Abstract
Severe fever with thrombocytopenia syndrome virus (SFTSV) is an emerging tick-borne Dabie bandavirus that causes hemorrhagic fever with high case fatality. Although numerous studies have examined specific aspects of SFTSV infection, an integrated framework that links viral immune cell tropism to immunopathogenesis remains lacking. The virus exhibits broad immune tropism, particularly infecting monocytes and B cells, which serve as major viral reservoirs and sources of inflammatory cytokines, while B cells additionally show impaired antibody production. T cells undergo numerical depletion and functional exhaustion, and dendritic cells lose antigen-presenting capacity in severe cases. Natural killer cells and macrophages also exhibit altered activation and polarization, contributing to both antiviral defense and immunopathology. A key viral protein, NSs, antagonizes host interferon signaling by sequestering TBK1, IRF3, and STAT1/2 into viral inclusion bodies, thereby suppressing type I and II IFN responses. Murine models with disrupted IFNAR signaling have been widely used to study SFTSV pathogenesis in vivo. In this review, we aim to integrate clinical, experimental, and molecular evidence to synthesize the roles and functional features of immune cells underlying SFTSV pathogenesis and highlight host-directed immunotherapeutic advances.