Dissolved organic matter (DOM) in the ocean encompasses complex and diverse organic compounds, and heterotrophic bacteria, the main DOM decomposers, also exhibit high biodiversity. The interactions between heterotrophic bacteria and DOM play an important role in biogeochemical cycles, which, however, are not fully understood.[Objective] To explore the dynamics of microbial communities with the addition of marine-derived concentrated DOM. [Methods] DOM with a molecular weight exceeding 1 kDa and enriched from coastal seawater was introduced into microcosm culture systems. Illumina amplicon sequencing, dissolved organic carbon (DOC) concentration measurement, and bacterial isolation were performed on different days of incubation. [Results] The addition of DOM significantly influenced bacterial community composition, inducing more pronounced changes in the high-DOM group. Specifically, the relative abundance of Campylobacterota, Nitrosococcales, and Nitrincolaceae increased in the high-DOM group on days 3, 10, and 30, respectively. The alpha diversity and evenness of the microbial community decreased during days 0-3 and increased during days 10-30, with a transition point occurring between days 3 and 10. The network analysis revealed that the high-DOM group exhibited a more tightly interconnected and complex network than the control group. In addition, bacterial isolates from the culture systems added with different concentrations of DOM were distinct. The specific genera of different DOM treatments were identified, which may be key groups in DOM degradation. [Conclusion] The addition of DOM triggers the succession of microbial community structures within microcosm culture systems, and the community composition may be associated with specific DOM components, which influence the direction of community succession. Furthermore, the varying DOM concentrations select for culturable bacteria with diverse survival strategies. This study provides a basis for enriching our understanding about the mechanisms underlying microbial responses to marine-derived DOM.