pH-dependence of the phospholipid interaction of diphtheria-toxin fragments

Targeted toxins

Objective. Current modalities used in the treatment of cancer often cause unacceptable damage to normal tissue. Toxins targeted toward tumor cells by antibodies or growth factors have the potential to selectively kill tumor cells while leaving normal tissue intact. The purpose of this review is to provide background information on targeted toxins and current clinical studies for this new class of anti-cancer compounds.

Data sources. A MEDLINE search was conducted using the term “immunotoxins.” Relevant articles were also obtained by the systematic examination of article references.

Data synthesis. The toxins Pseudomonas exotoxin, diphtheria toxin, and ricin toxin are often used as targeted toxins. Deletion or mutation of the binding domains of these toxins decreased binding of the toxins to normal tissues. Antibodies or growth factors can be used as targeting moiety, and the resulting agents are called immunotoxins or fusion proteins, respectively. DNA technology and chemical modifications of the toxin as well as the antibody moiety led to smaller and less immunogenic targeted toxins. Smaller targeted toxins are less toxic and penetrate further into the tumor. The summary of several targeted toxins elicited during clinical trials in this review makes it clear that several targeted toxins are potential agents for the treatment of various cancers, although some problems still need to be overcome. These problems include toxicity, immunogenicity, cross-reactivity of the targeted toxin with life-sustaining tissue, heterogenicity of tumor cells, and limited tumor penetration.

Topography of the TH5 Segment in the Diphtheria Toxin T-Domain Channel

The translocation domain (T-domain) of diphtheria toxin contains 10 α helices in the aqueous crystal structure. Upon exposure to a planar lipid bilayer under acidic conditions, it inserts to form a channel and transport the attached amino-terminal catalytic domain across the membrane. The TH5, TH8, and TH9 helices form transmembrane segments in the open-channel state, with TH1-TH4 translocated across the membrane. The TH6-TH7 segment also inserts to form a constriction that occupies only a small portion of the total channel length. Here, we have examined the TH5 segment in more detail, using the substituted-cysteine accessibility method. We constructed a series of 23 mutant T-domains with single cysteine residues at positions in and near TH5, monitored their channel formation in planar lipid bilayers, and probed for an effect of thiol-specific reagents added to the solutions on either side of the membrane. For 15 of the mutants, the reagent caused a decrease in single-channel conductance, indicating that the introduced cysteine residue was exposed within the channel lumen. We also found that reaction caused large changes in ionic selectivity for some mutant channels. We determined whether reaction occurred in the open state or in the brief flicker-closed state of the channel. Finally, we compared the reaction rates from either side of the membrane. Our experiments are consistent with the hypotheses that the TH5 helix has a transmembrane orientation and remains helical in the open-channel state; they also indicate that the middle of the helix is aligned with the constriction in the channel.

Microsecond Simulations of the Diphtheria Toxin Translocation Domain in Association with Anionic Lipid Bilayers

Diphtheria toxin translocation (T) domain undergoes conformational changes in acidic solution and associates with the lipid membranes, followed by refolding and transmembrane insertion of two nonpolar helices. This process is an essential step in delivery of the toxic catalytic domain of the diphtheria toxin to the infected cell, yet its molecular determinants are poorly characterized and understood. Therefore, an atomistic model of the T-domain-membrane interaction is needed to help characterize factors responsible for such association. In this work, we present atomistic model structures of T-domain membrane-bound conformations and investigate structural factors responsible for T-domain affinity with the lipid bilayer in acidic solution using all-atom molecular dynamics (MD) simulations. The initial models of the protein conformations and protein-membrane association that serve as starting points in the present work were developed using atomistic simulations of partial unfolding of the T-domain in acidic solution (Kurnikov, I. V.; et al. J. Mol. Biol. 2013, 425, 2752-2764), and coarse-grained simulations of the T-domain association with the membranes of various compositions (Flores-Canales, J. C.; et al. J. Membr. Biol. 2015, 248, 529-543). In this work we present atomistic level modeling of two distinct configurations of the T-domain in association with the anionic lipid bilayer. In microsecond-long MD simulations both conformations retain their compact structure and gradually penetrate deeper into the bilayer interface. One membrane-bound conformation is stabilized by the protein contacts with the lipid hydrophobic core. The second modeled conformation is initially inserted less deeply and forms multiple contacts with the lipid at the interface (headgroup) region. Such contacts are formed by the charged and hydrophilic groups of partially unfolded terminal helixes and loops. Neutralization of the acidic residues at the membrane interface allows for deeper insertion of the protein and reorientation of the protein at the membrane interface, which corroborates that acidic residue protonation as well as presence of the anionic lipids may play a role in the membrane association and further membrane insertion of the T-domain as implicated in experiments. All simulations reported in this work were performed using AMBER force-field on Anton supercomputer. To perform these reported simulations, we developed and carefully tested a force-field for the anionic 1-palmitoyl-2-oleoyl-phosphatidyl-glycerol (POPG) lipid, compatible with the Amber 99SB force-field and stable in microsecond-long MD simulations in isothermal-isobaric ensemble.

The membrane topography of the diphtheria toxin T domain linked to the a chain reveals a transient transmembrane hairpin and potential translocation mechanisms

The diphtheria toxin T domain helps translocate the A chain of the toxin across membranes. To gain insight into translocation, the membrane topography of key residues in T domain attached to the A chain (AT protein) was compared to that in the isolated T domain using fluorescence techniques. This study demonstrates that residues in T domain hydrophobic helices (TH5-TH9) tended to be less exposed to aqueous solution in the AT protein than in the isolated T domain. Under conditions in which the loop connecting TH5 to TH6/7 is located stably on the cis (insertion) side of the membrane in the isolated T domain, it moves between the cis and trans sides of the membrane in the AT protein. This is indicative of the formation of a dynamic, transient transmembrane hairpin topography by TH5-TH7 in the AT protein. Since TH8 and TH9 also form a transmembrane hairpin, this means that TH5-TH9 may form a cluster of transmembrane helices. These helices have a nonpolar surface likely to face the lipid bilayer in a helix cluster and a surface rich in uncharged hydrophilic residues which in a helix cluster would likely be facing inward (and perhaps be pore-lining). This uncharged hydrophilic surface could play a crucial role in translocation, interacting transiently with the translocating A chain. A similar motif can be found in, and may be important for, other protein translocation systems.

Characterization of diphtheria toxin's catalytic domain interaction with lipid membranes

In response to a low environmental pH and with the help of the B fragment (DTB) the catalytic domain of diphtheria toxin (DTA) crosses the endosomal membrane to inhibit protein synthesis. In this study, we investigated the interaction of DTA with lipid membranes by biochemical and biophysical approaches. Data obtained from proteinase K and trypsin digestion experiments of membrane-inserted DTA suggested that residues 134-157 may adopt a transmembrane orientation and residues 77-100 could be membrane-associated, adopting either a surface or a transmembrane orientation. Fourier transform infrared spectroscopy analysis (FTIR) was used to characterize the secondary and tertiary structure of DTA along its pathway, from the native secreted form at pH 7.2 to the refolded structure at neutral pH after interaction with and desorption from a lipid membrane. We found that the association of DTA with lipid membranes at low pH was characterized by an increase of beta-sheet structures and that the refolded structure at neutral pH after interaction with the membrane was identical to the native structure at the same pH. We also investigated the desorption of DTA from the membrane at neutral pH as a function of temperature. Although a complete desorption was observed at 37 degrees C, no desorption took place at 4 degrees C. A model of translocation involving the possibility that DTA might insert one or several transient transmembrane domains during translocation is discussed.

Interaction of the membrane-inserted diphtheria toxin T domain with peptides and its possible implications for chaperone-like T domain behavior

The T domain of diphtheria toxin is believed to aid the low-pH-triggered translocation of the partly unfolded A chain (C domain) through cell membranes. Recent experiments have suggested the possibility that the T domain aids translocation by acting as a membrane-inserted chaperone [Ren, J., et al. (1999) Science 284, 955-957]. One prediction of this model is that the membrane-inserted T domain should be able to interact with sequences that mimic unfolded proteins. To understand the basis of interaction of the membrane-inserted T domain with unfolded polypeptides, its interaction with water-soluble peptides having different sequences was studied. The membrane-inserted T domain was able to recognize helix-forming 23-residue Ala-rich peptides. In the presence of such peptides, hydrophobic helix 9 of the T domain underwent the previously characterized conformational change from a state exhibiting shallow membrane insertion to one exhibiting deep insertion. This conformational change was more readily induced by the more hydrophobic peptides that were tested. It did not occur at all in the presence a hydrophilic peptide in which alternating Ser and Gly replaced Ala or in the presence of unfolded hydrophilic peptides derived from the A chain of the toxin. Interestingly, a peptide with a complex sequence (RKE(3)KE(2)LMEW(2)KM(2)SETLNF) also interacted with the T domain very strongly. We conclude that the membrane-inserted T domain cannot recognize every unfolded amino acid sequence. However, it does not exhibit strong sequence specificity, instead having the ability to recognize and interact with a variety of amino acid sequences having moderate hydrophobicity. This recognition was not strictly correlated with the strength of peptide binding to the lipid, suggesting that more than just hydrophobicity is involved. Although it does not prove that the T domain functions as a chaperone, T domain recognition of hydrophobic sequences is consistent with it having polypeptide recognition properties that are chaperone-like.

Induction of neutralizing antibodies against diphtheria toxin by priming with recombinant Mycobacterium bovis BCG expressing CRM(197), a mutant diphtheria toxin

BCG, the attenuated strain of Mycobacterium bovis, has been widely used as a vaccine against tuberculosis and is thus an important candidate as a live carrier for multiple antigens. With the aim of developing a recombinant BCG (rBCG) vaccine against diphtheria, pertussis, and tetanus (DPT), we analyzed the potential of CRM(197), a mutated nontoxic derivative of diphtheria toxin, as the recombinant antigen for a BCG-based vaccine against diphtheria. Expression of CRM(197) in rBCG was achieved using Escherichia coli-mycobacterium shuttle vectors under the control of pBlaF*, an upregulated beta-lactamase promoter from Mycobacterium fortuitum. Immunization of mice with rBCG-CRM(197) elicited an anti-diphtheria toxoid antibody response, but the sera of immunized mice were not able to neutralize diphtheria toxin (DTx) activity. On the other hand, a subimmunizing dose of the conventional diphtheria-tetanus vaccine, administered in order to mimic an infection, showed that rBCG-CRM(197) was able to prime the induction of a humoral response within shorter periods. Interestingly, the antibodies produced showed neutralizing activity only when the vaccines had been given as a mixture in combination with rBCG expressing tetanus toxin fragment C (FC), suggesting an adjuvant effect of rBCG-FC on the immune response induced by rBCG-CRM(197). Isotype analysis of the anti-diphtheria toxoid antibodies induced by the combined vaccines, but not rBCG-CRM(197) alone, showed an immunoglobulin G1-dominant profile, as did the conventional vaccine. Our results show that rBCG expressing CRM(197) can elicit a neutralizing humoral response and encourage further studies on the development of a DPT vaccine with rBCG.

Penetration of protein toxins into cells

AB toxins deliver their enzymatically active A domain to the cytosol. Some AB-toxins are able to penetrate cellular membranes from endosomes where the low pH triggers their translocation. One such toxin is diphtheria toxin and important features of its translocation mechanism have been unraveled during the last year. Other toxins depend on retrograde transport through the secretory pathway to the ER before translocation, and recent findings suggest that these toxins take advantage of the ER translocation machinery normally used for transport of cellular proteins. In addition, the intracellular targets of many of these toxins have been identified recently.

The pH-dependent interaction of cinnamomin with lipid membranes investigated by fluorescence methods

Cinnamomin, a new type II ribosome-inactivating protein (RIP), was found to be able to induce the release of calcein loaded in lecithin small unilamellar vesicles and the fusion or aggregation of the lecithin liposomes. Such induction could be promoted severalfold by a pH 5.0 environment, a condition similar to that in endocytic vesicles. Lowering the pH from 7.5 to 5.0 evoked conformational changes of cinnamomin and unmasked its hydrophobic areas, including the exposure of 1-anilino-8-naphthalenesulfonate (1,8-ANS) binding sites of the molecule. Some tryptophan residues with affinity to acrylamide were demonstrated to participate in the lipid-protein interaction. The pH dependent fusogenicity of type II RIP might suggest its in vivo function as a fusogen to exert its cytotoxicity.

Membrane translocation of charged residues at the tips of hydrophobic helices in the T domain of diphtheria toxin

The low pH triggered membrane insertion of the T domain of diphtheria toxin is a critical step in the translocation of the C domain of the toxin across membranes in vivo. We previously established that the T domain can interact with membranes in two distinct conformations, one in which the TH8/TH9 helical hairpin lies close to the bilayer surface and a second in which it inserts more deeply and appears to be transmembraneous. The loss of charge on residues E349 and D352 due to protonation at low pH has been proposed to be a critical step in transmembrane insertion, because they are within a loop connecting TH8 and TH9, and must cross the membrane upon transmembrane insertion. In this report, the role of these residues was examined by measuring the effect of the double substitution E349K/D352K on the conformation of the TH8/TH9 hairpin through a fluorescent group attached to TH9. At pH 4.5, there was shallower insertion of TH8/TH9 of the E349K/D352K mutant relative to T domain with wild-type residues at 349 and 352. In addition, smaller and/or fewer pores were obtained with the E349K/D352K mutant relative to the wild-type. On the other hand, high T domain concentrations, or further decreasing pH, allowed transmembrane insertion of both the wild-type and the 349K/352K mutant as well as induction of larger and/or more numerous pores. Furthermore, the transmembrane insertion process was rapid for both the mutant and wild-type. This shows that the mutant has the capacity to form a transmembrane structure similar to that of the wild-type T domain and, thus, that introduction of charged groups in membrane-penetrating regions of a protein does not introduce an insurmountable barrier to transmembrane movement. The linkage between the ability of the T domain to form the transmembrane conformation and pores suggests that the effects of these mutations in inhibiting pore formation are likely to partly result from the inability to insert properly. Additionally, the observation that decreasing pH allows the 349K/352K mutant to insert deeply indicates that there are residues other than E349 and D352 whose protonation promotes transmembrane insertion.

Structure and topology of diphtheria toxin R domain in lipid membranes

The interaction of the receptor-binding domain (R domain) of diphtheria toxin with a pure lipid membrane has been characterized by several approaches. Using a photoactivatable lipid, the R domain has been shown to deeply insert in the lipid membrane. Three regions of the R domain (residues 380-421, 422-441, and 442 to about 483) are protected by their interaction with the membrane from externally added proteases. At least one of these regions is deeply interacting with the lipid membrane, as evidenced by the location of Cys 461 and 471 determined by fluorescence experiments. Binding of the R domain to the lipid membrane is characterized by the appearance of an alpha-helical component whose orientation is compatible with a transmembrane orientation.

The acid activation of Helicobacter pylori toxin VacA: structural and membrane binding studies

The cell vacuolating activity of the protein toxin VacA, released by Helicobacter pylori, is strongly increased in vitro by exposure to acidic pH followed by neutralization. This short acid exposure does not increase significantly the binding of VacA to cell or to lipid membranes. However, membrane photolabeling with photoactivatable radioactive phospholipids and ANS binding studies show that VacA transiently exposed to pH equal or lower than 5 changes conformation and exposes on its surface hydrophobic segments. Both the 32 and the 58 kDa subunits of the toxin insert in the lipid bilayer and interact with the fatty acid chains of phospholipids. Membrane binding and penetration are enhanced by incubating target cells or liposomes with the toxin at mild acidic pH values, similar to those present around H. pylori on the stomach mucosa. These findings are discussed with respect to the critical step in cell intoxication consisting in the translocation of the active toxin domain into the cell cytosol. We suggest that membrane translocation takes place at the plasma membrane level.

Use of Trp mutations to evaluate the conformational behavior and membrane insertion of A and B chains in whole diphtheria toxin

The structure of diphtheria toxin was examined using its Trp fluorescence. To examine the interactions of the A and B chains of the toxin independently, mutants were constructed in which Trp residues were restricted to either the A or the B chain. The conformation and stability of the mutants were very similar to those of the wild-type protein. In addition, they underwent the low-pH conformational transition and membrane insertion at about the same pH as wild-type toxin. This shows Trp do not play a critical role in these processes which are necessary for the translocation of toxin across endosomal membranes in vivo. There was a shift in fluorescence of the Trp mutants which showed the low-pH-induced transition increases exposure of both the A and B Trp to a more polar environment. This supports a model in which the interdomain interactions present at neutral pH break down at low pH. To evaluate the location of the A and B chains in the membrane, the fluorescence quenching of model membrane inserted toxin was measured. Comparison of the amount of quenching by lipid labeled with nitroxides localized at shallow, medium, or deep depths within the bilayer demonstrated that both the A and B chains insert deeply, but the A chain Trp are somewhat less deeply inserted. Trp on the A chain are also less exposed to lipid than on the B chain, as judged by their weaker quenching by the nitroxide-labeled lipid. This conclusion was supported by the observation that the Trp of membrane-inserted isolated A chain is more lipid-exposed than when the A chain is part of the whole toxin. Both the A and B chain Trp become less exposed to lipid after neutralizing pH. However, both chains remain inserted, with at least part of the B chain remaining deeply inserted. These results support the "partial wrapper" model in which both the A and B chains are inserted but contacts between the two chains significantly reduce the exposure of the A chain to lipid.

Interaction with a lipid membrane: a key step in bacterial toxins virulence

Bacterial toxins are secreted as soluble proteins. However, they have to interact with a cell lipid membrane either to permeabilize the cells (pore forming toxins) or to enter into the cytosol to express their enzymatic activity (translocation toxins). The aim of this review is to suggest that the strategies developed by toxins to insert in a lipid membrane is mediated by their structure. Two categories, which contains both pore forming and translocation toxins, are emerging: alpha helical proteins containing hydrophobic domains and beta sheets proteins in which no hydrophobicity can be clearly detected. The first category would rather interact with the membrane through multi-spanning helical domains whereas the second category would form a beta barrel in the membrane.

Secondary structure of anthrax lethal toxin proteins and their interaction with large unilamellar vesicles: a fourier-transform infrared spectroscopy approach

Attenuated total reflection Fourier transform infrared spectroscopy has been used to study the secondary structure of anthrax lethal toxin proteins: protective antigen (PA) and lethal factor (LF), as a function of pH in the absence and in the presence of phospholipid vesicles. We first characterized the binding of LF and PA to the lipid membrane and demonstrated the strong pH dependence of the association of PA and LF to the lipid bilayer as well as the effect of pH neutralization on this binding. Binding of LF to the lipid membrane can be, at least partially, reversed when the pH is brought to neutral whereas in the same conditions PA binding is irreversible. Characterization of the conformational changes undergone by PA and LF upon pH lowering, lipid binding, and, in the case of LF, reversal of binding was carried out (i) by determining the secondary structure of the proteins and (ii) by evaluating their ability to undergo an hydrogen/deuterium exchange.

Immunochemical analysis of the structure of diphtheria toxin shows all three domains undergo structural changes at low pH

Diphtheria toxin is a bacterial protein that undergoes a physiologically critical conformational change at low pH. This change involves a partial unfolding event forming a molten globule-like structure, which exposes hydrophobic regions and which allows the toxin to insert into, and translocate across, membranes. In this report, antibody binding was used to examine the regions of the toxin that undergo structural changes at low pH. Monoclonal antibodies specific to the catalytic (C), transmembrane (T), and receptor-binding (R) domains of diphtheria toxin were prepared and isolated. In addition, the binding of anti-peptide antibodies raised against peptides in the C and T domains to toxin was examined. Anti-C monoclonals and antipeptide antibodies were found to bind preferentially to low pH-treated toxin relative to native toxin. Anti-T and anti-R monoclonal binding ranged between preference for native toxin and preference for low pH-treated toxin. These results suggest that the C domain becomes more exposed to solution at low pH, and that both the T and R domains of the B chain undergo major conformational changes at low pH. Based on these results, a model in which low pH induces several coordinated changes in intra- and inter-domain interactions is suggested. The participation of the R domain in these changes is of particular significance because it suggests that the R domain plays a more important role in low pH-induced changes than previously realized.

Immunochemical analysis shows all three domains of diphtheria toxin penetrate across model membranes

Diphtheria toxin undergoes membrane insertion and translocation across membranes when exposed to low pH. In this study, the translocation of the toxin has been investigated by the binding of antibodies to two preparations of model membrane-inserted toxin. In one preparation, toxin was added externally to model membrane vesicles and then inserted by exposure to low pH. In the other preparation, toxin was entrapped in the vesicles at neutral pH, and then inserted by decreasing pH. At neutral pH, externally added antibodies could not bind to entrapped toxin, although they could bind to externally added native toxin. However, after low pH exposure, antibodies against all three toxin domains (catalytic (C), transmembrane (T), and receptor-binding (R)) could bind to entrapped toxin, and also to externally added membrane-inserted toxin. The binding to the entrapped toxin shows that all three domains of the toxin translocate to the trans face of the membrane after exposure to low pH. The observation that antibodies bind to both external and entrapped preparations of toxin after low pH exposure shows that toxin inserts in a mixed orientation. A difference in antibody binding to low pH-treated toxin in which the C domain is folded (Lr' conformation) or unfolded (Lr" conformation) was also observed. An increase in antibody binding to C and T domains in the Lr" conformation relative to binding to the Lr' conformation was found for entrapped toxin, suggesting that more of the C and T domains translocate across the bilayer in the Lr" conformation. These results suggest all three toxin domains insert in the membrane bilayer and participate in translocation in vitro. The C and R domains lack classical transmembrane hydrophobic sequences. However, they possess sequences that have the potential to form membrane-inserting beta-sheets.

Cell-mediated reduction and incomplete membrane translocation of diphtheria toxin mutants with internal disulfides in the A fragment

Active diphtheria toxin consists of two fragments, A and B, joined by a disulfide bond. The B fragment binds to cell surface receptors and aids in the translocation of the enzymatically active A fragment to the cytosol. Normally, the toxin A fragment enters the cytosol from acidic endosomes, but translocation can also be induced at the level of the plasma membrane by exposing cells with surface-bound toxin to low pH. Recently, we showed that disulfide bonds introduced into the A fragment by mutation are inhibitory for translocation. In the present work, we found that although the complete translocation of the A fragment is blocked, three mutant toxins underwent reduction of the interfragment disulfide bond upon low pH exposure, whereas the internal disulfide in the A fragment remained intact. In the case of two of these mutants, the A fragment was released into the extracellular medium upon exposure of cell-bound toxin to low pH. The pH profile for the release of the mutant A fragments was the same as for translocation of wild-type A fragment to the cytosol, and the release was inhibited by conditions that interfere with A fragment translocation. In the case of the third mutant, which remained cell-associated upon reduction of the interfragment disulfide bond, a translocation intermediate was detected. The results show that the reduction of the interfragment disulfide bond can occur in the absence of complete translocation of the A fragment to the cytosol, and they indicate that the reduction takes place at an early stage in the translocation process. Our findings suggest that the translocation of the A fragment across the membrane is initiated at the C terminus.

Refined structure of monomeric diphtheria toxin at 2.3 A resolution

The structure of toxic monomeric diphtheria toxin (DT) was determined at 2.3 A resolution by molecular replacement based on the domain structures in dimeric DT and refined to an R factor of 20.7%. The model consists of 2 monomers in the asymmetric unit (1,046 amino acid residues), including 2 bound adenylyl 3'-5' uridine 3' monophosphate molecules and 396 water molecules. The structures of the 3 domains are virtually identical in monomeric and dimeric DT; however, monomeric DT is compact and globular as compared to the "open" monomer within dimeric DT (Bennett MJ, Choe S, Eisenberg D, 1994b, Protein Sci 3:0000-0000). Detailed differences between monomeric and dimeric DT are described, particularly (1) changes in main-chain conformations of 8 residues acting as a hinge to "open" or "close" the receptor-binding (R) domain, and (2) a possible receptor-docking site, a beta-hairpin loop protruding from the R domain containing residues that bind the cell-surface DT receptor. Based on the monomeric and dimeric DT crystal structures we have determined and the solution studies of others, we present a 5-step structure-based mechanism of intoxication: (1) proteolysis of a disulfide-linked surface loop (residues 186-201) between the catalytic (C) and transmembrane (T) domains; (2) binding of a beta-hairpin loop protruding from the R domain to the DT receptor, leading to receptor-mediated endocytosis; (3) low pH-triggered open monomer formation and exposure of apolar surfaces in the T domain, which insert into the endosomal membrane; (4) translocation of the C domain into the cytosol; and (5) catalysis by the C domain of ADP-ribosylation of elongation factor 2.

Bacterial protein toxins penetrate cells via a four-step mechanism

Bacteria produce several protein toxins that act inside cells. These toxins bind with high affinity to glycolipid or glycoprotein receptors present on the cell surface. Binding is followed by endocytosis and intracellular trafficking inside vesicles. Different toxins enter different intracellular routes, but have the common remarkable property of being able to translocate their catalytic subunit across a membrane into the cytosol. Here, a toxin modifies a specific target with ensuing cell alterations, necessary for the survival and diffusion strategies of the toxin producing bacterium.

Topology of diphtheria toxin B fragment inserted in lipid vesicles

Diphtheria toxin (DT) is a bacterial protein that crosses the membrane of endosomes of target cells in response to the low endosomal pH. In this paper, we have inserted diphtheria toxin in asolectin vesicles at pH 5.0 and treated the reconstituted system with pronase. The peptides that were protected from digestion were separated by gel electrophoresis, transferred to a membrane and their N-terminal sequences were determined. All peptides belong to the B fragment of DT and cover residues 194-223, 265-375 and 429-528. The secondary structures of the peptides inserted in the membrane, determined by Fourier-transformed infrared spectroscopy, were shown to be mostly alpha-helices and beta-sheets (44% and 53%, respectively). On the basis of these data and the recently published X-ray structure of DT, we are proposing a topology for the DTB fragment in the membrane.

Ion channel and membrane translocation of diphtheria toxin

Diphtheria toxin is the best studied member of a family of bacterial protein toxins which act inside cells. To reach their cytoplasmic targets, these toxins, which include tetanus and botulinum neurotoxins and anthrax toxin, have to cross the hydrophobic membrane barrier. All of them have been shown to form ion channels across planar lipid bilayer and, in the case of diphtheria toxin, also in the plasma membrane of cells. A relation between the ion channel and the process of membrane translocation has been suggested and two different models have been put forward to account for these phenomena. The two models are discussed on the basis of the available experimental evidence and in terms of the focal points of difference, amenable to further experimental investigations.

Computer modelling of the transmembrane channel formed by a CNBr peptide of diphtheria toxin B fragment

Diphtheria toxin (DT) forms transmembrane, voltage-dependent channels in a planar lipid bilayer. Channels with similar characteristics were obtained with CB1, a cyanogen bromide peptide of diphtheria toxin B fragment (DTB) (res 340-459). Tryptophan 398 is in interaction with the hydrophobic core of the lipid bilayer. Using the Eisenberg method in association with the Shiffer-Edmunson wheel representation, we have identified two amphipathic alpha-helices within CB1 (res 346-364 and 389-406) that could be involved in the interaction with lipids. Bearing this information in mind, we are providing a model for the structure of the CB1 channel.

The ionic channels formed by cholera toxin in planar bilayer lipid membranes are entirely attributable to its B-subunit

The interaction of cholera toxin with planar bilayer lipid membranes (BLM) at low pH results in the formation of ionic channels, the conductance of which can be directly measured in voltage-clamp experiments. It is found that the B-subunit of cholera toxin (CT-B) also is able to induce ionic channels in BLM whereas the A-subunit is not able to do it. The increase of pH inhibited the channel-forming activity of CT-B. The investigation of pH-dependences of both the conductance and the cation-anion selectivity of the CT-B channel allowed us to suggest that the water pore of this channel is confined to the B-subunit of cholera toxin. The effective diameter of the CT-B channels water pores was directly measured in BLM and is equal to 2.1 +/- 0.2 nm. The channels formed by whole toxin and its B-subunit exhibit voltage-dependent activity. We believe these channels are relevant to the mode of action of cholera toxin and especially to the endosomal pathway of the A-subunit into cells.

Folding changes in membrane-inserted diphtheria toxin that may play important roles in its translocation

Diphtheria toxin membrane penetration is triggered by the low pH within the endosome lumen. Subsequent exposure to the neutral pH of the cytoplasm is believed to aid in translocation of the catalytic A domain of the toxin into the cytoplasm. To understand the effects of low pH and subsequent exposure to neutral pH on translocation, we studied toxin conformation in solution and in toxin inserted in model membranes. Two conformations were found at low pH. One form, L', predominates below 25-30 degrees C, and the other, L", predominates above 25-30 degrees C and is formed from the L' state by an unfolding event. Both forms are hydrophobic and penetrate deeply into membranes. After pH neutralization, the L' and L'' conformations give rise to two new conformations, R' and R'', respectively. The R' and R" conformations differ from each other in that in the R' state the A domain remains folded, whereas in the R" state the A domain is unfolded. This is confirmed by the finding that only the R' state possesses the capacity to bind and hydrolyze NAD+. It is also supported by the finding that the R'' state can also be formed by thermal unfolding of the R' state. The R conformations differ from the low-pH L conformations in that although they remain largely membrane-inserted, it appears that a large portion of the toxin is no longer in contact with the hydrophobic core of the bilayer.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of high pH upon diphtheria toxin conformation and model membrane association: role of partial unfolding

Penetration of membranes by diphtheria toxin in vivo is at least partially triggered by a low pH-induced conformational change occurring within the lumen of an acidic organelle. In order to gain insight into the nature of this change the behavior of the toxin at high pH was characterized and compared to that previously determined at low pH. We find that near pH 10.5 a major conformational change occurs. This change is accompanied by a marked decrease in fluorescence intensity, a red shift in fluorescence emission maximum, and increased susceptibility of protein fluorescence to acrylamide quenching. Differential scanning calorimetry shows that the high pH conformational change involves a cooperative endothermic unfolding transition. These changes at high pH are very similar to those induced by low pH, supporting the conclusion that the changes at low pH also involve a denaturation-like process. In addition, at high pH the toxin gains the ability to bind to model membranes, again similar to its behavior at low pH. On the basis of these studies we conclude that exposure of hydrophobic sequences due to partial unfolding is one dominating component in inducing hydrophobic behavior at both high and low pH, but that at low pH Asp/Glu protonation also contributes to hydrophobicity.

Chemistry and biology of N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-labeled lipids: fluorescent probes of biological and model membranes

Lipids that are covalently labeled with the 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) group are widely used as fluorescent analogues of native lipids in model and biological membranes to study a variety of processes. The fluorescent NBD group may be attached either to the polar or the apolar regions of a wide variety of lipid molecules. Synthetic routes for preparing the lipids, and spectroscopic and ionization properties of these probes are reviewed in this report. The orientation of various NBD-labeled lipids in membranes, as indicated by the location of the NBD group, is also discussed. The NBD group is uncharged at neutral pH in membranes, but loops up to the surface if attached to acyl chains of phospholipids. These lipids find applications in a variety of membrane-related studies which include membrane fusion, lipid motion and dynamics, organization of lipids and proteins in membranes, intracellular lipid transfer, and bilayer to hexagonal phase transition in liposomes. Use of NBD-labeled lipids as analogues of natural lipids is critically evaluated.

Histidine-21 is involved in diphtheria toxin NAD+ binding

Histidine-21 is the sole histidine present in the A chain of diphtheria toxin and recent evidence suggests that it is involved in NAD+ binding. Fluorimetric assays of NAD+ binding and diethylpyrocarbonate modification performed at different pH values provide further insights on the role of this residue and indicate that its pKa value is 6.3. Conformational changes of subunit A of diphtheria toxin have been detected by analysis of tryptophan fluorescence in the pH 2.5-4 and pH 9-10.5 ranges. This indicates that histidine-21 is unlikely to be involved in the low pH-driven conformational change of diphtheria toxin.

Fusion of phospholipid vesicles mediated by cytochrome c

Fusion of phosphatidylserine/phosphatidylethanolamine (1/1) vesicles induced by cytochrome c is studied at a wide range of pH values. A pH profile for the fusion with maximum values at pH 5 and pH 8 is obtained and this is found to be similar to the profile for cytochrome c binding to the vesicles. The binding property of apocytochrome c to the same phospholipid vesicles is found to be about the same as that of the cytochrome c at low ionic strength, but very different at high salt concentrations. No appreciable fusion of vesicles by apocytochrome c is observed. Proteolytic treatment and dansyl chloride labeling of cytochrome c- and apocytochrome c-vesicle complexes show that the C-terminal segments of these proteins with molecular weights of about 3000 and 5000, respectively, penetrate the bilayer. The hydrophobic labeling studies with photoreactive phosphatidylcholine in the bilayer show that segments of both cytochrome c and apocytochrome c go deep into the bilayer.

pH-dependent bilayer destabilization and fusion of phospholipidic large unilamellar vesicles induced by diphtheria toxin and its fragments A and B

The passage by the low endosomal pH is believed to be an essential step of the diphtheria toxin (DT) intoxication process in vivo. Several studies have suggested that this low pH triggers the insertion of DT into the membrane. We demonstrate here that its insertion into large unilamellar vesicles (LUV) is accompanied by a strong destabilization of the vesicles at low pH. The destabilization has been studied by following the release of a fluorescent dye (calcein) encapsulated in the liposomes. The influence of the lipid composition upon this process has been examined. At a given pH, the calcein release is always faster for a negatively charged (asolectin) than for a zwitterionic (egg PC) system. Moreover, the transition pH, which is the pH at which the toxin-induced release becomes significant, is shifted upward for the asolectin LUV as compared to the egg PC LUV. No calcein release is observed for rigid phospholipid vesicles (DPPC and DPPC/DPPA 9/1 mol/mol) below their transition temperature whereas DT induces an important release of the dye in the temperature range corresponding to the phase transition. The transition pH associated to the calcein release from egg PC vesicles is identical with that corresponding to the exposure of the DT hydrophobic domains, as revealed here by the binding of a hydrophobic probe (ANS) to the toxin. This suggests the involvement of these domains in the destabilization process. Both A and B fragments destabilize asolectin and PC vesicles in a pH-dependent manner but to a lesser extent than the entire toxin.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of pH on the interaction of botulinum neurotoxins A, B and E with liposomes

The interaction of botulinum neurotoxin serotypes A, B and E with membranes of different lipid compositions was examined by photolabelling with two photoreactive phosphatidylcholine analogues that monitor the polar region and the hydrophobic core of the lipid bilayer. At neutral pH the neurotoxins interacted both with the polar head groups and with fatty acid chains of phospholipids. At acidic pHs the neurotoxins underwent structural changes characterized by a more extensive interaction with lipids. Both the heavy and light chain subunits of the neurotoxins were involved in the process. The change in the nature and extent of toxin-lipid interaction occurred in the pH range 4-6 and was not influenced by the presence of polysialogangliosides. The present data are in agreement with the idea that botulinum neurotoxins enter into nerve cells from a low pH intracellular compartment.