Hu, H.; Popp, P.; Rutbeek, N. R.; Klein-Sousa, V.; Lopez- Mendez, B.; Roa-Eguiara, A.; Piel, D.; Pape, T. H.; Sofos, N. H.; Hendriks, I. A.; Olsen, J. V.; Songailiene, I.; Harms, A.; Erhardt, M.; Taylor, N. M. I.

Eukaryotes and prokaryotes have evolved diverse antiviral immune systems, many containing helicase modules central to defense. Druantia are widespread bacterial anti-phage defense systems, each built around a large helicase domain-containing protein, DruE, paired with variable subunits. Here, we investigate the molecular basis of a minimal two-protein module Druantia system, DruH-E. We demonstrate that DruH-E is sufficient to confer robust anti-phage defense. DruE exists in equilibrium between a monomer and an asymmetric dimer, with dimerization required for in vivo immunity. Cryo-EM structures define DruE asymmetric dimer assembly and its dsDNA unwinding mechanism, revealing a topologically closed architecture that is specifically activated by dsDNA substrates with a 3' overhang. We further identify DruH as an ssDNA-binding protein regulated by a metabolic switch, where its activity is inhibited by ATP at physiological concentrations through direct competition with ssDNA. Supported by mass spectrometry and single-cell microscopy data, we establish key determinants of the Druantia defense system and reveal how it mediates a direct antiviral immune mechanism.