Quantitative analysis of protein synthesis inhibition and recovery in CRM107 immunotoxin-treated HeLa cells.

Previously a mathematical model was proposed that quantitatively related protein synthesis inhibition kinetics of antitransferrin receptor-gelonin immunotoxins to the cellular trafficking of the targeting agent. That work is here extended to describe protein synthesis inhibition kinetics of immunotoxins containing the diphtheria toxin mutant CRM107. CRM107 differs from gelonin in both translocation and ribosomal inactivation mechanisms. Targeting agents used were antitransferrin monoclonal antibodies 5E9 and OKT9, OKT9Fab, and transferrin. CRM107 conjugates inhibited protein synthesis at substantially lower concentrations than gelonin conjugates; this effect was attributed to substantially higher translocation rates for CRM107. However, under certain conditions, CRM107 immunotoxin-treated cells were able to recover completely; this behavior was never observed with gelonin immunotoxins. To quantitatively capture this phenomenon, extracellular and cytosolic degradation of the toxin as well as growth-related recovery from toxin-induced damage were incorporated into the mathematical model. Translocation and cytosolic degradation rate constants were determined for each immunotoxin. Unlike the gelonin conjugates, the translocation rate of CRM107 conjugates depended on the targeting molecule. This provided indirect evidence that CRM107 remains disulfide linked to the targeting agent for at least part of the translocation process. Although the CRM107 conjugates all had higher translocation rates and inhibited protein synthesis at lower concentrations than the gelonin conjugates, the cells' ability to recover from protein synthesis inhibition at low immunotoxin concentrations limits the utility of CRM107 conjugates for targeted cell killing.

Influence of cellular trafficking on protein synthesis inhibition of immunotoxins directed against the transferrin receptor.

Previously, a quantitative analysis that related protein synthesis inhibition of transferrin-toxin conjugates to the cellular trafficking of transferrin was proposed (P.T. Yazdi and R. M. Murphy, Cancer Res., 54: 6387-6394, 1994). Here, this work is extended to evaluate cellular trafficking of anti-transferrin receptor antibodies and protein synthesis inhibition kinetics of immunotoxins constructed from the same antibodies and the toxin gelonin. Cellular trafficking models for two monoclonal anti-transferrin receptor antibodies (5E9 and OKT9) in HeLa cells were developed. The two mAbs had similar trafficking parameters, which differed significantly from those for transferrin. Protein synthesis inhibition kinetics for immunotoxins constructed from 5E9 or OKT9 and gelonin were measured. Analysis of the data using our previously proposed relationship between protein synthesis and cellular trafficking indicated that the relationship is also valid for these new systems. The protein synthesis inhibition constants for 5E9-gelonin and OKT9-gelonin conjugates were similar to those for the transferrin-gelonin conjugate. These results suggest that it may be possible to predict the efficacy of gelonin immunotoxins from knowledge of the trafficking of the corresponding targeting agent. A sensitivity analysis showed which cellular trafficking parameters have the greatest influence on immunotoxin efficacy and are, therefore, the most likely to be profitably manipulated.

Quantitative analysis of protein synthesis inhibition by transferrin-toxin conjugates.

A mathematical model was developed which relates the time and concentration dependence of protein synthesis inhibition of an immunotoxin to the properties of the targeting agent and the conjugated toxin. The role of the targeting agent and that of the toxin in determining the cytotoxicity were separated in this model by describing protein synthesis inhibition as a function of a cellular trafficking variable, which is calculated from the trafficking parameters of the targeting agent, and a protein synthesis inhibition constant, which is a property of the translocation and enzymatic rate constants of the toxin. Transferrin cellular trafficking parameters were determined experimentally for HeLa and SK-MEL-2 cells. Protein synthesis inhibition of transferrin-gelonin and transferrin-CRM107 conjugates in both cell lines was measured as a function of time and concentration. Analysis of the data showed that the model was a good representation of the experimental results, and correctly explained cell line differences in sensitivity to transferrin-toxin conjugates. The translocation rate constant for transferrin-CRM107 was approximately 3000 times greater than that for transferrin-gelonin. The model may be useful in understanding the factors that influence immunotoxin efficacy and in designing more lethal immunotoxins.