Influence of polycyclic aromatic hydrocarbon pollution on the diversity and function of bacterial communities in urban wetlands

Human disturbance has become the primary driving factor behind declining urban wetland ecological health due to rapid urbanization. Sediment microbial communities are critical for wetland ecosystem functioning but experience a range of natural and anthropogenic stressors due to rapid urbanization and land use changes, especially in developing countries. Polycyclic aromatic hydrocarbons (PAHs) released into the environment primarily come from anthropogenic sources like industrial activities and traffic emissions. Environmental PAH contamination is accelerating due to rapid urbanization, which also increases potential PAH-related dangers to human health. However, PAHs are widely distributed and not easy to centrally control. Microorganisms are the primary mediators of wetland purification, with most PAH-degrading microorganisms being bacteria. To better understand the influence of PAH contamination on urban wetland microbial communities, bacterial community compositions within sediments of urban wetlands in three land use types were investigated using high-throughput DNA sequencing and bioinformatics analyses. Statistical analyses revealed significant differences in overall microbial compositions among the three land use types, although gamma-proteobacteria was the dominant phyla across all samples. Among the potential PAH-degrading bacterial taxa in sediments, Sphingomonas was the most prevalent. The distributions of PAH-degrading taxa were primarily affected by variance in organic compound abundances in addition to various physico-chemical variables, among which high-ring PAH content was a key parameter associated with bacterial distributions, except in the riverine wetlands. Functional inference via phylogenetic investigation of communities by reconstruction of unobserved states (PICRUSt) indicated that 30 of the 43 genes related to PAH metabolism were predicted to be present within the genomes of bacteria among the three land use type. In particular, dioxygenase and dehydrogenase genes involved in PAH degradation were inferred to be prevalent, indicating that the host urban wetlands exhibited strong potential for organic pollutant degradation.