Evolutionary Genomics Guides Scalable Coral Probiotics for Climate Resilience

Coral reefs, critically endangered by climate warming, urgently require innovative, scalable interventions. Probiotics offer promise, but stability and effectiveness need improvement. We introduce an evolutionary genomic framework for selecting so-called next-generation probiotics using host adaptation signatures. Targeting bacteria transitioning irreversibly to host dependency, we identify coral-sourcedRuegeriaMC10, exhibiting insertion sequence proliferation and essential gene pseudogenization. In a proof-of-principle, coral model cnidarians showed increased thermal tolerance. Subsequent, real-world application of one-month nursery inoculations enabledAcropora pruinosacorals to retain MC10 for the monitored period (eight months) post-outplanting, including persistence through a natural bleaching event, with sustained coloration. MC10 colonized the gastrodermis, exhibited host flexibility, and minimally disrupted native microbiomes. This work pioneers a scalable, evolution-guided strategy for microbial-driven reef restoration, applicable to wildlife at large.