Antimicrobial and cytolytic polypeptides of amoeboid protozoa--effector molecules of primitive phagocytes

Responses to infection and possible recognition strategies in the innate immune system of Caenorhabditis elegans

In recent years, researchers investigating innate immunity have begun to use C. elegans as a new model system. The worm has been found to mount protective responses to a variety of fungal and bacterial pathogens. Four signalling pathways involved in such responses have been identified so far: the p38 MAP kinase pathway, the programmed cell death pathway, the TGF-beta pathway and the DAF-2 insulin/IGF-I like signalling pathway. Activation of these pathways can lead to the production of immune effector molecules such as lysozymes, lipases and saposin-like proteins, which can act directly against the invading microorganisms. The signalling pathways used and the effectors produced depend on the nature of the infection, indicating that the worm can detect and discriminate between infecting microorganisms. However, the molecules involved in recognition of pathogens have yet to be identified. The worm genome encodes various proteins which might have this recognition function, such as numerous proteins containing C-type lectin domains. These and other candidates are discussed.

Membrane lipid composition protects Entamoeba histolytica from self-destruction by its pore-forming toxins

The protozoan parasite and human pathogen Entamoeba histolytica is protected against killing by its own lytic effector proteins. Amoebae withstand doses of amoebapores, their pore-forming polypeptides, that readily kill human Jurkat T cells. Moreover, the polypeptides do not bind to the amoebic surface membrane as evidenced by using fluorescently labelled amoebapores and confocal laser microscopy. Experiments employing liposomes as a minimalistic membrane system and the major isoform amoebapore A revealed that the lipid composition of amoebic membranes prevents binding of the cytolytic molecule and that both the phospholipid ingredients and the high content of cholesterol contributes to the protection of the toxin-producing cell.

Evolution of the innate immune system: the worm perspective

Simple model organisms that are amenable to comprehensive experimental analysis can be used to elucidate the molecular genetic architecture of complex traits. They can thereby enhance our understanding of these traits in other organisms, including humans. Here, we describe the use of the nematode Caenorhabditis elegans as a tractable model system to study innate immunity. We detail our current understanding of the worm's immune system, which seems to be characterized by four main signaling cascades: a p38 mitogen-activated protein kinase, a transforming growth factor-beta-like, a programed cell death, and an insulin-like receptor pathway. Many details, especially regarding pathogen recognition and immune effectors, are only poorly characterized and clearly warrant further investigation. We additionally speculate on the evolution of the C. elegans immune system, taking into special consideration the relationship between immunity, stress responses and digestion, the diversification of the different parts of the immune system in response to multiple and/or coevolving pathogens, and the trade-off between immunity and host life history traits. Using C. elegans to address these different facets of host-pathogen interactions provides a fresh perspective on our understanding of the structure and complexity of innate immune systems in animals and plants.

Anti-microbial peptides: from invertebrates to vertebrates

Gene-encoded anti-microbial peptides (AMPs) are widespread in nature, as they are synthesized by microorganisms as well as by multicellular organisms from both the vegetal and the animal kingdoms. These naturally occurring AMPs form a first line of host defense against pathogens and are involved in innate immunity. Depending on their tissue distribution, AMPs ensure either a systemic or a local protection of the organism against environmental pathogens. They are classified into three major groups: (i) peptides with an alpha-helical conformation (insect cecropins, magainins, etc.), (ii) cyclic and open-ended cyclic peptides with pairs of cysteine residues (defensins, protegrin, etc.), and (iii) peptides with an over-representation of some amino acids (proline rich, histidine rich, etc.). Most AMPs display hydrophobic and cationic properties, have a molecular mass below 25-30 kDa, and adopt an amphipathic structure (alpha-helix, beta-hairpin-like beta-sheet, beta-sheet, or alpha-helix/beta-sheet mixed structures) that is believed to be essential to their anti-microbial action. Interestingly, in recent years, a series of novel AMPs have been discovered as processed forms of large proteins. Despite the extreme diversity in their primary and secondary structures, all natural AMPs have the in vitro particularity to affect a large number of microorganisms (bacteria, fungi, yeast, virus, etc.) with identical or complementary activity spectra. This review focuses on AMPs forming alpha-helices, beta-hairpin-like beta-sheets, beta-sheets, or alpha-helix/beta-sheet mixed structures from invertebrate and vertebrate origins. These molecules show some promise for therapeutic use.

Mammalian antibiotic peptides

The increasing development of bacterial resistance to traditional antibiotics has reached alarming levels, thus creating a strong need to develop new antimicrobial agents. These new antibiotics should possess novel mechanisms of action and different cellular targets compared with existing antimicrobials. Recent discoveries and isolations of so-called animal antibiotics, mostly small cationic peptides, which represent a potent branch of natural immunity, offered the possibility to acquire new and effective antibiotics of this provenance. To this date, more than 500 antibiotic peptides have been distinguished and defined. Their antimicrobial properties present new opportunities for their use as antibiotics or for construction of their more effective derivatives, but much research is still required to pave the way to their practical use. This is a survey of substances forming an armamentarium of natural immunity of mammals.

Molecular basis for membrane selectivity of NK-2, a potent peptide antibiotic derived from NK-lysin

Increasing resistance of pathogenic bacteria against antibiotics is a severe problem in health care. Natural antimicrobial peptides and derivatives thereof have emerged as promising candidates for "new antibiotics". In contrast to classical antibiotics, these peptides act by direct physical destabilization of the target cell membrane. Nevertheless, they exhibit a high specificity for bacteria over mammalian cells. However, the precise mechanism of action and the molecular basis for membrane selectivity are still a matter of debate. We have designed a new peptide antibiotic (NK-2) with enhanced antimicrobial activity based on an effector protein of mammalian immune cells (NK-lysin). Here we describe the interaction of this alpha-helical synthetic peptide with membrane mimetic systems, designed to mimic the lipid compositions of mammalian and bacterial cytoplasmic membranes. Utilizing fluorescence and biosensor assays, we could show that on one hand, NK-2 strongly interacts with negatively charged membranes; on the other hand, NK-2 is able to discriminate, without the necessity of negative charges, between the zwitterionic phospholipids phosphatidylethanolamine (PE) and phosphatidylcholine (PC), the major constituents of the outer leaflet of the cytoplasmic membranes of bacteria and mammalian cells, respectively.

Isolation and characterization of a novel insect defensin from Rhodnius prolixus, a vector of Chagas disease

An antimicrobial peptide belonging to the defensin family of small cationic peptides associated with innate immunity in insects was isolated from the hemolymph of Rhodnius prolixus, a vector of Chagas disease. This peptide, designated R. prolixus defensin A, was purified and sequenced. The active peptide contains 43 residues and aligns well with other insect defensins. However the pre-pro region of the sequence has little shared identity with other insect defensins. We have identified 3 isoforms of R. prolixus defensin from cDNA clones obtained from RNA isolated from the whole bodies of immune activated insects. Northern analysis and Real-Time Quantitative PCR indicate that there is a very low baseline transcription of this peptide in naïve insects, and that transcription increases significantly in the fat body of immune activated insects. In addition there is a delayed induction of transcription of this peptide in the intestine 24 h post activation suggesting that the midgut/intestine of this species is active in the immune response against pathogens.

Amoebapores, archaic effector peptides of protozoan origin, are discharged into phagosomes and kill bacteria by permeabilizing their membranes

Antimicrobial peptides are widespread in animal species and their function as defensive molecules may even have appeared before the evolution of metazoa. The amoeboid protozoon Entamoeba histolytica discharge membrane-permeabilizing polypeptides named amoebapores into the phagosome in which engulfed bacteria are situated as evidenced here by confocal laser microscopy and electron microscopy using specific antibodies. We demonstrate that the purified three isoforms of the amoebic polypeptides exhibit complementary antibacterial activities in vitro. The potency of amoebapores were compared with that of antimicrobial peptides of phylogenetically widespread species by monitoring in parallel their activities against representatives of gram-positive and gram-negative bacteria and liposomes in various assays, and differences in the mechanism of membrane permeabilization became apparent. Northern blot analysis revealed that expression of genes coding for amoebapores and amoebic lysozymes is not dramatically changed upon co-culture of amoebae with bacteria indicating that the antimicrobial arsenal is rather constitutively expressed than induced in these primitive phagocytes.

Surrogate hosts: protozoa and invertebrates as models for studying pathogen-host interactions

Animal models, primary cell culture systems and permanent cell lines have provided important information on virulence properties of pathogenic microorganisms. Recently, it has been shown that some inherent limitations of such models can be circumvented by using non-vertebrate hosts such as Caenorhabditis elegans, Drosophila melanogaster and Dictyostelium discoideum. These new models are helpful to follow infection processes at the molecular level. Persuasive support comes from the fact that processes such as phagocytosis, cell signaling or innate immunity can be studied in these surrogate hosts. This review describes the establishment and application of each of the three aforementioned and genetically tractable hosts. In addition, we will report on a number of approaches that led to the identification of host cell factors which influence the susceptibility of the hosts to infection.

Innate immunity: the worm fights back

Innate immunity is an evolutionarily ancient defense system that enables animals and plants to resist invading microorganisms. Recent studies have demonstrated the existence of innate immune responses in Caenorhabditis elegans.

Hemolytic activity and developmental expression of pore-forming peptide, clonorin

Peptides pore-forming in cell membrane have been identified from a wide range of animals. A putative pore-forming peptide deduced from a cDNA clone of Clonorchis sinensis (clonorin) was predicted to consist of four amphipathic alpha-helices. Clonorin contained six invariably conserved cysteine residues, identified to form three disulfide bonds. These predicted structural features are highly homologous with pore-forming peptides, the amoebapores. Recombinant clonorin showed hemolytic activity toward rabbit erythrocytes. The hemolytic activity of C. sinensis extract increased dose-dependently and was inhibited by anti-clonorin immune sera. The clonorin was expressed developmentally in juvenile and adult flukes and localized in the intestinal epithelium of adult flukes. It is proposed that, through lysing host cellular components, clonorin could enhance proteolytic digestion in the intestine of C. sinensis.

Inducible antibacterial defense system in C. elegans

The term innate immunity refers to a number of evolutionary ancient mechanisms that serve to defend animals and plants against infection. Genetically tractable model organisms, especially Drosophila, have contributed greatly to advances in our understanding of mammalian innate immunity. Essentially, nothing is known about immune responses in the nematode Caenorhabditis elegans. Using high-density cDNA microarrays, we show here that infection of C. elegans by the Gram-negative bacterium Serratia marcescens provokes a marked upregulation of the expression of many genes. Among the most robustly induced are genes encoding lectins and lysozymes, known to be involved in immune responses in other organisms. Certain infection-inducible genes are under the control of the DBL-1/TGFbeta pathway. We found that dbl-1 mutants exhibit increased susceptibility to infection. Conversely, overexpression of the lysozyme gene lys-1 augments the resistance of C. elegans to S. marcescens. These results constitute the first demonstration of inducible antibacterial defenses in C. elegans and open new avenues for the investigation of evolutionary conserved mechanisms of innate immunity.

Involvement of a 40-kDa glycoprotein in food recognition, prey capture, and induction of phagocytosis in the protozoon Actinophrys sol

A 40-kDa glycoprotein (gp40) was identified as a Con A-binding adhesive substance of the heliozoon Actinophrys sol for immobilizing and ingesting prey flagellates. Isolation and partial characterization of gp40 showed that: 1) gp40 is a major Con A-binding protein of Actinophrys with a molecular weight of 40 kDa, and is stored in secretory granules called extrusomes; 2) gp40 was purified by Con A-affinity chromatography, and the N-terminal amino acid sequence was determined as H2N-KVLK-FEDDFDTFDLQ; 3) prey flagellates became adhered to gp40-immobilized agarose beads; 4) phagocytosis of Actinophrys was induced against gp40-immobilized agarose beads; and 5) solubilized gp40 induced exocytosis of extrusomes and cell fusion of heliozoons. These results indicate that gp40 is a multi-functional secretory protein of Actinophrys, which is required in correct targeting of the heliozoon to food organisms as well as in self-recognition.

Innate immune response of Aedes aegypti

Insects are able to protect themselves from invasion by pathogens by a rapid and potent arsenal of inducible immune peptides. This fast, extremely effective response is part of the innate immunity exhibited by all insects and many invertebrates, and shows striking similarities with the innate immune response of vertebrates. In Aedes aegypti invasion of the hemocoel by bacteria elicits the production of defensins, cecropins, a peptide active only against Gram-negative bacteria, and several other peptides that we are now characterizing. However, not all insects utilize the same peptides in the same concentrations, which may reflect the pathogens to which they may have been exposed through evolutionary time. These protective measures we see in mosquitoes are the current state of the evolution of a rapid immune response that has contributed to the success of insects in inhabiting essentially every niche on earth. The molecules involved in the response of Aedes aegypti to pathogens, and the potential role of these peptides against eukaryotic parasites ingested and transmitted by mosquitoes are discussed.

Recent developments in amoebiasis:the Gal/GalNAc lectins of Entamoeba histolytica and Entamoeba dispar

Amoebiasis is responsible for 50000-100000 deaths annually. Invasive amoebic disease begins with the attachment of Entamoeba histolytica trophozoites to colonic mucin, a process mediated by the amoebic Gal/GalNAc lectin. The non-pathogenic counterpart, E. dispar, is morphologically identical but genetically distinct. Investigations comparing the Gal/GalNac lectin from these two organisms are under way.

Comparative modeling of amoebapores and granulysin based on the NK-lysin structure-structural and functional implications

Amoebapores, the pore-forming polypeptides of the protozoan parasite Entamoeba histolytica, and effector proteins of porcine and human lymphocytes, namely NK-lysin and granulysin, reveal a substantial sequence similarity despite their enormous evolutionary distance. Moreover, all these polypeptides display antibacterial activity and are in higher concentrations cytolytic to eukaryotic cells. The recently solved NMR structure of NK-lysin enabled us to build the three dimensional structures of amoebapores and granulysin by comparative modeling. The generated models revealed the expected similarities, but also fundamental differences with respect to charge distribution, hydrophobicity and core packing. The combination of these structural properties and known biochemical data provides insight in the different membrane-interacting mechanisms of the proteins. For amoebapores, exposed hydrophobic grooves and a locally loosely packed protein core may allow a rearrangement of the protein and therefore may account for its ability to penetrate the target membrane and to form defined ion channels in planar lipid bilayers. In contrast, the structural features of NK-lysin and granulysin appear to be suitable for a membrane-perturbing mode of action rather than for channel formation.