Abstract

Biphenyl and polychlorinated biphenyls (PCBs) are typical environmental pollutants. However, these pollutants are hard to be totally mineralized by environmental microorganisms. One reason for this is the accumulation of dead-end intermediates during biphenyl and PCBs biodegradation, especially benzoate and chlorobenzoates (CBAs). Until now, only a few microorganisms have been reported to have the ability to completely mineralize biphenyl and PCBs. In this research, a novel bacterium HC3, which could degrade biphenyl and PCBs without dead-end intermediates accumulation, was isolated from PCBs-contaminated soil and identified as Sphingobium fuliginis. Benzoate and 3-chlorobenzoate (3-CBA) transformed from biphenyl and 3-chlorobiphenyl (3-CB) could be rapidly degraded by HC3. This strain has strong degradation ability of biphenyl, lower chlorinated (mono-, di- and tri-) PCBs as well as mono-CBAs, and the biphenyl/PCBs catabolic genes of HC3 are cloned on its plasmid. It could degrade 80.7% of 100 mg L −1 biphenyl within 24 h and its biphenyl degradation ability could be enhanced by adding readily available carbon sources such as tryptone and yeast extract. As far as we know, HC3 is the first reported that can degrade biphenyl and 3-CB without accumulation of benzoate and 3-CBA in the genus Sphingobium, which indicates the bacterium has the potential to totally mineralize biphenyl/PCBs and might be a good candidate for restoring biphenyl/PCBs-polluted environments.

Highlights

  • Biphenyl is a compound with two benzene rings [1]

  • When the initial concentration of biphenyl was 1000 mg L-1, only 165.5 mg L-1 biphenyl was removed within a similar period of time

  • These results indicated that HC3 could tolerate at least 1000 mg L-1 biphenyl, but its biphenyl degradation ability could be inhibited at this concentration

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Summary

Introduction

Biphenyl is a compound with two benzene rings [1]. It exists in natural gas, coal tar and crude oil. The chlorinated derivatives of biphenyl, PCBs, are more toxic and cause serious effects on the nervous, immune and endocrine systems [6,7,8,9], in addition to causing cancer in animals [10]. The use of biphenyl and PCBs have been greatly reduced recently, they still remain in the environment because of their low bioavailability and stable structure. Removal of these organic pollutants from contaminated environments are urgently needed to mitigate their damage to ecosystems

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