A major goal of clinically oriented CRISPR-Cas9-based applications is safe and effectivegene editing (knockout or correction) with precise targeting. Substantial efforts have been devoted to the preclinical development of novel drug delivery platforms that enable efficient, targeted delivery. However, the immune responses induced by CRISPR-Cas9 treatment are often overlooked. Preexisting immunity to clinically relevant Cas9 proteins has already been established as a consequence of natural exposure to Cas9-bearing bacteria, which may implicate the safety and efficacy of CRISPR-Cas9-based therapies. Naturally, CRISPR-Cas9 therapies should be nonimmunogenic to avoid amplifying existing Cas9-specific immunity, especially cytotoxic T cell responses. Nonviral delivery systems, such as lipid nanoparticles (LNPs), are widely regarded as less immunogenic than more traditionally used viral vectors, even though LNPs are suitable as a vaccination platforms. In this study, we investigate the induction of SpCas9-directed immunity in C57BL/6 mice upon repeated dosing of LNPs encapsulating Cas9-coding mRNA in two different settings: (1) a vaccination-resembling setting using intramuscularly administered adjuvanted LNPs, and (2) a therapy-resembling setting using intravenously injected, liver-targeting LNPs. In both settings, Cas9-specific T cell responses were detected by evaluating increased total IFN-γ levels uponrestimulation of isolated splenocytes. However, undetectable Cas9-reactive antibodies induced in the therapeutic setting emphasize the discrepancy between humoral and cellular responses. To improve future monitoring of Cas9-specific T cell responses, we report six Cas9-derived epitopes recognized by CD8T cells, as well as a CD4T cell polypeptide carrying one of the CD8T cell epitopes that induced strong IFN-γ production. This work is intended to facilitate the preclinical monitoring of Cas9-specific T cell responses in C57BL/6 mice and support the development of safe CRISPR-Cas9-based therapies. in vivo ex vivo ex vivo + + +