Corals harbor diverse microbial partners (e.g., fungi, algae, and bacteria), leading to complex yet intriguing mesh of interactions among and within coral holobiont. Different organs of coral harbor diverse microbial communities, such as members of genus Endozoicomonas are abundant in coral mucus and epidermal tissues. Interestingly, Endozoicomonas are often abundant in healthy corals and their abundance declines in diseased or stressed corals, consequently, members of this genus are hypothesized to be potential probiotics of coral health. Recently, the identification of beneficial microorganisms for coral has been at the center of developing probiotics for coral reefs to mitigate stress from heat-induced coral bleaching. Endozoicomonas species which are potential candidates for coral probiotics lack cultured isolates with only two species isolated from scleractinian corals. Endozoicomonas montiporae CL-33T the first cultured and genome sequenced isolate has been shown to have the potential to internalize and interact with host cells and harbor genes to protect mitochondrial dysfunction and promote gluconeogenesis in the host. A recent study provided first genomic and functional evidence of the role of Endozoicomonas in the coral sulfur cycle by metabolizing dimethylsulfoniopropionate (DMSP) to climate active gas dimethylsulfide (DMS). With only two cultured isolates to date, it becomes important to identify and culture new species from this diverse genus in order to ascertain its role in coral reefs. In this study, we isolated and cultured two novel bacteria species, E. penghuensis 4G and E. ruthgatesii 8E from dominant coral Acroporae sp. of the coast of Penghu Archipelago and Kenting, Taiwan, respectively. The nearest neighbor of these new species is E. eunicicola (16S rRNA gene identity: 96.68%, 96.99% respectively). The two isolates exhibit different physiological and biochemical characteristics (optimal pH, temperature and salinity). E. ruthgatesii 8E grows in on optimal temperature of 25 °C, with an optimal pH of 7 and salinity 1-2 %, whereas E. penghuensis 4G grows at a temperature of 20-25 °C, a pH, and salinity of 8 and 1-2%, respectively. Furthermore, we sequenced and assembled high-quality (contamination <1%) near-complete (>97%) draft genomes of the two species. E. ruthgatesii 8E has the largest genome (7.1 Mb) in cultured species of Endozoicomonas to date, but E. penghuensis 4G has a genome size (5.73 Mb) comparable other species. E. ruthgatesii 8E harbors a putative operon to metabolize DMSP to DMS and use it as a carbon source. Quantification of DMSP usage by E. ruthgatesii 8E shows that it can metabolize more DMSP than previously characterized E. acroporae. Further, genomic analysis is being conducted to answer the intriguing question, why does E. ruthgatesii 8E have a disproportionate genome size. Overall, in this study we discovered two novel Endozoicomonas species and is the first study to quantify DMSP consumption and DMS production by a coral-associated dominant bacterium.