Development and characterization of anti-renal cell carcinoma x antichelate bispecific monoclonal antibodies for two-phase targeting of renal cell carcinoma.

To test a two-step approach for radioimmunotargeting of renal cell cancer, quadroma cells secreting antichelate x anti-renal cell carcinoma bispecific antibodies were obtained by somatic cell fusion. Five monoclonal antibodies against the chelate 1,4,7-triazaheptane-N,N',N"-pentaacetic acid (DTPA) were produced and characterized. Competitive binding assays indicated that the anti-DTPA antibodies reacted with DTPA chelated with indium, yttrium, chromium, iron, or zinc. The affinity constants of the anti-DTPA antibodies for 111In-DTPA ranged from 0.19 to 0.23 nM-1. Using different chelates, a remarkable chelate specificity of the anti-DTPA antibodies was demonstrated. The chelates recognized by the antibodies DTIn1, DTIn2, and DTIn4 share a N(N")-diacetic acid group, whereas the chelates recognized by DTIn3 share a N'-acetic acid group, suggesting the presence of different essential structures within the DTPA molecule that determine the reactivity of the antibodies. Five anti-DTPA antibody-producing hybridomas were used for somatic cell fusion with hybridoma G250 directed against renal cell carcinoma, resulting in three bispecific antibody-producing quadroma cell lines. The bispecific monoclonal antibodies were purified from ascites fluid using protein A affinity chromatography followed by hydroxylapatite chromatography and/or cation exchange chromatography. Of the total IgG amount present in the ascites fluid, 10-15% represented the bispecific antibodies. These bispecific antibodies will allow testing and optimization of a two-step approach for radioimmunotargeting of chelated radionuclides.

Pretargeting of renal cell carcinoma: improved tumor targeting with a bivalent chelate.

Radiolabeled monoclonal antibodies (mAbs) can target tumors selectively. Sustained activity levels in nontarget tissues limit their application. Pretargeting approaches using bispecific mAbs (bsmAbs) or the biotinavidin interaction have been proposed to improve tumor:nontumor ratios. Pretargeting a tumor and subsequently administering the radioactivity as a low molecular weight ligand fundamentally changes the pharmacokinetics of the radiolabel. In previous studies, we have shown successful radioimmunotargeting of diethylenetriaminepentaacetic acid (DTPA) labeled with indium-111 to renal cell carcinoma (RCC) after pretargeting in nude mice. In this study, we aimed to optimize further a pretargeting strategy in nude mice with RCC xenografts based on a bispecific anti-RCC x anti-DTPA mAb. Using this two-step approach, we studied whether the use of a bivalent chelate ((111)In-diDTPA) could improve radioimmunotargeting. The (111)In-diDTPA dose greatly affected the uptake of the radiolabeled chelate in the tumor. At a low (111)In-diDTPA dose (< or = 7 pmol), tumor uptake of (111)In-diDTPA was very high [>50% injected dose (ID)/g, 1 h postinjection (p.i.)], whereas at higher doses (> or = 20 pmol), tumor uptake of (111)In-diDTPA decreased (<30% ID/g). With monovalent (111)In-DTPA uptake of the radiolabel in the tumor was much lower (<10% ID/g, 1 h p.i.). Furthermore, the bivalent chelate accreted rapidly in the tumor (78% ID/g, 4 h p.i.) and was virtually completely retained in the tumor during several days p.i. (92% ID/g, 72 h p.i.). Clearance of the (111)In-diDTPA from the blood and kidneys was rapid and complete without the need to clear the bsmAb from the blood, probably due to the relative lability of the univalent bsmAb-diDTPA complexes in the blood. As a result, with this two-step pretargeting approach tumor:blood ratios increased up to values as high as 3500 at 72 h p.i. High doses of diDTPA could be targeted preferentially to the tumor, indicating that this approach could also be used for radioimmunotherapy. Tumors could be imaged up to 1 week p.i. of 50 microCi of (111)In-diDTPA. Quantitative analysis of the images confirmed the biodistribution data and indicated that, at 20 h p.i., 50 +/- 15% of the whole-body activity was localized in the tumor. In conclusion, these studies indicate that the use of bivalent chelates can very effectively optimize two-step targeting of tumors with bsmAbs. Our data indicate that this approach could optimize radioimmunotherapy.

Rapid imaging of experimental infection with technetium-99m-DTPA after anti-DTPA monoclonal antibody priming.

UNLABELLED: Antibodies accumulate nonspecifically in infectious foci due to the locally increased vascular permeability. This study describes a method of infection imaging in which 99mTc-DTPA (diethylenetriaminepentaacetic acid) is trapped at the target by a previously administered anti-DTPA monoclonal antibody. DTIn1. METHODS: Rats with Staphylococcus aureus-infected calf muscle were injected intravenously with DTIn1. Two to 24 hr after the DTIn1 injection, 99mTc-DTPA was injected intravenously. In separate experiments, excess DTIn1 was cleared from the circulation 2 hr after injection with bovine serum albumin (BSA)-DTPA-In, galactosylated BSA-DTPA-In, goat antimouse IgG or avidin. Additionally, the effect of DTIn1 dose on 99mTc-DTPA abscess uptake was determined in a three-step protocol. The distribution of the radiolabels was studied by gamma counting of dissected tissue and gamma camera imaging. RESULTS: Priming with DTIn1 resulted in specific retention of 99mTc-DTPA in the abscess. Such 99mTc-DTPA abscess uptake was not dependent on the interval between the DTIn1 and the 99mTc-DTPA injection: Optimal 99mTc-DTPA abscess uptake was already achieved within a 2-hr time span between the DTIn1 and DTPA injections. However, relatively high 99mTc-DTPA background was observed due to slowly clearing DTIn1-99mTc-DTPA complexes. Background reduction with various agents had a prominent effect on DTIn1 as well as 99mTc-DTPA biodistribution. The best reduction was obtained using BSA-DTPA-In. Optimal 99mTc-DTPA abscess uptake in the three-step protocol was obtained at higher DTIn1 doses (> 100 micrograms). CONCLUSION: Infectious foci in a rat model can be imaged earlier with extremely low background levels after priming with DTIn1, followed by BSA-DTPA-In and imaging with 99mTc-DTPA, as compared with directly labeled IgG.

In vivo and in vitro characterizations of three 99mTc-labeled monoclonal antibody G250 preparations.

UNLABELLED: In previous clinical studies, excellent visualization of tumor lesions has been observed with 131I-labeled monoclonal antibody (mAb) G250 in patients with renal cell carcinoma (RCC). In several cases, 131I-cG250 immunoscintigraphy disclosed tumor lesions that were not visualized by radiography or CT. To improve image quality, we aimed to develop a 99mTc-labeled mAb G250 preparation for radioimmunodetection of RCC. We studied in vitro stability, biodistribution and imaging potential of three 99mTc-labeled G250 preparations in nude mice with subcutaneous RCC xenografts.125I-G250 and the nonspecific mAb 131I-MN14 were used as control antibodies. METHODS: The mAb G250 was labeled with 99mTc according to three methods using: (a) S-hydrazinonicotinamide (HYNIC), (b) S-benzoylmercaptoacetyltriglycine (MAG3) and (c) a direct labeling method (Schwarz method). The stability of all preparations was tested in serum at 37 degrees C during 48 h. In addition, diethylenetriamine pentaacetic acid, cysteine and glutathione challenge assays were performed. RESULTS: All preparations showed good stability in serum during the 48-h incubation period. 99mTc-G250 (Schwarz) showed release of the radiolabel at a 100-fold or higher molar excess of cysteine and at a 10,000-fold or higher molar excess of glutathione. 99mTc-MAG3-G250 showed release of the radiolabel at a 10,000-fold molar excess of cysteine. 99mTc-HYNIC-G250 was stable under all conditions. Tumors were clearly visualized with all preparations. 99mTc-G250 (Schwarz) showed significantly lower blood levels (3.8 %ID/g) compared with all other preparations (11.2, 13.4 and 13.4 %ID/g for 99mTc-HYNIC-G250, 99mTc-MAG3-G250 and 125I-G250, respectively, 48 h postinjection). At 48-h postinjection, mean tumor uptake was very high with all mAb G250 preparations: 92.4 (99mTc-HYNIC-G250), 125.9 (99mTc-MAG3-G250), 29.4 (99mTc-G250 Schwarz) and 75.4 (125I-G250) %ID/g. Mean tumor uptake of the nonspecific 131I-MN14 mAb was 6.6 %ID/g. CONCLUSION: In this study, 99mTc-HYNIC-G250 showed excellent in vitro stability and tumor targeting. Moreover, this preparation could be labeled with high efficiency (>95%) at room temperature within 15 min. Therefore, 99mTc-HYNIC-G250 seems to be an ideal candidate for radioimmunodetection of RCC.

MON-150, a versatile monoclonal antibody against involucrin: characterization and applications.

A monoclonal antibody, designated MON-150, was found serendipitously to react strongly with the granular layer of normal human epidermis and with the upper spinous layers of psoriatic epidermis. From analysis by flow cytometry of cultured human keratinocytes, it appeared that the percentage of MON-150-positive cells strongly increased when the cells reached confluence and the growth fraction declined. To identify the antigen recognized by MON-150, a lysate of human keratinocytes was subjected to affinity chromatography using a MON-150 Sepharose column. This yielded a single protein of approximately 350 kDa as measured on Superose 6 FPLC gel permeation chromatography using non-denaturing conditions. In Western blot analysis under denaturing and reducing conditions, a 140-kDa protein was detected. The subcellular localization and the molecular weight of the antigen recognized by MON-150 suggested that the antigen involved might be involucrin. This was confirmed using a commercial polyclonal antiserum against involucrin. We conclude that MON-150 is a new, versatile antibody against human involucrin.

Tumor retention of 186Re-MAG3, 111In-DTPA and 125I labeled monoclonal antibody G250 in nude mice with renal cell carcinoma xenografts.

UNLABELLED: In radioimmunotherapy of solid tumors substantial gain might be achieved by carefully selecting the radionuclide and the linker connecting it to the antibody. In contrast to 131I, radiometals such as 90Y and 111In may be retained in the tumor cell after internalization of the antibody, thereby enhancing the radiation dose to the tumor. The physical properties of 186Re with 1.08 MeV beta-emission (71%) and 137 keV gamma-emission (10%) seem ideal for radioimmunotherapy. In this study we investigated in nude mice with s.c. renal cell carcinoma xenografts the biodistribution and the retention in the tumor of 186Re-MAG3 labeled monoclonal antibody (mAb) G250 as compared to 111In-DTPA-G250, to 125I-G250 and to 131I-MN14 (non-specific control mAb). Radiolabeled antibody preparations were i.v. injected. Seventy two hours p.i. the biodistribution of the radiolabel was determined. Blood levels of all mAb G250 preparations were remarkably low (mean: 2.38, 1.40 and 1.43% ID/g for 125I, 111In and 186Re respectively) whereas blood levels of mAb MN14 were significantly higher (mean: 12.3% ID/g), indicating tumor processing of mAb G250. Retention of 111In in the tumor was significantly higher than of 186Re and 125I whereas retention in the tumor of 186Re and 125I did not differ significantly. CONCLUSION: In contrast to other radiometals such as 111In and 90Y, 186Re is not retained in the tumor cell. Therefore 186Re has no additional advantage for radioimmunotherapy with respect to retention in the tumor.

The effect of antibody protein dose of anti-renal cell carcinoma monoclonal antibodies in nude mice with renal cell carcinoma xenografts.

BACKGROUND: Antibodies preferentially can direct radionuclides to solid tumors. However, antibody uptake in tumors is often highly heterogeneous. This heterogeneity may be overcome by increasing antibody protein dose. METHODS: The biodistribution of increasing protein doses of radioiodinated antirenal cell carcinoma (RCC) monoclonal antibodies (MoAbs) G250 and RC 38 was studied in mice with NU-12 or SK-RC-52 RCC xenografts. In addition, MoAb affinity constants and antigen densities (Scatchard analysis) and MoAb processing (internalization) were determined in vitro. RESULTS: The relative uptake of G250 in NU-12 tumors was very high at low protein doses (125% injected dose/g [%ID/g]), but decreased at higher doses, suggesting tumor saturation. Indeed, saturation of G250 antigen occurred at 3 microg protein. In this model, 9200 G250 determinants per NU-12 cell could be targeted, which is only 6.1% of the 150,000 G250 determinants per NU-12 cell as determined in vitro. The RC 38 uptake in NU-12 tumors remained constant up to the 10 microg dose level (40% ID/g) and decreased at higher doses. RC 38 antigens were saturated at 25 microg of RC 38. With RC 38, 15% of the available RC 38 antigens per NU-12 tumor cell were targeted. In contrast, G250 uptake in SK-RC-52 tumors was very low at low antibody dose (4% ID/g at 1 microg) and increased with increasing protein dose. These differences in G250 biodistribution might be related to differences in the processing of G250 by the tumor cells. CONCLUSIONS: Our studies show that some RCC tumors can be saturated with anti-RCC MoAbs at low (25 microg) to very low (3 microg) protein doses. At nonsaturated doses relatively high tumor uptake can be achieved. Surprisingly, in NU-12 tumors only 6.1% and 15% of the available antigenic sites were targeted at the saturating dose levels with G250 and RC 38, respectively.

Two-step radio-immunotargeting of renal-cell carcinoma xenografts in nude mice with anti-renal-cell-carcinoma X anti-DTPA bispecific monoclonal antibodies.

The specificity of antibodies offers unique opportunities to target tumors with radionuclides. However, due to the slow clearance of radiolabeled antibody, relatively high back-ground is observed in non-target organs. Pre-targeting protocols using bispecific monoclonal antibodies (bsMAbs) and radiolabeled chelates may overcome this problem. We have evaluated the anti-renal-cell-carcinoma (RCC) X anti-DTPA bsMAb G250 x DTIn1 for 2-step targeting of RCC tumors in nude mice. Tumor uptake of 111In-DTPA was similar up to a 3-day interval between bsMAb and 111In-DTPA injections and decreased thereafter. The effect of G250 x DTIn1 protein dose was studied. High tumor uptake was seen at 1 to 4 micrograms, whereas at higher doses uptake decreased. Tumor was saturated with 15 micrograms bsMAb. At the saturating bsMAb dose the 111In-DTPA amount was varied. High tumor uptake was observed at a 10-fold molar excess 111In-DTPA, whereas at higher excess uptake decreased. After priming with 15 micrograms bsMAb and targeting with a 10-fold molar excess 111In-DTPA, the biodistribution of 111In-DTPA was studied for 1 to 48 hr after injection. Good tumor retention of 111In-DTPA was observed, while the radiolabel cleared rapidly from the blood. Consequently, tumor-to-blood ratios increased with time to 500 at 24 hr after injection. In conclusion, RCC xenografts can be targeted efficiently using G250 x DTIn1 and 111In-DTPA. However, this requires careful tuning of bsMAb protein dose and 111In-DTPA dose. Using the optimal protein dose and 111In-DTPA dose, high 111In-DTPA tumor uptake and tumor-to-blood ratios can be obtained, thus providing good perspectives for diagnostic and therapeutic use in humans.