Protein signatures predict coral resilience and survival to thermal bleaching events
Brook L. Nunn, Tanya Brown, Emma Timmins‐Schiffman, Miranda C. Mudge, Michael Riffle, Jeremy B. Axworthy, Jenna Dilworth, Carly D. Kenkel, Jesse Zaneveld, Lisa J. Rodrigues, Jacqueline L. Padilla‐Gamiño
Abstract
Abstract Coral bleaching events from thermal stress are increasing globally in duration, frequency, and intensity. While bleaching can cause mortality, some corals survive, reacquire symbionts, and recover. We experimentally bleached Montipora capitata to examine molecular and physiological differences between corals that recover (resilient) and those that die (susceptible). Corals were collected and monitored for eight months post-bleaching to identify genets with long-term resilience. Using an integrated systems-biology approach that included quantitative proteomics, 16S rRNA sequencing to characterize the coral microbiome, total coral lipids, symbiont community composition and density, we explored molecular-level mechanisms of tolerance in corals pre- and post-bleaching. Prior to thermal stress, resilient corals have a more diverse microbiome and abundant proteins essential for carbon acquisition, symbiont retention, and pathogen resistance. Protein signatures of susceptible corals showed early symbiont rejection and utilized urea for carbon and nitrogen. Our results reveal molecular factors for surviving bleaching events and identify diagnostic protein biomarkers for reef management and restoration.