Immobilization and orientation‐dependent activity of a naturally occurring antimicrobial peptide

A naturally occurring antimicrobial peptide, SMAP‐29, was synthesized with an n‐terminal or c‐terminal cysteine, termed c_SMAP and SMAP_c, respectively, for site‐directed immobilization to superparamagnetic beads. Immobilized SMAP orientation‐dependent activity was probed against multiple bacteria of clinical interest including Acinetobacter baumannii, Pseudomonas aeruginosa, Bacillus anthracis sterne and Staphylococcus aureus. A kinetic microplate assay was employed to reveal both concentration and time‐dependent activity for elucidation of minimum bactericidal concentration (MBC) and sub‐lethal effects. Immobilized SMAP activity was equivalent or reduced compared with soluble SMAP_c and c_SMAP regardless of immobilization orientation, with only one exception. A comparison of immobilized SMAP_c and c_SMAP activity revealed a bacteria‐specific potency dependent on immobilization orientation, which was contrary to that seen in solution, wherein SMAP_c was more potent against all bacteria than c_SMAP. Sub‐MBC kinetic studies displayed the influence of peptide exposure to the cells with multiple bacteria exhibiting increased susceptibility and efficacy at lower concentrations upon extended exposure (i.e. MBC enhancement). For instances in which complete killing was not achieved, two predominant effects were evident: retardation of growth rate and an increased lag phase. Both effects, seen independently and concomitantly, indicate some degree of induced cellular damage that can serve as a predictor toward eventual cell death. SMAP_c immobilized on glass through standard silanization chemistry was also investigated to ascertain the influence of substrate on activity against select bacteria. Published 2015. This article is a U.S. Government work and is in the public domain in the USA.     

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.     

Collection of antimicrobial peptides database and its derivatives: Applications and beyond

Collection of antimicrobial peptides (CAMP), CAMPSign, and ClassAMP are open‐access resources that have been developed to enhance research on antimicrobial peptides (AMPs). Comprehensive information on AMPs and machine learning‐based predictive models are made available for users through these resources. As of date, CAMP_R3 has 10,247 sequences, 757 structures, and 114 family‐specific signatures of AMPs along with associated tools for AMP sequence and structure analysis. CAMPSign uses family‐specific sequence conservation, in the form of patterns and hidden Markov models for identification of AMPs. ClassAMP can be used to classify AMPs as antibacterial, antifungal, or antiviral based on sequence information. Here we describe CAMP and its derivatives and illustrate, with a few examples, the contribution of these online resources to the advancement of our current understanding of AMPs.     

α-螺旋型抗菌肽结构参数与功能活性的关系

随着耐药病原菌出现,寻求更为安全有效的新型抗菌制剂迫在眉睫。抗菌肽具有广谱抗菌活性,杀菌快,不易产生耐药性等优点,是理想的新型抗菌剂,具有广阔前景。α-螺旋型抗菌肽是抗菌肽中的一大类。本文从α-螺旋型抗菌肽螺旋度,疏水力矩,疏水性,净正电荷数等方面阐述了结构与功能关系,及构效关系在α-螺旋抗菌肽分子设计与改造中的应用。     

铰链结构对抗菌肽生物活性的影响及在分子设计中的应用研究进展

铰链结构,又称铰链区或转角,是部分抗菌肽序列中存在的一种特殊结构。但目前抗菌肽结构的研究多集中于标准的α-螺旋和β-折叠二级结构,对于铰链结构及其作用总结较少。铰链结构对抗菌肽生物活性有重要影响,主要原因是铰链结构能够提高抗菌肽的结构灵活性,促进其对细菌细胞膜的破坏作用或与胞内作用靶点的结合效率,进而提高抗菌肽的抗菌活性。同时,降低的抗菌肽结构刚性,消减了抗菌肽对真核细胞的毒性。文中结合了笔者课题组相关工作,就铰链结构特点、对抗菌肽生物活性的影响以及在抗菌肽分子设计方面的应用进行了综述,以期为新型抗菌肽的设计和开发提供参考。     

抗菌肽活性及天然抗菌肽的改造

抗菌肽具有抗菌谱广、热稳定性强、分子量小及免疫原性小等特点,其杀菌机制独特,病原菌不易产生耐药性,有望开发成新一代肽类抗生素。本文主要综述了影响抗菌肽生物活性的生化性质,即螺旋度、疏水性、两亲性、正电荷数等,并从结构的角度论述了其对抗菌肽抑菌活性的影响。部分抗菌肽具有空间结构不稳定、溶血活性等缺点,限制了其临床应用。因此,对天然抗菌肽的改造也成为目前抗菌肽的研究热点,本文还综述了天然抗菌肽的改造方法。     

Alpha-helical cationic antimicrobial peptides: relationships of structure and function

Antimicrobial peptides (AMPs), with their extraordinary properties, such as broad-spectrum activity, rapid action and difficult development of resistance, have become promising molecules as new antibiotics. Despite their various mechanisms of action, the interaction of AMPs with the bacterial cell membrane is the key step for their mode of action. Moreover, it is generally accepted that the membrane is the primary target of most AMPs, and the interaction between AMPs and eukaryotic cell membranes (causing toxicity to host cells) limits their clinical application. Therefore, researchers are engaged in reforming or de novo designing AMPs as a ‘single-edged sword’ that contains high antimicrobial activity yet low cytotoxicity against eukaryotic cells. To improve the antimicrobial activity of AMPs, the relationship between the structure and function of AMPs has been rigorously pursued. In this review, we focus on the current knowledge of α-helical cationic antimicrobial peptides, one of the most common types of AMPs in nature.     

抗菌肽RIKL的分子设计及生物学活性分析

天然抗菌肽具有较强的杀菌能力,但高生物相容性抗菌肽的构建一直阻碍着该领域的发展.为了提高抗菌肽的选择特异性,通过分子动力学分析探讨了抗菌肽的结构特性,并检测其生物学活性.首先以(RXKY)2(YRY)2 (X代表Ile,Y代表Leu)为模板设计新型抗菌肽分子RIKL.通过圆二色谱(circular dichroism,...     

Factors contributing to the potency of antimicrobial cationic peptides from the N-terminal region of human lactoferrin

This study investigated the antimicrobial activities of peptides derived from the N-terminal region of human lactoferrin, and examined the contributions of individual residues to the activity of the most potent peptide. Two regions of antimicrobial activity were identified, the first corresponding to a weakly active peptide, HLP-9, comprising residues 1-9, and a second corresponding to a more potent peptide, HLP-10, comprising residues 18-26 and containing the hexapeptide motif, FQWQRN. Inhibitory studies on peptides from the first region confirm the importance of tryptophan residues in enhancing and broadening peptide activity. Inhibitory studies with glycine-substituted homologues of the more potent peptide showed that F21/G and R25/G substitutions resulted in a major reduction or complete loss of activity, while increased peptide cationicity or flexibility had little effect. Our findings demonstrate that F21 and R25 are critical determinants of potency for HLP-10, and that the second aromatic residue may act synergistically with W23 in developing and enhancing the activity of this cationic peptide.     

蜜蜂抗菌肽研究及其应用进展

抗菌肽是一类由特定基因编码的小分子多肽,广泛分布于各种生物中,是生物天然免疫的重要效应分子,其对缺乏获得性免疫系统的昆虫尤为重要。蜜蜂是一种对环境极其重要的社会性模式昆虫,又有着极高的经济价值,因此蜜蜂抗菌肽有着较大的研究意义。本文对蜜蜂4种天然免疫抗菌肽(Apidaecin、Abaecin、Hymenoptaecin和Defensin)和蜂产品中的抗菌肽(Jelleines、Melittin和Apamin)研究进展进行了综述,介绍了它们的功能、作用机制及其应用,提出了蜜蜂抗菌肽未来可行的研究方向,旨在推动蜜蜂抗菌肽的研究。     

Folding profiles of antimicrobial scorpion venom-derived peptides on hydrophobic surfaces: a molecular dynamics study

Abstract

Most helical antimicrobial peptides (AMPs) are usually unfolded in aqueous solution; however they acquire their secondary structure in the presence of a hydrophobic environment such as lipid membranes. Being the biological membranes the main target of many AMPs it is necessary to understand their way of action. Pandinin 2 (Pin2) is an alpha-helical AMP isolated from the venom of the African scorpion Pandinus imperator which shows high antimicrobial activity against Gram-positive bacteria and it is less active against Gram-negative bacteria, nevertheless, it has strong hemolytic activity. Its chemically synthesized Pin2GVG analog has low hemolytic activity while keeping its antimicrobial activity. With the aim of exploring the partition and subsequent folding of these peptides, in this work we report the results of extensive molecular dynamics simulations of Pin2 and Pin2GVG peptides in the presence of 2 hydrophobic environments such as dodecyl-phosphocholine (DPC) micelle and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocoline (POPC) membrane. Our results indicate that Pin2 folds in DPC with a 79% of alpha-helical content, which is in agreement with the experimental results, while in POPC it has 62.5% of alpha-helical content. On the other hand, Pin2GVG presents a higher percentage of alpha-helical structure in POPC and a smaller content in DPC when compared with Pin2. These results can help to better choose the starting structures in future molecular dynamics simulations of AMPs, because these peptides can adopt slightly different conformations depending on the hydrophobic environment.

Communicated by Ramaswamy H. Sarma     

Identification of a cysteine-rich antimicrobial peptide from salivary glands of the tick Rhipicephalus haemaphysaloides

The presence of an effective immune response in the hemocoel of ticks is crucial for survival, as it prevents the invasion of pathogens throughout the animal's body. Antimicrobial peptides (AMPs) play an important role in this response by rapidly killing invading microorganisms. In this study, a subtraction hybridization cDNA library was constructed from the salivary glands of the unfed and fed female tick Rhipicephalus haemaphysaloides, and a novel cysteine-rich AMP designated Rhamp (R. haemaphysaloides antimicrobial peptide) was isolated and identified. The Rhamp was encoded by a gene with an open reading frame of 303 bp which encoded a mature peptide with 8 kDa molecular weight. No identity was found by BLAST search to any database entries. The sequence encoding the Rhamp was subcloned into the pGEX-4T vector and expressed in Escherichia coli. The recombinant protein of Rhamp showed chymotrypsin and elastase-inhibitory activity and markedly inhibited the growth of Gram-negative bacteria, including Pseudomonas aeruginosa, Salmonella typhimurium, and E. coli. Moreover, the recombinant protein also exerted low hemolytic activity. These results indicate the Rhamp is a novel antimicrobial peptide with proteinase activity from the tick R. haemaphysaloides.     

猪源抗菌肽PMAP-36的序列设计及其结构优化的研究进展

抗生素的耐药性和动物源性食品中的药物残留问题严重威胁全球公共卫生系统.因此,开发出不易产生耐药性、抗菌活性高的新型抗菌药物迫在眉睫.抗菌肽因其分子量小、抗菌谱广、不易产生耐药性等优点受到科学家们的广泛关注,但天然抗菌肽具有抗菌活性低、溶血活性和细胞毒性等缺陷.随着抗菌肽序列和结构的不断优化,多种具有显著体内外抗菌活性且...     

抗菌肽临床应用前景分析

抗菌肽是生物天然免疫的重要组成部分,几乎存在于所有种类的生物中。目前已发现的抗菌肽超过2 000种。抗菌肽具有广谱抗菌活性,对大多数革兰氏阳性菌、革兰氏阴性菌和真菌具有强大的抑制作用（包括多药物耐受微生物）,而且这种作用具有较好的选择性。这些特点使抗菌肽具有成为抗感染药物的重大潜力;但抗菌肽的临床应用也面临着一些困难,如抗菌肽大量生产、体内稳定性、微生物耐受等。对抗菌肽临床应用面临的问题及正在进行临床研究和临床前研究的抗菌肽做一简要综述。     

Rational design of bifunctional chimeric peptides that combine antimicrobial and titanium binding activity

Bacterial biofilm formation remains a serious problem for clinical materials and often leads to implant failure. To counteract bacterial adhesion, which initiates biofilm formation, the development of antibiotic surface coating strategies is of high demand and warrants further investigations. In this study, we have created bifunctional chimeric peptides by fusing the recently developed antimicrobial peptide MGD2 (GLRKRLRKFFNKIKF) with different titanium-binding sequences. The novel peptides were investigated regarding their antibacterial potential against a set of different bacterial strains including drug-resistant Staphylococcus aureus. All peptides showed high antimicrobial activities both when in solution and when immobilized on titanium surfaces. Owing to the ease of synthesis and handling, the herein described peptides might be a true alternative to prevent bacterial biofilm formation.     

抗菌肽抗肿瘤作用的研究进展

抗菌肽是生物体抵御外界病原体侵袭时产生的一类保守的小分子多肽,是生物体内先天免疫防御机制的重要组分。抗菌肽可以选择性杀伤肿瘤细胞,而对正常细胞损害较小,已作为化、放疗药物潜在的替代品被广泛研究和开发。从抗菌肽对不同肿瘤细胞选择性作用机制、抗菌肽药物设计的发展及应用前景等方面进行综述。     

AMP-BERT: Prediction of antimicrobial peptide function based on a BERT model

Antimicrobial resistance is a growing health concern. Antimicrobial peptides (AMPs) disrupt harmful microorganisms by nonspecific mechanisms, making it difficult for microbes to develop resistance. Accordingly, they are promising alternatives to traditional antimicrobial drugs. In this study, we developed an improved AMP classification model, called AMP-BERT. We propose a deep learning model with a fine-tuned bidirectional encoder representations from transformers (BERT) architecture designed to extract structural/functional information from input peptides and identify each input as AMP or non-AMP. We compared the performance of our proposed model and other machine/deep learning-based methods. Our model, AMP-BERT, yielded the best prediction results among all models evaluated with our curated external dataset. In addition, we utilized the attention mechanism in BERT to implement an interpretable feature analysis and determine the specific residues in known AMPs that contribute to peptide structure and antimicrobial function. The results show that AMP-BERT can capture the structural properties of peptides for model learning, enabling the prediction of AMPs or non-AMPs from input sequences. AMP-BERT is expected to contribute to the identification of candidate AMPs for functional validation and drug development. The code and dataset for the fine-tuning of AMP-BERT is publicly available at https://github.com/GIST-CSBL/AMP-BERT .     

Prokaryotic selectivity and LPS-neutralizing activity of short antimicrobial peptides designed from the human antimicrobial peptide LL-37

To develop novel antimicrobial peptides (AMPs) with shorter lengths, improved prokaryotic selectivity and retained lipolysaccharide (LPS)-neutralizing activity compared to human cathelicidin AMP, LL-37, a series of amino acid-substituted analogs based on IG-19 (residues 13-31 of LL-37) were synthesized. Among the IG-19 analogs, the analog a4 showed the highest prokaryotic selectivity, but much lower LPS-neutralizing activity compared to parental LL-37. The analogs, a5, a6, a7 and a8 with higher hydrophobicity displayed LPS-neutralizing activity comparable to that of LL-37, but much lesser prokaryotic selectivity. These results indicate that the proper hydrophobicity of the peptides is crucial to exert the amalgamated property of LPS-neutralizing activity and prokaryotic selectivity. Furthermore, to increase LPS-neutralizing activity of the analog a4 without a remarkable decrease in prokaryotic selectivity, we synthesized Trp-substituted analogs (a4-W1 and a4-W2), in which Phe(5) or Phe(15) of a4 is replaced by Trp. Despite their same prokaryotic selectivity, a4-W2 displayed much higher LPS-neutralizing activity compared to a4-W1. When compared with parental LL-37, a4-W2 showed retained LPS-neutralizing activity and 2.8-fold enhanced prokaryotic selectivity. These results suggest that the effective site for Trp-substitution when designing novel AMPs with higher LPS-neutralizing activity, without a remarkable reduction in prokaryotic selectivity, is the amphipathic interface between the end of the hydrophilic side and the start of the hydrophobic side rather than the central position of the hydrophobic side in their α-helical wheel projection. Taken together, the analog a4-W2 can serve as a promising template for the development of therapeutic agents for the treatment of endotoxic shock and bacterial infection.     

Smart tools for antimicrobial peptides expression and application: The elastic perspective

In recent years, antimicrobial peptides (AMPs) have become a promising alternative to the use of conventional and chemically synthesized antibiotics, especially after the emergence of multidrug-resistant organisms. Thus, this review aims to provide an updated overview of the state-of-the-art for producing antimicrobial peptides fused or conjugated with the elastin-like (ELP) peculiar carriers, and that are mostly intended for biomedical application. The elastin-like biopolymers are thermosensitive proteins with unique properties. Due to the flexibility of their modular structure, their features can be tuned and customized to improve the production of the antimicrobial domain while reducing their toxic effects on the host cells. Both fields of research faced a huge rise in interest in the last decade, as witnessed by the increasing number of publications on these topics, and several recombinant fusion proteins made of these two domains have been already described but they still present a limited variability. Herein, the approaches described to recombinantly fuse and chemically conjugate diverse AMPs with ELPs are reviewed, and the nature of the AMPs and the ELPs used, as well as the main features of the expression and production systems are summarized.