posted on 2018-10-30, 00:00authored byFang Wang, Min Xu, Robert D. Stedtfeld, Hongjie Sheng, Jianbo Fan, Ming Liu, Benli Chai, Teotonio Soares de Carvalho, Hui Li, Zhongpei Li, Syed A. Hashsham, James M. Tiedje
Different
fertilization and cropping systems may influence short-
and long-term residues of antibiotic resistance genes (ARGs) and mobile
genetic elements (MGEs) in soil. Soils from dryland (peanut) and paddy
(rice) fields, which originated from the same nonagricultural land
(forested), were treated with either chemical fertilizer, composted
manure, or no fertilizer for 26 years before sampling, which occurred
one year after the last applications. ARGs and MGEs were investigated
using highly parallel qPCR and high-throughput sequencing. Six of
the 11 antibiotics measured by LC–MS/MS were detected in the
manure applied soil, but not in the nonmanured soils, indicating their
source was from previous manure applications. Compared to the unfertilized
control, manure application did not show a large accumulation of ARGs
in either cropping system but there were some minor effects of soil
management on indigenous ARGs. Paddy soil showed higher accumulation
of these ARGs, which corresponded to higher microbial biomass than
the dryland soil. Chemical fertilizer increased relative abundance
of these ARGs in dryland soil but decreased their relative abundance
in paddy soil. These results show how long-term common soil management
practices affect the abundance and type of ARGs and MGEs in two very
different soil environments, one aerobic and the other primarily anaerobic.