Pretargeted radioimmunotherapy using 131I-labelled bivalent hapten-bearing peptides

The advantages of bivalent hapten-bearing peptides for the detection oftumours pretargeted with bispecific antibodies have been demonstrated. Thistechnology is now considered for radioimmunotherapy and bivalent haptensdesigned to target ¹³¹I are needed. We thus synthesised aseries of tyrosine-containing peptides bearing the histamine-hemisuccinatehapten. These molecules were tested for their ability to bind simultaneouslytwo anti-hapten antibody molecules. One of these bivalent haptens, AG3.0,with a lysyl-d-tyrosyl-lysine connecting chain, was found to have optimalbinding characteristics and was thus selected for further investigations.AG3.0 was shown to efficiently deliver radioactive iodine to humancolorectal tumours grafted in nude mice using an anti-carcinoembryonicantigen×anti-histamine-hemisuccinate bispecific antibody. AG3.0 wasalso targeted to human B lymphoma cells pretargeted with a bispecificantibody specific for membrane IgM. In this system, bivalent ligands such asF(ab)₂ or IgG are rapidly internalised and covalentlylinked radioactive iodine is released from target cells as a result ofintracellular catabolism. With the pretargeted iodine-labelled bivalenthapten, a fivefold increase in the intracellular activity retention time ascompared to ¹²⁵I-labelled F(ab)₂ and IgGwas observed. The radiolabelled hapten did not undergo any degradation afterinternalisation. These results have been confirmed in vivo with ananti-BCL₁ IgM idiotype bispecific antibody and¹³¹I-labelled AG3.0. These reagents injected as a single 300µCi dose, 7 days after inoculation of 10⁴BCL₁ lymphoma cells in BALB/c mice, cured 14/16 of the animalsand the treatment was well tolerated. Comparatively, the same dose oflabelled IgG cured 13/16 of the mice but three mice died of haematologictoxicity. The same dose of labelled F(ab)₂ orFab was completely inefficient. was completely inefficient. ¹³¹I-labelled bivalenthaptens are now used in phase I radioimmunotherapy clinical trials.     

Radioimmunotherapy of small-cell lung cancer xenografts using131I-labelled anti-NCAM monoclonal antibody 123C3

We have studied the therapeutic efficacy of¹³¹I-labelled monoclonal antibody 123C3 in human small-cell lung carcinoma xenografts established from the NCI-H69 cell line in nude mice. Several radiation does were administered intraperitoneally and different treatment schedules were tested. The maximal tolerated dose, 2×500 Ci, resulted in complete remission of tumours smaller than 200 mm³ and long-lasting remission (more than 135 days) of the larger tumours. In control experiments, treatment with unlabelled monoclonal antibody 123C3 did not affect the tumour growth rate, while the effect of radiolabelled non-relevant, isotype-matched, monoclonal antibody M6/1 was minor and transient. Regrowth of the tumours occurred in all cases and could not be attributed to loss of neural cell adhesion molecule (NCAM) expression. Tumour recurrence is probably caused by insufficient radiation dosage. Radiation-induced toxicity was monitored by assessment of weight and bone marrow examination. Weight loss was observed in all treatment groups, but the mice regained their initial weight within 14 days, except for the group receiving the highest radiation dose (3×600 Ci). In this group all mice died as a result of radiotoxicity. Of the mice injected with 600 Ci radiolabelled control antibody, 50% died within 2 weeks after administration. Apparently the higher uptake of the radiolabelled monoclonal antibody in the tumour reduced systemic radiation toxicity.     

Treatment of human lung carcinoma xenografts with a combination of 131I-labelled monoclonal antibody Po66 and doxorubicin

 Po66, a mouse monoclonal antibody, is directed against an intracytoplasmic antigen present in human lung squamous cell carcinoma cells. In previous work it was found that the co-administration of ¹²⁵I-radiolabelled Po66 and doxorubicin strongly enhanced the uptake of radioactivity by the tumour. The present-work was designed to evaluate, in a tumour-bearing mouse model of lung carcinoma, the ability of ¹³¹I-labelled Po66 to retard tumour growth when injected alone, or in combination with doxorubicin (8 mg kg ^– 1 at 1-week intervals). A single dose of 550 μCi ¹³¹I-Po66 alone had no effect on tumour growth, whereas three fractionated doses of 250 μCi ¹³¹I-Po66 decreased it over two doubling times from 14.5±1.5 days for untreated control mice to 24.8±2.7 days. Mice treated with doxorubicin alone had a double tumour doubling time of 22.6±4.9 days, compared to 35.2±2.9 days (1.55-fold increase) in mice treated with doxorubicin and a single dose of 550 μ Ci ¹³¹I-Po66. Doxorubicin combined with three fractionated doses of 250 μCi ¹³¹I-Po66 provoked a twofold decrease in tumour growth compared to mice treated with doxorubicin alone. The administration of fractionated doses of ¹³¹I-Po66 simultaneously with doxorubicin resulted in a highly delayed mortality, which was not observed when ¹³¹I-Po66 was administered after doxorubicin. Thus, in a non-small-cell lung tumour model, a ¹³¹I-radiolabelled monoclonal antibody, directed against an intracellular antigen, significantly potentiated the effect of chemotherapy. Such a therapeutic approach could be used as an adjuvant therapy and improve the effect of chemotherapy on distant small metastases. Received: 20 June 1996 / Accepted: 3 October 1996     

Detection of carcinoembryonic antigen using single-domain or full-size antibodies stained with quantum dot conjugates

Compact single-domain antibodies (sdAbs) are nearly 13 times smaller than full-size monoclonal antibodies (mAbs) and have a number of advantages for biotechnological applications, such as small size, high specificity, solubility, stability, and great refolding capacity. Carcinoembryonic antigen (CEA) is a tumor-associated glycoprotein expressed in a variety of cancers. Detection of CEA on the tumor cell surface may be carried out using anti-CEA antibodies and conventional fluorescent dyes. Semiconductor quantum dots (QDs) are brighter and more photostable than organic dyes; they provide the possibility for labeling of different recognition molecules with QDs of different colors but excitable with the same wavelength of excitation. In this study, the abilities for specific detection of CEA expressed by tumor cells with anti-CEA sdAbs biotinylated in vitro and in vivo, as well as with anti-CEA mAbs biotinylated in vitro, were compared using flow cytometry and the conjugates of streptavidin with QDs (SA-QDs). The results demonstrated that either in vitro or in vivo biotinylated anti-CEA sdAbs are more sensitive for cell staining compared to biotinylated anti-CEA mAbs. The data also show that simultaneous use of biotinylated sdAbs with highly fluorescent SA-QDs can considerably improve the sensitivity of detection of CEA on tumor cell surfaces.     

Correlation of beta-camera imaging and immunohistochemistry in radioimmunotherapy using90Y-labeled monoclonal antibodies in ovarian cancer animal models

Tumor stroma contains much fibrin and monoclonal antifibrin antibody targeting is possible in tumors. In this study, nude mouse human ovarian carcinoma xenograft specimens were investigated after treatment with⁹⁰Y-labeled monoclonal antifibrin antibody Fab fragment or with⁹⁰Y-labeled OC125-monoclonal antibody F(ab′)₂ fragments. The mice received the radioimmunotherapy activity either intratumorally, intraperitoneally, or intravenously. Beta-camera imaging (BCI) is a novel device for studying activity distribution in tissue specimens and, together with immunohistochemistry (IHC) with OC125, antifibrin, anticarcinoembryonic antigen, anti-cytokeratin, and anti-placental alkaline phosphatase antibodies, was used for correlation of activity distribution of tissue specimens. These results were in concordance: Antigen distribution measured with IHC and radioactivity distribution were similar with the same antibodies, antifibrin, and OC125: However, these antigens demonstrated rather different distribution. Tissue studies revealed that activity was concentrated also in the necrotic tumor tissue, indicating that cell death was also caused by radiation. Differences in the tumor cell morphology were observed using different routes of administration. With BCI, it is possible to quantitate activities in frozen sections (microdosimetry), and these results were in concordance with absolute activities as measured by tissue sampling and well-counting. Three-dimensional reconstruction of tissue slices combined with radioactivity distribution measured with BCI allows estimation of total absorbed radiation dose in tumor after an appropriate dose planning.     

Combination therapy using the cyclooxygenase-2 inhibitor Parecoxib and radioimmunotherapy in nude mice with small peritoneal metastases of colonic origin

Background: Inhibition of the COX-2 enzyme has been shown to have a radiosensitizing effect in epithelial cancers. The aim of this study was to investigate whether the efficacy of radioimmunotherapy (RIT) using ¹³¹I-labeled anti-CEA monoclonal antibody MN-14 could be enhanced by co-administration of the selective COX-2 inhibitor Parecoxib in mice with small volume (1–3 mm) peritoneal carcinomatosis of colonic origin. Methods: First, the efficacy of 14 daily injections of Parecoxib monotherapy (0 – 0.2 – 1.0 – 5.0 – 25.0 mg/kg) was determined in mice with intraperitoneal LS174T xenografts. Second, the influence of Parecoxib (1.0 or 5.0 mg/kg) on the biodistribution of ¹²⁵I-MN-14 was assessed. Finally, the efficacy of RIT alone [125 μCi ¹³¹I-MN-14/mouse ≈ 1/4 of the maximal tolerated dose (MTD)] was compared with that of Parecoxib monotherapy and RIT combined with daily injections of Parecoxib (1.0 or 5.0 mg/kg). Results: Parecoxib had no measurable antitumor effect up to the highest dose level (25 mg/kg). Parecoxib had no effect on the uptake of ¹²⁵I-MN-14 in the intraperitoneal tumor xenografts or on normal tissue distribution. Median survival of the control mice and the mice treated with Parecoxib monotherapy (1.0 or 5.0 mg/kg) was 48.5 days, 52 days and 52 days (P=0.47). RIT alone significantly delayed the growth of the intraperitoneal xenografts resulting in a median survival of 87 days (P<0.0001). Mice treated with RIT + Parecoxib at 1.0 or 5.0 mg/kg had a median survival of 73.5 days and 76 days, respectively, which was not statistically different from survival after RIT alone (P=0.15). Conclusion: The COX-2 inhibitor Parecoxib does not enhance the therapeutic efficacy of RIT of experimental small volume peritoneal carcinomatosis of colonic origin.     

Selective gene therapy for prostate cancer cells using liposomes conjugated with IgM type monoclonal antibody against prostate-specific membrane antigen

Prostate cancer cells express prostate-specific membrane antigen (PSMA). We developed an IgM type monoclonal antibody against PSMA. The antibody was coupled to poly-L-lysine and thereafter this conjugate was mixed with cationic liposomes containing plasmid DNA. The antibody-liposome complex was tested whether it could deliver the gene of interest selectively to the PSMA positive cells. As assessed by beta-galactosidase reporter gene, the transfection efficiency was 13.2% with anti-PSMA-liposome complex as compared to 4% with control IgM liposome complex. In contrast, no such differences were observed in PSMA negative PC-3, DU145 and T24 cells. Furthermore, in the suicide gene therapy in vitro with thymidine kinase gene plus ganciclovir system, anti-PSMA liposome complex demonstrated a selective growth inhibitory effect on PSMA positive LNCaP cells but not on PSMA negative cell lines.     

Determination and analysis of antigenic epitopes of prostate specific antigen (PSA) and human glandular kallikrein 2 (hK2) using synthetic peptides and computer modeling.

Prostate specific antigen (PSA) and human glandular kallikrein 2 (hK2), produced essentially by the prostate gland, are 237-amino acid monomeric proteins, with 79% identity in primary structure. Twenty-five anti-PSA monoclonal antibodies (Mabs) were studied for binding to a large array of synthetic linear peptides selected from computer models of PSA and hK2, as well as to biotinylated peptides covering the entire PSA sequence. Sixteen of the Mabs were bound to linear peptides forming four independent binding regions (I-IV). Binding region I was localized to amino acid residues 1-13 (identical sequence for PSA and hK2), II (a and b) was localized to residues 53-64, III (a and b) was localized to residues 80-91 (= kallikrein loop), and IV was localized to residues 151-164. Mabs binding to regions I and IIa were reactive with free PSA, PSA-ACT complex, and with hK2; Mabs binding to regions IIb, IIIa, and IV were reactive with free PSA and PSA-ACT complex, but unreactive with hK2; Mabs binding to region IIIb detected free PSA only. All Mabs tested (n = 7) specific for free PSA reacted with kallikrein loop (binding region IIIb). The presence of Mabs interacting with binding region I did not inhibit the catalytic activity of PSA, whereas Mabs interacting with other binding regions inhibited the catalysis. Theoretical model structures of PSA, hK2, and the PSA-ACT complex were combined with the presented data to suggest an overall orientation of PSA with regard to ACT.