Viral-deletion mutants that conditionally replicate and inhibit the wild-type virus (i.e., defective interfering particles, DIPs) have long been proposed as single-administration interventions with high genetic barriers to resistance. However, theories predict that robust, therapeutic DIPs (i.e., therapeutic interfering particles, TIPs) must conditionally spread between cells with R 0 >1. Here, we report engineering of TIPs that conditionally replicate with SARS-CoV-2, exhibit R 0 >1, and inhibit viral replication 10- to 100-fold. Inhibition occurs via competition for viral replication machinery, and a single administration of TIP RNA inhibits SARS-CoV-2 sustainably in continuous cultures. Strikingly, TIPs maintain efficacy against neutralization-resistant variants (e.g., B.1.351). In hamsters, both prophylactic and therapeutic intranasal administration of lipid-nanoparticle TIPs durably suppressed SARS-CoV-2 by 100-fold in the lungs, reduced pro-inflammatory cytokine expression, and prevented severe pulmonary edema. These data provide proof of concept for a class of single-administration antivirals that may circumvent current requirements to continually update medical countermeasures against new variants. Graphical abstract A defective viral particle derived from SARS-CoV-2 competes with the full virus for resources to replicate, showing therapeutic potential by inhibiting viral proliferation in culture and reducing viral load and pathology in animal models for infection.
【저자키워드】 Evolution, SARS-CoV-2, coronavirus, variants, RNA, defective interfering particles, intranasal, Lipid nanoparticle, Virus-like particle, therapeutic interfering particles,