Homodimerization of tumor-reactive monoclonal antibodies markedly increases their ability to induce growth arrest or apoptosis of tumor cells.

Monoclonal antibodies (mAbs) that exert antitumor activity can do so by virtue of their effector function and/or their ability to signal growth arrest or cell death. In this study, we demonstrate that mAbs which have little or no signaling activity-i.e., anti-CD19, CD20, CD21, CD22 and Her-2-can become potent antitumor agents when they are converted into IgG-IgG homodimers. The homodimers exert antigrowth activity by signaling G0/G1 arrest or apoptosis, depending upon which cell surface molecule they bind. This activity is specific and, in the case of the anti-CD19 mAb, did not require an Fc portion. These results offer the possibility that homodimers of other tumor-reactive mAbs which have little antitumor activity as monomers might be potent, antitumor agents.

Combination immunotoxin treatment and chemotherapy in SCID mice with advanced, disseminated Daudi lymphoma.

We describe the use of an immunotoxin (IT) cocktail (anti-CD22- and anti-CD19-ricin A chain) and any 1 of 3 chemotherapeutic drugs (doxorubicin, cytoxan or camptothecin) to treat advanced disseminated Daudi lymphoma in SCID mice (SCID/Daudi). In a previous report, we demonstrated that this regimen was curative when given the day following tumor cell inoculation. Here, we show that combination therapy in mice with advanced tumor significantly increased their survival, although it was not curative. Importantly, the outcome of therapy was dependent upon the temporal order in which IT and chemotherapy were administered. Thus, the best anti-tumor effect was achieved when an IT cocktail was given before or at the same time as chemotherapy. When the IT was given after chemotherapy, there was no additional therapeutic benefit. Our results confirm the rationale of using combination therapy in the treatment of advanced B-cell neoplasia and suggest that ITs should be administered prior to or during chemotherapy.

Effect of sublethal irradiation of SCID mice on growth of B-cell lymphoma xenografts and on efficacy of chemotherapy and/or immunotoxin therapy.

Severe combined immune deficiency (SCID) mice obtained from different vendors vary in their capacity to accept human tumor xenografts, and in some instances mice must first be irradiated. It has been reported that SCID mice are particularly sensitive to irradiation which, in addition, can partially restore their immune system so that they are no longer totally immunologically incompetent. For the past several years we have used nonirradiated SCID mice to grow human B-cell lymphomas. When we changed vendors, we found it necessary to irradiate the mice before xenografting. Sublethal irradiation of at least one source of SCID mice before tumor cell inoculation improved tumor take and dissemination, but irradiation changed the response of these mice to chemotherapy and immunotoxins. Thus the irradiated mice did not respond to chemotherapy, but the two immunotoxins used for therapy became more effective in extending survival of the mice. It then appears that irradiation affects the immune system of SCID mice in such a way as to change their response to the therapeutic regimens used here.