and growth factors were visualized with the TURBO FRODO program (33). The conformation of loops was analyzed by the Arch-Type program (34).

Ligand Binding Assays-- Capan-1 cells were seeded at a density of 1.25 × 105/well in 24-well plates in the presence of DMEM plus 10% FBS. After 48 h, the medium was replaced with DMEM without FBS. 24 h later, the cells were washed twice with ice-cold binding buffer (DMEM plus 20 mM HEPES, pH 7.5, and 0.3% (w/v) bovine serum albumin) and incubated for 4 h at 4 °C with binding buffer containing 350 pM 125I-labeled EGF and various concentrations of EGF or PCI. The cells were then washed rapidly three times with ice-cold PBS with 0.1% bovine serum albumin and solubilized by incubating them for 30 min at room temperature with 1 N NaOH with 0.1% SDS. The radioactivity in the suspension was determined with a gamma  counter (LKB, Uppsala, Sweden). Nonspecific binding was determined as the amount of radioactivity bound to cells incubated with a 100-fold molar excess of unlabeled EGF. The data were analyzed by computer fitting of one ligand with two binding sites.

Receptor Phosphorylation Analysis-- Receptor phosphorylation analyses of serum-starved cells were performed as follows. 50% confluent, serum-starved Capan-1 and A431 cells in 60-mm dishes were treated with various concentrations of PCI (in DMEM) for 10 min and immediately stimulated with EGF (5 ng/ml for Capan-1 and 1 ng/ml for A431 cells, also in DMEM) for 10 min. The cells were then lysed, and the EGFR was immunoprecipitated from cell extracts using equal amounts of proteins of each sample with anti-EGFR antibody EGFRI. The kinase activity of the immunoprecipitated receptor was measured by incubating it with [gamma -32P]ATP for 10 min (35). Samples were analyzed by SDS-polyacrylamide gel electrophoresis followed by autoradiography. The bands were quantified with a beta  counter. The level of tyrosine phosphorylation of the immunoprecipitated receptor was assessed by immunoblotting with anti-Tyr(P) antibody RC-20 (36). The blots were visualized by enhanced chemiluminiscence (Amersham Pharmacia Biotech) and then autoradiographed. The bands were quantified by densitometry.

For the receptor phosphorylation analyses of Capan-1 and A431 cells growing in DMEM plus 10% FBS, cells were treated with 10 ng/ml EGF or 50 µg/ml PCI. The kinase activity of the receptor was measured as described above.

Data Analysis-- Means ± S.E. are depicted unless indicated otherwise. Student's t test or analysis of variance for repeated measures was used for comparisons between data sets.

Covalent Cross-linking Experiments-- The cross-linking experiments were carried out as previously reported in Ref. 47. Briefly, cells of A431 human epidermal carcinoma line were lysed and homogenized. Samples were mixed with different concentrations of PCI alone and PCI plus EGF. Cross-linking was initiated by addition of glutaraldehyde. The samples were analyzed by SDS-polyacrylamide gel electrophoresis (5%), electrotransferred to polyvinylidene difluoride membranes, and immnunostained with antibodies against EGFR (ErbB-1). The presence of PCI was corroborated by immunostaining with rabbit antibodies against PCI on the same membrane.

    RESULTS
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Results
Discussion
References

Inhibition of Proliferation of Pancreatic Tumor Cell Lines by PCI-- To determine whether PCI could inhibit the growth of tumor cells, we tested its ability to affect the in vitro growth of two human pancreatic adenocarcinoma cell lines, Panc-1 and Capan-1, and the hamster insulinoma cell line HIT. Cells were cultured in medium supplemented with 10% fetal bovine serum. Concentrations of PCI greater than 10 µg/ml significantly inhibited growth, particularly for Capan-1 and HIT cells (Fig. 1A). The maximal effect was obtained at 50 µg/ml PCI; higher concentrations did not have stronger effects.


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Fig. 1.   Effects of PCI on the growth of pancreatic adenocarcinoma tumor cell lines. A, inhibition of Capan-1, Panc-1, and HIT proliferation by PCI. The number of cells was estimated after 10 days (for Panc-1 and HIT) or 23 days (for Capan-1). The values shown are means ± S.E. from 8 replicate wells for each treatment. An asterisk denotes significantly different from control (p < 0.001). B, effects of PCI on the growth curve of Capan-1 cells. The values shown are means ± S.E. C, effects of PCI pretreatment on the growth of Capan-1. Tumor cells were pretreated with 50 µg/ml PCI for 3 weeks. Then, the cells were trypsinized and seeded, and PCI was added at the indicated concentrations. The extent of cell proliferation was determined every 3 days by using the colorimetric EZ4U assay.

We subsequently obtained the growth curve of Capan-1 cells in the presence of 1 and 10 µg/ml PCI. There was a clear decrease in the growth rate of the cells in the presence of 10 µg/ml PCI (Fig. 1B). No significant differences were observed in the cells treated with 1 µg/ml PCI compared with controls.

Further studies were undertaken to assess the effect of protracted treatment with PCI on the proliferation of Capan-1 cells. The growth rate of the cells that had been pretreated with PCI for 3 weeks was significantly lower than that of Capan-1 control cells (Fig. 1C). The inhibitory effect was observed even when the pretreated cells were grown without PCI. These experiments demonstrated that PCI had a long lasting inhibitory effect on the growth of Capan-1 cells that was maintained even after PCI was removed from the culture medium.

Inhibition by PCI of Capan-1 Tumor Growth in Nude Mice-- We next determined whether PCI could also reduce the growth of solid tumors obtained by subcutaneous injection of Capan-1 cells into nude mice (Fig. 2). There was a significant reduction of the growth of the tumor transplantations at the three PCI doses tested. No toxic side effects were observed in any of the treated animals. Histological examination of the tumors showed no appreciable morphological differences between tumors from treated and control animals (data not shown), suggesting that the decreased size of tumors in treated animals was not due to cytotoxic effects or massive cellular death. That PCI could inhibit the growth of human pancreatic tumor cells is particularly important because the prognosis for pancreatic cancer is very poor and there are no effective treatments (37).


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Fig. 2.   Suppression by PCI of Capan-1 tumor growth in nude mice. Female Cd1 nude mice were injected subcutaneously in the dorsal area with 1 × 107 cells. Treatment was started 12 days after the injection. The tumors were injected daily with various doses of PCI dissolved in PBS. Control mice were treated with PBS alone. Each group was composed of five mice. The data are expressed as the final volume of the tumors (Vt) relative to their initial volume (Vo) and are the means ± S.E. The symbols above the bars denote significant difference from control values: #, p < 0.1; +, p < 0.025; &, p < 0.01; *, p < 0.001.

Effects of PCI on Cell Cycle Traversal-- To further characterize the effects of PCI on tumor cell growth, analyses of cell cycle phase distribution were performed with Capan-1 cells. Flow cytometry did not revealed any cell cycle changes in Capan-1 cells treated with 50 µg/ml PCI for up to 7 days compared with controls. No significant increase in the percentage of apoptotic cells was observed by flow cytometry, direct counting of apoptotic cells after nucleus staining, or agarose electrophoresis of nuclear DNA. However, after 12 days of treatment with PCI, a significant increase in the percentage of apoptotic cells (the sub-G0 population) was observed by flow cytometry (being the mean ± S.D. of 6.9 ± 0.9% for control and 10.5 ± 1.5% for treated cells). A small increase (65.2 ± 0.9% to 68.5 ± 2.9%) in the percentage of cells in the G0/G1 phase was also detected. These findings suggested that the increase in the percentage of apoptotic cells in presence of PCI could be one of the mechanisms responsible for the inhibitory effect of this protein on tumor cell growth.

Internalization of PCI by Capan-1 and Panc-1 Cells-- The results so far obtained led us to examine whether PCI was taken up by tumor cells. Using fluorescent labeling of PCI, we demonstrated that PCI was easily internalized by Capan-1 and Panc-1 cells. RITC-conjugated PCI was observed in the cytoplasm of the cells as early as 30 min after its addition to the culture medium of logarithmically growing cells. The fluorescence was located mainly around the nucleus (Fig. 3A).


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Fig. 3.   Uptake of PCI by logarithmically growing Capan-1 cells. A, cells grown for 30 min in the presence of RITC-labeled PCI viewed by fluorescence microscopy (magnification, 400×). B, PCI concentration in the medium of a Capan-1 culture. PCI was added at 50 µg/ml, and its concentration was followed for 24 h. Similar disappearance and reappearance cycles were observed in separate experiments using initial concentrations of 10 and 200 µg PCI/ml.

To better characterize the kinetics of the internalization of PCI by the cells, we measured the PCI concentration in the medium every 30 min for 24 h after its addition. Three separate experiments were performed using three different PCI initial concentrations. In all cases, PCI underwent several cycles of disappearance and reappearance (Fig. 3B). 24 h after its addition, PCI was purified from the medium and subjected to mass spectrometry analysis, which showed that the molecular mass of PCI remained unaltered. This finding was not surprising, because PCI has been reported to be very resistant to proteolytical degradation (38).

Computer Comparison of the Three-dimensional Structures of PCI and EGF-- PCI and several mammalian growth factors, omega -toxins, and other proteins share a cystine-knot scaffold, the so-called T-knot (30-32). To gain insight into the possible mechanisms responsible for the growth inhibitory effects of PCI, we compared the three-dimensional structures of PCI and other T-knot proteins by means of Knot-Match program.2 The program yielded several groups. One of these groups contained growth factors and other proteins such as PCI. The geometries of the disulfide bridges in PCI are very similar to those in EGF (Fig. 4), TGF-alpha , and heregulin (data not shown). In addition, the conformation of two PCI loops (residues 18-24 and particularly residues 27-34) and a stretch of PCI C-tail (residues 33-37) is very similar and can be superimposed with a good root mean square deviation with loops 14-20 and 22-29 and the C-terminal tail (42-46) of EGF. PCI loop 27-34 showed a root mean square deviation of 0.79 Å for backbone atoms with loop 22-29 of EGF. Moreover, some key functional positions in EGF related to receptor binding (19) turned out to be of similar character in PCI when the three-dimensional structures of both proteins were superimposed, based on disulfide bridges topology. Among them are Leu26, Tyr37, Arg41, and Leu47, which correspond to Ala31, Trp22, Lys10, and Val38 of PCI (Fig. 4).


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Fig. 4.   Superimposition of the three-dimensional structures of PCI and EGF by using the Knot-Match program. Upper left, ribbon representation of superimposed PCI (yellow) and EGF (white) backbones. Right, Van der Waals representation of the three-dimensional structures of PCI and EGF. The side chains of the residues that coincide after superimposition of the disulfide bridges of the two proteins are color-coded: brown, hydrophobic; cyan, basic; green, polar; purple, aromatic. Center, Van der Waals representation of the superimposition of the three-dimensional structures of PCI (yellow) and EGF (white) using the same color code as in the representations on the right. The table shows the residues that coincide after the superimposition.

The structural and conservative positional similarities between PCI and human EGF and TGF-alpha suggested that PCI could act as an EGF/TGF-alpha antagonist, competing with these growth factors for binding to EGFR and thus inhibiting its activation. This could be the mechanism for the suppressive effect of PCI on tumor cell growth, because EGFR stimulation by either EGF or TGF-alpha seems to be required for proliferation by a variety of tumor cell lines and carcinomas (13, 39, 40). We used several approaches to test the hypothesis that PCI is an EGF antagonist.

Suppression by PCI of the Stimulatory Effect of EGF on the Growth of Capan-1 Cells-- We performed experiments with serum-starved Capan-1 cells in presence of PCI, EGF, insulin, or PCI and growth factor simultaneously. Both growth factors had a stimulatory effect on cell growth that was stronger in the case of EGF. The presence of PCI completely abolished the EGF stimulation of cell proliferation but had no effect in the case of insulin-induced cell growth (Fig. 5).


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Fig. 5.   Suppression by PCI of the stimulatory effect of EGF on the growth of serum-starved Capan-1 cells. Cells were treated during 72 h with EGF (10 ng/ml), insulin (5 µg/ml), PCI (50 µg/ml), EGF and PCI, or EGF and insulin. The values shown are the means ± S.E. from 8 replicate wells for each treatment. Significant difference from control values are indicated: dagger , p < 0.05; *, p < 0.001. The results shown are a representative of three different experiments.

PCI Competition with EGF for Binding to EGFR-- Binding experiments using the Capan-1 cell line were performed. The binding of 125I-labeled EGF was measured in the presence of increasing concentrations of EGF (Fig. 6A). The data revealed that Capan-1 had high and low affinity receptors for EGF. For the former, the IC50 for EGF was 0.6 pM. We then measured the binding of 125I-EGF in presence of increasing concentrations of PCI (Fig. 6B). PCI competed with 125I-EGF for binding to the high and low affinity receptors. The IC50 of the high affinity receptors for PCI was 100 pM.


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Fig. 6.   Displacement of 125I-labeled EGF from Capan-1 cells by unlabeled EGF (A) and PCI (B). Monolayers of serum-starved cells were incubated at 4 °C with 350 pM of 125I-labeled EGF and various concentrations of EGF and PCI. Cell-bound radioactivity was determined following 4 h of incubation and extensive washing. Nonspecific binding was determined in the presence of an excess of the unlabeled factor and was subtracted from the total amount of cell-bound radioactivity. The specifically bound percentage of 125I-labeled EGF (B) was used to calculate log (B/[100 - B]), which is plotted against the logarithm of the concentrations of EGF and PCI. The plots were also used to calculate the IC50.

PCI Inhibition of EGFR Kinase Activity and Transphosphorylation Induced by EGF-- We next investigated whether PCI could inhibit the activation of the receptor induced by EGF in the EGFR-overexpressing vulvar carcinoma cell line A431 (41) and in Capan-1. In experiments using serum-starved A431 cells, we found that there was a low level of EGFR kinase activity. Addition of EGF caused a rapid increase in this activity (detectable after 10 min), and PCI was found to be an effective inhibitor of this activation. Preincubation of the cells with 50 µg/ml PCI for 10 min completely suppressed any detectable activation of EGFR by EGF (Fig. 7A). Similar results were obtained in Capan-1 cells, in which 50 µg/ml PCI strongly reduced the activation of EGFR by EGF (Fig. 7B). Western blot analyses confirmed that 50 µg/ml PCI blocks the EGF-induced tyrosine transphosphorylation of EGFR in both A431 (Fig. 7A) and Capan-1 (Fig. 7B).


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Fig. 7.   Inhibition by PCI of EGFR activation by EGF in A431 (A) and Capan-1 (B) cells. 50% confluent serum-starved Capan-1 and A431 cells were treated with various concentrations of PCI for 10 min and immediately stimulated with EGF (5 ng/ml for Capan-1 and 1 ng/ml for A431 cells) for 10 min. The activation of the receptor was measured by an immune complex kinase assay (bottom panels) as well as by blotting of the immunoprecipitated receptor with anti-phosphotyrosine antibody (top panels). In the autoradiographs of the kinase assays, the number below each lane is its intensity relative to the control (untreated cells) as measured by a beta  counter. The results shown are a representative of three different experiments.

We also examined the effect of PCI on EGFR activation in Capan-1 and A431 cells growing in medium with 10% FBS, without added EGF. These cells showed a significant level of EGFR activation that was not affected by addition of EGF for 10 min (data not shown). When PCI was added for 10 min, the kinase activity of the receptor was significantly reduced about 20% (Fig. 8A), probably as a result of the PCI-induced blockage of EGFR activation by growth factors either present in the FBS or produced by the cells. When PCI was maintained in the culture medium for 6 days, the reduction in the kinase activity was stronger; in this case the possibility that PCI down-regulates EGFR cannot be ruled out (Fig. 8B).


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Fig. 8.   Reduction of EGFR kinase activity by PCI in cells growing in medium with 10% FBS with no EGF added. A, Capan-1 and A431 cells growing in DMEM plus 10% FBS were treated with 50 µg/ml PCI for 10 min, and the kinase activity of the immunoprecipitated receptor was measured. Four independent experiments were performed with each cell line. The bars represent the average 32P-counts/min of the EGFR bands, quantified with a beta  counter, ± S.E. Significant differences from control values are indicated: #, p < 0.1; &, p < 0.01. A representative autoradiograph of each cell line is shown. B, A431 cells were treated with 50 µg/ml PCI for 6 days, and the kinase activity of the receptor was measured. The number below each band is its intensity relative to the control value.

Covalent Cross-linking Experiments-- Cross-linking assays showed that PCI interacts with EGFR and that this interaction could be reverted by EGF (not shown). PCI only cross-reacts with monomers of EGFR, thus indicating that it is inhibiting the dimerization capacity of EGF. PCI seems to act as an antagonist analogue of EGF preventing the dimerization process.

    DISCUSSION
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Much effort is currently being devoted to finding new molecules that target signal transduction pathways (13), including antagonists that bind to growth factor receptors without activating them (8, 19, 20). Such antagonists are of both theoretical and clinical interest, because they can lead to a better understanding of the interactions responsible for the binding of growth factors to their receptors and can be used as new antitumor drugs.

The EGFR is one of the most studied growth factor receptors due to its importance in the development and functionality of epidermal tissues as well as carcinomas, where it is frequently overexpressed. Both EGF and TGF-alpha bind to this receptor, whose activation initiates a cascade of biological processes (42) and is required for proliferation in many cell types and cancer cells. Despite its importance, no antagonist for human EGF has been reported so far. An inhibitory ligand of the Drosophila homologue of the mammalian EGFR has been recently described (43), and monoclonal antibodies against human EGFR have been produced (44). PCI is, however, the first reported antagonistic analogue of human EGF that is able to bind to EGFR without eliciting the activation of the receptor. In addition, PCI can suppress tumor cell growth, probably as a result of diminished EGFR activation.

The results of the binding experiments presented here demonstrated that PCI competed with EGF for binding to EGFR. The affinity of the receptor for EGF was higher than for PCI, as was expected. The internalization of PCI by the cells observed by using fluorescent labeling was perhaps a consequence of the endocytosis of the EGFR once it was bound to PCI. Some indirect evidence supports this hypothesis. First, after internalization PCI was located around the nucleus, as is EGF (45). Second, PCI underwent several cycles of appearance and disappearance from the culture medium, which might have been produced by the recycling and lysosomal degradation of the receptor (7). This reappearance in the culture medium of a dissociated recycled ligand has also been observed in the case of EGF (46). Third, PCI was not altered by the cells, which rules out the possibility that PCI binds to a membrane metallo-carboxypeptidase, given that the last residue of the inhibitor is quickly cleaved when it binds to these kinds of enzymes (24).

PCI not only bound to EGFR, but it also inhibited the activation of the receptor induced by EGF. The experiments performed in serum-starved Capan-1 and A431 cells demonstrated that PCI binding did not significantly activate EGFR and that the inhibitor blocked the EGF-induced increase in the kinase activity of the receptor and the transphosphorylation of tyrosine residues (Fig. 7). In serum-starved cells, the level of EGFR activation was low, raising very significantly after addition of EGF. By contrast, in cells growing in presence of FBS, a significant level of EGFR activation was observed, probably as a result of the presence of growth factors in serum capable of activating the receptor. In these conditions, the addition of EGF did not have any effect on the level of EGFR activation. In contrast, PCI reduced the kinase activity of the receptor in a significant way, suggesting that it competed with the growth factors present in serum for binding to EGFR (Fig. 8A). In all the previous experiments, the cells were incubated with PCI only for 10 min. When the inhibitor was maintained for 6 days in the culture medium of A431 cells growing with serum, the reduction in the kinase activity of the receptor was stronger, perhaps because of the PCI-induced down-regulation of EGFR (Fig. 8B).

Computer-based analysis showed that PCI had clear structural similarities to EGF that can explain its antagonistic activity. Both PCI and EGF are small proteins with three disulfide bridges arranged in a special scaffold called the T-knot. We developed a computer program to superimpose proteins by structural alignment of the disulfide bridges. When applied to PCI and growth factors such as EGF, TGF-alpha , and heregulin, it revealed that two loops of the inhibitor and part of its C-terminal tail superimposed onto the corresponding growth factor loops. It also revealed that some residues of EGF involved in receptor binding (19) fit in the space with residues of PCI with similar physico-chemical properties (Fig. 4).

The inhibitory effect of PCI on the growth of human pancreatic adenocarcinoma cell lines was demonstrated in a variety of conditions. In the case of Capan-1 cells growing in medium with serum, the effect of PCI was apparent after 7-10 days of culture (Fig. 1) and was only observed when the PCI concentration was higher than 10 µg/ml. These findings correlate with the results obtained from cell cycle analyses, which indicated that after 12 days of treatment with PCI, the percentage of apoptotic cells significantly increased over the control values. A small increase in the number of cells in the G0-G1 phase was also observed. These results are in agreement with those obtained by Wu et al. (44) using a monoclonal antibody against EGFR that blocks EGF binding and inhibits the proliferation of many tumor cell lines. They found that in some lines this antibody induced G1 arrest or apoptosis. The effects of PCI on cell cycle traversal could explain the inhibition of cell growth induced by this protein.

The results obtained in the proliferation experiments using serum-starved Capan-1 cells indicate that the antiproliferative effect of PCI is probably due to the fact that it is an EGF antagonist. When EGF was added to serum-starved Capan-1 cells, it stimulated cell proliferation, but this effect was abolished if PCI was administered simultaneously to the cells. This result is in perfect agreement with those obtained when studying EGFR activation. By contrast, the stimulatory effect of insulin on Capan-1 cell growth was not affected by the presence of PCI. The inhibitor is therefore capable of specifically suppressing the EGF proliferative effect on serum-starved Capan-1 cells. In cells growing in medium with FBS, PCI probably competes with the growth factors present in serum capable of binding to EGFR, as EGFR activation experiments indicate, and blocks their proliferative effect. This offers an explanation for the inhibitory effect of PCI on cells growing with serum.

When Capan-1 cells were grown in presence of PCI for at least 3 weeks and then transferred into fresh medium, the growth rate of this cells even without PCI was significantly lower than that of control cells (Fig. 1C). If protracted treatment with PCI can down-regulate EGFR, as some of our results seem to suggest (Fig. 8B), the lower amounts of EGFR could be responsible for the reduction in the growth rate of the treated cells.

Some protease inhibitors have been reported to have anticarcinogenic properties (22), but the mechanisms responsible for these properties are unclear. We offer an explanation for the tumor growth suppressive activity of a protease inhibitor, PCI, showing that it acts as a growth factor antagonist. The effect of PCI on tumor growth seems attributable to its special topology and not to its protease-inhibitory activity. Several protease inhibitors with cancer-chemopreventive properties have a T-knot scaffold, and our work suggests that they may also act as growth factor antagonists.

Several properties of PCI make it a good candidate for a therapeutic agent. First, it was able to inhibit the development of human adenocarcinoma tumors transplantated into nude mice without inducing any observable toxic side effects. This fact is particularly interesting because there are not effective treatments available for pancreatic cancer. Second, PCI is a small protein very resistant to denaturation and proteolytic degradation. And third, PCI had a long lasting inhibitory effect on the in vitro growth of pancreatic adenocarcinoma cell lines that was maintained even when it was removed from the culture medium. In addition, we have obtained a transgenic mice that develop insulinomas, and preliminary results indicate that PCI also reduces the growth of these tumors and increases the survival time of the animals.3

In summary, we have described the antitumor properties of PCI, a small protein with three disulfide bridges arranged in a T-knot, and we have demonstrated that it is the first antagonistic analogue of human EGF described. PCI is of both theoretical and clinical interest and opens the possibility of engineering PCI-like EGF antagonists with improved properties. At present, we are testing whether PCI can also inhibit the growth of other carcinoma cell lines expressing EGFR. That the most common cancers (lung, prostate, breast, and colon) are of epithelial origin gives an additional clinical interest to this approach.

    ACKNOWLEDGEMENTS

We thank Prof. T. L. Blundell for the critical revision of the manuscript and helpful suggestions. We also thank G. E. Gallick (M. D. Anderson Cancer Center) for assistance with the EGFR phosphorylation studies; R. Peracaula, N. Ruiz, A. Oliva, and M. Sitjà (Universitat de Girona) for the review of the manuscript; and C. Marino, G. Venhudová, and F. Canals (Institut de Biologia Fonamental, Universitat Autònoma de Barcelona) for technical assistance with the production of recombinant PCI.

    FOOTNOTES

* This study was supported by Grants SAF94-0939, BIO94-0912-CO2, and BIO95-0848 from the Comisión Interministerial para la Ciencia y la Tecnología of the Spanish Ministry of Education (to R. de L., E. Q., and F. X. A., respectively) and by National Institutes of Health Cancer Center Core Grant ROI-CA46687 (to the University of Texas M. D. Anderson Cancer Center).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.

§ These authors contributed equally to this work.

** To whom correspondence should be addressed: Institut de Biologia Fonamental, Universitat Autònoma de Barcelona, 08193 Bellaterra, Barcelona, Spain. Tel.: 34-3-5811315; Fax: 34-3-5812011; E-mail: fx.aviles{at}blues.uab.es.

1 The abbreviations used are: EGF, epidermal growth factor; EGFR, epidermal growth factor receptor; PCI, potato carboxypeptidase inhibitor; TGF-alpha , transforming growth factor alpha ; DMEM, Dulbecco's modified Eagle's medium; FBS, fetal bovine serum; PBS, phosphate-buffered saline; RITC, rhodamine B isotiocyanate.

2 J. M. Mas, B. Oliva, C. Blanco-Aparicio, M. A. Molina, R. de Llorens, E. Querol, and F. X. Avilés, submitted for publication.

3 C. Blanco, M. A. Molina, M. L. Frazier, and R. de Llorens, manuscript in preparation.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
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