ABSTRACT: Lung adenocarcinoma with KRAS mutation represents a formidable challenge in cancer treatment due to its undruggable oncogenic mutation. Here, we explored the CasRx-editing approach on lung adenocarcinoma driven by the KRAS activation and Tp53 loss in vivo, a scenario closely resembling clinical conditions. We screened seven sgRNAs in cultured cells and identified that CasRx combined with sgRNA5 effectively suppressed murine KRASG12D transcript levels by 93.185 ± 4.758%, leading to significant attenuation of cell viability and proliferation. Subsequently, we administered CasRx + sgRNA5 via in vivo Adeno-associated viruses (AAV) delivery at the early tumorigenesis stage, resulting in inhibition of tumor initiation and progression, ultimately enhancing the survival of the mice. Mechanistically, the treatment directly targeted the classic KRAS signal pathways and regulated a potential protein network comprising KRAS, DUSP8, NR4A1, DUSP1, and EGR1. Encouragingly, the CasRx + sgRNA5 treatment in mice bearing the induced lung adenocarcinoma demonstrated an optimistic therapeutic outcome, characterized by reduced mutation burden, diminished tumor size, and seemingly improved overall survival. Remarkably, no obvious off-target events were detected in the treated tissues, highlighting the specificity and safety of CasRx + sgRNA5 therapy. This study establishes the feasibility of CasRx-based-KRASG12D editing for efficient in vivo tumor inhibition and provides insights into the potential role of the KRAS-associated protein network in the early development of lung cancer. These findings hold great promise for the development of novel targeted therapies for this aggressive malignancy.