C Klas

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.

The APO-1 antigen as defined by the mouse monoclonal antibody anti-APO-1 was previously found to be expressed on the cell surface of activated human T and B lymphocytes and a variety of malignant human lymphoid cell lines. Cross-linking of the APO-1 antigen by anti-APO-1 induced programmed cell death, apoptosis, of APO-1 positive cells. To characterize the APO-1 cell surface molecule and to better understand its role in induction of apoptosis, the APO-1 protein was purified to homogeneity from membranes of SKW6.4 B lymphoblastoid cells by solubilization with sodium deoxycholate, affinity chromatography with anti-APO-1 antibody, and reversed phase high performance liquid chromatography. Each purification step was followed by an APO-1-specific solid phase enzyme-linked immunosorbent assay using the monoclonal antibody anti-APO-1. In sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the APO-1 antigen was found to be a membrane glycoprotein of 48-kDa. Endoproteinase-cleaved peptides of the APO-1 protein were subjected to amino acid sequencing, and corresponding oligonucleotides were used to identify a full-length APO-1 cDNA clone from an SKW6.4 cDNA library. The deduced amino acid sequence of APO-1 showed sequence identity with the Fas antigen, a cysteine-rich transmembrane protein of 335 amino acids with significant similarity to the members of the tumor necrosis factor/nerve growth factor receptor superfamily. The APO-1 antigen was expressed upon transfection of APO-1 cDNA into BL60-P7 Burkitt's lymphoma cells and conferred sensitivity towards anti-APO-1-induced apoptosis to the transfectants.

One of the mechanisms to terminate a specific immune response may involve elimination of antigen activated T cells by programmed cell death, apoptosis. Apoptosis in activated T cells may be induced via the TCR-CD3 complex or/and cell surface molecules like the APO-1 (Fas) antigen, a new member of the nerve growth factor/tumor necrosis factor receptor superfamily. To investigate apoptosis in activated T cells we studied expression of APO-1 and sensitivity to APO-1 mediated apoptosis in human peripheral T lymphocytes. APO-1 is not expressed on cord blood and the majority of resting T cells, but on activated T cells. One day activated T cells in culture showed activation induced resistance to apoptosis (ARA). However, after prolonged in vitro culture, 6 day activated T cells acquired sensitivity to activation induced sensitivity to apoptosis (ASA). Restimulation of the ASA+ activated T cells by triggering TCR-CD3 or CD2 induced proliferation and apoptosis in a fraction of the cells. In the surviving fraction of ASA+ activated T cells, however, this treatment reinduced a transient ARA+ phenotype. Thus, activation of resting mature T cells or restimulation of activated T cells may induce a transient resistance to apoptotic signals. Activation signals may interfere with the APO-1 pathway and may prevent elimination of activated T cells in the periphery (peripheral selection).

APO-1 is a cell surface molecule that induces apoptosis when ligated with the monoclonal antibody anti-APO-1. Expression of APO-1 and response to anti-APO-1 was investigated in a number of Epstein-Barr virus (EBV)-positive and -negative Burkitt lymphoma (BL) cell lines, in EBV-immortalized lymphoblastoid cell lines, and in cells from fresh BL biopsies. APO-1 was not expressed in EBV-negative cell lines and in EBV-positive BL cell lines with a phenotype corresponding to BL tumor biopsy cells (CD10+, CD21-, CD23-, CD30-, CD39-, CDw70-, CD77+). Accordingly, fresh BL cells obtained from three BL biopsies were APO-1 negative. EBV-positive BL cell lines that had acquired a lymphoblastoid phenotype (CD10-, CD21+, CD23+, CD30+, CD39+, CDw70+, CD77-) upon prolonged in vitro cultivation, as well as normal B-lymphoblastoid cell lines, expressed a high density of APO-1. APO-1 may, therefore, be regarded as a B-cell activation marker. APO-1 expression is not the only prerequisite for anti-APO-1-induced apoptosis because 6 of 7 APO-1-expressing EBV-positive BL cell lines were not sensitive to anti-APO-1, whereas all lymphoblastoid cell lines were killed by anti-APO-1. The sensitivity of lymphoblastoid cell lines to anti-APO-1-mediated apoptosis may open a new therapeutic approach for the treatment of EBV-induced lymphoproliferative lesions in immunocompromised individuals, because these are composed of cells with a lymphoblastoid phenotype.

Escherichia coli hemolysin is the prototype of a large family of pore-forming toxins produced by gram-negative organisms. Besides its known cytotoxic activities against granulocytes, monocytes, endothelial cells, and renal epithelial cells, we now demonstrate that the toxin potently kills human T lymphocytes. Evidence based on different and independent approaches indicates that lymphocidal activity is due to formation of transmembrane pores. Additionally, cells prestimulated with phytohemagglutinin respond to low doses of E. coli hemolysin with DNA fragmentation similar to that observed in cells undergoing programmed cell death. Kinetic considerations lead us to conclude that DNA degradation may, however, represent an epiphenomenon. Killing of T cells is another means through which E. coli hemolysin could directly impair host defense.