Abstract Mouse NK cells recognize MHC-I antigens via stochastically expressed inhibitory Ly49 receptors. The loss of MHC-I expression on tumor cells (“missing self”) abrogates inhibitory signals, resulting in NK activation. We have identified an anti-mouse pan MHC-I mAb (M1/42), which blocks Ly49-MHC-I interactions but not TCR-MHC-I interactions. Administration of M1/42 in vivo markedly activated IFNg-producing NK cells that further drove the proliferation of NK cells and memory phenotype (MP) T cells and profoundly augmented adaptive immunity against viral infection and cancer metastasis. In contrast to mouse Ly-49 antigens, human killer cell inhibitory receptors bind to HLA at a site overlapping the TCR binding site and blocking of KIR binding to MHC-I would inhibit TCR recognition. However, two anti-pan-human MHC-I abs (DX17 and W6/32) markedly induced NK cell proliferation and IFNg production in cultures of human PBMC. DX17 potently blocked the interaction of leukocyte Ig-like inhibitory receptors LILRB1, B2, B3 and B5 with human MHC-I but had no effect on TCR-MHC-I interactions. The crystal structure of a DX17 Fab/MHC-I complex reveals that the footprint of DX17 overlaps the LILRB1 binding site on MHC-I. Administration of W6/32 Fab to humanized mice (PBMC reconstituted NSG or NK cell reconstituted NOG-IL-15) induced human NK and MP T cell proliferation. Marked reduction of tumor size was seen when NOG-hIL-15Tg mice were reconstituted with CD3 −cells and then treated with W6/32 Fab. DX17 Fc silenced mAb (DX17 LALAPG) activated human tumor infiltrating lymphocytes and monocytes. These results strongly suggest that inhibition of LILRB-MHC-I interactions by anti-MHC-I in humans may result in marked augmentation of anti-tumor immunity. This work was supported by the Intramural Research Program of NIAID, NIH.