Abstract Chemotherapeutic agents not only cause apoptosis and necrosis of cancer cells but also induce cellular senescence (TIS), resulting in a persistent cell population that re-enters the cell cycle with stemness characteristics via the senescence-associated secretory phenotype. These senescent cancer cells, therefore, seed disease relapses if they are not effectively eliminated. TIS cancer cells lack HLA expression and cannot be targeted by T cells. Herein, we show that chemotherapy-induced senescent B16F10 cells express the NK ligands Rae1e and Ulbp1, and are effectively killed by mouse NK cells in vitro. Docetaxel treatment also induced senescent B16F10 cells in vivo. We have previously shown that the TGF-β trap/IL-15 fusion protein, aka HCW9218, effectively activates NK cells in vivo. Therefore, we treated B16F10 tumor bearing mice with docetaxel and then a single dose of HCW9218 in combination with the ADCC antibody TA99. This treatment regimen exhibited potent antitumor activity compared to docetaxel alone. End point analysis showed that HCW9218-treated tumors have lower mitotic activity, reduced expression of senescence markers, and increased frequencies of infiltrating CD8 T cells. We further showed in this model that HCW9218 treatment followed by anti-PD-L1 therapy was more effective than anti-PD-L1 therapy followed by HCW9218. These results suggest that the optimal sequence of cancer treatment is: (1) standard-of-care chemotherapy to control tumor burden and induce cellular senescence, (2) immunotherapy for removal of senescent cells and enhanced tumor infiltration of CD8+ T cells and (3) checkpoint blockade to maintain infiltrated T cell effector function to enhance therapeutic responses and treatment durability.