Rapid detection of microbes is crucial for eliciting an effective immune response. Innate immune receptors survey the intracellular and extracellular environment for signs of a microbial infection. When they detect a pathogen-associated molecular pattern (PAMP), such as viral DNA, they alarm the cell about the ongoing infection. The central signaling hub in sensing of viral DNA is the stimulator of interferon genes (STING). Upon activation, STING induces downstream signaling events that ultimately result in the production of type I interferons (IFN I), important cytokines in antimicrobial defense, in particular towards viruses. In this review, we describe the molecular features of STING, including its upstream sensors and ligands, its sequence and structural conservation, common polymorphisms, and its localization. We further highlight how STING activation requires a careful balance: its activity is essential for antiviral defense, but unwanted activation through mutations or accidental recognition of self-derived DNA causes autoinflammatory diseases. Several mechanisms, such as post-translational modifications, ensure this balance by fine-tuning STING activation. Finally, we discuss how viruses evade detection of their genomes by either exploiting cells that lack a functional DNA sensing pathway as a niche or by interfering with STING activation through viral evasion molecules. Insight into STING's exact mechanisms in health and disease will guide the development of novel clinical interventions for microbial infections, autoinflammatory diseases, and beyond.
Keywords: Antiviral defense; DNA sensing; Innate immunity; Interferonopathy; Type I interferon; Viral evasion.
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