Nuclease-NTPase systems use shared molecular features to control bacterial anti-phage defense

Bacteria encode diverse defense systems including restriction-modification and CRISPR-Cas that cleave nucleic acid to protect against phage infection. Bioinformatic analyses demonstrate many recently identified anti-phage defense operons are comprised of a nuclease and NTPase protein, suggesting additional nucleic acid targeting systems remain to be understood. Here we develop large-scale comparative cell biology and biochemical approaches to analyze 16 nuclease-NTPase systems and define molecular features that control anti-phage defense. Purification, biochemical characterization, and in vitro reconstitution of nucleic acid degradation demonstrates protein–protein complex formation is a shared feature of multi-gene nuclease-NTPase systems. We show that AbpAB, Hachiman, and PD-T4-8 system nucleases use highly degenerate recognition site preferences to enable broad nucleic acid degradation, and the Azaca system exhibits specific phage targeting through the recognition of modified phage genomic DNA. Our results uncover principles of anti-phage defense system function and highlight the mechanistic diversity of nuclease-NTPase systems in bacterial immunity. Overall design: Cleavage sequencing analysis of DNA (Bacteriophage T4 and pGEM9z plasmid) incubated with Nuclease-NTPase proteins (PaAbpAB, BmAzaca, BtHachiman, EcPD-T4-8).