- Email: [email protected]
Two proteins share immunological epitopes on the tumor-associated antigen 17-1A
Cancer Letters 144 (1999) 101±105
Two proteins share immunological epitopes on the tumorassociated antigen 17-1A Ying-Hua Chen*, Tianwei Yu, Yun Bai, Nanming Zhao School of Life Science and Engineering, Tsinghua University, Beijing 100084, PR China Received 12 April 1999; received in revised form 17 May 1999; accepted 18 May 1999
Abstract The mouse monoclonal antibody (mAb) 17-1A which recognizes the tumor-associated antigen 17-1A (also called EGP-40 or EpCAM) was successfully used in adjuvant therapy for colorectal carcinoma. In the 17-1A antigen analysis, we isolated not only a protein of 33 kDa (P33) which was reported as the tumor associated antigen 17-1A, but also a protein of 65 kDa (P65) using af®nity chromatography from cell lysates of HCT, and another protein of 50 kDa (P50) from lysates of human colorectal tumor tissues. The mAbs 17-1A and M79 (mAb M79 recognizes a different epitope on the 17-1A antigen) both could bind P33 and P50, but only M79 bound to P65 in an enzyme-linked immunosorbant assay (ELISA). These results indicate that P33 and P50 share at least two epitopes, and a common immunological epitope exists among P33, P50 and P65, suggesting that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A. q 1999 Elsevier Science Ireland Ltd. All rights reserved. Keywords: Tumor-associated antigen; EpCAM; 17-1A; Common immunological epitope
1. Introduction The murine monoclonal antibody (mAb) 17-1A against human tumor-associated antigen 17-1A (EpCAM) can mediate antibody-dependent cellmediated cytotoxicity (ADCC) against human colorectal tumor cells [1] and has protective effect on nude mice xenografted with human colorectal carcinoma cells [2]. It has been shown that injection of mAb 17-1A can decrease recurrence rate and death rate of patient with colorectal cancer after surgery [3,4]. A 17-1A cancer vaccine is also in clinical development [5]. Monoclonal antibodies against 17-1A antigen recognize various normal epithelial tissues and carcinomas of different tissue origin by immunohistochem* Corresponding author. Fax: 186-10-627-855-05. E-mail address: [email protected] (Y.H. Chen)
ical staining [6]. The 17-1A antigen, a 33-kDa glycoprotein (P33), was isolated and identi®ed from several human colorectal tumor cell lines [6,7]. In this study, we used M79-sepharose and Con-A-sepharose columns in af®nity chromatography to purify 17-1Arelated proteins, and found that two proteins share immunological epitopes present on the tumor-associated antigen 17-1A. 2. Materials and methods 2.1. Human colorectal carcinoma cell lines and tissues Human colorectal carcinoma cell lines HCT and HT-29 were grown in DMEM medium (Gibco) supplemented with 10% fetal calf serum (Gibco),
0304-3835/99/$ - see front matter q 1999 Elsevier Science Ireland Ltd. All rights reserved. PII: S 0304-383 5(99)00205-0
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Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
2 mmol/l glutamine, 100 units/ml penicillin (Sigma) and 50 mg/l streptomycin (Sigma). Cells were harvested by digestion using 0.05% EDTA and 0.05% trypsin (Sigma) in DMEM medium (Gibco). Four, fresh human colorectal tumor tissue samples were obtained from the Sino-Japan Friendship Hospital in Beijing. 2.2. Antibodies Mouse mAbs 17-1A and M79 recognizing two different epitopes on 17-1A antigen [described in Ref. 1] were kindly provided by Prof. G. Riethmuller (Munich, Germany). Peroxidase-conjugated rabbit anti-mouse immunoglobulins were obtained from Dako (Denmark). FITC-conjugated goat anti-mouse IgG was obtained from Sigma, USA. 2.3. Isolation of proteins by af®nity chromatography and silver-staining Using standard procedure from Pharmacia, mAb M79 (4 mg) was coupled to 2 ml CNBr-activated sepharose 4B. The concanavalin A (Con A)-sepharose column (5 ml) was obtained from Sigma. The tumor tissues were homogenized in lysis buffer (5 % vol/vol) for 3 min and lysed for 1 h at 48C. The lysis buffer comprise of 50 mmol/l Tris±HCl, 0.5% NP-40, 0.18 mg/l PMSF, 1.57 mg/ml benzamidin±HCl, 0.1 mg/ml trypsin inhibitor and 0.1% leupeptin (all reagents purchased from Sigma). Cell lysates were prepared by centrifugation at 800 £ g for 30 min and at 10 000 £ g for 45 min, then ®ltrated by 0.22 mm membrane (Gelman, USA). With a low ¯ow-rate, tissue lysates were run through M79-sepharose af®nity chromatography column. The column was washed with 20 ml phosphate-buffered saline (PBS), eluted with 0.5 mol/l acetic acid at 48C. Eluates were neutralized immediately with 1 mol/l Tris (pH 9.6). Cell lysates were also run through con A-sepharose column. The column was washed with 40 ml PBS, eluated with 100 mmol/l a-methyl-d-mannose, 20 mmol/l Tris±HCl, 100 mmol/l NaCl, 0.1% Triton X100, 1 mmol/l CaCl2 (all reagents purchased from Sigma). Eluates from con A-sepharose column and unbound materials of cell lysates were run through M79-sepharose column separately, and eluted as described above. Eluates were subjected to electrophoresis in a 12.5% sodium dodecyl sulphate (SDS)-
polyacrylamide gel under reducing conditions and then examined by silver-staining. 2.4. Enzyme-linked immunosorbent assay (ELISA) The isolated proteins (P33, P50 and P65) were coated overnight on a microtiter plate at 48C, separately. Non-speci®c binding was blocked by incubation with 0.3% gelatine (Sigma) in PBS for 1 h at room temperature. After washing twice with PBS containing 0.1% Tween 20, mouse mAb M79 or 171A were added and incubated for 1 h at room temperature. The plate was washed again with PBS-Tween 20. Peroxidase-conjugated rabbit anti-mouse antibody was added. After further washing, freshly prepared O-phenylenediamine-peroxide solution was added and the optical density was measured (l 490 nm). 2.5. Flow cytometry analysis HT-29 cells (1 £ 106 ) were incubated with mAb 171A or M79 (10 mg/ml) for 45 min in a 50 ml ®nal volume. Cells were washed with PBS-supplemented 2% FCS and incubated with 50 ml FITC-conjugated goat anti-mouse IgG (Sigma, 1:50 dilution in PBS). After further washing with PBS plus 2% FCS, cells were ®xed with 1% paraformaldehyde in PBS and analyzed on a FACScan (Becton-Dickinson, USA). In the blockade test with isolated proteins, mAbs 17-1A and M79 were incubated with the proteins
Fig. 1. Isolation of proteins from cell and tissue lysates by af®nity chromatography using M79- and Con A-sepharose columns. The proteins were subjected to SDS-PAGE under reducing conditions and silver staining. Lane A, protein weight-marker; Lane B, P33 isolated from HCT cell lysates by M79-column; Lane C, P50 isolated from lysates of human colorectal tumor tissue by M79column; Lane D, P65 isolated from HCT cell lysates by con-Aand M79-columns.
Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
(5 mg/ml) separately for 30 min at 48C before incubation with cells. 3. Results By af®nity chromatography using M79-sepharose column, a 33-kDa protein (P33) was isolated from HCT cell lysates (Fig. 1B). Moreover, a 50-kDa protein (P50) was isolated from lysates of human colorectal tumor tissues (Fig. 1C), and a very weak band of 33 kDa (data not shown) was also detected by silver-staining. A 65-kDa protein (P65) was also found by af®nity chromatography using Con A-
103
sepharose column and then M79-sepharose column (Fig. 1D). In a previous study, we found a 33-kDa protein (P33) from HT-29 cell lysates by af®nity chromatography using M79-sepharose column [8]. To test the interaction of both mAb 17-1A and M79 with these isolated proteins, an ELISA was performed. mAbs 17-1A and M79 recognizing two different epitopes on the 17-1A antigen could bind P33 and P50 (Fig. 2a,b), but only M79 bound to P65 (Fig. 2c). These results indicate that P33 and P50 share at least two epitopes, and a common immunological epitope exists among P33, P50 and P65, suggesting that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A.
Fig. 2. Identi®cation of interaction of mAbs 17-1A and M79 with the isolated proteins by ELISA. a: A, mAb 17-1A binding to P33; B, mAb M79 binding to P33. b: A, mAb 17-1A binding to P50; B, mAb M79 binding to P50. c: mAb 17-1A binding to P65; B, mAb M79 binding to P65. Control: gelatine instead of these antigens by coating the microtiter plate.
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Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
Fig. 3. Inhibition of mAb 17-1A (a) and M79 (b) binding to HT-29 cells by P50, in ¯ow cytometry analysis. FACS-histogram overlays: A, PBS (control); B, mAb (10 mg/ml); C, mAb (10 mg/ml) plus P65 (5 mg/ml).
To know whether P50 or P65 could inhibit the binding of mAb 17-1A and M79 to HT-29 cells, the binding of both mAbs to HT-29 cells were examined by ¯ow cytometry analysis. P50 showed an enhancement effect on the binding of both mAbs (Fig. 3). P65 did not inhibit the binding of mAb 17-1A to HT-29 cells (Fig. 4a), and on the contrary, could weakly upmodulate the binding of M79 (Fig. 4b). 4. Discussion Mouse monoclonal antibodies against the tumor-
associated antigen 17-1A have been used in adjuvant therapy for human colorectal tumors and have produced good curative effects [3,4]. In this study, we isolated three different proteins, two of which are not reported before. The isolation of P33 is consistent with the report that a 33-kDa glycoprotein (or 37 kDa, under non-reducing conditions) had been isolated from cell lines HT-29, WiDr, DLD-1 [4,5]. In our study, P33 was not isolated by Con A-sepharose column, which suggests that P33 does not contain ad-mannosyl or a-d-glucosyl groups. The interaction between P50 and both mAbs 17-1A and M79 (recog-
Fig. 4. Inhibition of mAb 17-1A (a) and M79 (b) binding to HT-29 cells by P65, in ¯ow cytometry analysis. FACS-histogram overlays: A, PBS (control); B, mAb (10 mg/ml); C, mAb (10 mg/ml) plus P65 (5 mg/ml).
Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
nizing two different epitopes on 17-1A antigen) suggests P33 and P50 share at least two epitopes. P65 only bound mAb M79, indicating a common immunological epitope exists among P33, P50 and P65. These results demonstrate that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A, at least on a serological level. Up to now, we have no experimental data to explain the enhancement effect of P50 and P65 on the binding of the mAbs to HT-29. This will the subject of future investigation in. One possibility is that P50 binds directly to a certain cell surface antigen on the HT29 cells and thus making more binding sites on the cells available for the antibodies. HT-29 cells in part should be mutated during cultivation so that the cells showed different behavior in the blockade test. The slight enhancement of M79 binding to HT-29 cells by P65 could be explained by a similar proposal. Another explanation may be that P65 contains two or more M79 epitopes, thus by the linkage of P65, more antibodies could bind to a single cell. 17-1A antigens extracted in different laboratories are not congruent. Gottlinger et al. reported that 171A antigen was a 33-kDa glycoprotein [6,7]. Ross et al. reported that the 17-1A antigen contained a 30- and a 40-kDa subunit [9]. There is still another report that 17-1A antigen is a 41-kDa protein [9]. Tumor associated antigen GA733 is also recognized by mAb 171A [10]. Now we report a 50-kDa protein which is a putative 17-1A antigen and a 65-kDa protein which is related to the 17-1A antigen. The difference among the reports on 17-1A antigen indicates that there may exist a group of cell surface antigens that are recognized by mAb 17-1A and related antibodies. Gottlinger et al. reported a wide distribution of 171A antigen (EpCAM) among normal and malignant tissues. Based on the ®ndings by us and others, we can propose a hypothesis that a 17-1A tumor-associated antigen family may exist, and the success of the adjuvant therapy is based on the interaction of the anti-171A mAbs with a set of proteins, for example, P33, P50 and P65. More studies should be carried on about the biochemical properties of P50 and P65, and their relationship with P33.
105
Acknowledgements The authors wish to thank Prof. Dr. G. Riethmuller (Munich, Germany) for his kindly providing the antibodies. This work was supported by Tsinghua University and Tsinghua Novel Hi-Tech Investment Holdings Limited.
References [1] M. Herlyn, Z. Steplewski, D. Herlyn, H. Koprowski, Colorectal carcinoma-speci®c antigen: detection by means of monoclonal antibodies, Proc. Natl. Acad. Sci. USA 76 (1979) 1438±1442. [2] D. Herlyn, Z. Steplewski, M. Herlyn, H. Koprowski, Inhibition of growth of colorectal carcinoma in nude mice by monoclonal antibody, Cancer Res. 40 (1980) 717±721. [3] G. Riethmuller, E. Schneider-Gadicke, G. Schlimok, W. Schmiegel, R. Raab, K. Hoffken, R. Gruber, H. Pichlmaier, H. Hirche, R. Pichlmayr, P. Buggisch, J. Witte, The German Cancer Aid 17-1A Study Group, Randomised trial of monoclonal antibody for adjuvant therapy of resected Dukes' C colorectal carcinoma, Lancet 343 (1994) 1177±1183. [4] G. Riethmuller, E. Holz, G. Schlimok, W. Schmiegel, R. Raab, K. Hoffken, R. Gruber, I. Funke, H. Pichlmaier, H. Hirche, P. Buggisch, J. Witte, R. Pichlmayr, Monoclonal-antibody therapy for resected Dukes-C colorectal-cancer-7-year outcome of a multicenter randomized trial, J. Clin. Oncol. 16 (1998) 1788±1794. [5] C.A. Maxwell-Armstrong, L.G. Durrant, J.H. Schole®eld, Colorectal-cancer vaccines, Br. J. Surg. 85 (1998) 149±154. [6] H. Gottlinger, I. Funke, J. Johnson, J. Gokel, G. Riethmuller, The epithelial cell surface antigen 17-1A, a target for antibody-mediated tumor therapy: its biochemical nature, tissue distribution and recognition by different monoclonal antibodies, Int. J. Cancer 38 (1986) 47±53. [7] H. Gottlinger, J. Johnson, G. Riethmuller, Biochemical and epitope analysis of the 17-1A membrane antigen, Hybridoma 5 (1986) S29±S37. [8] Y. Zhao, T. Yu, Y. Xiao, Y. Bai, Y.H. Chen, Modulation of 17-1A antigen expression and puri®cation of the antigen, Tsinghua Sci. Technol. 3 (1998) 1070±1072. [9] A. Ross, M. Lubeck, Z. Steplewski, Identi®cation and characterization of the CO17-1A carcinoma-associated antigen, Hybridoma 5 (1986) S21±S28. [10] A. Ross, D. Herlyn, D. Iliopoulos, H. Koprowski, Isolation and characterization of a carcinoma-associated antigen, Biochem. Biophys. Res. Commun. 135 (1986) 297±303.
Two proteins share immunological epitopes on the tumorassociated antigen 17-1A Ying-Hua Chen*, Tianwei Yu, Yun Bai, Nanming Zhao School of Life Science and Engineering, Tsinghua University, Beijing 100084, PR China Received 12 April 1999; received in revised form 17 May 1999; accepted 18 May 1999
Abstract The mouse monoclonal antibody (mAb) 17-1A which recognizes the tumor-associated antigen 17-1A (also called EGP-40 or EpCAM) was successfully used in adjuvant therapy for colorectal carcinoma. In the 17-1A antigen analysis, we isolated not only a protein of 33 kDa (P33) which was reported as the tumor associated antigen 17-1A, but also a protein of 65 kDa (P65) using af®nity chromatography from cell lysates of HCT, and another protein of 50 kDa (P50) from lysates of human colorectal tumor tissues. The mAbs 17-1A and M79 (mAb M79 recognizes a different epitope on the 17-1A antigen) both could bind P33 and P50, but only M79 bound to P65 in an enzyme-linked immunosorbant assay (ELISA). These results indicate that P33 and P50 share at least two epitopes, and a common immunological epitope exists among P33, P50 and P65, suggesting that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A. q 1999 Elsevier Science Ireland Ltd. All rights reserved. Keywords: Tumor-associated antigen; EpCAM; 17-1A; Common immunological epitope
1. Introduction The murine monoclonal antibody (mAb) 17-1A against human tumor-associated antigen 17-1A (EpCAM) can mediate antibody-dependent cellmediated cytotoxicity (ADCC) against human colorectal tumor cells [1] and has protective effect on nude mice xenografted with human colorectal carcinoma cells [2]. It has been shown that injection of mAb 17-1A can decrease recurrence rate and death rate of patient with colorectal cancer after surgery [3,4]. A 17-1A cancer vaccine is also in clinical development [5]. Monoclonal antibodies against 17-1A antigen recognize various normal epithelial tissues and carcinomas of different tissue origin by immunohistochem* Corresponding author. Fax: 186-10-627-855-05. E-mail address: [email protected] (Y.H. Chen)
ical staining [6]. The 17-1A antigen, a 33-kDa glycoprotein (P33), was isolated and identi®ed from several human colorectal tumor cell lines [6,7]. In this study, we used M79-sepharose and Con-A-sepharose columns in af®nity chromatography to purify 17-1Arelated proteins, and found that two proteins share immunological epitopes present on the tumor-associated antigen 17-1A. 2. Materials and methods 2.1. Human colorectal carcinoma cell lines and tissues Human colorectal carcinoma cell lines HCT and HT-29 were grown in DMEM medium (Gibco) supplemented with 10% fetal calf serum (Gibco),
0304-3835/99/$ - see front matter q 1999 Elsevier Science Ireland Ltd. All rights reserved. PII: S 0304-383 5(99)00205-0
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Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
2 mmol/l glutamine, 100 units/ml penicillin (Sigma) and 50 mg/l streptomycin (Sigma). Cells were harvested by digestion using 0.05% EDTA and 0.05% trypsin (Sigma) in DMEM medium (Gibco). Four, fresh human colorectal tumor tissue samples were obtained from the Sino-Japan Friendship Hospital in Beijing. 2.2. Antibodies Mouse mAbs 17-1A and M79 recognizing two different epitopes on 17-1A antigen [described in Ref. 1] were kindly provided by Prof. G. Riethmuller (Munich, Germany). Peroxidase-conjugated rabbit anti-mouse immunoglobulins were obtained from Dako (Denmark). FITC-conjugated goat anti-mouse IgG was obtained from Sigma, USA. 2.3. Isolation of proteins by af®nity chromatography and silver-staining Using standard procedure from Pharmacia, mAb M79 (4 mg) was coupled to 2 ml CNBr-activated sepharose 4B. The concanavalin A (Con A)-sepharose column (5 ml) was obtained from Sigma. The tumor tissues were homogenized in lysis buffer (5 % vol/vol) for 3 min and lysed for 1 h at 48C. The lysis buffer comprise of 50 mmol/l Tris±HCl, 0.5% NP-40, 0.18 mg/l PMSF, 1.57 mg/ml benzamidin±HCl, 0.1 mg/ml trypsin inhibitor and 0.1% leupeptin (all reagents purchased from Sigma). Cell lysates were prepared by centrifugation at 800 £ g for 30 min and at 10 000 £ g for 45 min, then ®ltrated by 0.22 mm membrane (Gelman, USA). With a low ¯ow-rate, tissue lysates were run through M79-sepharose af®nity chromatography column. The column was washed with 20 ml phosphate-buffered saline (PBS), eluted with 0.5 mol/l acetic acid at 48C. Eluates were neutralized immediately with 1 mol/l Tris (pH 9.6). Cell lysates were also run through con A-sepharose column. The column was washed with 40 ml PBS, eluated with 100 mmol/l a-methyl-d-mannose, 20 mmol/l Tris±HCl, 100 mmol/l NaCl, 0.1% Triton X100, 1 mmol/l CaCl2 (all reagents purchased from Sigma). Eluates from con A-sepharose column and unbound materials of cell lysates were run through M79-sepharose column separately, and eluted as described above. Eluates were subjected to electrophoresis in a 12.5% sodium dodecyl sulphate (SDS)-
polyacrylamide gel under reducing conditions and then examined by silver-staining. 2.4. Enzyme-linked immunosorbent assay (ELISA) The isolated proteins (P33, P50 and P65) were coated overnight on a microtiter plate at 48C, separately. Non-speci®c binding was blocked by incubation with 0.3% gelatine (Sigma) in PBS for 1 h at room temperature. After washing twice with PBS containing 0.1% Tween 20, mouse mAb M79 or 171A were added and incubated for 1 h at room temperature. The plate was washed again with PBS-Tween 20. Peroxidase-conjugated rabbit anti-mouse antibody was added. After further washing, freshly prepared O-phenylenediamine-peroxide solution was added and the optical density was measured (l 490 nm). 2.5. Flow cytometry analysis HT-29 cells (1 £ 106 ) were incubated with mAb 171A or M79 (10 mg/ml) for 45 min in a 50 ml ®nal volume. Cells were washed with PBS-supplemented 2% FCS and incubated with 50 ml FITC-conjugated goat anti-mouse IgG (Sigma, 1:50 dilution in PBS). After further washing with PBS plus 2% FCS, cells were ®xed with 1% paraformaldehyde in PBS and analyzed on a FACScan (Becton-Dickinson, USA). In the blockade test with isolated proteins, mAbs 17-1A and M79 were incubated with the proteins
Fig. 1. Isolation of proteins from cell and tissue lysates by af®nity chromatography using M79- and Con A-sepharose columns. The proteins were subjected to SDS-PAGE under reducing conditions and silver staining. Lane A, protein weight-marker; Lane B, P33 isolated from HCT cell lysates by M79-column; Lane C, P50 isolated from lysates of human colorectal tumor tissue by M79column; Lane D, P65 isolated from HCT cell lysates by con-Aand M79-columns.
Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
(5 mg/ml) separately for 30 min at 48C before incubation with cells. 3. Results By af®nity chromatography using M79-sepharose column, a 33-kDa protein (P33) was isolated from HCT cell lysates (Fig. 1B). Moreover, a 50-kDa protein (P50) was isolated from lysates of human colorectal tumor tissues (Fig. 1C), and a very weak band of 33 kDa (data not shown) was also detected by silver-staining. A 65-kDa protein (P65) was also found by af®nity chromatography using Con A-
103
sepharose column and then M79-sepharose column (Fig. 1D). In a previous study, we found a 33-kDa protein (P33) from HT-29 cell lysates by af®nity chromatography using M79-sepharose column [8]. To test the interaction of both mAb 17-1A and M79 with these isolated proteins, an ELISA was performed. mAbs 17-1A and M79 recognizing two different epitopes on the 17-1A antigen could bind P33 and P50 (Fig. 2a,b), but only M79 bound to P65 (Fig. 2c). These results indicate that P33 and P50 share at least two epitopes, and a common immunological epitope exists among P33, P50 and P65, suggesting that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A.
Fig. 2. Identi®cation of interaction of mAbs 17-1A and M79 with the isolated proteins by ELISA. a: A, mAb 17-1A binding to P33; B, mAb M79 binding to P33. b: A, mAb 17-1A binding to P50; B, mAb M79 binding to P50. c: mAb 17-1A binding to P65; B, mAb M79 binding to P65. Control: gelatine instead of these antigens by coating the microtiter plate.
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Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
Fig. 3. Inhibition of mAb 17-1A (a) and M79 (b) binding to HT-29 cells by P50, in ¯ow cytometry analysis. FACS-histogram overlays: A, PBS (control); B, mAb (10 mg/ml); C, mAb (10 mg/ml) plus P65 (5 mg/ml).
To know whether P50 or P65 could inhibit the binding of mAb 17-1A and M79 to HT-29 cells, the binding of both mAbs to HT-29 cells were examined by ¯ow cytometry analysis. P50 showed an enhancement effect on the binding of both mAbs (Fig. 3). P65 did not inhibit the binding of mAb 17-1A to HT-29 cells (Fig. 4a), and on the contrary, could weakly upmodulate the binding of M79 (Fig. 4b). 4. Discussion Mouse monoclonal antibodies against the tumor-
associated antigen 17-1A have been used in adjuvant therapy for human colorectal tumors and have produced good curative effects [3,4]. In this study, we isolated three different proteins, two of which are not reported before. The isolation of P33 is consistent with the report that a 33-kDa glycoprotein (or 37 kDa, under non-reducing conditions) had been isolated from cell lines HT-29, WiDr, DLD-1 [4,5]. In our study, P33 was not isolated by Con A-sepharose column, which suggests that P33 does not contain ad-mannosyl or a-d-glucosyl groups. The interaction between P50 and both mAbs 17-1A and M79 (recog-
Fig. 4. Inhibition of mAb 17-1A (a) and M79 (b) binding to HT-29 cells by P65, in ¯ow cytometry analysis. FACS-histogram overlays: A, PBS (control); B, mAb (10 mg/ml); C, mAb (10 mg/ml) plus P65 (5 mg/ml).
Y.H. Chen et al. / Cancer Letters 144 (1999) 101±105
nizing two different epitopes on 17-1A antigen) suggests P33 and P50 share at least two epitopes. P65 only bound mAb M79, indicating a common immunological epitope exists among P33, P50 and P65. These results demonstrate that the two new proteins (P50 and P65) are related to the tumor-associated antigen 17-1A, at least on a serological level. Up to now, we have no experimental data to explain the enhancement effect of P50 and P65 on the binding of the mAbs to HT-29. This will the subject of future investigation in. One possibility is that P50 binds directly to a certain cell surface antigen on the HT29 cells and thus making more binding sites on the cells available for the antibodies. HT-29 cells in part should be mutated during cultivation so that the cells showed different behavior in the blockade test. The slight enhancement of M79 binding to HT-29 cells by P65 could be explained by a similar proposal. Another explanation may be that P65 contains two or more M79 epitopes, thus by the linkage of P65, more antibodies could bind to a single cell. 17-1A antigens extracted in different laboratories are not congruent. Gottlinger et al. reported that 171A antigen was a 33-kDa glycoprotein [6,7]. Ross et al. reported that the 17-1A antigen contained a 30- and a 40-kDa subunit [9]. There is still another report that 17-1A antigen is a 41-kDa protein [9]. Tumor associated antigen GA733 is also recognized by mAb 171A [10]. Now we report a 50-kDa protein which is a putative 17-1A antigen and a 65-kDa protein which is related to the 17-1A antigen. The difference among the reports on 17-1A antigen indicates that there may exist a group of cell surface antigens that are recognized by mAb 17-1A and related antibodies. Gottlinger et al. reported a wide distribution of 171A antigen (EpCAM) among normal and malignant tissues. Based on the ®ndings by us and others, we can propose a hypothesis that a 17-1A tumor-associated antigen family may exist, and the success of the adjuvant therapy is based on the interaction of the anti-171A mAbs with a set of proteins, for example, P33, P50 and P65. More studies should be carried on about the biochemical properties of P50 and P65, and their relationship with P33.
105
Acknowledgements The authors wish to thank Prof. Dr. G. Riethmuller (Munich, Germany) for his kindly providing the antibodies. This work was supported by Tsinghua University and Tsinghua Novel Hi-Tech Investment Holdings Limited.
References [1] M. Herlyn, Z. Steplewski, D. Herlyn, H. Koprowski, Colorectal carcinoma-speci®c antigen: detection by means of monoclonal antibodies, Proc. Natl. Acad. Sci. USA 76 (1979) 1438±1442. [2] D. Herlyn, Z. Steplewski, M. Herlyn, H. Koprowski, Inhibition of growth of colorectal carcinoma in nude mice by monoclonal antibody, Cancer Res. 40 (1980) 717±721. [3] G. Riethmuller, E. Schneider-Gadicke, G. Schlimok, W. Schmiegel, R. Raab, K. Hoffken, R. Gruber, H. Pichlmaier, H. Hirche, R. Pichlmayr, P. Buggisch, J. Witte, The German Cancer Aid 17-1A Study Group, Randomised trial of monoclonal antibody for adjuvant therapy of resected Dukes' C colorectal carcinoma, Lancet 343 (1994) 1177±1183. [4] G. Riethmuller, E. Holz, G. Schlimok, W. Schmiegel, R. Raab, K. Hoffken, R. Gruber, I. Funke, H. Pichlmaier, H. Hirche, P. Buggisch, J. Witte, R. Pichlmayr, Monoclonal-antibody therapy for resected Dukes-C colorectal-cancer-7-year outcome of a multicenter randomized trial, J. Clin. Oncol. 16 (1998) 1788±1794. [5] C.A. Maxwell-Armstrong, L.G. Durrant, J.H. Schole®eld, Colorectal-cancer vaccines, Br. J. Surg. 85 (1998) 149±154. [6] H. Gottlinger, I. Funke, J. Johnson, J. Gokel, G. Riethmuller, The epithelial cell surface antigen 17-1A, a target for antibody-mediated tumor therapy: its biochemical nature, tissue distribution and recognition by different monoclonal antibodies, Int. J. Cancer 38 (1986) 47±53. [7] H. Gottlinger, J. Johnson, G. Riethmuller, Biochemical and epitope analysis of the 17-1A membrane antigen, Hybridoma 5 (1986) S29±S37. [8] Y. Zhao, T. Yu, Y. Xiao, Y. Bai, Y.H. Chen, Modulation of 17-1A antigen expression and puri®cation of the antigen, Tsinghua Sci. Technol. 3 (1998) 1070±1072. [9] A. Ross, M. Lubeck, Z. Steplewski, Identi®cation and characterization of the CO17-1A carcinoma-associated antigen, Hybridoma 5 (1986) S21±S28. [10] A. Ross, D. Herlyn, D. Iliopoulos, H. Koprowski, Isolation and characterization of a carcinoma-associated antigen, Biochem. Biophys. Res. Commun. 135 (1986) 297±303.