The fluid migration and early diagenesis impose an important control on the geochemical cycling in accretionary prisms. The interaction between compounds supplied from land, seawater, and deeply-rooted fluids facilitate many microbial processes and degrade considerable organic matter, leaving refractory organic matter buried into great depths. The final product, methane, can be formed through thermogenic and microbial processes in subsurface sedimentary environments and then discharge into seawater and even the atmosphere, exerting profound impacts on biogeochemical cycles and greenhouse effects. Mineral-bound water would be also released as temperature and pressure increase with depths, bearing deeply-rooted signals as fluids migrating upward. However, the methane and fluids budgets along with microbial processes remain rarely explored, qualified and quantified in subduction systems. This study combined fluid gechemical analysis and numerical modeling to explore fluid processes and microbial activities, aiming at better systematically understanding of organic-carbon related microbial activities as well as cycling of methane and water in accretionary prisms. In the first part, sediment cores distributed across a submarine mud volcano (SMV), TY1 (one of the Tsangyao Mud Volcano Group), were investigated to determine the characteristics of fluids generated through the convergence between the Eurasian and Phillippine Sea Plates. The fluid geochemistry indicated that fresh water derived from smectite dehydration at an equilibrium temperature of 100 to 150 oC. The upward fluid velocities affected the rate and efficiency of anaerobic methanotrophy. About 1.1–28.6% of the smectite-bound water originally stored in the incoming sediments was exploded from SMVs, suggesting that SMVs could act as a conduit to channel the fluids produced from great depth/temperature into seafloor environments in a subduction system. In the second part, the production, consumption, and migration of methane were systematically quantified along a continental margin in offshore southwestern Taiwan. Combined with published data, the results showed that high methane fluxes and the methane carbon isotopic values tend to be associated with structural features, suggesting a strong structural control on the methane transport. Anaerobic oxidation of methane played an effective biological filtration as a significant portion of ascending methane was consumed. The flux imbalance arose primarily due to the larger production of methane through deep microbial and thermogenic processes and could be likely accounted for by the sequestration of methane into hydrate forms, and clay absorption. In the third part, TY1 was chosen to denote a model system that could witness how microbial activities react under mixing of seawater and deeply-sourced fluids in subsurface environment. Inorganic geochemical and simulation results indicated the porewater profiles were obviously affected by deep fluids while the organic geochemistry showed that the in situ microbial activities controlled the distribution of dissolved organic carbon and short-chain compounds. In conclusion, tectonic-controlled fluids migration in accretionary prisms strongly influenced microbial activities in subsurface environment. Systematically investigation into methane and water could better understand the predominant mechanism in their cycling.