Abstract Marine microbial communities are vital to biogeochemical cycling, yet their dynamics in regions of ecological and industrial significance, such as the Santos Basin (SB), Brazil’s largest offshore oil-producing basin, remain poorly resolved. To address this gap, we combined 16S rRNA amplicon sequencing, flow cytometry, and a hybrid machine learning framework (Self-Organizing Maps and Random Forest) to analyze microbial community stratification across pelagic depths in the SB. We identified five depth-specific microbial associations predicted with 86% accuracy, driven primarily by temperature, salinity, water density, and nutrient availability. Shallow epipelagic and mesopelagic zones were dominated by temperature-driven assemblages, while deeper bathypelagic communities responded to salinity and density gradients. Temporal and spatial patterns further highlighted the influence of regional oceanographic processes, including the Cabo Frio upwelling and Rio de la Plata plume. Microbial diversity increased with depth, contrasting with higher cell abundances in nutrient-rich shallow waters. We provided new insights into the relative importance of oceanographic processes, suggesting that vertical stratification and regional hydrography may play a more central role shaping microbial communities than previously recognized. We also established a predictive framework for microbial dynamics in marine ecosystems, with direct implications for assessing anthropogenic impacts in industrially active regions like the SB.
Moreira et al. (Fri,) studied this question.
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