Induced pluripotent stem cells as platforms for engineering NK cell immunotherapies

Human induced pluripotent stem cells (iPSCs) are transforming adoptive cell therapy by combining unlimited self-renewal, broad differentiation potential, and high amenability to genome engineering. These attributes make iPSCs a versatile source for the development of standardized immune effector cells at industrial scale, enabling a shift from patient- or donor-restricted cell products toward true off-the-shelf immunotherapies that can be improved through iterative genome engineering. iPSC-derived natural killer (iNK) cells are the most clinically advanced and exemplify the platform’s advantages over conventional autologous or donor-sourced approaches. Unlike autologous therapies, which require labor-intensive and expensive personalized clinical-grade manufacturing, and are constrained by variable quality and genetic intractability of donor products, iPSC technology supports the creation of renewable, clonally defined master cell banks as uniform starting material for NK-cell therapy products. Advances in CRISPR/Cas-based editing now permit multiplex introduction of functional traits, enhanced cytokine signaling, antibody-dependent cytotoxicity, checkpoint resistance, optimized trafficking, safety switches, and increasing signal complexity, directly at the pluripotent or progenitor stages; ultimately allowing for fully-programmable iNK cells with customizable potency and persistence. Early clinical studies of iNK products validate the feasibility, safety, and therapeutic potential of this approach, but also underscore the need for continued refinement of differentiation protocols, manufacturing pipelines, and regulatory standards to ensure efficacy, genomic stability, phenotypic maturity, and long-term safety. This review outlines current breakthroughs and future directions of iNK cell therapies, emphasizing how programmable iPSC chassis platforms are enabling modular and off-the-shelf targeted immunotherapies.