| Summary: | Although composting is effective in deactivating antibiotic substances in manure, the influence of compost fertilization on the occurrence and dissemination of antibiotic resistance in arable soils remains to be controversial. Herein, the abundance and diversity of two sulfonamide resistance genes (<i>sul1</i> and <i>sul2</i>) in soil fertilized by compost spiked with two concentrations of sulfadiazine (1 and 10 mg kg<sup>−1</sup>) were studied intensively by qPCR and high throughput sequencing based on a two-month microcosm experiment. The concentration of sulfadiazine decreased rapidly after spiking from 25% at Day 1 to less than 2.7% at Day 60. Relative abundance of both <i>sul1</i> and <i>sul2</i> were significantly higher in soil amended with compost than the non-amended control at Day 1 and slightly decreased with incubation time except for <i>sul2</i> in the S10 treatment. Soil bacterial communities were transiently shifted by compost fertilization regardless of the presence of sulfadiazine. Relative abundance of genera in three hubs positively interlinked with <i>sul1</i> and <i>sul2</i> were significantly higher in compost treated soil than the control at Day 1, 7 and 21, but not at Day 60. High throughput sequencing analyses revealed that most detected (>67% in relative abundance) <i>sul1</i> and <i>sul2</i> genotypes sharing >99% similarity with those found in gammaproteobacterial pathogens frequently were commonly present in compost and soil. These results indicated that compost fertilization might increase the abundance rather than diversity of sulfadiazine-resistant populations in soil, which may be facilitated by the presence of sulfadiazine.
|
|---|
