Time-series metagenomic analysis reveals robustness of soil microbiome against chemical disturbance.

Soil microbial communities have great potential for bioremediation of recalcitrant aromatic compounds. However, it is unclear which taxa and genes in the communities, and how they contribute to the bioremediation in the polluted soils. To get clues about this fundamental question here, time-course (up to 24 weeks) metagenomic analysis of microbial community in a closed soil microcosm artificially polluted with four aromatic compounds, including phenanthrene, was conducted to investigate the changes in the community structures and gene pools. The pollution led to drastic changes in the community structures and the gene sets for pollutant degradation. Complete degradation of phenanthrene was strongly suggested to occur by the syntrophic metabolism by Mycobacterium and the most proliferating genus, Burkholderia. The community structure at Week 24 (∼12 weeks after disappearance of the pollutants) returned to the structure similar to that before pollution. Our time-course metagenomic analysis of phage genes strongly suggested the involvement of the 'kill-the-winner' phenomenon (i.e. phage predation of Burkholderia cells) for the returning of the microbial community structure. The pollution resulted in a decrease in taxonomic diversity and a drastic increase in diversity of gene pools in the communities, showing the functional redundancy and robustness of the communities against chemical disturbance.

Insertion sequence-based cassette PCR: cultivation-independent isolation of gamma-hexachlorocyclohexane-degrading genes from soil DNA.

gamma-Hexachlorocyclohexane (gamma-HCH) is a highly chlorinated pesticide that has caused serious environmental problems. Based on the frequently observed association of insertion sequence IS6100 with lin genes for gamma-HCH degradation in several gamma-HCH-degrading bacterial strains isolated to date, DNA fragments flanked by two copies of IS6100 were amplified by nested polymerase chain reaction (PCR) technique using a DNA sample extracted from soil contaminated with HCH. Four distinct DNA fragments with sizes of 6.6, 2.6, 1.6, and 1.3 kb were obtained, three of which carried lin genes: the 6.6-kb fragment carried linD and linE as well as linR; the 2.6-kb fragment showed a truncated form of linF; and the 1.6-kb fragment carried linB. Our approach, named as insertion sequence (IS)-based cassette PCR, was successful in the isolation of the lin genes from HCH-contaminated soil without cultivation of host cells and is applicable for the culture-independent isolation of other functional genes bordered by other IS elements.