Biophysical and biochemical strategies to understand membrane binding and pore formation by sticholysins,pore-forming proteins from a sea anemone

Actinoporins constitute a unique class of pore-forming toxins found in sea anemones that are able to bind and oligomerize in membranes, leading to cell swelling, impairment of ionic gradients and, eventually, to cell death. In this review we summarize the knowledge generated from the combination of biochemical and biophysical approaches to the study of sticholysins I and II (Sts, StI/II), two actinoporins largely characterized by the Center of Protein Studies at the University of Havana during the last 20 years. These approaches include strategies for understanding the toxin structure–function relationship, the protein–membrane association process leading to pore formation and the interaction of toxin with cells. The rational combination of experimental and theoretical tools have allowed unraveling, at least partially, of the complex mechanisms involved in toxin–membrane interaction and of the molecular pathways triggered upon this interaction. The study of actinoporins is important not only to gain an understanding of their biological roles in anemone venom but also to investigate basic molecular mechanisms of protein insertion into membranes, protein–lipid interactions and the modulation of protein conformation by lipid binding. A deeper knowledge of the basic molecular mechanisms involved in Sts–cell interaction, as described in this review, will support the current investigations conducted by our group which focus on the design of immunotoxins against tumor cells and antigen-releasing systems to cell cytosol as Sts-based vaccine platforms.     

Binding properties of sea anemone toxins to sodium channels in the crayfish giant axon

1. Effects of four different sea anemone toxins from Anthopleura (AP-A and AP-C), Anemonia (ATX II) and Parasicyonis (PaTX), and a scorpion toxin from Leiurus (LqTX) on crayfish giant axons were studied. 2. These toxins slowed the Na channel inactivation process, inducing a maintained Na current during a depolarizing pulse. 3. The binding rates for these toxins markedly decreased under depolarization. The decrease in AP-A binding was mainly derived from an increased dissociation rate under depolarization whereas that in PaTX binding from a reduced association rate. 4. The potential-dependent toxin binding kinetics seemed to be related to the gating mechanism of the Na channel. 5. Competitive bindings between these toxins were demonstrated.     

Effect of membrane-partitioned n-alcohols and fatty acids on pore-forming activity of a sea anemone toxin

Equinatoxin II, a 19.8 kDa pore-forming toxin from the sea anemone Actinia equina, was examined for hemolytic activity and permeabilization of small unilamellar lipid vesicles (SUV) in the presence of increasing amounts of n-alcohols (methanol to n-octanol) and fatty acids (palmitic and palmitoleic acid). We observed an enhancement of toxin activity which was dependent on the concentration of the membrane partitioning additive. An exception was palmitic acid which exerted a bimodal role. While at low bulk concentrations it increased toxin-induced hemolysis, above 3 μM bulk concentration it was inhibitory; in neither case was it efficient in promoting release of the fluorescent marker calcein from SUV. The increased permeabilization activity was correlated with an increase in the amount of toxin bound as indicated by changes in the intrinsic toxin fluorescence. In the case of n-alcohols, at least, these effects appeared to depend on the actual amount of alcohol present inside the membrane rather than on its specific chemical nature. This suggests that the observed effects could be due to changes of the biophysical properties of the lipid bilayer, such as thickness, lipid acyl-chain ordering, and dielectric constant induced by the partitioned additives. Received: 27 March 1996 / Accepted: 10 October 1996     

Binding of the sea anemone polypeptide BDS II to the voltage-gated sodium channel.

BDS II, a 43-residue polypeptide from the sea anemone Anemonia sulcata, is reported to have both antihypertensive and antiviral activity. This polypeptide possesses a number of sequence and structural similarities to a class of cardiotonic proteins which bind to receptor site 3 of the voltage-gated sodium channel. In contrast to these cardiostimulant proteins, which produce positive inotropic effects at concentrations of 2-15 nM, BDS II produced a weak negative inotropic effect upon isolated guinea-pig atria, with doses of 90 and 180 nM depressing contractile strength by 15 and 28%, respectively. BDS II also competed with a 125-iodine labelled derivative of AP-A (a representative of the cardiostimulant proteins) bound to sodium channels in rat brain synaptosomes. The IC50 for BDS II versus AP-A was 5.2 microM. BDS II may therefore be considered an antagonist for receptor site 3 of the voltage-gated sodium channel. Structural differences between BDS II and the agonist AP-A which may give rise to their different effects on the sodium channel are considered.     

Purification, sequence, and pharmacological properties of sea anemone toxins from Radianthus paumotensis. A new class of sea anemone toxins acting on the sodium channel

Four new toxins have been isolated from the sea anemone Radianthus paumotensis: RpI, RpII, RpIII, and RpIV. They are polypeptides comprised of 48 or 49 amino acids; the sequence of RpII has been determined. Toxicities of these toxins in mice and crabs are similar to those of the other known sea anemone toxins, but they fall into a different immunochemically defined class. The sequence of RpII shows close similarities with the N-terminal end (up to residue 20) of the previously sequenced long sea anemone toxins, but most of the remaining part of the molecule is completely different. Like the other sea anemone toxins, Radianthus toxins are active on sodium channels; they slow down the inactivation process. Through their Na+ channel action, Radianthus toxins stimulate Na+ influx into tetrodotoxin-sensitive neuroblastoma cells and tetrodotoxin-resistant rat skeletal myoblasts. The efficiency of the toxins is similar in the two cellular systems. In that respect, Radianthus toxins behave much more like scorpion neurotoxins than sea anemone toxins from Anemonia sulcata or Anthopleura xanthogrammica. In binding experiments to synaptosomal Na+ channels, Radianthus toxins compete with toxin II from the scorpion Androctonus australis but not with toxins II and V from Anemonia sulcata.     

Binding of a radiolabeled sea anemone cytolysin to erythrocyte membranes

Stichodactyla helianthus cytolysin III, a 17 kDa basic polypeptide isolated from a Caribbean sea anemone, is one of the most potent hemolysins yet found in a living organism. This toxin has been reported to form new ion channels in artificial lipid bilayer membranes. The ability of this toxin to attack cell membranes is greatly enhanced by the presence of sphingomyelin. In order to investigate the mechanism by which the cytolysin causes cell lysis, we have prepared a highly active [3H]cytolysin derivative by reductive methylation with sodium cyanoborohydride and [3H]formaldehyde. A dimethylated toxin derivative was used to investigate the basis for the differential lytic activity of this polypeptide upon erythrocytes from six mammalian species. Using both direct [3H]toxin binding and indirect (Thron method) binding techniques, we found that the interspecies differences are due to variable membrane susceptibilities toward the bound toxin, rather than to differences in membrane affinity for the toxin. Similarly, we showed the enhanced lytic activity of the toxin for rat erythrocytes at elevated pH to be caused by enhanced activity of the bound toxin.     

Crystal structure of the soluble form of equinatoxin II, a pore-forming toxin from the sea anemone Actinia equina

BACKGROUND: Membrane pore-forming toxins have a remarkable property: they adopt a stable soluble form structure, which, when in contact with a membrane, undergoes a series of transformations, leading to an active, membrane-bound form. In contrast to bacterial toxins, no structure of a pore-forming toxin from an eukaryotic organism has been determined so far, an indication that structural studies of equinatoxin II (EqtII) may unravel a novel mechanism. RESULTS: The crystal structure of the soluble form of EqtII from the sea anemone Actinia equina has been determined at 1.9 A resolution. EqtII is shown to be a single-domain protein based on a 12 strand beta sandwich fold with a hydrophobic core and a pair of alpha helices, each of which is associated with the face of a beta sheet. CONCLUSIONS: The structure of the 30 N-terminal residues is the largest segment that can adopt a different structure without disrupting the fold of the beta sandwich core. This segment includes a three-turn alpha helix that lies on the surface of a beta sheet and ends in a stretch of three positively charged residues, Lys-30, Arg-31, and Lys-32. On the basis of gathered data, it is suggested that this segment forms the membrane pore, whereas the beta sandwich structure remains unaltered and attaches to a membrane as do other structurally related extrinsic membrane proteins or their domains. The use of a structural data site-directed mutagenesis study should reveal the residues involved in membrane pore formation.     

Specificity of antibodies to sea anemone toxin III and immunogenicity of the pharmacological site of anemone and scorpion toxins

Toxin III (ATX III) of the sea anemone (Anemonia sulcata) is a polypeptide containing 27 amino acid residues. It has no sequence similarity with other toxins (ATX I and II) from the same species, or with scorpion toxins, although they apparently act in a similar manner by prolonging action potentials. The specificity of ATX III antibodies was characterized using ATX III, ATX I, native and chemically modified ATX II, and scorpion alpha-toxins. The results obtained suggest that a region of ATX III, partially or totally overlapping the pharmacological site shared with ATX I and ATX II, is immunogenic. It includes a guanidino and at least two carboxylate groups. The corresponding region is not immunogenic in ATX I and ATX II. Anti-(ATX III) antibodies recognize the similar regions of ATX I and ATX II and apparently do not recognize scorpion toxins.     

The sea anemone Bunodosoma granulifera contains surprisingly efficacious and potent insect-selective toxins

Two sodium channel toxins, BgII and BgIII, isolated from the sea anemone Bunodosoma granulifera, have been subjected to an elaborate electrophysiological and pharmacological comparison between five different cloned sodium channels expressed in Xenopus laevis oocytes in order to determine their efficacy, potency and selectivity. Our results reveal large differences in toxin-induced effect between the different sodium channels. These toxins possess the highest efficacy for the insect sodium channel (para). Our data also show that BgII, generally known as a neurotoxin, is especially potent on the insect sodium channel with an EC(50) value of 5.5+/-0.5 nM. Therefore, this toxin can be used as a template for further development of new insecticides. Based on our findings, an evolutionary relationship between crustaceans and insects is also discussed.     

Two-step membrane binding by Equinatoxin II,a pore-forming toxin from the sea anemone,involves an exposed aromatic cluster and a flexible helix

Equinatoxin II (EqtII) belongs to a unique family of 20-kDa pore-forming toxins from sea anemones. These toxins preferentially bind to membranes containing sphingomyelin and create cation-selective pores by oligomerization of 3-4 monomers. In this work we have studied the binding of EqtII to lipid membranes by the use of lipid monolayers and surface plasmon resonance (SPR). The binding is a two-step process, separately mediated by two regions of the molecule. An exposed aromatic cluster involving tryptophans 112 and 116 mediates the initial attachment that is prerequisite for the next step. Steric shielding of the aromatic cluster or mutation of Trp-112 and -116 to phenylalanine significantly reduces the toxin-lipid interaction. The second step is promoted by the N-terminal amphiphilic helix, which translocates into the lipid phase. The two steps were distinguished by the use of a double cysteine mutant having the N-terminal helix fixed to the protein core by a disulfide bond. The kinetics of membrane binding derived from the SPR experiments could be fitted to a two-stage binding model. Finally, by using membrane-embedded quenchers, we showed that EqtII does not insert deeply in the membrane. The first step of the EqtII binding is reminiscent of the binding of the evolutionarily distant cholesterol-dependant cytolysins, which share a similar structural motif in the membrane attachment domain.     

Biological activity of sea anemone proteins: II. Cytolysis and cell line toxicity

Potent cytolytic activity was exhibited by proteins extracted from three sea anemones viz. Heteractis magnifica, Stichodactyla haddoni and Paracodylactis sinensis by affecting the red blood corpuscles (RBC) and the mouse fibroblast cell line (L929) and leukemia cell line (P388). Crude toxin of all the three anemone species induced spontaneous hemolysis of chicken, goat and human erythrocytes. The crude toxin of H. magnifica (0.98 mg/ml) elicited hemolysis at levels of 4096, 512 and 4096 HU (hemolytic unit) in chicken, goat and human erythrocytes respectively. Subsequently, the crude toxin of S. haddoni (0.82 mg/ml) exhibited a hemolytic activity of 256, 128 and 512 HU and that of P. sinensis (0.60 mg/ml) had a hemolytic activity of 128, 4096 and 512 HU. Most of the partially purified proteins of these anemones also exhibited the activity against the three different erythrocytes. The viability of L929 and P388 was adversely affected on adding the crude toxins. The symptoms of toxicity shown by the cells were rounding, lysis and detachment from the substratum. These effects were the least in S. haddoni, as compared to those the crude toxins of the other two species. Inhibition of growth of L929 exhibited by the toxin of the three species ranged between 61.08 and 93.38%. Similarly, inhibition of the growth of P388 ranged between 51.32 and 86.16%. The present investigation reveal the cytotoxic nature of anemone toxins.     

CgNa, a type I toxin from the giant Caribbean sea anemone Condylactis gigantea shows structural similarities to both type I and II toxins, as well as distinctive structural and functional properties(1)

CgNa (Condylactis gigantea neurotoxin) is a 47-amino-acid- residue toxin from the giant Caribbean sea anemone Condylactis gigantea. The structure of CgNa, which was solved by 1H-NMR spectroscopy, is somewhat atypical and displays significant homology with both type I and II anemone toxins. CgNa also displays a considerable number of exceptions to the canonical structural elements that are thought to be essential for the activity of this group of toxins. Furthermore, unique residues in CgNa define a characteristic structure with strong negatively charged surface patches. These patches disrupt a surface-exposed cluster of hydrophobic residues present in all anemone-derived toxins described to date. A thorough characterization by patch-clamp analysis using rat DRG (dorsal root ganglion) neurons indicated that CgNa preferentially binds to TTX-S (tetrodotoxin-sensitive) voltage-gated sodium channels in the resting state. This association increased the inactivation time constant and the rate of recovery from inactivation, inducing a significant shift in the steady state of inactivation curve to the left. The specific structural features of CgNa may explain its weaker inhibitory capacity when compared with the other type I and II anemone toxins.     

Cysteine-scanning mutagenesis of an eukaryotic pore-forming toxin from sea anemone: topology in lipid membranes.

Equinatoxin II is a cysteineless pore-forming protein from the sea anemone Actinia equina. It readily creates pores in membranes containing sphingomyelin. Its topology when bound in lipid membranes has been studied using cysteine-scanning mutagenesis. At approximately every tenth residue, a cysteine was introduced. Nineteen single cysteine mutants were produced in Escherichia coli and purified. The accessibility of the thiol groups in lipid-embedded cysteine mutants was studied by reaction with biotin maleimide. Most of the mutants were modified, except those with cysteines at positions 105 and 114. Mutants R144C and S160C were modified only at high concentrations of the probe. Similar results were obtained if membrane-bound biotinylated mutants were tested for avidin binding, but in this case three more mutants gave a negative result: S1C, S13C and K43C. Furthermore, mutants S1C, S13C, K20C, K43C and S95C reacted with biotin only after insertion into the lipid, suggesting that they were involved in major conformational changes occurring upon membrane binding. These results were further confirmed by labeling the mutants with acrylodan, a polarity-sensitive fluorescent probe. When labeled mutants were combined with vesicles, the following mutants exhibited blue-shifts, indicating the transfer of acrylodan into a hydrophobic environment: S13C, K20C, S105C, S114C, R120C, R144C and S160C. The overall results suggest that at least two regions are embedded within the lipid membrane: the N-terminal 13-20 region, probably forming an amphiphilic helix, and the tryptophan-rich 105-120 region. Arg144, Ser160 and residues nearby could be involved in making contacts with lipid headgroups. The association with the membrane appears to be unique and different from that of bacterial pore-forming proteins and therefore equinatoxin II may serve as a model for eukaryotic channel-forming toxins.     

Binding of active and inactive hemolytic factor of sea anemone nematocyst venom to red blood cells

Sea anemone nematocyst venom, in the presence of Ca²⁺, induced the lysis of red blood cells after an induction period. In the absence of Ca²⁺, however, no lysis occurred, but the hemolytic factor was shown to bind to the cells. This binding was shown to be requisite for the Ca²⁺ dependent lysis to ensue. After freeze thawing, the venom proteins responsible for lysis lost their hemolytic activity, yet still bound to the cells. The freezethawed inactivated venom competitively blocked hemolysis by active venom.     

Bacterial two-component and hetero-heptameric pore-forming cytolytic toxins: structures, pore-forming mechanism, and organization of the genes

Staphylococcal gamma-hemolysin (Hlg), leukocidin (Luk), and Panton-Valentine leukocidin (PVL) are two-component and hetero-oligomeric pore-forming cytolytic toxins (or cytolysin), that were first identified in bacteria. No information on the existence of hetero-oligomeric pore-forming cytolytic toxins in bacteria except for staphylococcal strains is available so far. Hlg (Hlg1 of 34 kDa/Hlg2 of 32 kDa) effectively lyses erythrocytes from human and other mammalian species. Luk (LukF of 34 kDa/LukS of 33 kDa) is cytolytic toward human and rabbit polymorphonuclear leukocytes and rabbit erythrocytes, and PVL (LukF-PV of 34 kDa/LukS-PV of 33 kDa) reveals cytolytic activity with a high cell specificity to leukocytes. Hlg1 is identical to LukF and that the cell specificities of the cytolysins are determined by Hlg2 and LukS. Based on the primary and 3-dimensional structures of the toxin components, Hlg, Luk, and PVL are thought to form a family of proteins. In the first chapter of this article, we describe the molecular basis of the membrane pore-forming nature of Hlg, Luk, and PVL. We also describe a requirement of the phosphorylation of LukS and LukS-PV by protein kinase for their leukocytolytic activity besides their pore formation on human leukocytes.Recently, the assembly mechanism of the LukF and Hlg2 monomers into pore-forming hetero-oligomers of Hlg on human erythrocyte membranes has been clarified for the first time by our study using a single-molecular fluorescence imaging technique. We estimated 11 sequential equilibrium constants for the assembly pathway which includes the beginning with membrane binding of monomers, proceeds through single pore oligomerization, and culminates in the formation of clusters of the pores. In the second chapter of this article, we refer to an assembly mechanism of LukF and Hlg2 on human erythrocytes as well as the roles of the membranes of the target cells in pore formation by Hlg.The LukF, LukS, and Hlg2 proteins are derived from the Hlg locus (hlg), and have been found in 99% of clinical isolates of Staphylococcus aureus. In contrast, LukF-PV and LukS-PV are derived from the PVL locus (pvl) which is distinct from the hlg locus, and only a small percentage of clinically isolated S. aureus strains carries pvl. Recently, we discovered pvl on the genome of lysogenic bacteriophages, psiPVL, and determined the entire gene of the phage. We also demonstrated the phage conversion of S. aureus leading to the production of PVL through the discovery of a PVL-carrying temperate phage, psiSLT, from a clinical isolate of S. aureus. In the third chapter of this article, we discuss genetic analyses of the Hlg, Luk, and PVL genes. We also discuss the current status of knowledge of the genetic organization of PVL-converting phages in order to achieve an understanding of their molecular evolution.     

Purification and pharmacological properties of eight sea anemone toxins from Anemonia sulcata, Anthopleura xanthogrammica, Stoichactis giganteus, and Actinodendron plumosum

Eight different polypeptide toxins from sea anemones of four different origins (Anemonia sulcata, Anthopleura xanthogrammica, Stoichactis giganteus, and Actinodendron plumosum) have been studied. Three of these toxins are new; the purification procedure for the five other ones has been improved. Sea anemone toxins were assayed (i) for their toxicity to crabs and mice, (ii) for their affinity for the specific sea anemone toxin receptor situated on the Na+ channels of rat brain synaptosomes, and (iii) for their capacity to increase, in synergy with veratridine, the rate of 22Na+ entry into neuroblastoma cells via the Na+ channel. Some of the toxins are more active on crustaceans, whereas others are more toxic to mammals. A very good correlation exists between the toxic activity to mice, the affinity of the toxin for the Na+ channel in rat brain synaptosomes, and the stimulating effect on 22 Na+ uptake by neuroblastoma cells. The observation has also been made that the most cationic toxins are also the most active on mammals and the least active on crustaceans. Toxicities (LD50) to mice of the most active sea anemone toxins and of the most active scorpion toxins are similar, and sea anemone toxins at high enough concentrations prevent binding of scorpion toxins to their receptor. However, scorpion toxins have affinities for the Na+ channel which are approximately 60 times higher than those found for the most active sea anemone toxins. Three sea anemone toxins appear to be more interesting than toxin II from A. sulcata (the "classical" sea anemone toxin) for studies of the Na+ channel structure and mechanism when the source of the channel is of a mammalian origin. Two of these three toxins can be radiolabeled with iodine while retaining their toxic activity; they appear to be useful tools for future biochemical studies of the Na+ channel.     

Effects of lipid composition on membrane permeabilization by sticholysin I and II, two cytolysins of the sea anemone Stichodactyla helianthus

Sticholysin I and II (St I and St II), two basic cytolysins purified from the Caribbean sea anemone Stichodactyla helianthus, efficiently permeabilize lipid vesicles by forming pores in their membranes. A general characteristic of these toxins is their preference for membranes containing sphingomyelin (SM). As a consequence, vesicles formed by equimolar mixtures of SM with phosphatidylcholine (PC) are very good targets for St I and II. To better characterize the lipid dependence of the cytolysin-membrane interaction, we have now evaluated the effect of including different lipids in the composition of the vesicles. We observed that at low doses of either St I or St II vesicles composed of SM and phosphatidic acid (PA) were permeabilized faster and to a higher extent than vesicles of PC and SM. As in the case of PC/SM mixtures, permeabilization was optimal when the molar ratio of PA/SM was ~1. The preference for membranes containing PA was confirmed by inhibition experiments in which the hemolytic activity of St I was diminished by pre-incubation with vesicles of different composition. The inclusion of even small proportions of PA into PC/SM LUVs led to a marked increase in calcein release caused by both St I and St II, reaching maximal effect at ~5 mol % of PA. Inclusion of other negatively charged lipids (phosphatidylserine (PS), phosphatidylglycerol (PG), phosphatidylinositol (PI), or cardiolipin (CL)), all at 5 mol %, also elicited an increase in calcein release, the potency being in the order CL approximately PA > PG approximately PI approximately PS. However, some boosting effect was also obtained, including the zwitterionic lipid phosphatidylethanolamine (PE) or even, albeit to a lesser extent, the positively charged lipid stearylamine (SA). This indicated that the effect was not mediated by electrostatic interactions between the cytolysin and the negative surface of the vesicles. In fact, increasing the ionic strength of the medium had only a small inhibitory effect on the interaction, but this was actually larger with uncharged vesicles than with negatively charged vesicles. A study of the fluidity of the different vesicles, probed by the environment-sensitive fluorescent dye diphenylhexatriene (DPH), showed that toxin activity was also not correlated to the average membrane fluidity. It is suggested that the insertion of the toxin channel could imply the formation in the bilayer of a nonlamellar structure, a toroidal lipid pore. In this case, the presence of lipids favoring a nonlamellar phase, in particular PA and CL, strong inducers of negative curvature in the bilayer, could help in the formation of the pore. This possibility is confirmed by the fact that the formation of toxin pores strongly promotes the rate of transbilayer movement of lipid molecules, which indicates local disruption of the lamellar structure.     

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.