The immune system of maggots of the blow fly (<Emphasis Type="Italic">Calliphora vicina</Emphasis>) as a source of medicinal drugs

Studies of cellular and humoral immunity of the blow fly Calliphora vicina maggot revealed three groups of pharmacologically active substances that are perspective for use in medicine: alloferons, allocations, and antimicrobial peptides. Alloferons are the C. vicina peptide family selectively stimulating cytotoxic activity of the natural killer cells, an evolutionary ancient group of immunocompetent cells playing the key role in antiviral and antitumoral immunity of mammals. Alloferons are used in medicine for treatment of herpes viral infections and viral hepatitis B. Allostatins are synthetic peptides combining structural characteristics both of alloferons and of some mammalian immunoactive proteins. Allostatins, like alloferons, stimulate cytotoxic activity of the natural killer cells and interferon production, but, unlike alloferons, have pronounced adjuvant properties, i.e., the ability to enhance immune recognition of alien (non-self) antigens. At present, allostatins are used to enhance resistance of skin and mucous membranes to viral infections; in future, they might find use in immunotherapy of cancer and other diseases. One more group of proteins and peptides of the C. vicina maggot immune response, which are promising for use in medicine, serve antimicrobial peptides. The study of the preparation whose composition inclusdes defensins, cecropins, diptericins, and proline-rich peptides of C. vicina show that this type of drugs has great potential for treatment and prevention of antibiotic-resistant infections.     

Neurogenic and septic inductions of synthesis of peptide antibiotics in larvae of Calliphora vicina R.-D. (Diptera: Calliphoridae)

Synthesis of antimicrobial peptides in diapausing larvae Calliphora vicina can be induced by two different pathways. One pathway is well known in insects and includes recognition of microbial particles by the pattern-recognizing receptors. The other pathway includes perception and transduction of stress signal to immunocompetent cells by neuroendocrine system. This phenomenon consists in stimulation of synthesis of defensins, cecropins, and diptericins under effect of chromic stimulation of mechanoreceptors with ligature applied on the larva head end. Formation of immune response in brain is established to need less than 30 s, after which isolation of the neuroendocrine complex does not eliminate activation of immune response As judging from rate of the neurogenic induction, transduction of the stimulating signal from brain to the immune system cells can be connected with release into hemolymph of biogenic amines or other neurohormones stored preliminarily in the neurohemal organ. The nature of this inductor at present remains unknown, as analysis of role of octopamine, dopamine, and adipokynetic hormone did not reveal stimulating effect on synthesis of bactericidal peptides. Physiological mechanism of this phenomenon is not finally understood, its key links seem to be CNS, hormonal factor of cardial bodies, and system of antimicrobial peptides. Synthesis of antimicrobial peptides is directly regulated by the neuroendocrine system that can produce both stimulating and stress action by reminding in this aspect the known immunoneuroendocrine interrelations in vertebrates. The existence of similar integrating mechanisms in such polar animal kingdom groups which are insects and vertebrates indicate that they are more ancient than this was considered earlier.     

The imd gene is required for local Cecropin expression in Drosophila barrier epithelia

Surfaces of higher eukaryotes are normally covered with microorganisms but are usually not infected by them. Innate immunity and the expression of gene-encoded antimicrobial peptides play important roles in the first line of defence in higher animals. The immune response in Drosophila promotes systemic expression of antimicrobial peptides in response to microbial infection. We now demonstrate that the epidermal cells underlying the cuticle of larvae respond to infected wounds by local expression of the genes for the antimicrobial peptide cecropin A. Thus, the Drosophila epidermis plays an active role in the innate defence against microorganisms. The immune deficiency (imd) gene was found to be a crucial component of the signal-induced epidermal expression in both embryos and larvae. In contrast, melanization, which is part of the wound healing process, is not dependent on the imd gene, indicating that the signalling pathways promoting melanization and antimicrobial peptide gene expression can be uncoupled.     

Induction of antimicrobial peptide synthesis by fat body cells in Calliphora vicina R.-D. (diptera, calliphoridae) larvae

The fat body is the main place of synthesis if peptide antibiotics in insects. The goal of the present study was the search in the body of the larva Calliphora vicina for humoral factors inducing synthesis of antimicrobial peptides by fat body cells during trauma. The preliminary analysis has shown that the activation factor revealed in hemolymph is the thermostable hydrophilic compound with molecular mass less than 3 kDa. According to results of experiments, the integument epitheliocytes and hemocytes also release the humoral factors directly stimulating synthesis of antimicrobial peptides by fat body.     

Effect of Cecropin B and a Synthetic Analogue on Propagation of Fish Viruses In Vitro

Abstract Cecropins and other natural antimicrobial peptides are widely distributed in animals from insects to mammals. These proteins have been shown to be major constituents of the innate immune systems of animals for nonspecific defense of the host against various bacteria and parasites. Therefore, exploitation of this natural innate defense system may lead to the development of effective methods for protecting fish from invasion by microbial pathogens. Recently, we have demonstrated that the introduction of cecropin transgenes into Japanese medaka (Oryzias latipes) conferred resistance to infection by fish bacterial pathogens. Aside from a few reports documenting the antiviral effect of antimicrobial peptides including cecropins against mammalian viruses, there is no evidence for the effect of these peptides against fish viruses. In this article we present results of in vitro characterization of native cecropin B and a synthetic analogue, CF17, against several important fish viral pathogens—namely, infectious hematopoietic necrosis virus (IHNV), viral hemorrhagic septicemia virus (VHSV), snakehead rhabdovirus (SHRV), and infectious pancreatic necrosis virus (IPNV). Upon coincubation of these peptides and viruses, the viral titers yielded in fish cells were reduced from several fold to 104-fold. Direct disruption of the viral envelope and disintegration of the viral capsids may be involved in the inhibition of viral replication by the peptides. Results of our studies demonstrate the potential of manipulating antimicrobial peptide genes by transgenesis to combat viral infection in fish.     

Influence of bacteria of Lactobaccilus genera on cytotoxic activity of splenocytes in experimental animals

Influence of lactobacilli on cytotoxic activity of splenocytes from mice of CBA line was studied in vivo and in vitro (after cultivation of splenocytes with chloroform-killed bacteria, homologous lysates obtained by ultrasound, and with native filtrates). Data on increase of splenocytes cytotoxic functions induced by lactobacilli has been obtained. Mechanisms of lactobacilli-mediated activation of cellular factors of antitumor immunity (cytotoxic lymphocytes and natural killers) were discussed. Information on the ability of cell wall components, cytoplasmic fractions, and substances secreted by lactobacilli to stimulate the immune response of a microorganism is presented.     

Antibacterial peptides isolated from insects.

Insects are amazingly resistant to bacterial infections. To combat pathogens, insects rely on cellular and humoral mechanisms, innate immunity being dominant in the latter category. Upon detection of bacteria, a complex genetic cascade is activated, which ultimately results in the synthesis of a battery of antibacterial peptides and their release into the haemolymph. The peptides are usually basic in character and are composed of 20-40 amino acid residues, although some smaller proteins are also included in the antimicrobial repertoire. While the proline-rich peptides and the glycine-rich peptides are predominantly active against Gram-negative strains, the defensins selectively kill Gram-positive bacteria and the cecropins are active against both types. The insect antibacterial peptides are very potent: their IC50 (50% of the bacterial growth inhibition) hovers in the submicromolar or low micromolar range. The majority of the peptides act through disintegrating the bacterial membrane or interfering with membrane assembly, with the exception of drosocin, apidaecin and pyrrhocoricin which appear to deactivate a bacterial protein in a stereospecific manner. In accordance with their biological function, the membrane-active peptides form ordered structures, e.g. alpha-helices or beta-pleated sheets and often cast permeable ion-pores. Their cytotoxic properties were exploited in in vivo studies targeting tumour progression. Although the native peptides degrade quickly in biological fluids other than insect haemolymph, structural modifications render the peptides resistant against proteases without sacrificing biological activity. Indeed, a pyrrhocoricin analogue shows lack of toxicity in vitro and in vivo and protects mice against experimental Escherichia coli infection. Careful selection of lead molecules based on the insect antibacterial peptides may extend their utility and produce viable alternatives to the conventional antimicrobial compounds for mammalian therapy.     

Innate immune responses of the airway epithelium

Barrier epithelia, especially airway epithelial cells, are persistently exposed to micro-organisms and environmental factors. To protect the host from these microbial challenges, many immune strategies have evolved. The airway epithelium participates in the critical innate immune response through the secretion of immune effectors such as mucin, antimicrobial peptides (AMP), and reactive oxygen species (ROS) to entrap or kill invading microbes. In addition, airway epithelial cells can act as mediators connecting innate and adaptive immunity by producing various cytokines and chemokines. Here, we present an overview of the role of mucosal immunity in airway epithelium, emphasizing the framework of bacterial and viral infections along with regulatory mechanisms of immune effectors in human cells and selected animal models. We also describe pathophysiological roles for immune effectors in human airway disease.     

Immunopathogenesis of hepatitis C virus infection

Hepatitis C virus, a recently identified member of the family Flaviviridae, is an important cause of chronic viral hepatitis and cirrhosis. There are similarities in the nature of the immune response to this pathogen with immunity in other flavivirus and hepatotropic virus infections, such as hepatitis B. However, the high rate of viral persistence after primary hepatitis C infection, and the observation that neutralizing antibodies are not protective, would suggest that there are a number of important differences between hepatitis C, other flaviviruses, and hepatitis B. The phenomenon of quasispecies evolution and other viral factors have been proposed to contribute to immune evasion by hepatitis C virus. In the face of established persistent infection, virus-specific cytotoxic T lymphocytes may exert some control over viral replication. However, these same effectors may also be responsible for the progressive liver damage characteristic of chronic hepatitis C infection. The nature of protective immunity, including the role of innate immune responses early after hepatitis C exposure, remains to be defined.     

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。     

The Drosophila systemic immune response: sensing and signalling during bacterial and fungal infections

A hallmark of the potent, multifaceted antimicrobial defence of Drosophila melanogaster is the challenge-induced synthesis of several families of antimicrobial peptides by cells in the fat body. The basic mechanisms of recognition of various types of microbial infections by the adult fly are now understood, often in great detail. We have further gained valuable insight into the infection-induced gene reprogramming by nuclear factor-kappaB (NF-kappaB) family members under the dependence of complex intracellular signalling cascades. The striking parallels between the adult fly response and mammalian innate immune defences described below point to a common ancestry and validate the relevance of the fly defence as a paradigm for innate immunity.     

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。     

Critical evaluation of the role of the Toll-like receptor 18-Wheeler in the host defense of Drosophila

Essential aspects of innate immune responses to microbial infections appear to be conserved between insects and mammals. In particular, in both groups, transmembrane receptors of the Toll superfamily play a crucial role in activating immune defenses. The Drosophila Toll family member 18-Wheeler had been proposed to sense Gram-negative infection and direct selective expression of peptides active against Gram-negative bacteria. Here we re-examine the role of 18-Wheeler and show that in adults it is dispensable for immune responses. In larvae, 18wheeler is required for normal fat body development, and in mutant larvae induction of all antimicrobial peptide genes, and not only of those directed against Gram-negative bacteria, is compromised. 18-Wheeler does not qualify as a pattern recognition receptor of Gram-negative bacteria.     

宿主防御肽抗病毒感染机制研究进展

宿主防御肽是一类广泛存在于脊椎动物的小分子多肽,具有广谱的抗菌活性以及抗炎、细胞趋化、促进血管生成和修复损伤等免疫调节功能。以往的研究多集中在宿主防御肽抗细菌和真菌感染的研究上。近年来大量研究发现,宿主防御肽也具有广泛的抗病毒活性,在临床各类病毒病的预防和治疗上具有潜在的应用前景。本文围绕宿主防御肽直接杀伤病毒、调节病毒感染过程和参与宿主抗病毒天然免疫调节这3个方面的作用机制进行综述,为宿主防御肽抗病毒相关研究和相关抗病毒生物药物的研发提供参考和借鉴。     

Structure-activity relation of human beta-defensin 3: influence of disulfide bonds and cysteine substitution on antimicrobial activity and cytotoxicity

Human beta-defensins form a group of cysteine-rich antimicrobial peptides which have been found in epithelial tissue and, more recently, in the male genital tract. They play a role in the defense against microbial pathogens in innate immunity and display additional chemotactic functions in the adaptive immune system. An important characteristic of antimicrobial peptides is that they also exhibit toxic potential on eukaryotic cells. Very little is known about the structure dependence of antimicrobial and cytotoxic effects. We investigated human beta-defensin 3 (hBD-3), a potent broad-spectrum antimicrobial effector peptide, regarding the influence of structural parameters on the antimicrobial and cytotoxic activity. We have established a structure-activity relation of the hBD-3 using synthetic derivatives differing in length, charge, disulfide connectivity, and overall hydrophobicity. The antimicrobial activity of the peptides was compared to the cyctotoxic effects on monocytic THP-1 cells and the hemolytic activity on human erythrocytes. We found that it is not important for antimicrobial and cytotoxic activity whether and how cysteine residues are arranged to form disulfide bonds. Substitution of half-cystinyl residues by tryptophan resulted in increased activities, while other substitutions did not change activity. Correlation of activities with the structural changes demonstrates that the activity on eukaryotic cells appears to depend strongly on the overall hydrophobicity. In contrast, the antimicrobial potency of hBD-3 peptides is determined by the distribution of positively charged amino acid residues and hydrophobic side chains. The results facilitate the understanding of beta-defensin interaction with different cell types and guide the design of antimicrobially active peptides.     

Neonatal vaccination against respiratory syncytial virus infection

Respiratory syncytial virus (RSV) is the leading cause of pneumonia and bronchiolitis in infants and is the most frequent cause of lower respiratory tract infections in children.Efficacious vaccination...     

Antimicrobial peptides important in innate immunity

Antimicrobial peptides are present in all walks of life, from plants to animals, and they are considered to be endogenous antibiotics. In general, antimicrobial peptides are determinants of the composition of the microbiota and they function to fend off microbes and prevent infections. Antimicrobial peptides eliminate micro-organisms through disruption of their cell membranes. Their importance in human immunity, and in health as well as disease, has only recently been appreciated. The present review provides an introduction to the field of antimicrobial peptides in general and discusses two of the major classes of mammalian antimicrobial peptides: the defensins and the cathelicidins. The review focuses on their structures, their main modes of action and their regulation.     

Heteroconjugate antibodies enhance cell-mediated anti-herpes simplex virus immunity

Impaired cell-mediated immunity predisposes individuals to severe systemic HSV infections. A potential approach for enhancing antiviral immunity is to alter the specificity of T cells and NK cells so that they become cytotoxic against HSV. We describe here the use of heteroconjugate antibodies to augment the killing of HSV-infected cells. Two different types of heteroconjugate antibodies were used: 1) CD3-specific mAb, covalently linked to HSV-specific mAb (e.g., anti-CD3 x anti-HSV-1 glycoprotein C); 2) FcR-specific mAb linked to HSV-specific mAb (e.g., anti-Fc gamma RIII x anti-HSV-1 glycoprotein D). Whereas freshly isolated, PBL were not cytotoxic against HSV-infected target cells in a 5-h 51Cr-release assay, co-incubation with either heteroconjugate resulted in significant cytotoxicity. In vitro activated PBL (anti-CD3 + IL-2) also became more potent killers of HSV-infected cells in the presence of each heteroconjugate. The specificity of anti-CD3 x anti-HSV-1 and anti-Fc gamma RIII x anti-HSV-1 gD for enhancing T cell and NK cell immunity, respectively, was confirmed by using cloned, homogeneous human T cell and NK cell lines as effectors. Kinetic analysis demonstrated that as soon as the infected cells began to express HSV glycoproteins on their surface they became susceptible to this enhanced killing. Prolonged culture of HSV-infected cells with heteroconjugate antibodies and effector cells also decreased the amount of viral replication that occurred, as measured in a plaque inhibition assay. These results suggest that heteroconjugate antibodies are potent immunotherapeutic tools that enhance anti-HSV immunity.