Multi-biological risk in groundwater-surface water system under landfill stress: Driven by bacterial size and biological toxicity

Abstract

The variation in bacterial size and biotoxicity leads to different ecological risks. However, the diversity of bacterial size and virulence in bacterial communities has been neglected, leading to limitations and inaccuracies in risk assessment. Surface-subsurface interactions lead to the complexity, variability, and insidiousness of pathogen transmission in the environment. Mountainous landfills are considered as a major source of pathogens in subsurface systems. Although numerous studies have reported the geographic distribution of microbes in landfills, there is a lack of knowledge regarding the impacts on the microbial spatial distribution of bacterial size, which is a key factor affecting microbial migration and risks. In this study, the groundwater, river water, soil and leachate samples were collected inside and around a typical mountainous urban landfill, which is close to a river with a high hydraulic gradient and a strong surface–subsurface interaction. Small-sized (<0.2 μm) and large-sized (>0.2 μm) bacteria were separated to verify the variability of migration potential and spatial distribution of different sizes of bacteria in groundwater-surface water and soil, investigating the driving factors and accessing the biological risk of different sizes of bacteria. The results revealed notable differences in spatial distribution and driving factors among various bacterial sizes. Small-sized bacterial communities in groundwater and soils exhibited clear trends towards leachate along the water flow direction. In contrast, large-sized bacterial communities remained stable and resembled native bacterial communities. Groundwater hydrodynamics was the main driving force affecting the spatial distribution of small-sized bacteria. The small-sized bacteria showed a higher content of virulence genes which were predominantly expressed for invasion. Thus, small-sized bacteria exhibited a stronger migration potential and a higher biological risk. Due to the surface–subsurface interactions, the bacterial communities in river water were more similar to that in groundwater after rain. Our results provide strong support to guide the management of subsurface system safety in mountainous landfills.