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T cell activation by natural antigen-presenting cells depends on nanoscale ligand organization that dynamically reorganizes upon receptor engagement. Mimicking this spatial precision and adaptive ligand reorganization in synthetic systems remains challenging. Here, we introduce a programmable assembly of framework nucleic acids (FNA) to construct artificial antigen-presenting cells (FNA-aAPCs) with adaptive nanoscale control over ligand organization. The FNA-aAPCs, assembled hierarchically from tetrahedral framework nucleic acid (tFNA) units, precisely regulate anti-CD3 (αCD3) ligand spacing, valency, and density, enabling adaptive ligand configurations that match receptor reorganization and thereby directing TCR clustering and activation. Shorter ligand spacing and higher valency synergistically enhance T cell activation, as indicated by marker upregulation and cytokine secretion. The FNA-aAPCs promote TCR clustering, drive T cell proliferation, and mitigate T cell exhaustion, demonstrating the potential of programmable and adaptive ligand configurations. These results establish FNAs as an adaptively programmable and biomimetic platform for engineering artificial immune interfaces.
Zhou et al. (Sun,) studied this question.