Purification of antimicrobial peptide from Antarctic Krill (Euphausia superba) and its function mechanism

文献类型: 外文期刊

第一作者: Zhao Ling

作者: Zhao Ling;Yin Bangzhong;Liu Qi;Cao Rong

作者机构:

关键词: Antarctic Krill;antimicrobial peptide;purification;antimicrobial mechanism

期刊名称:JOURNAL OF OCEAN UNIVERSITY OF CHINA ( 影响因子:0.913; 五年影响因子:1.012 )

ISSN: 1672-5182

年卷期: 2013 年 12 卷 3 期

页码:

收录情况: SCI

摘要: The preliminary purification and antimicrobial mechanism of antimicrobial peptide from Antarctic Krill were studied in this paper. The results showed that the molecular weight range of antimicrobial polypeptide (CMCC-1) obtained by cation exchange chromatography was between 245-709D as detected by molecular sieve chromatography, and the minimum inhibition concentration (MIC) of CMCC-1 against Staphylococcus aureus was 5.0 mg mL(-1). The antimicrobial mechanism of CMCC-1 was studied with S. aureus as indicator bacterium. Compared with control group, the results of the experimental group in which S. aureus was treated with CMCC-1 were as follows: 1) CMCC-1 could inhibit cell division at logarithmic phase. 2) The protein and reducing sugar content, and the conductivity of culture medium increased, and the activity of alkaline phosphatase and beta-galactosidase could be detected in the culture medium. 3) Observation under scanning electron microscope revealed that somatic morphology became irregular, and then somatic surface became coarse. The cell became much smaller, and most somatic cells gathered. The boundary between cells became dim and finally fused as a whole. 4) Observation under transmission electron microscope showed that the surface of S. aureus became rough and the reproducing ability was restrained. The cell wall became thin and the cytoplasm shrunk. Substances inside cell leaked out, which caused cells death. 5) SDS-PAGE analysis showed that some bands disappeared, and the residual bands became vague. 6) The genomic DNA electrophoresis results showed that the genomic DNA bands of S. aureus were not degraded but the brightness significantly reduced. Thus, it is supposed that CMCC-1 could destroy the cell wall and membrane of S. aureu, increase the cell membrane permeability and the leaking-out of intracellular substances, and thus cause the death of S. aureu.

分类号:

  • 相关文献

[1]Purification and characterization of a novel antimicrobial peptide from Brevibacillus laterosporus strain A60. Guo, Lihua,Zeng, Hongmei,Yang, Xiufen,Yuan, Jingjing,Shi, Huaixing,Xiong, Yehui,Chen, Mingjia,Han, Lei,Qiu, Dewen.

[2]Higher efficiency soluble prokaryotic expression, purification, and structural analysis of antimicrobial peptide G13. Che, Yuanyuan,Lu, Yinghu,Zha, Xiangdong,Ma, Lijuan,Xu, Xuejiao,Huang, Huoqing,Yang, Peilong.

[3]Multimerization and fusion expression of bovine lactoferricin derivative LfcinB15-W4,10 in Escherichia coli. Tian, Zi-gang,Da Teng,Yang, Ya-lin,Luo, Jin,Feng, Xing-jun,Fan, Ying,Zhang, Fan,Wang, Jian-hua.

[4]Expression and activity analysis of beta Gallinacin-3 in Arabidopsis. Jin, Libo,Wang, Yunpeng,Xu, Nuo,Wang, Dezhong,Peng, Renyi,Jiang, Chao,Li, Xiaokun,Jin, Libo,Liu, Xiuming,Jiang, Chao,Wang, Yunpeng,Li, Xiaokun. 2018

[5]Transgenic rice expressing a novel phytase-lactoferricin fusion gene to improve phosphorus availability and antibacterial activity. Deng Li-hua,Weng Lu-shui,Deng Xiang-yang,Xiao Guo-ying,Wang Zuo-ping,Fu Xi-qin,Xin Ye-yun. 2017

[6]The in vitro, in vivo antifungal activity and the action mode of Jelleine-I against Candida species. Jia, Fengjing,Wang, Jiayi,Peng, Jinxiu,Zhao, Ping,Wang, Kairong,Yan, Wenjin,Wang, Rui,Kong, Ziqing. 2018

[7]Identification of a cysteine-rich antimicrobial peptide from salivary glands of the tick Rhipicephalus haemaphysaloides. Zhang, Houshuang,Zhang, Wenjie,Wang, Xinzhi,Zhou, Yongzhi,Wang, Na,Zhou, Jinlin. 2011

[8]Design and pharmacodynamics of recombinant NZ2114 histidine mutants with improved activity against methicillin-resistant Staphylococcus aureus. Chen, Huixian,Feng, Xingjun,Chen, Huixian,Mao, Ruoyu,Teng, Da,Wang, Xiumin,Hao, Ya,Wang, Jianhua,Chen, Huixian,Mao, Ruoyu,Teng, Da,Wang, Xiumin,Hao, Ya,Wang, Jianhua. 2017

[9]Functional analysis of a novel cysteine-rich antimicrobial peptide from the salivary glands of the tick Rhipicephalus haemaphysaloides. Zhang, Houshuang,Yang, Siqi,Gong, Haiyan,Cao, Jie,Zhou, Yongzhi,Zhou, Jinlin,Zhou, Jinlin,Yang, Siqi.

[10]Design and recombination expression of a novel plectasin-derived peptide MP1106 and its properties against Staphylococcus aureus. Cao, Xintao,Zhang, Yong,Mao, Ruoyu,Teng, Da,Wang, Xiumin,Wang, Jianhua,Cao, Xintao,Zhang, Yong,Mao, Ruoyu,Teng, Da,Wang, Xiumin,Wang, Jianhua.

[11]Two novel antimicrobial peptides purified from the symbiotic bacteria Xenorhabdus budapestensis NMC-10. Xiao, Yao,Meng, Fanlu,Qiu, Dewen,Yang, Xiufen.

[12]TC38, a teleost TFPI-2 peptide that kills bacteria via penetration of the cell membrane and interaction with nucleic acids. Zhang, Min,Yue, Bin,Wang, Guang-hua,Liu, Yong,Zhou, Shun,Cheng, Shun-feng,Li, Ning-qiu,Zhang, Ai-hua.

[13]D-amino acid substitution enhances the stability of antimicrobial peptide polybia-CP. Jia, Fengjing,Wang, Jiayi,Peng, Jinxiu,Zhao, Ping,Wang, Kairong,Yan, Wenjin,Wang, Rui,Kong, Ziqing. 2017

[14]Modification and characterization of a new recombinant marine antimicrobial peptide N2. Yang, Na,Feng, Xingjun,Wang, Xiumin,Teng, Da,Mao, Ruoyu,Hao, Ya,Zong, Lifen,Wang, Jianhua,Yang, Na,Wang, Xiumin,Teng, Da,Mao, Ruoyu,Hao, Ya,Zong, Lifen,Wang, Jianhua. 2016

[15]Improved antibacterial activity of a marine peptide-N2 against intracellular Salmonella typhimurium by conjugating with cell-penetrating peptides-bLFcin(6)/Tat(11). Li, Zhanzhan,Wang, Xiao,Teng, Da,Mao, Ruoyu,Hao, Ya,Yang, Na,Chen, Huixian,Wang, Xiumin,Wang, Jianhua,Li, Zhanzhan,Wang, Xiao,Teng, Da,Mao, Ruoyu,Hao, Ya,Yang, Na,Chen, Huixian,Wang, Xiumin,Wang, Jianhua. 2018

[16]High-level secretory expression of metchnikowin in Escherichia coli. Wu, Di,Lu, Yinghu,Ma, Lijuan,Che, Yuanyuan,Zha, Xiangdong,Yao, Bin,Huang, Huoqing,Yang, Peilong. 2013

[17]Construction of Salmonella Pullorum ghost by co-expression of lysis gene E and the antimicrobial peptide SMAP29 and evaluation of its immune efficacy in specific-pathogen-free chicks. Tian Qiu-feng,Zhou Wei,Si Wei,Yi Fei,Hua Xin,Chen Li-ping,Liu Si-guo,Yu Shen-ye,Tian Qiu-feng,Zhou Wei,Yi Fei,Yue Min. 2018

[18]GAP-initiated constitutive expression of a novel plectasin-derived peptide MP1106 by Pichia pastoris and its activity against Streptococcus suis. Jiao, Jian,Feng, Xingjun,Jiao, Jian,Mao, Ruoyu,Wang, Xiumin,Zhang, Yong,Teng, Da,Wang, Jianhua,Jiao, Jian,Mao, Ruoyu,Wang, Xiumin,Zhang, Yong,Teng, Da,Wang, Jianhua. 2015

[19]Recombinant production of the antimicrobial peptide NZ17074 in Pichia pastoris using SUMO3 as a fusion partner. Wang, X. J.,Wang, X. M.,Teng, D.,Zhang, Y.,Mao, R. Y.,Wang, J. H.,Wang, X. J.,Wang, X. M.,Teng, D.,Zhang, Y.,Mao, R. Y.,Wang, J. H..

[20]Expression of antimicrobial peptide LH multimers in Escherichia coli C43(DE3). Tian, Zi-gang,Dong, Tian-tang,Yang, Ya-lin,Teng, Da,Wang, Jian-hua.

作者其他论文 更多>>

微信小程序