Mechanisms underlying the role of Fe3O4 in enhancing antibiotic degradation and mitigating the spread of antibiotic resistance in aquaculture sediment: coupling dissimilatory iron reduction with methanogenesis
Description
The dataset contains the raw data of the Fig.1, Fig.2, Fig. 3, Fig. 4, Fig.5, Fig.6, Fig.7, Fig.S1, Fig. S2, Fig. S3, Fig. S4, Fig. S5, Fig. S6, Fig. S7 and Fig. S8. Research data includes the follows: first-order rate constants for SMX degradation under varying operational parameters; degradation products of SMX; the log-transformed absolute copies of the target ARGs and integron gene under different treatments; the composition and difference of the bacterial communities; correlations of bacterial community at ASV level, ARG abundance. The fold changes of ETS activity in the different treatments. (B) The changes of physiological and biochemical indicators related to oxidative stress. Aboudances of genes and functions related to Methane metabolism pathway, ARG-related functions and function genes associated with biofilm formation, antioxidant, and mating pair formation system; Quantitative X-ray diffraction spectra of synthetic goethite; XRD spectra of the tested sediment; Soluble Fe2+ concentrations in the different treatments; SMX degradation with time within 7 days; Change of CH4 production in the different treatments; Heatmap of abundance for methanogens communities at genus level; Log-transformed absolute copies of sulI and sulII in the different treatments with time; Comparison of Alpha diversity of the bacterial community in the different treatments.