Cleavage‐Responsive Biofactory T Cells Suppress Infectious Diseases‐Associated Hypercytokinemia

Abstract Severe infectious diseases, such as coronavirus disease 2019 (COVID‐19), can induce hypercytokinemia and multiple organ failure. In spite of the growing demand for peptide therapeutics against infectious diseases, current small molecule‐based strategies still require frequent administration due to limited half‐life and enzymatic digestion in blood. To overcome this challenge, a strategy to continuously express multi‐level therapeutic peptide drugs on the surface of immune cells, is established. Here, chimeric T cells stably expressing therapeutic peptides are presented for treatment of severe infectious diseases. Using lentiviral system, T cells are engineered to express multi‐level therapeutic peptides with matrix metallopeptidases‐ (MMP‐) and tumor necrosis factor alpha converting enzyme‐ (TACE‐) responsive cleavage sites on the surface. The enzymatic cleavage releases γ‐carboxyglutamic acid of protein C (PC‐Gla) domain and thrombin receptor agonist peptide (TRAP), which activate endothelial protein C receptor (EPCR) and protease‐activated receptor‐1 (PAR‐1), respectively. These chimeric T cells prevent vascular damage in tissue‐engineered blood vessel and suppress hypercytokinemia and lung tissue damages in vivo, demonstrating promise for use of engineered T cells against sepsis and other infectious‐related diseases.