Suchergebnisse

The hypothesis that phenanthrene, an aromatic compound without a hydroxyl group, can form nonextractable residues in soil with the aid of phenanthrene-biodegrading bacteria and birnessite was tested. The mutant strain Sphingobium yanoikuyae B8/36 successfully accumulated cis-phenanthrene dihydrodiol, and the intermediate was readily radicalized and coupled into soil organic matter in the presence of birnessite. Phenanthrene and the intermediate disappeared from the soil in 96 h in the presence of birnessite, but the intermediate accumulation occurred without birnessite. By determining the total organic carbon contents before and after birnessite treatment, it could be seen that birnessite did not mineralize cis-phenanthrene dihydrodiol. Fourier transform infrared and ultraviolet analyses suggest instead that the intermediate was incorporated into the soil organic matter, forming nonextractable, bound residues. Increases in the aromaticity and pH in birnessite-treated soil also present more evidence for bound residue formation. The soil in which bound residue formed did not exhibit an acute toxicity of phenanthrene, but evidence indicated that such toxicity existed in the freshly spiked soil. In addition, a long-term column test revealed that the bound residues could not be eluted by the combination of water, 80% methanol, and U.S. Environmental Protection Agency Toxicity Characteristic Leaching Procedure solution (pH 2.88) for four months, implying stability of the nonextractable residues in the soil. ; This research received substantial support from the Seoul Research and Business Development Program (10676). Additional financial support was provided by the Korea Science and Engineering Foundation through the Advanced Environment Biotechnology Research Center at POSTECH and by an Ecoriver 21 Project of the Ministry of Land, Transport, and Maritime Affairs of Korean Government.

Abstract
Background
Since the industrial revolution, the contamination of agricultural soils by polycyclic aromatic hydrocarbons (PAHs) has increasingly become of serious global environmental concern and poses a huge threat to human beings and natural ecosystems. Microbial degradation is a proved technology mostly used to depollute polycyclic aromatic hydrocarbon (PAH) in the environment. However, very limited information is available regarding the interaction of earthworms with rice straw on the soil microbial community and the degradation of phenanthrene. This study was performed to enlighten the rice straw and earthworms' interaction on soil bacterial abundance and structure and phenanthrene removal.

Results
Result about functional gene information revealed that both rice straw and earthworm enhanced phenanthrene degradation. Subsequently, both Shannon diversity index (r2 = − 0.8807, p < 0.001) and bacterial 16S rRNA genes (r2 = − 0.7795, p < 0.001) negatively correlated with the remaining phenanthrene concentration in soil. The application of both rice straw and earthworms in soil had the lowest ratio of soil remaining phenanthrene concentration (0.16 ± 0.02), the highest Shannon diversity index (6.45 ± 0.2) and the highest bacterial 16S rRNA genes. This implied that both earthworms and rice straw might improve the phenanthrene metabolism by increasing soil bacteria diversity. The abundance of genera Pseudomonas, Luteimonas, Rhodanobacter, Sphingomonas, Gemmatimonas, Flavobacterium, and Leifsonia was significantly increased in the presence of both earthworms and rice straw and was found to negatively correlate with the remaining phenanthrene concentration in soil.

Conclusion
Based on these results, this study offers clear and strong evidences that the positive interaction between earthworms and rice straw could promote phenanthrene degradation in soil. These finding will improve our understanding on the importance of the natural resources forsaken and how they can interact with the soil macro- and microorganisms to change soil structure and enhance PAH degradation in soil.