Immunohistochemical analysis of tumor antigen saturation following injection of monoclonal antibody G250.

Clinical tumor targeting studies with monoclonal antibody (mAb) G250 showed excellent targeting of primary renal cell carcinomas (RCC). However, tumor uptake decreased at higher mAb G250 doses, suggesting saturation of the G250 antigenic determinants. In this immunohistochemical study we investigated the saturability of G250 antigen sites after i.v. administration of mAb G250 at various protein doses in nude mice with RCC xenografts. Five groups of mice received five different protein doses (1, 3, 10, 30 or 100 micrograms) of murine mAb G250. Three days post injection mice were killed and the tumors were removed. Free G250 antigen sites, i.e., not targeted by the i.v. injected murine mAb G250 were determined by immunohistochemical staining with chimeric mAb G250. Distinct staining of the G250 antigen was observed only at the 1 and 3 micrograms dose whereas G250 antigen staining at higher doses was virtually negative. The results of this study indicate that saturation of antigen occurs at relatively low doses of i.v. administered mAb G250. Apparently, all antigenic determinants present on the RCC tumor cells were targeted, while previous preclinical studies suggested that i.v. administration of mAb G250 only saturated the accessible antigen sites.

A quantitative analysis of vascularization and perfusion of human glioma xenografts at different implantation sites.

The effect of tissue site of implantation of four different human gliomas on tumor vascularity and perfusion was examined. Vascular parameters of gliomas implanted subcutaneously in the nude mouse and intracerebrally in the nude rat were analyzed. Tumor vessels were stained with an antibody to collagen type IV and perfusion was investigated with the perfusion marker Hoechst 33342. Characteristic vascular patterns were observed in both intracerebral and subcutaneous xenografts belonging to the same tumor line. Major differences in vascular architecture and in the degree of vascularization were noted in comparisons of the two implantation sites for the same tumor line. Tumor perfusion was highly variable for both locations of tumor growth. Distinct differences between the implantation sites of similar tumor lines in vascular perfusion, intervascular distance, and vascular density were present. Incomplete perfusion of vascular structures, as seen in this study, may result in reduced delivery of oxygen to tumor areas. Therefore, measurements of vascular density and intervascular distance alone, without knowledge of the perfusion status, may not be sufficient to estimate the degree of tumor oxygenation. Furthermore, differences in vascular parameters may have important consequences for treatment modalities such as radiotherapy and chemotherapy. Thus, the findings in our study suggest that care has to be taken in extrapolating therapy results obtained with subcutaneous glioma tumor models to the original growth location of gliomas, the brain, due to major differences in vasculature.

Immunohistochemical analysis of intratumoral heterogeneity of [131I]cG250 antibody uptake in primary renal cell carcinomas.

In previous studies, highly heterogeneous uptake of 131I-labelled chimeric monoclonal antibody G250 ([131I]cG250) in primary renal cell carcinomas has been observed (intratumoral differences > factor 100). In this study, we investigated a possible correlation between intratumoral antibody uptake and four immunohistochemically determined parameters: G250 antigen expression, blood vessel density, neovascularization and percentage of viable tumour cells. Whole tumour slices of four different tumours were cut into 1-cm3 cubes, and in each cube the [131I]cG250 uptake was determined. The correlation between [131I]cG250 uptake and each individual parameter was determined in a multiple regression analysis. Additionally, the data were reanalysed after introducing arbitrary cut-off values for each parameter. If a sample showed expression of a parameter above the introduced threshold value, this sample fulfilled one condition. Subsequently, the Pearson correlation coefficients were calculated from [131I]cG250 uptake and the number of fulfilled conditions (0-3). All tumour samples with high [131I]cG250 uptake [> 0.1% of the injected dose per gram (ID g(-1))] showed high antigen expression (> 50%). However, not all samples with high antigen expression displayed high uptake. A statistically significant correlation between [131I]cG250 uptake and antigen expression was found (beta = 0.44, 0.69 and 0.74) in three out of four tumours analysed. Of the other determined parameters, no consistent correlation with [131I]cG250 uptake was found; only the percentage of viable tumour cells correlated significantly in two out of four tumours (beta = 0.80 and 0.26). Calculation of the Pearson correlation coefficients showed a statistically significant correlation between [131I]cG250 uptake and an increased number of fulfilled conditions in all tumours, indicating that each of the individual parameters contribute to the uptake of [131I]cG250. These observations indicate that high antigen expression is a prerequisite for high antibody uptake. However, regional differences in antibody uptake within a tumour cannot be explained by antigen expression alone.

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.

Vascular perfusion and hypoxic areas in RIF-1 tumours after photodynamic therapy.

The influence of photodynamic therapy (PDT) on vascular perfusion and the development of hypoxia was investigated in the murine RIF-1 tumour. Image analysis was used to quantify changes in perfusion and hypoxia at 5 min after interstitial Photofrin-mediated PDT. The fluorescent stain Hoechst 33342 was used as an in vivo marker of functional vascular perfusion and the antibody anti-collagen type IV as a marker of the tumour vasculature. The percentage of total tumour vasculature that was perfused decreased to less than 30% of control values after PDT. For the lower light doses this decrease was more pronounced in the centre of the tumour. The observed reduction in vascular perfusion showed a good linear correlation (r = 0.98) with previously published tumour perfusion data obtained with the 86Rb extraction technique. The image analysis technique provides extra information concerning the localisation of (non)-perfused vessels. To detect hypoxic tumour areas in vivo, an immunohistochemical method was used employing NITP [7-(4'-(2-nitroimidazol-1-yl)-butyl)-theophylline]. A large increase in hypoxic areas was found for PDT-treated tumours. More than half the total tumour area was hypoxic after PDT, compared with < 4% for control tumours. Our studies illustrate the potential of image analysis systems for monitoring the functional consequences of PDT-mediated vascular damage early after treatment. This provides direct confirmation that the perfusion changes lead to tissue hypoxia, which has implications for the combined treatment of PDT with bioreductive drugs.