【目的】从生物垃圾燃料电池阳极淋洗液中分离一株产电菌WJ5-4,研究其产电特性。【方法】根据菌株的形态、生理生化性质及16S r RNA基因测序分析确定其种属,以该菌株为产电菌,以生物垃圾为底物,构建微生物燃料电池(Microbial fuel cell,...【目的】从生物垃圾燃料电池阳极淋洗液中分离一株产电菌WJ5-4,研究其产电特性。【方法】根据菌株的形态、生理生化性质及16S r RNA基因测序分析确定其种属,以该菌株为产电菌,以生物垃圾为底物,构建微生物燃料电池(Microbial fuel cell,MFC),研究在不同接种浓度和底物固含量条件下菌株的产电性能。【结果】菌株WJ5-4被初步鉴定属于Nitratireductor属,当接种量200 m L时可获得最大功率密度135.16 m W/m2、稳定电压370 m V和总有机碳(Total organic carbon,TOC)降解率41.46%。当底物固含量为23%时,可获得最大功率密度163.69 m W/m2、稳定电压434 m V和TOC降解率46.29%。【结论】WJ5-4菌能够利用较高固含量的生物垃圾产电,产电周期较长,为下一步微生物燃料电池处理生物垃圾提供科学依据。展开更多
In this study, bacteria associated with marine organisms were screened for the production of exopolysaccharides(EPSs) on MY media containing sea salts(2.5%-10%). Three selected isolates were identified as Alteromo...In this study, bacteria associated with marine organisms were screened for the production of exopolysaccharides(EPSs) on MY media containing sea salts(2.5%-10%). Three selected isolates were identified as Alteromonas sp. PRIM-21, Nitratireductor sp. PRIM-24 and Enterobacter sp. PRIM-26 using 16 S r RNA gene sequencing. Optimization of the growth and EPS production kinetics in relation to incubation time were assessed. The purified EPS yield was 590, 650 and 540 mg·L-1 culture media respectively in Alteromonas sp. PRIM-21, Nitratireductor sp. PRIM-24 and Enterobacter sp. PRIM-26. Biochemical and FTIR analyses revealed the presence of biologically important functional groups in the EPS produced by all the three isolates. The EPS produced by Nitratireductor sp. PRIM-24 and Alteromonas sp. PRIM-21 showed 2.0% sulfate content. These bacterial EPS also showed antioxidant and emulsifying activities and the EPS produced by Enterobacter sp.PRIM-26 showed significantly higher antioxidant activities in terms of superoxide(IC50 0.33 mg·mL -1) and DPPH(IC50 0.44 mg·mL -1) radical scavenging. It also showed higher emulsifying activities against selected hydrophobic substrates with EI24 values above 60%. From the results of the study, it can be concluded that the isolated bacteria produce EPS that can be investigated in detail for biotechnological applications.展开更多
文摘【目的】从生物垃圾燃料电池阳极淋洗液中分离一株产电菌WJ5-4,研究其产电特性。【方法】根据菌株的形态、生理生化性质及16S r RNA基因测序分析确定其种属,以该菌株为产电菌,以生物垃圾为底物,构建微生物燃料电池(Microbial fuel cell,MFC),研究在不同接种浓度和底物固含量条件下菌株的产电性能。【结果】菌株WJ5-4被初步鉴定属于Nitratireductor属,当接种量200 m L时可获得最大功率密度135.16 m W/m2、稳定电压370 m V和总有机碳(Total organic carbon,TOC)降解率41.46%。当底物固含量为23%时,可获得最大功率密度163.69 m W/m2、稳定电压434 m V和TOC降解率46.29%。【结论】WJ5-4菌能够利用较高固含量的生物垃圾产电,产电周期较长,为下一步微生物燃料电池处理生物垃圾提供科学依据。
基金financially supported by the India and author Priyanka P acknowledges the Yenepoya University Junior research fellowshipBRNS(2013/34/19/BRNS/1210)
文摘In this study, bacteria associated with marine organisms were screened for the production of exopolysaccharides(EPSs) on MY media containing sea salts(2.5%-10%). Three selected isolates were identified as Alteromonas sp. PRIM-21, Nitratireductor sp. PRIM-24 and Enterobacter sp. PRIM-26 using 16 S r RNA gene sequencing. Optimization of the growth and EPS production kinetics in relation to incubation time were assessed. The purified EPS yield was 590, 650 and 540 mg·L-1 culture media respectively in Alteromonas sp. PRIM-21, Nitratireductor sp. PRIM-24 and Enterobacter sp. PRIM-26. Biochemical and FTIR analyses revealed the presence of biologically important functional groups in the EPS produced by all the three isolates. The EPS produced by Nitratireductor sp. PRIM-24 and Alteromonas sp. PRIM-21 showed 2.0% sulfate content. These bacterial EPS also showed antioxidant and emulsifying activities and the EPS produced by Enterobacter sp.PRIM-26 showed significantly higher antioxidant activities in terms of superoxide(IC50 0.33 mg·mL -1) and DPPH(IC50 0.44 mg·mL -1) radical scavenging. It also showed higher emulsifying activities against selected hydrophobic substrates with EI24 values above 60%. From the results of the study, it can be concluded that the isolated bacteria produce EPS that can be investigated in detail for biotechnological applications.