The Fas (Apo-1/CD95) ligand (FasL) plays a central role in the elimination of target cells by effector T lymphocytes and in the suppression of cellular immune responses against nonmalignant and malignant cells. We show the expression of FasL on the surface of neoplastic plasma cells. We provide evidence that the FasL is functionally active because five of five neoplastic plasma cell lines tested killed CEM-C7H2 T-acute lymphoblastic leukemia (T-ALL) cells. The effect was mediated via the Fas (Apo-1/CD95) receptor molecule because blocking of Fas on the target cells or the FasL on the tumor cells by receptor- and ligand-specific monoclonal antibodies (MoAbs), respectively, protected T cells from being killed by myeloma cells. In addition, overexpression of the cowpox virus protein CrmA, a molecule with inhibitory potential on caspase-1 and caspase-8, specifically involved in Fas-induced signaling, protected T cells from being destroyed by the neoplastic cells or the agonistic anti-Fas MoAb. The potential of the malignant plasma cells to extinguish target T cells was independent of their own sensitivity to the agonistic anti-Fas MoAb, and FasL-positive (FasL+) CEM-C7H2 T cells were incapable of killing myeloma cells. Our results suggest that tumor cell–induced suppression of the immune system may be exerted via the FasL active on malignant plasma cells. Furthermore, loss of Fas expression or insensitivity to the agonistic anti-Fas MoAb do not seem to be prerequisites for myeloma cells to defeat T cells via Fas/FasL interaction.
B-chronic lymphocytic leukemia (B-CLL) is characterized by cellular and humoral immune defects resulting in increased rates of infection and disturbed immune surveillance against cancer cells as well as by the expansion of slowly proliferating tumor cells. We found increased Fas receptor (FasR) expression in peripheral blood CD4+and CD8+ cells of B-CLL patients compared with the equivalent cells of healthy donors. Although increased Fas receptor expression was significant in both T-lymphocytic subsets, only CD4+ cells from B-CLL patients underwent apoptosis after treatment with the agonistic Fas antibody CH11. In CD4+cells of B-CLL patients, the Fas-sensitivity also correlated with a CD4+/CD8+ ratio below the lower threshold of healthy individuals (<1.0). By contrast, FasR expression in the CD19+ fraction of B-CLL patients was downregulated compared with normal controls, and this was associated with an insensitivity to CH11-induced apoptosis. The B-CLL cell line EHEB as well as CD19+ cells from B-CLL patients constitutively expressed Fas ligand (FasL). The FasL was functionally active, as the B-CLL cell line as well as T-cell–depleted CD19+ B-CLL fractions were able to kill target T-acute lymphatic leukemia (T-ALL) cells in vitro. This effect was inhibited by the antagonistic FasR-antibody ZB4, the neutralizing anti-FasL monoclonal antibody (MoAb) NOK-2 or by transfection of the caspase inhibitor crmA. These data point to the fact that expression of FasL on CD19+B-CLL cells, together with enhanced susceptibility of CD4+ T cells toward FasL-bearing effector cells, are causally linked to the relative reduction of CD4+ cells occurring during B-CLL progression. These findings could explain the inversion of the ratio of CD4+/CD8+ cell numbers, which may be causally linked to the immune deficiency observed in these patients and to the expansion of the neoplastic clone in B-CLL.
A number of studies revealed that high expression of the proto-oncogene bcl-2 correlated with poor prognosis or resistance to chemotherapy in some tumors but predicted a favorable clinical course in other neoplasias. In these studies, however, different immunologic techniques for Bcl-2 detection were used, raising the question of whether the methods applied were comparable. Using chronic lymphocytic leukemia (CLL) cells, the aims of our study were as follows: (1) to determine the reproducibility of Bcl-2 semiquantitation by immunocytochemistry, flow cytometry, or immunoblotting; (2) to study the agreement between results obtained by these methods; and (3) to examine the association between Bcl-2 expression in tumor cells of 99 patients with CLL and clinical parameters. We found that determination of Bcl-2 expression by immunocytochemistry was reproducible and the results were comparable with those of flow cytometry and immunoblotting. In the patient collective examined, Bcl-2 expression did not reflect the extent of tumor mass, but higher levels were found more often in patients with progressive disease.
Summary. The down-regulation of apoptosis may be an essential mechanism for tumour cell expansion in slowly proliferating tumours such as multiple myeloma. We studied eight myeloma cell lines for the presence of Bcl-2, which inhibits apoptosis, of Bax, which counteracts Bcl-2, of Bcl-x L and Bcl-x S , which act in an anti-and pro-apoptotic fashion, respectively, and of Apo-1/Fas, which induces programmed cell death, when activated by the Apo-1/Fas ligand or the relevant monoclonal antibody (mab). All cell lines constitutively expressed homogenous amounts of Bcl-2, but displayed different amounts of Bax and Bcl-x proteins. The Apo-1/Fas antigen could be detected in seven out of eight myeloma lines, but expression levels varied considerably. The relative expression levels of Apo-1/Fas correlated with that of Bax, but not with that of Bcl-2 or Bcl-x subtypes. Furthermore, the effectiveness of the Apo-1/Fas mab was associated with the relative expression levels of the Apo-1/Fas and with that of the Bax antigen, but not with that of the Bcl-2 and Bcl-x antigens. We further showed that wild-type p53 function is not required for Apo-1/Fas-induced apoptosis, nor is it necessary for the expression of Bax or Apo-1/Fas antigens in myeloma.In conclusion, our results suggest a p53-independent coregulation of Apo-1/Fas and Bax, as well as a role for Bax in Apo-1/Fas-induced apoptosis in myeloma.
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