Ithin 48 h incubation. Subject A has moderate activity in terms of metabolizing GA to PG. This suggests that microbial composition may impact on the ability of a given individual to 58-49-1 site generate theaflavins-derived metabolites. Nextgeneration sequencing on fecal material would help identify bacterial community associated with theaflavins-derived metabolites. These experiments may prove important in defining the human Arg8-vasopressin chemical information population better 18325633 suited to generate theaflavins-derived metabolites. This population may include better responders of theaflavins-mediated beneficial effects. Numerous studies have demonstrated that gut microbiota can cleave the C-ring of tea catechins to generate several lower molecular weight phenolic acids as well as ring-fission metabolites, such as 4-hydroxylphenylacetic acid, 3-(3-hydroxyphenyl)-propionic acid, 5-(39,49-dihydroxyphenyl)-c-valerolactone, and 5(39,49,59-trihydroxyphenyl)-c-valerolactone [4,22,37]. With the unique benzotropolone structure, it is unlikely that theaflavins can be metabolized to similar simple phenolic compounds as catechins do. We did observe several metabolites of TF from fecal samples collected from TF treated mice through oral gavage (200 mg/kg) (data not shown). However, we were unable to identify any benzotropolone-derived metabolites of TF by searching potential degradation metabolites using LC/MS. It is worthwhile to investigate how the benzotropolone structure of theaflavins is metabolized by gut microbiota in order to gain a full picture on the microbial metabolism of theaflavins.The in vivo functional impact of microbiota-generated theaflavins-derived metabolites is unclear. However, multiple studies have revealed that both GA and PG play an important role in the inhibition of cancer. It is reported that GA induced apoptosis in A375.S2 human melanoma cells and suppressed lipopolysaccharide-induced nuclear factor-kB signaling by preventing ReIA acetylation in A-549 lung cancer cells [38,39]. Several laboratory animal studies have shown that GA can prevent cancer in different organs including colon, prostate and lung [40?5]. In addition, PG has been reported to inhibit the growth of human lung cancer Calu-6 cells via multi pathways [46?9]. Han et al. found PG inhibited the growth of human pulmonary adenocarcinoma A549 1317923 cells by arresting cell cycle and triggering apoptosis [50]. Furthermore, Yang et al. reported that PG induced G2-M arrest in human lung cancer cells and inhibited tumor growth in a xenograft nude mouse model [51]. However, the impact of these microbial-derived metabolites on cancer prevention observed from theaflavins is currently unknown. Moreover, the functional impact of various member of the microbiota on metabolite generation remains to be defined.Materials and Methods Chemicals and ReagentsTF, TF3G, TF39G, and TFDG were prepared previously in our laboratory [52]. Gallic acid, pyrogallol and Tween 80 were purchased from Sigma-Aldrich (St. Louis, MO). Peptone was obtained from VWR Scientific (South Plainfield, NJ). HPLC-Microbial Metabolites of TheaflavinsFigure 6. HPLC-ECD chromatograms of microbial metabolites of TF39G after incubation with human fecal bacteria (A ). A, B and C represent the three human volunteers, respectively. TF39G: theaflavin 39-gallate. doi:10.1371/journal.pone.0051001.ggrade and LC/MS-grade solvents and other reagents were purchased from Thermo Fisher Scientific (Pittsburgh, PA).Treatment of Mice and Feces CollectionExperiments with mice wer.Ithin 48 h incubation. Subject A has moderate activity in terms of metabolizing GA to PG. This suggests that microbial composition may impact on the ability of a given individual to generate theaflavins-derived metabolites. Nextgeneration sequencing on fecal material would help identify bacterial community associated with theaflavins-derived metabolites. These experiments may prove important in defining the human population better 18325633 suited to generate theaflavins-derived metabolites. This population may include better responders of theaflavins-mediated beneficial effects. Numerous studies have demonstrated that gut microbiota can cleave the C-ring of tea catechins to generate several lower molecular weight phenolic acids as well as ring-fission metabolites, such as 4-hydroxylphenylacetic acid, 3-(3-hydroxyphenyl)-propionic acid, 5-(39,49-dihydroxyphenyl)-c-valerolactone, and 5(39,49,59-trihydroxyphenyl)-c-valerolactone [4,22,37]. With the unique benzotropolone structure, it is unlikely that theaflavins can be metabolized to similar simple phenolic compounds as catechins do. We did observe several metabolites of TF from fecal samples collected from TF treated mice through oral gavage (200 mg/kg) (data not shown). However, we were unable to identify any benzotropolone-derived metabolites of TF by searching potential degradation metabolites using LC/MS. It is worthwhile to investigate how the benzotropolone structure of theaflavins is metabolized by gut microbiota in order to gain a full picture on the microbial metabolism of theaflavins.The in vivo functional impact of microbiota-generated theaflavins-derived metabolites is unclear. However, multiple studies have revealed that both GA and PG play an important role in the inhibition of cancer. It is reported that GA induced apoptosis in A375.S2 human melanoma cells and suppressed lipopolysaccharide-induced nuclear factor-kB signaling by preventing ReIA acetylation in A-549 lung cancer cells [38,39]. Several laboratory animal studies have shown that GA can prevent cancer in different organs including colon, prostate and lung [40?5]. In addition, PG has been reported to inhibit the growth of human lung cancer Calu-6 cells via multi pathways [46?9]. Han et al. found PG inhibited the growth of human pulmonary adenocarcinoma A549 1317923 cells by arresting cell cycle and triggering apoptosis [50]. Furthermore, Yang et al. reported that PG induced G2-M arrest in human lung cancer cells and inhibited tumor growth in a xenograft nude mouse model [51]. However, the impact of these microbial-derived metabolites on cancer prevention observed from theaflavins is currently unknown. Moreover, the functional impact of various member of the microbiota on metabolite generation remains to be defined.Materials and Methods Chemicals and ReagentsTF, TF3G, TF39G, and TFDG were prepared previously in our laboratory [52]. Gallic acid, pyrogallol and Tween 80 were purchased from Sigma-Aldrich (St. Louis, MO). Peptone was obtained from VWR Scientific (South Plainfield, NJ). HPLC-Microbial Metabolites of TheaflavinsFigure 6. HPLC-ECD chromatograms of microbial metabolites of TF39G after incubation with human fecal bacteria (A ). A, B and C represent the three human volunteers, respectively. TF39G: theaflavin 39-gallate. doi:10.1371/journal.pone.0051001.ggrade and LC/MS-grade solvents and other reagents were purchased from Thermo Fisher Scientific (Pittsburgh, PA).Treatment of Mice and Feces CollectionExperiments with mice wer.
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