抗菌肽高效表达及生产优化研究进展

抗菌肽是基因编码、经外界诱导产生的一类多肽。在抗生素引发"耐药性"难题的时代,抗菌肽以广谱杀菌、不易产生耐药性、抗肿瘤、抗病毒等特点而拥有超越抗生素、造福人类的巨大潜能。然而,天然抗菌肽还需进行增强抗菌性和稳定性、降低细胞毒性等改造,并通过工业化改良实现大规模生产。因此现从抗菌肽改造设计、生产应用等最新研究做较为详细的综述。     

抗菌肽研究进展

抗菌肽是广泛存在于自然界生物中的一种具有抗菌、抗病毒和抗肿瘤活性的多态,由于抗菌肽具有普通抗生素所不具有的一系列优点,抗菌肽的研究已经成了现代学术和应用研究的一个热点。作者综述了抗菌肽的抗菌机制和应用研究等方面的内容。     

抗菌肽的治疗应用综述

抗菌肽作为最有潜力的抗生素替代药物,其临床应用和商品化生产还十分有限。科研人员采用各种方法克服这些障碍,如引入稀有氨基酸或多肽模拟的技术以避免抗菌肽的水解,或设计更短的多肽在保持其活性的同时降低生产的成本,这些手段均基于对抗菌肽结构的了解。可见,研究抗菌肽的分子结构对改进其功能必不可少,本文将介绍抗菌肽结构与功能的关系。     

抗菌肽在大肠杆菌中的融合表达

抗菌肽作为新一代抗生素的潜在应用价值使其备受关注,大量高纯度的抗菌肽是开展基础及临床实验的关键。天然来源的抗菌肽资源有限、纯化困难,化学合成抗菌肽成本高、活性不稳定,因此通过基因重组表达得到大量抗菌肽是低成本、高效益的方法。目前采用大肠杆菌表达系统获得抗菌肽已成为研究者的首选,通常以形成融合蛋白的方式表达,这不仅可避免抗菌肽对宿主的杀伤作用,也保护了抗菌肽免受蛋白酶降解。文章结合课题组的研究工作,综述了近年来抗菌肽在大肠杆菌中表达的融合载体、融合蛋白的裂解方法及表达条件优化的研究进展。     

昆虫抗菌肽研究现状与展望

昆虫抗菌肽具有分子量小、热稳定性强、无免疫原性、生物活性广泛等特点,在医药、农业、食品工业等领域逐渐显示出广阔的应用前景,特别是在当前大量耐药性菌株的出现,而新抗生素发现又极其困难的情况下．昆虫抗菌肽的潜在药用价值倍受人们关注。本文将对昆虫抗菌肽的结构特征,抗菌机理．基因工程及其应用前景等知识作一简要介绍。     

抗菌肽对糜烂型OLP患者唾液中真菌的影响

抗菌肽经临床研究,发现具有抗生素不具备的优点,可对糜烂型口腔扁平苔藓(oral lichen planus,OLP)患者唾液中真菌有抑制和杀菌的作用,弥补了抗生素的缺点。通过使用不同浓度、不同种类的抗菌肽,作用于自糜烂型OLP患者口腔唾液标本中提取并经鉴定的菌种,对三种常见菌——白色念珠菌、光滑念珠菌、热带念珠菌进行抑菌试验。结果表明,抗菌肽使用前后的数值比对、菌落生长情况、最小抑菌值有明显变化。发现RISE-AP12对三种常见真菌的抑菌、杀菌效果优于其他的抗菌肽,在临床上有较大应用前景。     

海洋无脊椎动物抗菌肽研究进展及其在食品保鲜中的应用

海洋无脊椎动物抗菌肽抑菌广谱,稳定性高,且对生物体本身无害,其应用日益引起大量研究者的关注。综述了抗菌肽的几种类型、抑菌机理,介绍了海洋无脊椎动物抗菌肽研究进展、存在的问题并分析其在食品保鲜中的应用前景。     

家蚕抗菌肽的特性与应用

家蚕抗菌肽是在抗菌、抗病毒和抗肿瘤方面具有重要的潜在应用价值的活性肽。家蚕抗菌肽抗菌谱广,由于抗菌肽有普通抗生素所不具有的一系列优点。其研究已经成热点。该文综述了冢蚕抗菌肽理化性质、结构与功能、作用机埋以及应用前景。     

综述人工合成型抗菌肽及其药学应用研究进展

天然抗菌肽（antimicrobial peptides, AMPs）是一类小分子阳离子多肽,具备多种杀菌机制,呈现出高效、广谱的杀菌特性,在抑制耐药性细菌、制备新型抗菌素等方面具有重要的研究价值。以天然抗菌肽为蓝本,设计和开发的人工合成型抗菌肽可以有效克服天然抗菌肽对蛋白酶敏感、细胞毒性较大、生产成本高等缺陷,作为抗感染的潜在药物具有更广阔的应用前景。综述了目前主要的抗菌肽人工改造技术,包括化学修饰法、蛋白质工程技术、计算机分子模拟技术和从头设计最小化抗菌肽方法的研究进展,并对人工合成抗菌肽作为抗菌药物的应用现状进行了简介。     

家蝇幼虫抗菌肽的抗菌谱及其与抗生素的协同作用研究

研究3种家蝇幼虫抗菌肽的抗菌谱以及每种抗菌肽的最小抑菌浓度(MIC),初步探讨3种抗菌肽分别与青霉素、链霉素相结合后对抗菌活性的影响,并采用分级抑制浓度指数(Fractionalinhibitoryconcentrationindex,FIC)来定量检测抗菌肽与抗生素之间的抗菌作用关系。结果表明3种抗菌肽的抗菌谱不同,不同的抗菌肽对不同病原菌的抗菌活性不同。3种抗菌肽与链霉素、青霉素之间的抗菌协同关系因细菌种类不同。抗菌肽与抗生素之间并不是都存在协同关系,有些不相关,甚至表现为对抗关系,表明抗菌肽、抗生素与细菌三者的相互作用关系非常复杂。     

Defense peptides of plant immune system

Antimicrobial peptides (AMPs) are natural antibiotics produced by all living organisms to combat pathogens. They are important effector molecules of the immune system both in animals and plants. AMPs are diverse in structure and mode of action. Based on homology of amino acid sequences and 3D structures several AMP families have been distinguished. They are defensins, thionins, lipid transfer proteins, hevein- and knottin-like peptides, and cyclotides. AMPs display broad-spectrum antimicrobial activity and thus show promise for the development of disease- resistant crops by genetic engineering and for the production of new-generation drugs. In this paper, the properties of the main AMP families (defensins and hevein-like peptides) and of a new 4-Cys plant AMP family are reviewed.     

Defense peptides of plant immunity

Antimicrobial peptides (AMPs) are natural antibiotics produced by all living organisms to fight pathogens. They are important effector molecules of the immune system both in animals and plants. AMPs are diverse in structure and mode of action. Based on the homology of amino acid sequences and 3D structures several AMP families have been distinguished. They are defensins, thionins, lipid transfer proteins, hevein- and knottin-like peptides, and cyclotides. AMPs display broad-spectrum antimicrobial activity and thus show promise for the development of disease-resistant crops by genetic engineering and for the production of new-generation drugs. In this paper, the properties of the main AMP families (defensins and hevein-like peptides) and of new 4-Cys plant AMP family are reviewed.     

Extremely abundant antimicrobial peptides existed in the skins of nine kinds of Chinese odorous frogs

Peptide agents are regarded as hopeful candidates to solve life-threatening resistance of pathogenic microorganisms to classic antibiotics due to their unique action mechanisms. Peptidomic and genomic investigation of natural antimicrobial peptides (AMPs) from amphibian skin secretions can provide a large amount of structure-functional information to design peptide antibiotics with therapeutic potential. In the present study, we identified a large number of AMPs from the skins of nine kinds of Chinese odorous frogs. Eighty AMPs were purified from three different odorous frogs and confirmed by peptidomic analysis. Our results indicated that post-translational modification of AMPs rarely happened in odorous frogs. cDNAs encoding precursors of 728 AMPs, including all the precursors of the confirmed 80 native peptides, were cloned from the constructed AMP cDNA libraries of nine Chinese odorous frogs. On the basis of the sequence similarity of deduced mature peptides, these 728 AMPs were grouped into 97 different families in which 71 novel families were identified. Out of these 728 AMPs, 662 AMPs were novel and 28 AMPs were reported previously in other frog species. Our results revealed that identical AMPs were widely distributed in odorous frogs; 49 presently identified AMPs could find their identical molecules in different amphibian species. Purified peptides showed strong antimicrobial activities against 4 tested microbe strains. Twenty-three deduced peptides were synthesized and their bioactivities, including antimicrobial, antioxidant, hemolytic, immunomodulatory and insulin-releasing activities, were evaluated. Our findings demonstrate the extreme diversity of AMPs in amphibian skins and provide plenty of templates to develop novel peptide antibiotics.     

Truncated antimicrobial peptides from marine organisms retain anticancer activity and antibacterial activity against multidrug-resistant Staphylococcus aureus

Antimicrobial peptides (AMPs) were recently determined to be potential candidates for treating drug-resistant bacterial infections. The aim of this study was to develop shorter AMP fragments that combine maximal bactericidal effect with minimal synthesis cost. We first synthesized a series of truncated forms of AMPs (anti-lipopolysaccharide factor from shrimp, epinecidin from grouper, and pardaxin from Pardachirus marmoratus). The minimum inhibitory concentrations (MICs) of modified AMPs against ten bacterial species were determined. We also examined the synergy between peptide and non-peptide antibiotics. In addition, we measured the inhibitory rate of cancer cells treated with AMPs by MTS assay. We found that two modified antibacterial peptides (epinecidin-8 and pardaxin-6) had a broad range of action against both gram-positive and gram-negative bacteria. Furthermore, epinecidin and pardaxin were demonstrated to have high antibacterial and anticancer activities, and both AMPs resulted in a significant synergistic improvement in the potencies of streptomycin and kanamycin against methicillin-resistant Staphylococcus aureus. Neither AMP induced significant hemolysis at their MICs. In addition, both AMPs inhibited human epithelial carcinoma (HeLa) and fibrosarcoma (HT-1080) cell growth. The functions of these truncated AMPs were similar to those of their full-length equivalents. In conclusion, we have successfully identified shorter, inexpensive fragments with maximal bactericidal activity. This study also provides an excellent basis for the investigation of potential synergies between peptide and non-peptide antibiotics, for a broad range of antimicrobial and anticancer activities.     

AMPer: a database and an automated discovery tool for antimicrobial peptides

MOTIVATION: Increasing antibiotics resistance in human pathogens represents a pressing public health issue worldwide for which novel antibiotic therapies based on antimicrobial peptides (AMPs) may offer one possible solution. In the current study, we utilized publicly available data on AMPs to construct hidden Markov models (HMMs) that enable recognition of individual classes of antimicrobials peptides (such as defensins, cathelicidins, cecropins, etc.) with up to 99% accuracy and can be used for discovering novel AMP candidates. RESULTS: HMM models for both mature peptides and propeptides were constructed. A total of 146 models for mature peptides and 40 for propeptides have been developed for individual AMP classes. These were created by clustering and analyzing AMP sequences available in the public sources and by consequent iterative scanning of the Swiss-Prot database for previously unknown gene-coded AMPs. As a result, an additional 229 additional AMPs have been identified from Swiss-Prot, and all but 34 could be associated with known antimicrobial activities according to the literature. The final set of 1045 mature peptides and 253 propeptides have been organized into the open-source AMPer database. AVAILABILITY: The developed HMM-based tools and AMP sequences can be accessed through the AMPer resource at http://www.cnbi2.com/cgi-bin/amp.pl     

Display of Multimeric Antimicrobial Peptides on the Escherichia coli Cell Surface and Its Application as Whole-Cell Antibiotics

Concerns over the increasing emergence of antibiotic-resistant pathogenic microorganisms due to the overuse of antibiotics and the lack of effective antibiotics for livestock have prompted efforts to develop alternatives to conventional antibiotics. Antimicrobial peptides (AMPs) with a broad-spectrum activity and rapid killing, along with little opportunity for the development of resistance, represent one of the promising novel alternatives. Their high production cost and cytotoxicity, however, limit the use of AMPs as effective antibiotic agents to livestock. To overcome these problems, we developed potent antimicrobial Escherichia coli displaying multimeric AMPs on the cell surface so that the AMP multimers can be converted into active AMP monomers by the pepsin in the stomach of livestock. Buf IIIb, a strong AMP without cytotoxicity, was expressed on the surface of E. coli as Lpp-OmpA-fused tandem multimers with a pepsin substrate residue, leucine, at the C-terminus of each monomer. The AMP multimers were successfully converted into active AMPs upon pepsin cleavage, and the liberated Buf IIIb-L monomers inhibited the growth of two major oral infectious pathogens of livestock, Salmonella enteritidis and Listeria monocytogenes. Live antimicrobial microorganisms developed in this study may represent the most effective means of providing potent AMPs to livestock, and have a great impact on controlling over pathogenic microorganisms in the livestock production.     

Antimicrobial Peptides: Successes, Challenges and Unanswered Questions

Multidrug antibiotic resistance is an increasingly serious public health problem worldwide. Thus, there is a significant and urgent need for the development of new classes of antibiotics that do not induce resistance. To develop such antimicrobial compounds, we must look toward agents with novel mechanisms of action. Membrane-permeabilizing antimicrobial peptides (AMPs) are good candidates because they act without high specificity toward a protein target, which reduces the likelihood of induced resistance. Understanding the mechanism of membrane permeabilization is crucial for the development of AMPs into useful antimicrobial agents. Various models, some phenomenological and others more quantitative or semimolecular, have been proposed to explain the action of AMPs. While these models explain many aspects of AMP action, none of the models captures all of the experimental observations, and significant questions remain unanswered. Here, we discuss the state of the field and pose some questions that, if answered, could speed the discovery of clinically useful peptide antibiotics.     

病原微生物对抗菌肽抗性机制的研究进展

抗菌肽(antimicrobial peptides, AMPs)是生物先天免疫系统的重要组成部分,可帮助宿主有效应对病原细菌、真菌和病毒等微生物的胁迫,被认为是医疗、食品加工和农业领域最具前途和潜力的抗生素替代物。病原微生物在与抗菌肽的互作中进化出了多种有针对性的抗性机制,本文从病原微生物对AMPs的感应与基因调控、细胞壁/膜成份的修饰、分泌蛋白酶降解及利用外排泵排出等四个方面综述了国内外的研究进展,并对AMPs类制品的研究前景进行了讨论与展望。     

Two novel families of antimicrobial peptides from skin secretions of the Chinese torrent frog, Amolops jingdongensis

The characterization of new natural antimicrobial peptides (AMPs) can help to solve the serious problem of bacterial resistance to currently used antibiotics. In the current study, we analyzed two families of AMPs from the Chinese torrent frog Amolops jingdongensis with a range of bioactivities. The first family of peptides, named jindongenin-1a, is 24 amino acids in length; a BLAST search of jindongenin-1a revealed no sequence similarity with other AMPs. The second family consists of two peptides containing 29 amino acid residues each. These peptides have high sequence similarity with the AMPs of palustrin-2 and are therefore designated palustrin-2AJ1 and palustrin-2AJ2. The cDNA sequences encoding these AMPs have been cloned and the deduced protein sequence of each AMP has been determined by protein sequencing. Sequence and structural analysis showed that each precursor is composed of a putative signal peptide, an N-terminal spacer, a processing site and a disulfide-bridged heptapeptide segment at the C-terminus. We synthesized jindongenin-1a and palustrin-AJ1 to test their antimicrobial, hemolytic, antioxidative and cytotoxic activities. These two peptides showed broad-spectrum antimicrobial activity to standard and clinically isolated strains of bacteria. In addition, they exhibited weak hemolytic activity to human and rabbit erythrocytes under our experimental conditions. Moreover, these peptides also displayed cytotoxic activity against the K562 and HT29 mammalian cell lines and low anti-oxidant activity. These findings provide helpful insight that will be useful in the design of anti-infective peptide agents.     

Computational resources and tools for antimicrobial peptides

Antimicrobial peptides (AMPs), as evolutionarily conserved components of innate immune system, protect against pathogens including bacteria, fungi, viruses, and parasites. In general, AMPs are relatively small peptides (<10 kDa) with cationic nature and amphipathic structure and have modes of action different from traditional antibiotics. Up to now, there are more than 19 000 AMPs that have been reported, including those isolated from nature sources or by synthesis. They have been considered to be promising substitutes of conventional antibiotics in the quest to address the increasing occurrence of antibiotic resistance. However, most AMPs have modest direct antimicrobial activity, and their mechanisms of action, as well as their structure–activity relationships, are still poorly understood. Computational strategies are invaluable assets to provide insight into the activity of AMPs and thus exploit their potential as a new generation of antimicrobials. This article reviews the advances of AMP databases and computational tools for the prediction and design of new active AMPs. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.