Characterization of antibodies to CA 125 that bind preferentially to the cell-associated form of the antigen.

OBJECTIVE: Antibodies to CA 125 have been used to predict relapse of ovarian cancer, but have performed poorly as therapeutic agents. One rationale for this is antibody binding to circulating shed antigen. Our aim in this study was to develop antibodies to human CA 125 that have enhanced selectivity for the cell-associated form of the antigen. METHODS: Monoclonal antibodies were raised to a recombinant fragment of CA 125 that included sequence proximal to the putative membrane attachment site. Antibodies were characterized in terms of their binding site, affinity and selectivity for cell-associated CA 125. RESULTS: In assays using patient-derived CA 125, a subset of high-affinity (KD <5 nM) monoclonal antibodies demonstrated a 10- to greater than 200-fold increase in selectivity for cell-associated CA 125 when compared with controls. Based on mapping of the various monoclonal antibodies obtained, it was determined that shedding of CA 125 most likely occurs in the most C-terminal repeat domain. CONCLUSION: Results from competition analysis using patient-derived shed antigen predict that the antibodies described in this study may have significantly enhanced tumor-targeting properties when compared with existing antibodies to CA 125 in a tumor environment having high concentrations (>10,000 CA 125 units) of shed CA 125.

Radiotherapy of human xenograft NSCLC tumors in nude mice with a 90Y-labeled anti-tissue factor antibody.

Tissue factor (TF) is a type I transmembrane protein and the initiator of the extrinsic blood coagulation pathway. TF plays a critical role in tumor development and its overexpression is observed in many tumors. To understand the prevalence and relative level of TF expression in non-small-cell lung cancer (NSCLC), we analyzed 50 NSCLC tumors by immunohistochemical staining and found that 88% of human NSCLC tumors overexpressed TF. We then generated a high affinity anti-TF antibody, TF278, which specifically binds TF on the surface of cells and is internalized upon binding. An 111In-labeled TF278 demonstrated favorable tumor accumulation in an SW-900 xenograft tumor model with a maximum mean percent of injected dose per gram of tissue (%ID/g) of 73.1% at 96 hours postinjection. In addition, we labeled the antibody with 90Y and tested its ability to inhibit the growth of tumors in an SW-900 xenograft tumor model in immunocompromised mice. The 90Y-TF278 slowed the growth of SW-900 tumors at a 50 microCi dose and completely regressed SW-900 tumors at a 150 microCi dose with little toxicity.

Characterization of human tissue factor (TF)-specific monoclonal antibodies prepared using a rapid immunization protocol.

Tissue factor (TF) plays an important, physiological role in hemostasis. Recent studies have demonstrated the over-expression of TF in a number of solid tumor types and its pathological roles in angiogenesis and tumor metastasis. In this study, we report the development and characterization of a panel of murine MAbs that are specific for human TF, but do not inhibit TF-mediated blood coagulation. By using a modified repetitive immunizations at multiple sites (RIMMS) protocol in conjunction with an efficient hybridoma cloning procedure, anti-TF MAbs were generated within a relatively short time frame of 5-6 weeks. Following primary screening by ELISA, the binding of the MAbs to the native form of human TF was demonstrated in flow cytometry using a stable cell line expressing human TF. Several of these TF-specific MAbs did not inhibit blood coagulation in a blood coagulation assay and bound with high affinity (0.5-2 nM) to human TF in BIAcore analyses. Importantly, this study represents an independent evaluation of the RIMMS strategy for MAb generation and demonstrates that class-switched, high-affinity MAbs can be generated rapidly and reliably using RIMMS.

Mapping and binding analysis of peptides derived from the tumor-associated antigen survivin for eight HLA alleles.

There is considerable interest in developing immunotherapeutic approaches to elicit tumor-specific CTL responses in cancer patients. Epitope-based approaches aim to deliver the antigenic peptides or epitopes recognized by CTLs rather than the intact tumor antigen. Many tumor-associated proteins are nonmutated self proteins for which the dominant peptide epitopes are usually poorly immunogenic. The subdominant epitopes, however, can elicit robust T cell responses if optimized for their ability to bind to class I MHC molecules. Only the epitopes for a few tumor antigens expressed in human cancers have been defined to this level, mainly for technical reasons. The means to rapidly screen and characterize the binding of epitopes derived from complex tumor-associated antigens is an important enabling technology. Here, we have used the high-throughput technology iTopia to identify those peptides derived from the tumor-associated antigen survivin that bind 8 class I alleles. A library of overlapping nonamers spanning the length of the survivin protein was initially screened for peptides capable of binding each allele. Nineteen HLA-A*0201, zero HLA-A*0101, seven HLA-A*0301, twelve HLA-A*1101, twenty-four HLA-A*2402, six HLA-B*0702, six HLA-B*0801, and eight HLA-B*1501 binding peptides were identified based on an arbitrary cutoff. Peptides capable of binding a given allele were further characterized by their affinity for MHC class I molecules and by the rate of dissociation of the complex. This information should help guide functional studies and future epitope-based immunotherapies.

Pharmacokinetics, biodistribution, and radioimmunotherapy with monoclonal antibody 776.1 in a murine model of human ovarian cancer.

776.1 is a murine IgG1 monoclonal antibody to the human ovarian cancer antigen CA 125 that has the unique property of having a clear preference for binding to the cell-associated form of the antigen. We have examined the tumor localization properties and efficacy of 776.1 in a subcutaneous OVCAR-3 xenograft mouse model of human ovarian cancer. Biodistribution experiments using (125)I-labeled 776.1 demonstrated a peak uptake in tumors at 72 hours postinjection, with an average of 17.7% of injected dose per gram localized to the tumor. Little uptake in other organs was observed. Further experiments using CA 125-transfected syngeneic tumors, as well as an immunoprecipitation assay using human chimeric 776.1, both clearly demonstrated that 776.1 localizes to the tumor in a CA 125-dependent manner. DOTA-776.1 (1,4,7,10-tetraazacyclododecane-N,N',N",N'" tetraacetic acid-conjugated 776.1) was labeled with (90)Y and used in efficacy studies. [(90)Y-DOTA]776.1 at a single dose of 150 microCi was able to mediate efficient reduction of tumor growth, with regression observed in a subset of animals for a period ranging from 3 to 48 days, equivalent to 3 weekly administrations of cisplatin at 6 mg/kg. No significant regression was observed in groups receiving [(90)Y-DOTA]MOPC-21 control antibody at any dose. These results suggest that 776.1 may be a promising radioimmunotherapeutic agent for the treatment of human ovarian cancer.