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Endozoicomonas , a dominant symbiotic bacterium in coral holobionts, is noted for its ability to degrade dimethylsulfoniopropionate (DMSP) so as to generate acetate. While acetate is a well-known short-chain fatty acid in metabolic cross-feeding relationships, it remains unclear whether acetate derived from bacterial DMSP degradation is available to corals and their other symbionts. In this study, we employed Endozoicomonas ruthgatesiae strain 8E (herein referred as 8E) as a model to examine availability of DMSP-derived acetate for other symbionts. Using gas chromatography-mass spectrometry (GC-MS), we observed a significant increase in acetate excretion in 8E upon exposure to DMSP. Stable isotope labeling further confirmed that this elevated acetate efflux originated directly from DMSP, suggesting a complete cycle of DMSP-derived carbon among coral symbionts. Transcriptomic analysis revealed that DMSP exposure upregulated dddD expression and triggered a systemic reconfiguration of metabolism, characterized by down-regulation of the TCA cycle and the Pta-AckA pathway, with carbon flux redirected to the glyoxylate shunt. These findings suggest that upon exposure to DMSP, metabolism of 8E shifts from biomass production to DMSP catabolism, resulting in acetate efflux. Notably, we found that elevated temperature diminishes DMSP cleavage activity of 8E, indicating thermal sensitivity of this bacterial metabolic activity.