Giant clams (Tridacna spp.) are the biggest bivalves that live in tropical coral reefs in the Indo-Pacific Ocean. They play an important role in the coral reef ecosystem and are considered indicator species for ecosystem health. However, in recent years, these giant clams have faced challenges due to overexploitation driven by the aquarium trade, habitat destruction, marine pollution, and rising sea temperatures, resulting in declining populations and reduced sizes. Most of species are classified as Vulnerable on IUCN Red List of Threatened Species and protected under CITES. Previous studies have demonstrated that the coral-associated microbiota participate in carbon and nitrogen fixation as well as cycling of sulfur, phosphorus, and other elements, aiding corals in maintaining health and adapting to environmental changes. Similar findings are anticipated for the microbiota associated with giant clams, although research in this area is currently limited. Therefore, this study collected samples of mantle tissue (0.5 cm2) from four species of giant clam (Tridacna maxima, T. noae, T. squamosa, and T. crocea) across various locations in Taiwan (Kenting, Xiao Liuqiu, Penghu, Taiping Island, Dongsha, Northeast Coast, Guishan Island, Yilan, Hualien, Taitung, Lyudao, Lanyu) and Okinawa, Japan. Shell length and growth depth are also recorded. And microbiome composition, including symbiotic algae and bacteria, were analyzed using next-generation sequencing. The investigation revealed uneven distribution of giant clam species across different regions of Taiwan. Microbial analysis indicated that location was the primary factor influencing bacterial composition, followed by species, with lesser influence from shell size and growth depth had no significant impact. Dominant bacterial phyla included Proteobacteria, Verrucomicrobia, Firmicutes, Cyanobacteria, and Bacteroidetes. In terms of symbiotic algae, location was also the primary factor, followed by species, with shell size and growth depth having less discernible effects. The predominant genera of symbiotic algae were predominantly Symbiodinium, followed by Durusdinium and Cladocopium. Additionally, T. maxima, T. noae and T. squamosa, microbial composition, both bacterial and algal, exhibited clear geographic specificity, with unique microbial communities associated with different geographic environments. Furthermore, variations in shell size resulted in different trends in microbial composition among different species from different locations.