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http://dx.doi.org/10.4014/jmb.1801.01043

Different Catabolism Pathways Triggered by Various Methylxanthines in Caffeine-Tolerant Bacterium Pseudomonas putida CT25 Isolated from Tea Garden Soil  

Ma, Yi-Xiao (Zhejiang University Tea Research Institute)
Wu, Xiao-Han (Zhejiang University Tea Research Institute)
Wu, Hui-Shi (Zhejiang University Tea Research Institute)
Dong, Zhan-Bo (Wenzhou Vocational College of Science and Technology)
Ye, Jian-Hui (Zhejiang University Tea Research Institute)
Zheng, Xin-Qiang (Zhejiang University Tea Research Institute)
Liang, Yue-Rong (Zhejiang University Tea Research Institute)
Lu, Jian-Liang (Zhejiang University Tea Research Institute)
Publication Information
Journal of Microbiology and Biotechnology / v.28, no.7, 2018 , pp. 1147-1155 More about this Journal
Abstract
The degradation efficiency and catabolism pathways of the different methylxanthines (MXs) in isolated caffeine-tolerant strain Pseudomonas putida CT25 were comprehensively studied. The results showed that the degradation efficiency of various MXs varied with the number and position of the methyl groups on the molecule (i.e., xanthine > 7-methylxanthine ${\approx}$ theobromine > caffeine > theophylline > 1-methylxanthine). Multiple MX catabolism pathways coexisted in strain CT25, and a different pathway would be triggered by various MXs. Demethylation dominated in the degradation of N-7-methylated MXs (such as 7-methylxanthine, theobromine, and caffeine), where C-8 oxidation was the major pathway in the catabolism of 1-methylxanthine, whereas demethylation and C-8 oxidation are likely both involved in the degradation of theophylline. Enzymes responsible for MX degradation were located inside the cell. Both cell culture and cell-free enzyme assays revealed that N-1 demethylation might be a rate-limiting step for the catabolism of the MXs. Surprisingly, accumulation of uric acid was observed in a cell-free reaction system, which might be attributed to the lack of activity of uricase, a cytochrome c-coupled membrane integral enzyme.
Keywords
Pseudomonas; methylxanthines; degradation efficiency; metabolic pathway; uric acid accumulation;
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