The chronic lymphocytic leukemia (CLL) antigen (cCLLa) is potentially suitable for targeted immunotherapy given its restriction to clonal CLL cells and lack of expression by normal lymphocytes. In order to assess the pharmacokinetics and biodistribution of two potent anti-cCLLa immunotoxins (ITs) were examined in the mouse model. The IgG fraction of anti-cCLLa monoclonal antibody CLL2m was conjugated with 125I-labeled intact (RTA) or deglycosylated (dgA) ricin chain A, injected intravenously into athymic mice engrafted with cCLLa-expressing human tumors, and monitored over 120 hours. Blood concentrations of CLL2m/125I-RTA and CLL2m/125I-dgA were best fit to biexponential equations but the latter exhibited a lower αT1/2 and βT1/2 (4.1 and 102 min v.s 5.9and 126 min), a smaller volume of distribution (5.1 g vs 9.7 g), and a lower blood clearance (2.2 g/hr vs 4.6 g/hr). Both ITs exhibited preferential tumor uptake that followed distinct kinetics: rising tumor uptake for 2 hrs post-injection (while tissue uptake decreased), reaching tumor/non-tumoral tissue uptake ratios up to 16.9; and slower dissociation rates of tumor- vs tissue-bound ITs (<45% vs >20% remaining tissue-bound 6 hrs post-injection, respectively). Non-specific liver uptake was not prominent for either IT. In vivo IT deconjugation reached 50% approximately 12 hours post-injection. The pharmacokinetics and biodistribution data in the mouse model suggest that ricin-based anti-cCLLa ITs are suitable for use in human trials.