A tissue-intrinsic mechanism sensitizes HIV-1 particles for TLR-triggered innate immune responses

In vivo, HIV-1 replicates within tissue, but how three-dimensional (3D) tissue-like environments influence viral spread and pathogenesis remains largely unknown. We previously identified an Environmental Restriction to cell-free Virus Infectivity (ERVI), imposed by collagen-rich 3D extracellular matrix (ECM), which diminishes HIV-1 particle infectivity. Here we report that ERVI is broadly implemented by various adhesive ECM components assembled into tissue-like 3D scaffolds. This restriction rapidly reduces infectivity within minutes, is saturable, and affects diverse primary HIV-1 strains and virions with distinct viral glycoproteins by impairing their ability to fuse with target cells. Importantly, particles subjected to ERVI also trigger pronounced pro-inflammatory cytokine secretion by monocyte-derived macrophages. Mechanistic analyses reveal that transient contact with collagen fibers induces conformational changes in the viral envelope glycoprotein (Env) and enhance its recognition by toll-like receptor (TLR) 2. This recognition promotes routing of viral particles into TLR8-positive endosomes, amplifying innate immune sensing of viral RNA genomes. ERVI thus acts via a dual mechanism: directly limiting the fusogenicity of cell-free virions and sensitizing them for innate immune detection. These findings highlight the biophysical properties of the ECM as a previously unrecognized, tissue-intrinsic barrier that restricts HIV-1 spread and promotes local inflammation representing a novel, broadly acting arm of antiviral innate immunity.