Endozoicomonas acroporae enhances coral thermal resilience through host–microbe coordination
Chih-Ying Lu, Yung-Pei Chang, Victor M Piñon-Gonzalez, Thomas D Lewin, Kai-Ning Shih, Po-Shun Chuang, Naohisa Wada, Sheng-Ping Yu, Zhao-Rong Yu, Yi-Hua Chen, Mo Chen, Ching-Hsiang Chin, Yu-Jing Chiou, Yi-Ling Chiu, Isabel Jiah-Yih Liao, Hsin-Feng Chang, Jui-Hung Yen, Mei-Yeh Jade Lu, Yi-Jyun Luo, Sen-Lin TangAbstract
Probiotics hold promise for enhancing coral resilience under climate-driven thermal stress, yet their mechanisms remain poorly understood. Although the bacterial genus Endozoicomonas has been proposed to benefit corals, in vivo evidence of beneficial effects on the host remains limited. Here, we establish Endozoicomonas acroporae Acr-14T as a coral probiotic and characterize its effects on the reef-building coral Stylophora pistillata. We show that E. acroporae Acr-14T enhances host thermal tolerance, colonizes coral tissues, and forms coral-associated microbial aggregates (CAMAs). Microbial profiling indicates that probiotic treatment is associated with reduced relative abundances of opportunistic microbes and enrichment of putatively beneficial taxa. To support transcriptomic analyses, we assembled a chromosome-level genome of S. pistillata clade 1 (Pacific lineage) and found that E. acroporae Acr-14T treatment mitigates heat-induced protein-folding stress and apoptotic signaling. Single-cell transcriptomics further revealed altered expression of genes involved in S-adenosylmethionine (SAMe) metabolism and pro-survival signaling in gastrodermal cells of probiotic-treated corals. Together, our results provide a cell-type-resolved view of host responses linked to Endozoicomonas-mediated coral thermal resilience and offer insight into molecular mechanisms implicated in host–microbe interactions under environmental stress.