Siegfried Matzku

Bio: Siegfried Matzku is an academic researcher from German Cancer Research Center. The author has contributed to research in topics: Monoclonal antibody & Antibody. The author has an hindex of 18, co-authored 50 publications receiving 3319 citations.

Monoclonal antibody-mediated tumor regression by induction of apoptosis

Abstract: To characterize cell surface molecules involved in control of growth of malignant lymphocytes, monoclonal antibodies were raised against the human B lymphoblast cell line SKW6.4. One monoclonal antibody, anti-APO-1, reacted with a 52-kilodalton antigen (APO-1) on a set of activated human lymphocytes, on malignant human lymphocyte lines, and on some patient-derived leukemic cells. Nanogram quantities of anti-APO-1 completely blocked proliferation of cells bearing APO-1 in vitro in a manner characteristic of a process called programmed cell death or apoptosis. Cell death was preceded by changes in cell morphology and fragmentation of DNA. This process was distinct from antibody- and complement-dependent cell lysis and was mediated by the antibody alone. A single intravenous injection of anti-APO-1 into nu/nu mice carrying a xenotransplant of a human B cell tumor induced regression of this tumor within a few days. Histological thin sections of the regressing tumor showed that anti-APO-1 was able to induce apoptosis in vivo. Thus, induction of apoptosis as a consequence of a signal mediated through cell surface molecules like APO-1 may be a useful therapeutic approach in treatment of malignancy.

Participation in normal immune responses of a metastasis-inducing splice variant of CD44

Abstract: A variant of the glycoprotein CD44 (CD44v) that shares sequences with variants causally involved in metastasis formation is transiently expressed on B and T lymphocytes and macrophages after antigenic stimulation and in the postnatal period. Antibodies to the variant hinder in vivo activation of both B and T cells. The observation that a protein domain that is expressed on CD44 and required for the lymphatic spread of tumor cells can catalyze an essential step in the process of lymphocyte activation supports the idea that metastasizing tumor cells mimic lymphocyte behavior.

Prevention of tumor metastasis formation by anti-variant CD44.

Abstract: A splice variant of CD44 (CD44v) originally discovered on metastases of a rat pancreatic adenocarcinoma (BSp73ASML) has been shown by transfection to confer metastatic behavior to nonmetastatic tumor cells (Gunthert U., M. Hofmann, W. Rudy, S. Reber, M. Zoller, I. Haussmann, S. Matzku, A. Wenzel, H. Ponta, and P. Herrlich. 1991. Cell. 65:13). A monoclonal antibody (mAb), 1.1ASML, to the metastasis-specific domain of the CD44v molecule retards growth of lymph node and lung metastases of the metastatic tumor line BSp73ASML, and can efficiently prevent formation of metastases by the transfected line. The antibody is only effective when given before lymph node colonization. Anti-CD44v does not downregulate the expression of CD44v, and prevention of metastatic growth by anti-CD44v is not due to activation of any kind of immune defense. We suggest that the mAb interferes with proliferation of metastasizing tumor cells in the draining lymph node, most probably by blocking a ligand interaction. The interference with metastatic spread will greatly facilitate the exploration of the function of CD44v and, in particular, may also open new strategies for the therapy of human metastases.

Antigenic differences between metastatic and nonmetastatic BSp73 rat tumor variants characterized by monoclonal antibodies.

Abstract: Variants AS and ASML of the BSp73 rat tumor differ markedly with respect to morphology and to the capacity for spontaneous metastasis via the lymphatics Monoclonal antibodies (MAbs) were raised in order to identify surface molecules associated with both phenotypes Mice were immunized with either whole cells or isolated membranes and hybridoma supernatants were screened according to the criteria of selective binding to cultured cells of the variant used for immunization Of two MAbs reacting with the nonmetastasizing AS variant, one showed immunostaining of AS tissue From 11 MAbs binding to the metastatic ASML variant, 6 showed specific staining of ASML tissue, while the remaining 5 MAbs showed cross-reaction with normal rat tissues According to Western blot data, the 6 MAbs selectively binding to ASML tissue identified at least 2 different antigens, one of them showing up as a complex of 12 bands

Retardation of metastatic tumor growth after immunization with metastasis-specific monoclonal antibodies.

Abstract: The influence of 4 murine monoclonal antibodies (MAbs) directed against surface determinants of a metastasizing rat adenocarcinoma (BSp73ASML) on metastatic spread was evaluated and compared to their in vivo binding as well as to the induction of a humoral anti-MAb response, especially with respect to the development of anti-idiotypic (ID) antibodies of the internal image type. In a protocol of explicit immunization, all 4 MAbs transiently inhibited metastatic growth. Survival was prolonged only with one MAb (4.4ASML). With another MAb (1.1ASML), directed against a new variant form of CD44, metastatic growth was accelerated after transient retardation. Retardation of metastatic growth correlated with the humoral anti-MAb response. This accounted for the isotype- as well as for the idiotype-specific response. An exception was noted after immunization with MAb 1.1ASML. Rats with high levels of anti-1.1ASML antibodies, which inhibited binding to the tumor cells (internal image-type antibodies) showed accelerated metastatic spread. Data are interpreted to mean that MAb-induced inhibition of metastatic spread may be based on 2 independent mechanisms: blockade of metastasis-associated epitopes (i.e., with MAb 1.1ASML) and induction of an anti-mouse Ig response. In the latter case it was irrelevant whether the response was isotype- or idiotype-specific.

The Fas Death Factor

Abstract: Fas ligand (FasL), a cell surface molecule belonging to the tumor necrosis factor family, binds to its receptor Fas, thus inducing apoptosis of Fas-bearing cells. Various cells express Fas, whereas FasL is expressed predominantly in activated T cells. In the immune system, Fas and FasL are involved in down-regulation of immune reactions as well as in T cell-mediated cytotoxicity. Malfunction of the Fas system causes lymphoproliferative disorders and accelerates autoimmune diseases, whereas its exacerbation may cause tissue destruction.