Biodegradation of phenol and m-cresol by mutated Candida tropicalis 被引量：11

Biodegradation of phenol and m-cresol by mutated Candida tropicalis

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摘要 The phenol and m-cresol biodegradations were studied using the mutant strain CTM 2 obtained by the He-Ne laser irradiation on wild-type Candida tropicalis. The results showed that C. tropicalis exhibited the increased capacity of phenolic compounds degradation after laser irradiation. It could degrade 2600 mg/L phenol and 300 mg/L m-cresol by 5% inoculum concentration, respectively. In the dual-substrate biodegradation system, 0-500 mg/L phenol could accelerate m-cresol biodegradation, and 300 mg/L m-cresol could be completely utilized within 46 hr at the presence of 350 mg/L phenol. Besides, the maximum biodegradation of m-cresol could reach 350 mg/L with 80 mg/L phenol within 61 hr. Obviously, phenol, as a growth substrate, could promote CTM 2 to degrade m-cresol, and was always preferentially utilized as carbon source. Comparatively, low-concentration m-cresol could result in a great inhibition on phenol degradation. In addition, the kinetic behaviors of cell growth and substrate biodegradation were described by kinetic model proposed in our laboratory. The phenol and m-cresol biodegradations were studied using the mutant strain CTM 2 obtained by the He-Ne laser irradiation on wild-type Candida tropicalis. The results showed that C. tropicalis exhibited the increased capacity of phenolic compounds degradation after laser irradiation. It could degrade 2600 mg/L phenol and 300 mg/L m-cresol by 5% inoculum concentration, respectively. In the dual-substrate biodegradation system, 0-500 mg/L phenol could accelerate m-cresol biodegradation, and 300 mg/L m-cresol could be completely utilized within 46 hr at the presence of 350 mg/L phenol. Besides, the maximum biodegradation of m-cresol could reach 350 mg/L with 80 mg/L phenol within 61 hr. Obviously, phenol, as a growth substrate, could promote CTM 2 to degrade m-cresol, and was always preferentially utilized as carbon source. Comparatively, low-concentration m-cresol could result in a great inhibition on phenol degradation. In addition, the kinetic behaviors of cell growth and substrate biodegradation were described by kinetic model proposed in our laboratory.

作者 Yan Jiang Xun Cai Di Wu Nanqi Ren

机构地区 State Key Laboratory of Urban Water Resource and Environment Department of Chemical Engineering School of Life Sciences and Chemistry

出处《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2010年第4期621-626,共6页 环境科学学报（英文版）

基金 supported by the Youth Academic Cadreman Project of Heilongjiang Provincial Education Department (No.1152G068) the Natural Science Foundation of Heilongjiang Provincial (No.B200819) the 41st Science Fund of China Postdoctor (No.20070410268)

关键词 BIODEGRADATION the mutant strain CTM 2 PHENOL M-CRESOL KINETIC biodegradation the mutant strain CTM 2 phenol m-cresol kinetic

分类号 TQ243.1 [化学工程—有机化工] X172 [环境科学与工程—环境科学]

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参考文献3

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