Hydralysins, a new category of beta-pore-forming toxins in cnidaria

Cnidaria are venomous animals that produce diverse protein and polypeptide toxins, stored and delivered into the prey through the stinging cells, the nematocytes. These include pore-forming cytolytic toxins such as well studied actinoporins. In this work, we have shown that the non-nematocystic paralytic toxins, hydralysins, from the green hydra Chlorohydra viridissima comprise a highly diverse group of beta-pore-forming proteins, distinct from other cnidarian toxins but similar in activity and structure to bacterial and fungal toxins. Functional characterization of hydralysins reveals that as soluble monomers they are rich in beta-structure, as revealed by far UV circular dichroism and computational analysis. Hydralysins bind erythrocyte membranes and form discrete pores with an internal diameter of approximately 1.2 nm. The cytolytic effect of hydralysin is cell type-selective, suggesting a specific receptor that is not a phospholipid or carbohydrate. Multiple sequence alignment reveals that hydralysins share a set of conserved sequence motifs with known pore-forming toxins such as aerolysin, epsilon-toxin, alpha-toxin, and LSL and that these sequence motifs are found in and around the poreforming domains of the toxins. The importance of these sequence motifs is revealed by the cloning, expression, and mutagenesis of three hydralysin isoforms that strongly differ in their hemolytic and paralytic activities. The correlation between the paralytic and cytolytic activities of hydralysin suggests that both are a consequence of receptor-mediated pore formation. Hydralysins and their homologues exemplify the wide distribution of beta-pore formers in biology and provide a useful model for the study of their molecular mode of action.     

Polypeptide cytolytic toxins from sea anemones (Actiniaria)

Abstract Biochemical and biological properties of 30 cytolytic polypeptide toxins isolated from 18 species of sea anemones ( Actiniaria ) are presented and classified into three groups according to their molecular mass, isoelectric points and the molecular mechanism of action. Phospholipase A₂-like toxins (30 kDa) from Aiptasia pallida are dissimilar to acidic metridiolysin (80 kDa) from Metridium senile and the group of about 27 predominantly basic toxins, having a molecular mass of 16–20 or 10 kDa, inhibited by sphingomyelin. They are lethal for both invertebrates and vertebrates, cardiotoxic, cutolytic and cytotoxic. Pharmacological activities, cytotoxic and cytolytic properties are mediated, at least in part, by forming pores in lipid membranes. Channels, 1–2 nm in diameter, formed in planar lipid membranes are cation selective and rectified. The mechanisms and some characteristics of ion channel formation by the toxins in the cells as well as in artificial lipid membranes are summarized and discussed in view of the structure-function studies of the toxins. Putative biological roles of toxins, based on their channel-forming activity, in the capture and killing of prey, digestion, repelling of predators and intraspecific spatial competition are suggested.     

Cysteine-rich toxins from Lachesana tarabaevi spider venom with amphiphilic C-terminal segments

Venom of Lachesana tarabaevi (Zodariidae, “ant spiders”) exhibits high insect toxicity and serves a rich source of potential insecticides. Five new peptide toxins active against insects were isolated from the venom by means of liquid chromatography and named latartoxins (LtTx). Complete amino acid sequences of LtTx (60-71 residues) were established by a combination of Edman degradation, mass spectrometry and selective proteolysis. Three toxins have eight cysteine residues that form four intramolecular disulfide bridges, and two other molecules contain an additional cystine; three LtTx are C-terminally amidated. Latartoxins can be allocated to two groups with members similar to CSTX and LSTX toxins from Cupiennius salei (Ctenidae) and Lycosa singoriensis (Lycosidae). The interesting feature of the new toxins is their modular organization: they contain an N-terminal cysteine-rich (knottin or ICK) region as in many neurotoxins from spider venoms and a C-terminal linear part alike some cytolytic peptides. The C-terminal fragment of one of the most abundant toxins LtTx-1a was synthesized and shown to possess membrane-binding activity. It was found to assume amphipathic α-helical conformation in membrane-mimicking environment and exert antimicrobial activity at micromolar concentrations. The tails endow latartoxins with the ability to bind and damage membranes; LtTx show cytolytic activity in fly larvae neuromuscular preparations. We suggest a membrane-dependent mode of action for latartoxins with their C-terminal linear modules acting as anchoring devices.     

Cytolytic toxins as triggers of plant immune response

NEP1-like proteins (NLPs) are secreted proteins from fungi, oomycetes and bacteria, triggering immune responses and cell death in dicotyledonous plants. It has been unclear for a long time, whether NLPs are toxins or triggers of plant immunity. In a recent study we report that NLPs are toxins that exert cytolytic activity on dicotyledonous plants. Mutational analysis revealed a causal link between membrane damaging, cell death inducing and virulence promoting properties of NLPs. Interestingly, also induction of immune responses by NLPs required the same protein fold, providing evidence for damage-induced immunity in plants. Structural similarity to pore forming toxins from marine invertebrates allows the proposal of a model for the mode of NLP interaction with the host''s membrane.Key words: toxin, immunity, virulence, crystal structure, plant immunity, pathogen     

Voltage-gated sodium channel toxins

Neurotoxins have served as invaluable agents for identification, purification, and functional characterization of voltage-gated ion channels. Multiple classes of these toxins, which target voltage-gated Na⁺ channels via high-affinity binding to distinct but allosterically coupled sites, have been identified. The toxins are chemically diverse, including guanidinium heterocycles, a variety of structurally unrelated alkaloids, and multiple families of nonhomologous polypeptides having either related or distinct functions. This review describes the biochemistry and pharmacology of these agents, and summarizes the structure-function relationships underlying their interaction with molecular targets. In addition, we explore recent advances in the use of these toxins as molecular scaffolding agents, drugs, and insecticides.     

Activation of insect cell adenylate cyclase by Bacillus thuringiensis delta-endotoxins and melittin. Toxicity is independent of cyclic AMP.

Insecticidal Bacillus thuringiensis (Bt) delta-endotoxins are cytolytic to a range of insect cell lines in vitro. Addition of Bt var. aizawai or var. israelensis toxins to Mamestra brassicae (cabbage moth) cells in vitro increased intracellular cyclic AMP, which was paralleled by activation of adenylate cyclase in isolated membranes. Var. kurstaki toxin, which does not lyse M. brassicae cells, had no effect on cyclic AMP concentrations in intact cells, but was able to stimulate adenylate cyclase in membrane preparations. In contrast, the bee-venom toxin melittin, which is also cytolytic, increased intracellular cyclic AMP in whole cells, but inhibited adenylate cyclase in isolated membranes. Octopamine and forskolin also increased cyclic AMP in cells, but were not cytolytic. When added to cells at concentrations exceeding their LC90 (concentration causing 90% cell death), melittin and var. israelensis toxins caused cell lysis without a concomitant increase in intracellular cyclic AMP. Taken together, these results suggest that activation of adenylate cyclase by cytolytic toxins is a secondary effect (related perhaps to interactions of these toxins with membrane lipids) and is neither necessary nor sufficient for cytolysis.     

Novel genes encoding six kinds of three-finger toxins in Ophiophagus hannah (king cobra) and function characterization of two recombinant long-chain neurotoxins

Three-finger toxins are a family of low-molecular-mass toxins (<10 kDa) having very similar three-dimensional structures. In the present study, 19 novel cDNAs coding three-finger toxins were cloned from the venom gland of Ophiophagus hannah (king cobra). Alignment analysis showed that the putative peptides could be divided into six kinds of three-finger toxins: LNTXs (long-chain neurotoxins), short-chain neurotoxins, cardiotoxins (CTXs), weak neurotoxins, muscarinic toxins and a toxin with a free SH group. Furthermore, a phylogenetic tree was established on the basis of the toxin cDNAs and the previously reported similar nucleotide sequences from the same source venom. It indicated that three-finger-toxin genes in O. hannah diverged early in the course of evolution by long- and short-type pathways. Two LNTXs, namely rLNTX1 (recombinant LNTX1) and rLNTX3, were expressed and showed cytolytic activity in addition to their neurotoxic function. By comparing the functional residues, we offer some possible explanations for the differences in their neurotoxic function. Moreover, a plausible elucidation of the additonal cytolytic activity was achieved by hydropathy-profile analysis. This, to our knowledge, is the first observation that recombinant long chain alpha-neurotoxins have a CTX-like cytolytic activity.     

Marginal cross-resistance to mosquitocidal Bacillus thuringiensis strains in Cry11A-resistant larvae: presence of Cry11A-like toxins in these strains

Culex quinquefasciatus mosquito larvae resistant to the Cry11A toxin showed marginal cross-resistance to the multiple toxin crystals from B. thuringiensis subsp. israelensis and also to toxin crystals from three other mosquitocidal strains, i.e. B. thuringiensis subsp. fukuokaensis, subsp. jegathesan, and subsp. kyushuensis. Cross-resistance patterns of the Cry11A-resistant larvae to mosquitocidal strains of B. thuringiensis together with the immunological screening using antisera raised against Cry11A indicated the presence of Cry11A-like toxins in these strains and could be used as a screening tool for the identification of novel toxins. The Cry11A-resistant larvae had significantly less resistance to the Cry11B toxin from B. thuringiensis subsp. jegathesan. The occurrence of cytolytic toxins in all of these mosquitocidal strains partially explains the marginal cross-resistance observed with multiple toxin crystals since each of these crystals also contains cytolytic toxins.     

Genes and evolution of two-domain toxins from lynx spider venom

Spiderines are comparatively long polypeptide toxins (∼110 residues) from lynx spiders (genus Oxyopes). They are built of an N-terminal linear cationic domain (∼40 residues) and a C-terminal knottin domain (∼60 residues). The linear domain empowers spiderines with strong cytolytic activity. In the present work we report 16 novel spiderine sequences from Oxyopes takobius and Oxyopes lineatus classified into two subfamilies. Strikingly, negative selection acts on both linear and knottin domains. Genes encoding Oxyopes two-domain toxins were sequenced and found to be intronless. We further discuss a possible scenario of lynx spider modular toxin evolution.     

Fungal toxins as a parasitic factor responsible for the establishment of fungal infections

Although the mechanism of fungal infections, particularly that of opportunistic fungus infections, has been studied extensively, much still remains to be clarified. As is the case for certain bacterial infections, it has long been assumed by numerous investigators that some toxins, enzymes and other metabolites produced in vitro as well as in vivo by pathogenic fungi or their cellular constituents might be responsible for the establishment of fungal infections. However, there are very few papers which deal with isolation and/or characterization of pathogenic fungus-derived toxins, particularly those of high molecular weight, to sufficiently meet various criteria for toxins including etiopathological ability. Likewise, it has been speculated that certain enzymes produced by pathogenic fungi are related to the pathogenesis of infections with the fungi implicated, but no direct evidence has been provided.It is commonly held by researchers concerned with medical mycology that the lowering of specific and/or nonspecific resistance of a host to pathogenic fungi is a prerequisite for the establishment of infections, particularly opportunistic infections. However, it is also accepted that if a given fungus possesses no parasite factors (e.g. toxigenicity, invasiveness and others), it would be unable to initiate infection even when the host is in a severe immunodeficient state. This is supported by our recent studies working with Saccharomyces cerevisiae and some other so-called nonpathogenic yeasts (unpublished data). Based on these considerations, the author and his co-workers have attempted to isolate several high and low molecular weight toxins in a pure state from virulent strains of Candida albicans and Aspergillus fumigatus as opportunist. Studies have also been made on the etiopathological roles of some successfully isolated toxins in infections with the fungi implicated (46).In addition to our experimental results, general concepts in fungal toxins, particularly those related to such toxins as isolated in our laboratory are outlined. Since opportunistic fungus infections have created a global problem because of their world-wide prevalence, a sharp demarcation between the so-called pathogenic and nonpathogenic fungi has become vague. Despite this situation, two terms are conventionally used throughout this paper.The author thanks Drs. H. Yamaguchi and K. Uchida, Y. Yamamoto, T. Hiratani, and Y. Nozu for their collaboration during these studies.     

Molecular features of the cytolytic pore-forming bacterial protein toxins

The repertoire of the cytolytic pore-forming protein toxins (PFT) comprises 81 identified members. The essential feature of these cytolysins is their capacity to provoke the formation of hydrophilic pores in the cytoplasmic membranes of target eukaryotic cells. This process results from the binding of the proteins on the cell surface, followed by their oligomerization which leads to the insertion of the oligomers into the membrane and formation of protein-lined channels. It impairs the osmotic balance of the cell and causes cytolysis. In this review the molecular aspects of a number of important PFT and their respective encoding structural genes will be briefly described.     

A broad-spectrum cytolytic toxin from Bacillus thuringiensis var. kyushuensis.

Bacillus thuringiensis (Bt) var. kyushuensis synthesizes a mosquitocidal crystalline inclusion containing several proteins ranging from 140 to 14 kDa. We have identified a 25 kDa protein protoxin in this inclusion which is not cytolytic, but when activated proteolytically to 23-22 kDa products is cytolytic to mosquito, lepidopteran and mammalian cells, can release entrapped glucose from liposomes and forms cation-selective channels in a planar lipid bilayer. This broad-spectrum cytolytic toxin is related antigenically to the 23 kDa toxin from Bt var. darmstadiensis strain 73-E10-2, but not to the 25 kDa CytA toxin of Bt var. israelensis. The cytolytic activity of these Bt var. kyushuensis toxins, like that of the latter two toxins, can be neutralized by incubation with liposomes containing phospholipids.     

A fluorimetric assay for the effects of cytolytic toxins on the transport properties of resealed erythrocyte ghosts.

We prepared resealed erythrocyte ghosts loaded with SPQ and chloride. We demonstrated that these membranes were still functional, as they were capable of exchanging anions, most probably through the band-3 protein. When cytolytic toxins (Escherichia coli hemolysin and Staphylococcus aureus alpha-toxin) were offered to the resealed ghosts, the internal SPQ was released. This could be attributed to the formation of toxin-induced ion channels into the ghost membrane that were so large that SPQ could escape through them. This release was actually independent of the anion-exchanging protein, since DIDS had no inhibitory effect on it. Due to their simplicity, and because they do not lyse, erythrocyte ghosts may serve as useful models to study the action of cytolytic pore-forming toxins. To assess the validity of these model membranes we compared results obtained using RBC and resealed erythrocyte ghosts as targets for the toxin, finding complete consistency. Pre-assembled toxin channels could also be studied on the ghosts. Applying different proteolytic enzymes to the external compartment after channel formation, we found that performed E. coli hemolysin pores were at least partially destroyed by enzymatic digestion.     

Why Bacillus thuringiensis insecticidal toxins are so effective: unique features of their mode of action

The spore-forming bacterium Bacillus thuringiensis produces intracellular inclusions comprised of protoxins active on several orders of insects. These highly effective and specific toxins have great potential in agriculture and for the control of disease-related insect vectors. Inclusions ingested by larvae are solubilized and converted to active toxins in the midgut. There are two major classes, the cytolytic toxins and the delta-endotoxins. The former are produced by B. thuringiensis subspecies active on Diptera. The latter, which will be the focus of this review, are more prevalent and active on at least three orders of insects. They have a three-domain structure with extensive functional interactions among the domains. The initial reversible binding to receptors on larval midgut cells is largely dependent upon domains II and III. Subsequent steps involve toxin insertion into the membrane and aggregation, leading to the formation of gated, cation-selective channels. The channels are comprised of certain amphipathic helices in domain I, but the three processes of insertion, aggregation and the formation of functional channels are probably dependent upon all three domains. Lethality is believed to be due to destruction of the transmembrane potential, with the subsequent osmotic lysis of cells lining the midgut. In this review, the mode of action of these delta-endotoxins will be discussed with emphasis on unique features.     

Malarial toxins and the regulation of parasite density

For over a century it has been recognized that many of the clinical symptoms of malaria are caused by toxins released by rupturing schizonts, but it is only in the past few years that the underlying mechanisms have begun to be understood. Dominic Kwiatkowski here focuses on the toxins that cause malaria fever by stimulating host cells to produce tumour necrosis factor a (TNF) and other pyrogenic cytokines. Both TNF and fever have antiparasite properties, and it is proposed that the release of these toxins plays an important role in the regulation of parasite density within the host. Cerebral malaria is related to excessive TNF production. Recent data indicate that this can be the consequence of genetic variation in the host's propensity to produce TNF.     

Modulation of gut physiology through enteric toxins

Diarrheal diseases caused by microorganisms and their toxins are a major cause of mortality and morbidity throughout the world. Acute diarrhea is mainly caused due to increased intestinal secretion, commonly as a result of infection with enterotoxin producing organisms (enterotoxigenic Escherichia coli, Vibrio cholera) or due to decreased intestinal absorption from infection with organisms that damage the intestinal epithelium (enteropathogenic E. coli sp., Shigella sp., Salmonella sp.) The studies of the impact of enteric pathogens and their virulence factors exert their effect by producing toxins, called bacterial toxins. The protein toxins are produced by diverse group of bacteria. Most of the bacterial toxins exert their effect through involvement of ADP-ribosylation proteins; otherwise essential for several cellular functions while other toxins involve guanylate cyclase systems or calcium and protein kinases for their ultimate action.     

Animal toxins and ion channels

Animal venoms contain various toxins which act on ion-channels, responsible for either sodium, potassium, calcium or chloride permeation. Structure determination of these toxins demonstrate that they are organised around two different structural motifs: potassium and sodium channel effectors are organised around an alpha-helix connected by two disulfide bridges to a two- or three-stranded beta sheet whereas calcium channels effectors are structured around an "Inhibitory Cystine Knot" motif made of a dense disulfide-rich core from which emerge several loops. Analysis of local structural modifications allows us to understand the structural basis of the selectivity of these effectors towards the various ion channels. This is the first step in the design of new synthetic molecules which are potent therapeutic drugs for diseases involving ion channel dysfunctioning.     

Novel proteinaceous toxins from the nematocyst venom of the Okinawan sea anemone Phyllodiscus semoni Kwietniewski

The Okinawan sea anemone Phyllodiscus semoni is known to cause cases of severe stinging. We isolated P. semoni toxins 60A and 60B (PsTX-60A and PsTX-60B; ca. 60 kDa) as the major toxins from the isolated nematocysts of this species for the first time. PsTX-60A and PsTX-60B showed lethal toxicity to the shrimp Palaemon paucidence when administered via intraperitoneal injection (LD(50) values: 800-900 and 800 microg/kg, respectively) and hemolytic activity toward a 0.8% suspension of sheep red blood cells (ED(50) values: 600 and 300 ng/ml, respectively). Furthermore, we sequenced the cDNA encoding PsTX-60A. The deduced amino acid sequence of PsTX-60A did not show any similarity to previously reported proteins. The N-terminal amino acid sequence of PsTX-60B showed homology with that of PsTX-60A. These toxins represent a novel class of cytolytic proteinaceous toxins.     

Cytolethal distending toxins

The cytolethal distending toxins (CDTs) constitute the most recently discovered family of bacterial protein toxins. CDTs are unique among bacterial toxins as they have the ability to induce DNA double strand breaks (DSBs) in both proliferating and nonproliferating cells, thereby causing irreversible cell cycle arrest or death of the target cells. CDTs are encoded by three linked genes (cdtA, cdtB and cdtC) which have been identified among a variety of Gram-negative pathogenic bacteria. All three of these gene products are required to constitute the fully active holotoxin, and this is in agreement with the recently determined crystal structure of CDT. The CdtB component has functional homology with mammalian deoxyribonuclease I (DNase I). Mutation of the conserved sites necessary for this catalytic activity prevents the induction of DSBs as well as all subsequent intoxication responses of target cells. CDT is endocytosed via clathrin-coated pits and requires an intact Golgi complex to exert the cytotoxic activity. Several issues remain to be elucidated regarding CDT biology, such as the detailed function(s) of the CdtA and CdtC subunits, the identity of the cell surface receptor(s) for CDT, the final steps in the cellular internalization pathway, and a molecular understanding of how CDT interacts with DNA. Moreover, the role of CDTs in the pathogenesis of diseases still remains unclear.     

Bacterial protein toxins acting on intracellular targets

A number of bacterial toxins act on targets located in the cytosol. Diphtheria toxin, Pseudomonas aeruginosa exotoxin A and shigella toxin inhibit protein synthesis by enzymatic inactivation of elongation factor 2 or the 60 S ribosomal subunit. These toxins enter the cells by receptor-mediated endocytosis, followed by translocation across the membranes of intracellular organelles. Also a number or toxins that are not cytocidal act on targets in the cytosol. A number of nontoxic bacterial proteins are able to modify enzymatically intracellular molecules. Some of these proteins could be considered for targeting to special cells followed by translocation to obtain defined physiological effects.