昆虫抗菌肽对肿瘤细胞的抑制作用研究进展

昆虫抗菌肽(antimicrobial peptide,AMPs)是一类昆虫先天免疫系统中十分重要的效应因子,它分子量小、热稳定,并且具有广谱抗菌性,能够抑制、杀死多种细菌、真菌.近几年来,由于昆虫抗菌肽具有抗肿瘤的活性且其不具有抗原性而受到研究者的广泛关注.昆虫种类多、分布广,因此昆虫抗菌肽具有很高的开发潜力和实际应用价值.但是,目前对于昆虫抗菌肽抗肿瘤能力的研究尚不够深入,对其作用机制还没有一套准确并且系统的理论.现在普遍认为昆虫抗菌肽的抗肿瘤机制与其抗菌机制类似,可以分为破坏细胞膜机制以及非破坏细胞膜机制,并且同一种昆虫抗菌肽可以通过多种方式来抑制甚至杀死肿瘤细胞,但是对正常真核细胞无明显的毒副作用.相较于传统化疗药物的无差别杀伤,昆虫抗菌肽在肿瘤治疗领域有着巨大潜力.本文简要综述了昆虫抗菌肽对肿瘤细胞的抑制作用及其作用机制,并对其开发潜力和实际应用价值进行了展望,以期为今后的研究提供理论支持.     

昆虫抗菌肽对肿瘤细胞的抑制作用研究进展

昆虫抗菌肽(antimicrobial peptide,AMPs)是一类昆虫先天免疫系统中十分重要的效应因子,它分子量小、热稳定,并且具有广谱抗菌性,能够抑制、杀死多种细菌、真菌.近几年来,由于昆虫抗菌肽具有抗肿瘤的活性且其不具有抗原性而受到研究者的广泛关注.昆虫种类多、分布广,因此昆虫抗菌肽具有很高的开发潜力和实际应用价值.但是,目前对于昆虫抗菌肽抗肿瘤能力的研究尚不够深入,对其作用机制还没有一套准确并且系统的理论.现在普遍认为昆虫抗菌肽的抗肿瘤机制与其抗菌机制类似,可以分为破坏细胞膜机制以及非破坏细胞膜机制,并且同一种昆虫抗菌肽可以通过多种方式来抑制甚至杀死肿瘤细胞,但是对正常真核细胞无明显的毒副作用.相较于传统化疗药物的无差别杀伤,昆虫抗菌肽在肿瘤治疗领域有着巨大潜力.本文简要综述了昆虫抗菌肽对肿瘤细胞的抑制作用及其作用机制,并对其开发潜力和实际应用价值进行了展望,以期为今后的研究提供理论支持.     

昆虫抗菌肽分类及在医学中应用

昆虫是地球上种类最为繁多的生物,其抗菌肽的种类和应用范围也远多于其他生物产生的抗菌肽。随着越来越多昆虫抗菌肽的发现及对其深入的研究,昆虫抗菌肽的结构和作用机制也被逐一阐明,并广泛应用于畜牧、食品工业及医药等领域。然而,由于某些限制因素,昆虫抗菌肽还未应用于临床。为了加快昆虫抗菌肽在临床中的应用,本文将从昆虫抗菌肽的结构分类、潜在的医学应用以及昆虫抗菌肽的生产研究现状等方面作一综述,以期为昆虫抗菌肽在抗细菌、抗病毒、抗肿瘤及抗寄生虫药物等方面的医用研发提供文献支持。     

昆虫抗菌肽基因工程研究进展

昆虫抗菌肽对细菌、真菌、病毒和原虫都具有杀灭作用 ,甚至对肿瘤细胞也具有杀伤作用。昆虫抗菌肽并且有独特的作用机制 ,成为众多表达系统外源导入基因的侯选对象之一 ,综述了昆虫抗菌肽的种类及其在微生物转基因工程和植物转基因工程中的进展。     

昆虫抗菌肽的结构和功能研究现状

昆虫抗菌肽是昆虫血淋巴中的一类活性肽。在昆虫感染病菌或体壁受到损伤的情况下其脂肪体能迅速合成一系列抗菌活性物质并释放到血淋巴中发挥作用,抑杀多种致病菌、真菌、病毒等,但不破坏生物体的正常细胞。对昆虫抗菌肽的结构特征、生物活性及抗菌肽分子的作用模式的最新研究进展作了综述。     

昆虫抗菌肽结构、性质和基因调控

昆虫抗菌肽是昆虫先天免疫系统中非常重要的一类效应分子。昆虫抗菌肽带正电荷,分子量小,大多数少于100个氨基酸残基。根据结构可以将昆虫抗菌肽分为一些不同的家族。昆虫抗菌肽不同的抗菌谱表明,它具有不同的作用机制。以果蝇为模式生物研究表明,昆虫抗菌肽的基因调控涉及到多个信号通路及大量的信号分子。     

含有Fxa切割位点的抗菌肽X在大肠杆菌中的融合表达

抗菌肽是昆虫体液免疫的重要成分[1,2 ] ,它们的分子量较小 ,具有抗菌、抗病毒和杀伤某些肿瘤细胞的功能 ,而不破坏人体正常细胞。基于它的这种选择性效应和分子小、无抗原性的特点 ,可望成为新一代的抗菌、抗肿瘤药物。然而 ,天然抗菌肽来源十分困难 ,不能满足研究和临床应用的需要 ,通过基因工程技术生产抗菌肽已成为人们普遍关注的焦点。抗菌肽ＣＭＩＶ是从家蚕蛹中分离并测定了其一级结构的新型抗菌肽 ,它由 35个氨基酸组成 ,不含甲硫氨酸 ,Ｃ 末端为酰胺[3 ] 。抗菌肽Ｘ是中国家蚕抗菌肽ＣＭＩＶ的变体 ,其一级结构与天然的抗菌肽ＣＭ…     

昆虫抗菌肽的功能、作用机理与分子生物学研究最新进展

昆虫虽然没有完善的免疫防御体系,但却具有高效的无细胞免疫系统。抗菌肽是昆虫免疫后血淋巴中的一类抗菌多肽,它具有分子量小,热稳定,水溶性好,无免疫原性,抗菌谱广等特点。现在,它被认为是从细菌到高等哺乳动物普遍存在的一类防御性多肽,称之为“第二防御体系”。抗菌肽不仅抗菌谱广,而且可以抑杀某些真菌、病毒及原虫,并对多种癌细胞及动物实体瘤有明显的杀伤作用,而不破坏正常细胞。近年来,对昆虫抗菌物质的研究,特别是对昆虫抗菌肽的研究已成为一个迅速发展的新领域,越来越引起人们的关注和重视。抗菌肽可望成为新一代的抗菌、抗病毒、抗癌药物。但天然抗菌肽的来源少,成本高,无法满足临床试用和基础研究的需要。因此通过 Ｄ Ｎ Ａ 重组技术来获得大量抗菌肽,成为人们普遍关注的焦点。同时,对抗菌肽抗菌、抗肿瘤机理的深入研究也越来越具有重大的理论意义和实际应用价值,前景十分广阔     

昆虫抗菌肽的研究进展

昆虫抗菌肽是昆虫免疫后存在于血淋巴中的一类肽类活性物质.具有相对分子质量小、热稳定性强、无免疫原性、抗菌谱广等特点.结合昆虫抗菌肽的研究现状和发展前景,对昆虫抗菌肽的分类、作用机理、基因工程等方面进行了综述.     

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。     

Diversity of antimicrobial peptides and their mechanisms of action

Antimicrobial peptides encompass a wide variety of structural motifs. Many peptides have alpha-helical structures. The majority of these peptides are cationic and amphipathic but there are also hydrophobic alpha-helical peptides which possess antimicrobial activity. In addition, some beta-sheet peptides have antimicrobial activity and even antimicrobial alpha-helical peptides which have been modified to possess a beta-structure retain part of their antimicrobial activity. There are also antimicrobial peptides which are rich in a certain specific amino acid such as Trp or His. In addition, antimicrobial peptides exist with thio-ether rings, which are lipopeptides or which have macrocyclic Cys knots. In spite of the structural diversity, a common feature of the cationic antimicrobial peptides is that they all have an amphipathic structure which allows them to bind to the membrane interface. Indeed, most antimicrobial peptides interact with membranes and may be cytotoxic as a result of disturbance of the bacterial inner or outer membranes. Alternatively, a necessary but not sufficient property of these peptides may be to be able to pass through the membrane to reach a target inside the cell. The interaction of these peptides with biological membranes is not just a function of the peptide but is also modulated by the lipid components of the membrane. It is not likely that this diverse group of peptides has a single mechanism of action, but interaction of the peptides with membranes is an important requirement for most, if not all, antimicrobial peptides.     

抗菌肽改良设计及抗炎作用的研究进展

抗菌肽因其具有广谱抗菌活性、不容易引起抵抗性,被认为是先天免疫系统对抗微生物感染的多功能工具。然而,天然抗菌肽存在抗菌活性低、稳定性低、溶血性高等问题,使其较难应用于临床,所以研究人员对抗菌肽进行改良设计以期获得更高抗菌活性、更低溶血活性的新型抗菌肽。另外,天然抗菌肽作为一类免疫效应因子而被发现,其表现出的抑菌、免疫调节、内毒素中和等作用,使得研究人员对抗菌肽在抗炎作用的研究表现出极大的兴趣。就抗菌肽的药物设计方法及抗炎作用机制进行综述。     

Antimicrobial Peptides from Plants

Peptides with antimicrobial properties are present in most if not all plant species. All plant antimicrobial peptides isolated so far contain even numbers of cysteines (4, 6, or 8), which are all pairwise connected by disulfide bridges, thus providing high stability to the peptides. Based on homologies at the primary structure level, plant antimicrobial peptides can be classified into distinct families including thionins, plant defensins, lipid transfer proteins, and he vein- and knottin-type antimicrobial peptides. Detailed three-dimensional structure information has been obtained for one or more members of these peptide families. All antimicrobial peptides studied thus far appear to exert their antimicrobial effect at the level of the plasma membrane of the target microorganism, but the different peptide types are likely to act via different mechanisms. Antimicrobial peptides can occur in all plant organs. In unstressed organs, antimicrobial peptides are usually most abundant in the outer cell layer lining the organ, which is consistent with a role for the antimicrobial peptides in constitutive host defense against microbial invaders attacking from the outside. Thionins are predominantly located intracellularly but are also found in the extracellular space, whereas most plant defensins and lipid transfer proteins are deposited exclusively in the extracellular space. In a number of plant species, a strong induction of genes expressing either thionins, plant defensins, or lipid transfer proteins has been observed on infection of the leaves by microbial pathogens. Hence, antimicrobial peptides can also take part in the inducible defense response of plants. Constitutive expression in transgenic plants of heterologous antimicrobial peptide genes has been achieved, which in some cases has led to enhanced resistance to particular microbial plant pathogens.     

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。     

Single molecule resolution of the antimicrobial action of quantum dot-labeled sushi peptide on live bacteria

Background  

Antimicrobial peptides are found in all kingdoms of life. During the evolution of multicellular organisms, antimicrobial peptides were established as key elements of innate immunity. Most antimicrobial peptides are thought to work by disrupting the integrity of cell membranes, causing pathogen death. As antimicrobial peptides target the membrane structure, pathogens can only acquire resistance by a fundamental change in membrane composition. Hence, the evolution of pathogen resistance has been a slow process. Therefore antimicrobial peptides are valuable alternatives to classical antibiotics against which multiple drug-resistant bacteria have emerged. For potential therapeutic applications as antibiotics a thorough knowledge of their mechanism of action is essential. Despite the increasingly comprehensive understanding of the biochemical properties of these peptides, the actual mechanism by which antimicrobial peptides lyse microbes is controversial.     

Three novel antimicrobial peptides from the skin of Rana shuchinae

Intensive studies have demonstrated that there are many antimicrobial peptides in amphibian skins. Three novel antimicrobial peptides were identified from the skin of the frog, Rana shuchinae. They are named shuchins 3–5. Their sequences were determined as KAYSMPRCKGGFRAVMCWL-NH₂, KAYSTPRCKGLFRALMCWL-NH₂, and KAYSMPRCKYLFRAVLCWL-NH₂ by Edman degradation and mass spectrometry analysis, respectively. They are composed of 19 amino acids (aa) with unique sequences. BLAST search indicated that they showed no similarity to any known peptides or proteins. They are a novel family of antimicrobial peptide. These peptides showed antimicrobial activities against all of tested microorganisms including Gram-positive bacteria, Gram-negative bacteria and fungi. The cDNAs encoding precursors of these peptides were cloned from the skin cDNA library of R. shuchinae. The precursors are composed of 64 amino acid residues including predicted signal peptides, acidic spacer peptides, and mature antimicrobial peptides. The current work identified a novel antimicrobial peptide family.     

蜘蛛抗菌肽研究进展

蜘蛛活性多肽研究主要集中于蜘蛛毒液中作用于离子通道的神经毒素多肽。但近年来,一些蜘蛛抗菌肽不断被分离纯化,其结构和抗菌活性也被广泛深入研究,这将成为蜘蛛活性多肽研究领域的一个新热点。在蜘蛛毒液和血液中,存在不同种类的抗菌肽,其多肽长度、结构、抗菌作用各不相同。而且,有些抗菌肽甚至具有抗肿瘤作用。概述了蜘蛛抗菌肽在结构和功能方面的研究进展。     

There are abundant antimicrobial peptides in brains of two kinds of Bombina toads

It is well-known that there is a large amount of antimicrobial peptides in amphibian skins but few antimicrobial peptides are found in amphibian brains. Twenty-two and four antimicrobial peptides were purified and characterized from the brain homogenate of Bombina maxima and B. microdeladigitora, respectively. One hundred fifty-eight cDNA clones encoding 79 antimicrobial peptides were isolated from brain cDNA libraries of B. maxima and B. microdeladigitora. These antimicrobial peptides belong to two peptide groups (maximin and maximin-H). Twenty of them are identical to previously reported antimicrobial peptides (maximin 1-8, 10, 11, maximin H1, 3-5, 7, 9, 10, 12, 15, 16) from B. maxima skin secretions. Fifty-nine of them are novel antimicrobial peptides. Some of these antimicrobial peptides showed strong antimicrobial activities against tested microorganism strains including Gram-positive and -negative bacteria and fungi. The current diversity in peptide coding cDNA sequences is, to our knowledge, the most extreme yet described for any animal brains. The extreme diversity may give rise to interest to prospect the actual functions of antimicrobial peptides in amphibian brains.     

A new family of antimicrobial peptides from skin secretions of Rana pleuraden

While conducting experiments to investigate antimicrobial peptides of amphibians living in the Yunnan-Guizhou region of southwest China, a new family of antimicrobial peptides was identified from skin secretions of the Yunnan frog, Rana pleuraden. Members of the new peptide family named pleurain-As are composed of 26 amino acids with a unique N-terminal sequence (SIIT) and a disulfide-bridged heptapeptide sequence (CRLYNTC). By BLAST search, pleurain-As had no significant similarity to any known peptides. Native and synthetic peptides showed antimicrobial activities against tested microorganisms including Gram-negative and Gram-positive bacteria and fungi. Twenty different cDNAs encoding pleurain-As were cloned from the skin cDNA library of R. pleuraden. The precursors of pleurain-As are composed of 69 amino acid residues including predicted signal peptides, acidic propieces, and cationic mature antimicrobial peptides. The preproregion of pleurain-A precursor comprises a hydrophobic signal peptide of 22 residues followed by an 18 residue acidic propiece which terminates by a typical prohormone processing signal Lys-Arg. The preproregions of precursors are very similar to other amphibian antimicrobial peptide precursors but the mature pleurain-As are different from other antimicrobial peptide families. The remarkable similarity of preproregions of precursors that give rise to very different antimicrobial peptides in distantly related frog species suggests that the corresponding genes form a multigene family originating from a common ancestor. Furthermore, pleurain-As could exert antimicrobial capability against Helicobacter pylori. This is the first report of naturally occurring peptides with anti-H. pylori activity from Rana amphibians.     

The role of amphibian antimicrobial peptides in protection of amphibians from pathogens linked to global amphibian declines

Amphibian species have experienced population declines and extinctions worldwide that are unprecedented in recent history. Many of these recent declines have been linked to a pathogenic skin fungus, Batrachochytrium dendrobatidis, or to iridoviruses of the genus Ranavirus. One of the first lines of defense against pathogens that enter by way of the skin are antimicrobial peptides synthesized and stored in dermal granular glands and secreted into the mucus following alarm or injury. Here, I review what is known about the capacity of amphibian antimicrobial peptides from diverse amphibians to inhibit B. dendrobatidis or ranavirus infections. When multiple species were compared for the effectiveness of their in vitro antimicrobial peptides defenses against B. dendrobatidis, non-declining species of rainforest amphibians had more effective antimicrobial peptides than species in the same habitat that had recently experienced population declines. Further, there was a significant correlation between the effectiveness of the antimicrobial peptides and resistance of the species to experimental infection. These studies support the hypothesis that antimicrobial peptides are an important component of innate defenses against B. dendrobatidis. Some amphibian antimicrobial peptides inhibit ranavirus infections and infection of human T lymphocytes by the human immunodeficiency virus (HIV). An effective antimicrobial peptide defense against skin pathogens appears to depend on a diverse array of genes expressing antimicrobial peptides. The production of antimicrobial peptides may be regulated by signals from the pathogens. However, this defense must also accommodate potentially beneficial microbes on the skin that compete or inhibit growth of the pathogens. How this delicate balancing act is accomplished is an important area of future research.