Novel Ab-based immunotherapeutic strategies have exploited T-cell receptor-like chimeric immune receptors (CIR) expressed on the surface of transduced human peripheral blood mononuclear cell (PBMC) to redirect potent non-major histocompatibility complex-dependent cytotoxicity to tumor cells expressing a tumor-associated antigens. We transduced human PBMC with 2 fully human CIRs that trigger through the zeta-chain of CD3 and contain either one of two human scFv specific for the same epitope on the extracellular domain of HER2 but with distinctly different affinities (KD 1616 and 1 nM) for this antigen. Potent direct CIR-mediated killing and in vitro tumor growth inhibition mediated by transduced PBMC were observed against targets expressing different levels of HER2. High-affinity CIR showed stronger ability to bind Ag and retain binding than low-affinity CIR. When lytic potential of the 2 CIRs was evaluated, their efficiency was comparable under conditions of high CIR and Ag expression, whereas low-affinity CIR was more efficient than high-affinity CIR in conditions of limiting Ag and CIR expression levels. When tumor growth inhibition was evaluated, Ag and CIR levels, rather than CIR affinity appeared relevant. Ag-driven CIR activation resulted in the production of soluble factors mediating efficient bystander effect. By carefully defining CIR surface expression and increasing affinity for a specific target antigen, it may be possible to selectively exclude CIR-mediated activity against targets expressing low levels of antigen, as normal cells. On the contrary, low antigen-expressing tumor variants could be eliminated by decreasing CIR affinity. Tuning CIR expression and affinity might help in discriminating different biologic contexts.