Chimeric proteins provide a unique opportunity to target therapeutic bacterial toxins to a subset of specific cells. We have generated a new recombinant chimeric toxin composed of human interleukin 13 (hIL13) and a Pseudomonas exotoxin A (PE) mutant, PE38QQR. The hIL13-PE38QQR chimera is highly cytotoxic to cell lines derived from several human epithelial carcinomas such as adenocarcinoma of stomach, colon, and skin. The cytotoxic action of hIL13-PE38QQR, which can only occur upon internalization of ligand-receptor complex, is blocked by an excess of hIL13 but not of hIL2. This action is not solely hIL13-specific because an excess of hIL4 also blocks the cytotoxicity of hIL13-toxin. Conversely, hIL13 blocks the cytotoxicity of a hIL4-PE38QQR chimera. Binding studies showed that hIL13 displaces competitively 125I-labeled hIL4-PE38QQR on carcinoma cells. These results indicate that IL4 and IL13 compete for a common binding site on the studied human cell lines. Despite this competition, hIL4 but not hIL13 decreased protein synthesis in malignant cells susceptible to the cytotoxicity of both hIL13- and hIL4-PE38QQR. Our results suggest that a spectrum of human carcinomas express binding sites for IL13. Furthermore, hIL13 and hIL4 compete reciprocally for a form of the receptor that is internalized upon binding a ligand. Thus, cancer cells represent an interesting model for studying receptors for these two growth factors. Finally, hIL13-PE38QQR may be a useful agent in the treatment of several malignancies.