Diphtheria toxin translocation across endosome membranes. A novel cell permeabilization assay reveals new diphtheria toxin fragments in endocytic vesicles

Resolving the Molecular Steps in Clostridial Neurotoxin Light Chain Translocation

The clostridial neurotoxins (CNTs), botulinum toxin and tetanus toxin, are the most toxic proteins for humans. Neurotoxicity is based upon the specificity of the CNTs for neural host receptors and substrates. CNTs are organized into three domains, a Light Chain (LC) that is a metalloprotease and a Heavy Chain (HC) that has two domains, an N-terminal LC translocation domain (HCN) and a C-terminal receptor binding domain (HCC). While catalysis and receptor binding functions of the CNTs have been developed, our understanding of LC translocation is limited. This is due to the intrinsic complexity of the translocation process and limited tools to assess the step-by-step events in LC translocation. Recently, we developed a novel, cell-based TT-reporter to measure LC translocation as the translocation of a β-lactamase reporter across a vesicle membrane in neurons. Using this approach, we identified a role for a cis-Loop, located within the HCN, in LC translocation. In this commentary, we describe our current understanding of how CNTs mediate LC translocation and place the role of the cis-Loop in the LC translocation process relative to other independent functions that have been implicated in LC translocation. Understanding the basis for LC translocation will enhance the use of CNTs in vaccine development and as human therapies.

The first fatal case of Corynebacterium ulcerans infection in Japan

Introduction.Corynebacterium ulcerans (C. ulcerans) is a zoonotic pathogen that occasionally causes diphtheria-like symptoms in humans. Cases of C. ulcerans infection have been increasing in recent years, and C. ulcerans has been recognized as an emerging pathogen. Case presentation. Here we report a case of asphyxia death due to pseudomembrane caused by diphtheria toxin (DT)-producing C. ulcerans. This is, to our knowledge, the first fatal case of C. ulcerans infection in Japan. A strain of C. ulcerans was obtained from the patient's pet cat and was confirmed to be identical to the patient's isolate by sequencing of the 16S rRNA gene and the DT gene, by pulsed-field gel electrophoresis (PFGE) and by ribotyping. In the same way, it was revealed that the isolate in this case belonged to the same molecular type as the C. ulcerans 0102 isolated from the first case in Japan in a distant prefecture 15 years earlier, in 2001. Conclusion. DT-producing C. ulcerans can be contracted from a companion animal and causes human death if the appropriate treatment is delayed. The finding indicates that this molecular type of virulent C. ulcerans is currently widespread in Japan.

Trojan horse or proton force: Finding the right partner(s) for toxin translocation

Much is known about the structure function relationships of a large number of bacterial protein toxins, the nature of their cell surface receptors, and their enzymatic activities which lead to the inactivation of their respective cytosolic targets. Despite this wealth of knowledge a detailed understanding of the mechanisms which underlie translocation of the catalytic domain across the eukaryotic cell membrane to the cytosol, the penultimate event in the intoxication process, have been slow in developing. In the case of diphtheria toxin, two prominent hypotheses have been advanced to explain how the catalytic domain is translocated from the lumen of endocytic vesicles to the target cell cytosol. We discuss each of these hypotheses and provide an overview of recent observations that tend to favor a mechanism employing a Cytosolic Translocation Factor complex in the entry process. This facilitated mechanism of translocation appears to rely upon protein-protein interactions between conserved domains within the transmembrane domain of diphtheria toxin with host cell factors to effect delivery of the enzymatic moiety. We have recently identified a 10 amino acid motif in the transmembrane domain of diphtheria toxin that is conserved in anthrax Lethal and Edema Factors, as well as in botulinum neurotoxins A, C and D. Stable eukaryotic cell transfectants that express a peptide containing this motif become resistant to the toxin, and sensitivity is completely restored by co-expression of siRNA which inhibits peptide expression. Data obtained from use of the protein fusion toxin DAB(389)IL-2 in cytotoxicity assays using susceptible Hut 102/6TG and resistant transfectant Hut102/6TG-T1 cells, as well as pull down assays have led to the formulation of a working model of facilitated delivery of the diphtheria toxin catalytic domain to the cytosol of target cells which is discussed in detail.

New liver cell mutants defective in the endocytic pathway

To isolate mutant liver cells defective in the endocytic pathway, a selection strategy using toxic ligands for two distinct membrane receptors was utilized. Rare survivors termed trafficking mutants (Trf2-Trf7) were stable and more resistant than the parental HuH-7 cells to both toxin conjugates. They differed from the previously isolated Trf1 HuH-7 mutant as they expressed casein kinase 2 alpha'' (CK2alpha'') which is missing from Trf1 cells and which corrects the Trf1 trafficking phenotype. Binding of (125)I-asialoorosomucoid (ASOR) and cell surface expression of asialoglycoprotein receptor (ASGPR) were reduced approximately 20%-60% in Trf2-Trf7 cells compared to parental HuH-7, without a reduction in total cellular ASGPR. Based on (125)I-transferrin binding, cell surface transferrin receptor activity was reduced between 13% and 88% in the various mutant cell lines. Distinctive phenotypic traits were identified in the differential resistance of Trf2-Trf7 to a panel of lectins and toxins and to UV light-induced cell death. By following the endocytic uptake and trafficking of Alexa(488)-ASOR, significant differences in endosomal fusion between parental HuH-7 and the Trf mutants became apparent. Unlike parental HuH-7 cells in which the fusion of endosomes into larger vesicles was evident as early as 20 min, ASOR endocytosed into the Trf mutants remained within small vesicles for up to 60 min. Identifying the biochemical and genetic mechanisms underlying these phenotypes should uncover novel and unpredicted protein-protein or protein-lipid interactions that orchestrate specific steps in membrane protein trafficking.

Two distinct cytotoxic activities of subtilase cytotoxin produced by shiga-toxigenic Escherichia coli

Subtilase cytotoxin (SubAB) is a recently identified AB5 subunit toxin produced by Shiga-toxigenic Escherichia coli. The A subunit is thought to be a subtilase-like, serine protease, whereas the B subunit binds to the toxin receptor on the cell surface. We cloned the genes from a clinical isolate; the toxin was produced as His-tagged proteins. SubAB induced vacuolation at concentrations greater than 1 microg/ml after 8 h, in addition to the reported cytotoxicity induced at a ng/ml level after 48 h. Vacuolation was induced with the B, but not the A, subunit and was dependent on V-type ATPase. The cytotoxicity of SubAB at low concentrations was associated with the inhibition of protein synthesis; the 50% inhibitory dose was approximately 1 ng/ml. The A subunit, containing serine 272, which is thought to be a part of the catalytic triad of a subtilase-like serine protease, plus the B subunit was necessary for this activity, both in vivo and in vitro. SubAB did not cleave azocasein, bovine serum albumin, ovalbumin, or synthetic peptides. These data suggest that SubAB is a unique AB toxin: first, the B subunit alone can induce vacuolation; second, the A subunit containing serine 272 plus the B subunit inhibited protein synthesis, both in vivo and in vitro; and third, the A subunit proteolytic activity may have a strict range of substrate specificity.

Stimulation of CD8+ T cells following diphtheria toxin-mediated antigen delivery into dendritic cells

Recognition and clearance of many intracellular pathogens requires the activation and subsequent effector functions of CD8+ T lymphocytes. To stimulate CD8+ T cells by immunization, the target antigens must be delivered into the cytosol of host cells. There they can be processed into peptides and presented in the context of major histocompatibility complex class I molecules to antigen-specific CD8+ T cells. One method of delivering antigens into the cytosol is to fuse them to modified bacterial toxins that are able to enter mammalian cells. The expression pattern of the toxin receptors in the host will determine the cell population that the toxin fusion protein targets and will thus restrict antigen-specific T-cell recognition to the same population. In this study we describe the development and characterization of a diphtheria toxin (DT)-based antigen delivery system. Using CD11c-DTR transgenic mice that express the DT receptor in dendritic cells (DC), this system allows for targeted delivery of CD8+ T-cell antigen to DC. We show that antigen-specific CD8+ T cells proliferate in CD11c-DTR mice following immunization with catalytically inactive DT-antigen fusion proteins. We also show that a toxin-based system that restricts antigen delivery to DC results in more robust antigen-specific CD8+ T-cell proliferation than a toxin-based system that does not restrict delivery to a particular cell type. These results have implications for vaccine design, and they suggest that use of a toxin-based vector to target antigen to DC may be an effective way to induce a CD8+ T-cell response.

Reconstitution of active diphtheria toxin based on a hexahistidine tagged version of the B-fragment produced to high yields in bacteria

Diphtheria toxin consists of an A-fragment that inactivates elongation factor 2 and a B-fragment that both binds to the toxin receptor and mediates translocation of the A-fragment across cellular membranes to the cytosol. Several fragments of the toxin and an inactive version of the holotoxin have been expressed in Escherichia coli, but the B-fragment alone has proven difficult to express. Only low levels of expression have been achieved. We have designed a hexahistidine tagged version of a modified diphtheria toxin B-fragment (DT-BHis) that can be expressed to high levels in E. coli. DT-BHis contains the entire diphtheria toxin B-fragment preceded by an alanine and succeeded by a leucine, a glutamic acid and a hexahistidine tag and could be purified in a single step using nickel-coated agarose beads to 85% homogeneity. DT-BHis bound specifically to the diphtheria toxin receptor and was able to compete out the effect of the wild type diphtheria toxin. Furthermore, DT-BHis was able to form pores in cellular membranes in a manner similar to the wild type B-fragment. The high yield makes DT-BHis a suitable tool in studies of diphtheria toxin interaction with cells or liposomes since functional diphtheria toxin was easily formed upon addition of A-fragment. The reconstituted diphtheria toxin showed toxicity in the same range as the wild type.

Topography of Diphtheria Toxin A Chain Inserted into Lipid Vesicles

The membrane-inserting T domain of diphtheria toxin aids the low-pH-triggered translocation of the catalytic A chain of the toxin across endosomal membranes. To evaluate the role of the isolated A chain in translocation, the topography of isolated A chain inserted into model membrane vesicles was investigated using a mixture either of dioleoylphosphatidylcholine (DOPC) and dioleoylphosphatidylglycerol (DOPG) or of dimyristoleoylphosphatidylcholine (DMoPC) and DOPG. The latter mixture was previously found to promote deep insertion of the T domain. A series of single Cys mutants along the A chain sequence were labeled with bimane or BODIPY groups. After A chain insertion into model membranes, the location of these groups within the lipid bilayer was determined via bimane fluorescence emission lambda(max), binding of externally added anti-BODIPY antibodies, and a novel technique involving the comparison of the quenching of bimane fluorescence by aqueous iodide and membrane-associated 10-doxylnonadecane. The results show that in both DOPC- and DMoPC-containing bilayers, membrane-inserted residues all along the A chain sequence occupy shallow locations that are relatively exposed to the external solution. There were only small differences between A chain topography in the two different types of lipid mixtures. However, the behavior of the A chain in the two different lipid mixtures was distinct in that it strongly oligomerized in DMoPC-containing vesicles as judged by Trp fluorescence. In addition, A chain selectively induced fusion of the DMoPC-containing vesicles, and this may aid oligomerization by increasing the A chain/vesicle ratio. Fusion may also explain why A chain also selectively induced leakage of the contents of DMoPC-containing vesicles. We propose that isolated A chain is unlikely to be inserted in a transmembrane orientation, and thus its interaction with the T domain is likely to be critical for properly orienting the A chain within the bilayer in a fashion that allows translocation.

Analyzing Topography of Membrane-Inserted Diphtheria Toxin T Domain Using BODIPY-Streptavidin: At Low pH, Helices 8 and 9 Form a Transmembrane Hairpin but Helices 5−7 Form Stable Nonclassical Inserted Segments on the cis Side of the Bilayer

Low pH-induced membrane insertion by diphtheria toxin T domain is crucial for A chain translocation into the cytoplasm. To define the membrane topography of the T domain, the exposure of biotinylated Cys residues to the cis and trans bilayer surfaces was examined using model membrane vesicles containing a deeply inserted T domain. To do this, the reactivity of biotin with external and vesicle-entrapped BODIPY-labeled streptavidin was measured. The T domain was found to insert with roughly 70-80% of the molecules in the physiologically relevant orientation. In this orientation, residue 349, located in the loop between hydrophobic helices 8 and 9, was exposed to the trans side of the bilayer, while other solution-exposed residues along the hydrophobic helices 5-9 region of the T domain located near the cis surface. A protocol developed to detect the movement of residues back and forth across the membranes demonstrated that T domain sequences did not rapidly equilibrate between the cis and the trans sides of the bilayer. Binding streptavidin to biotinylated residues prior to membrane insertion only inhibited T domain pore formation for residues in the loop between helices 8 and 9. Pore formation experiments used an approach avoiding interference from transient membrane defects/leakage that may occur upon the initial insertion of protein. Combined, these results indicate that at low pH hydrophobic helices 8 and 9 form a transmembrane hairpin, while hydrophobic helices 5-7 form a nonclassical deeply inserted nontransmembraneous state. We propose that this represents a novel pre-translocation state that is distinct from a previously defined post-translocation state.

Bordetella dermonecrotic toxin undergoes proteolytic processing to be translocated from a dynamin-related endosome into the cytoplasm in an acidification-independent manner

Bordetella pertussis dermonecrotic toxin (DNT), which activates intracellular Rho GTPases, is a single chain polypeptide composed of an N-terminal receptor-binding domain and a C-terminal enzymatic domain. We found that DNT was cleaved by furin, a mammalian endoprotease, on the C-terminal side of Arg(44), which generates an N-terminal fragment almost corresponding to the receptor-binding domain and a C-terminal remainder (deltaB) containing the enzymatic domain. These two fragments remained associated even after the cleavage and made a nicked form. DNT mutants insensitive to furin had no cellular effect, whereas the nicked toxin was much more potent than the intact form, indicating that the nicking by furin was a prerequisite for action. DeltaB, but not the nicked toxin, associated with artificial liposomes and activated Rho in cells resistant to DNT because of a lack of surface receptor. These results imply that deltaB, dissociated from the binding domain, fully possesses the ability to enter the cytoplasm across the lipid bilayer membrane. The translocation ability of deltaB was found to be attributable to the N-terminal region encompassing amino acids 45-166, including a putative transmembrane domain. Pharmacological analyses with various reagents disturbing vesicular trafficking revealed that the translocation requires neither the acidification of the endosomes nor retrograde vesicular transport to deeper organelles, although DNT appeared to be internalized via a dynamin-dependent endocytosis. We conclude that DNT binds to its receptor and is internalized into endosomes where the proteolytic processing occurs. DeltaB, liberated from the binding domain after the processing, begins to translocate the enzymatic domain into the cytoplasm.

The molecular basis for the pH-activation mechanism in the channel-forming bacterial colicin E1

The in vitro activity of the channel-forming bacteriocins such as colicin E1 in model membranes requires the specific activation of the protein by an acidic environment in the presence of a membrane potential. Acid activation of the C-terminal domain results in the formation of an insertion-competent intermediate with an enhanced ability to penetrate and perforate cell membranes. We report novel findings of this activation process through the design and study of mutant proteins involving the replacement of conserved Asp residues Asp-408, Asp-410, and Asp-423 within helices 5a and 4 in the colicin E1 channel domain that resulted in enhanced membrane binding, bilayer insertion rates, and ion channel activities at near neutral pH values. This activation process involves the destabilization of a critical salt bridge (Asp-410 and Lys-406) and H-bonds (Asp-408 and Ser-405 main chain; Asp-423 and Lys-420 main chain). The helix-to-coil transition of this motif was identified previously by time-resolved Trp fluorescence measurements (Merrill, A. R., Steer, B. A., Prentice, G. A., Weller, M. J., and Szabo, A. G. (1997) Biochemistry 36, 6874-6884), and here we use this approach to demonstrate that disruption of the helical structure of helices 4 and 5a results in a shift in this equilibrium to favor the coil state. Finally, we show that the essential components of the pH trigger motif are conserved among the channel-forming colicins and that it likely exists within other bacterial proteins and may even have evolved into more sophisticated devices in a number of microbial species.

Membrane protein insertion regulated by bringing electrostatic and hydrophobic interactions into play. A case study with the translocation domain of diphtheria toxin

The study of the membrane insertion of the translocation domain of diphtheria toxin deepens our insight into the interactions between proteins and membranes. During cell intoxication, this domain undergoes a change from a soluble and folded state at alkaline pH to a functional membrane-inserted state at acid pH. We found that hydrophobic and electrostatic interactions occur in a sequential manner between the domain and the membrane during the insertion. The first step involves hydrophobic interactions by the C-terminal region. This is because of the pH-induced formation of a molten globule specialized for binding to the membrane. Accumulation of this molten globule follows a precise molecular mechanism adapted to the toxin function. The second step, as the pH decreases, leads to the functional inserted state. It arises from the changes in the balance of electrostatic attractions and repulsions between the N-terminal part and the membrane. Our study shows how the structural changes and the interaction with membranes of the translocation domain are finely tuned by pH changes to take advantage of the cellular uptake system.

Binding component of Clostridium perfringens iota-toxin induces endocytosis in Vero cells

Clostridium perfringens iota-toxin is a binary toxin consisting of two individual proteins, the binding component (Ib) and the enzyme component (Ia). Wild-type Ib bound to Vero cells at 4 and 37 degrees C and formed oligomers at 37 degrees C but not at 4 degrees C. The Ib-induced K(+) release from the cells was dependent on the oligomer formation of Ib in the cells, but the oligomer formation did not induce rounding activity or cytotoxicity. After incubation of the cells with recombinant Ib (rIb) at 37 degrees C, the Ib oligomer in the cell became resistant to pronase treatment with time, but the Ib monomer was sensitive to the treatment. Furthermore, treatment of Vero cells with rIb in the presence of bafilomycin, methylamine, or ethylamine resulted in accumulation of the oligomer in the cells but had no effect on K(+) release. Moreover, incubation with Ib plus Ia in the presence of these agents caused no rounding in the cells. These observations suggest that Ib binds to Vero cells, itself oligomerizing to form ion-permeable channels and that the formation of oligomer then induces endocytosis.

Targeting endothelial cells overexpressing VEGFR-2: selective toxicity of Shiga-like toxin-VEGF fusion proteins

Growing endothelial cells at the sites of angiogenesis express high numbers of VEGF receptors and therefore may be particularly sensitive to VEGF-mediated drug delivery. To test this hypothesis we have constructed a protein containing the catalytic A-subunit of Shiga-like toxin I fused to VEGF121 (SLT-VEGF/L). Wild-type A-subunit is a site-specific N-glycosidase of 28S rRNA that inhibits protein synthesis after being delivered into cells by separate cell-binding B-subunits. SLT-VEGF/L retains functional activities of both SLT and VEGF121 moieties, since it inhibits protein synthesis in a cell-free translation system and induces VEGFR-2 tyrosine autophosphorylation. SLT-VEGF/L selectively inhibits growth of porcine endothelial cells expressing 2.5 x 10(5) VEGFR-2/cell with an IC50 of 0.2 nM and rapidly induces apoptosis at concentrations >1 nM. We found that sensitivity of VEGFR-2 transfected PAE cells to SLT-VEGF/L declined as the cellular VEGFR-2 density decreased; PAE cells expressing 25000 VEGFR-2/cell were as sensitive as parental cells lacking the receptor. Growth inhibition and induction of apoptosis by SLT-VEGF/L require intrinsic N-glycosidase activity of the SLT moiety, but take place without significant inhibition of protein synthesis. Selective cytotoxicity of SLT-VEGF/L against growing endothelial cells overexpressing VEGFR-2 suggests that it may be useful in targeting similar cells at the sites of angiogenesis.

Extension of juxtamembrane domain of diphtheria toxin receptor arrests translocation of diphtheria toxin fragment A into cytosol

Diphtheria toxin (DT) binds to the EGF-like domain of the DT receptor (DTR), followed by internalization and translocation of the enzymatically active fragment A into the cytosol. The juxtamembrane domain (JM) of the DTR is the linker domain connecting the transmembrane and EGF-like domains. We constructed mutants of DTRs with altered JMs and studied their abilities for DT intoxication. Although DTR mutants with extended JMs showed normal DT binding activity, the cells expressing the mutants showed both reduced translocation of DT fragment A into the cytosol and reduced sensitivity to DT, when compared with cells expressing wild-type DTR. These results indicate that the JM contributes to DT intoxication by providing a space appropriate for the interaction of DT with the cell membrane. The present study also indicates that consideration of epitopes of an immunotoxins would be an important factor in the design of potent immunotoxins.

Selective membrane permeabilization by the rotavirus VP5* protein is abrogated by mutations in an internal hydrophobic domain

Rotavirus infectivity is dependent on the proteolytic cleavage of the VP4 spike protein into VP8* and VP5* proteins. Proteolytically activated virus, as well as expressed VP5*, permeabilizes membranes, suggesting that cleavage exposes a membrane-interactive domain of VP5* which effects rapid viral entry. The VP5* protein contains a single long hydrophobic domain (VP5*-HD, residues 385 to 404) at an internal site. In order to address the role of the VP5*-HD in permeabilizing cellular membranes, we analyzed the entry of o-nitrophenyl-beta-D-galactopyranoside (ONPG) into cells induced to express VP5* or mutated VP5* polypeptides. Following IPTG (isopropyl-beta-D-thiogalactopyranoside) induction, VP5* and VP5* truncations containing the VP5*-HD permeabilized cells to the entry and cleavage of ONPG, while VP8* and control proteins had no effect on cellular permeability. Expression of VP5* deletions containing residues 265 to 474 or 265 to 404 permeabilized cells; however, C-terminal truncations which remove the conserved GGA (residues 399 to 401) within the HD abolished membrane permeability. Site-directed mutagenesis of the VP5-HD further demonstrated a requirement for residues within the HD for VP5*-induced membrane permeability. Functional analysis of mutant VP5*s indicate that conserved glycines within the HD are required and suggest that a random coiled structure rather than the strictly hydrophobic character of the domain is required for permeability. Expressed VP5* did not alter bacterial growth kinetics or lyse bacteria following induction. Instead, VP5*-mediated size-selective membrane permeability, releasing 376-Da carboxyfluorescein but not 4-kDa fluorescein isothiocyanate-dextran from preloaded liposomes. These findings suggest that the fundamental role for VP5* in the rotavirus entry process may be to expose triple-layered particles to low [Ca](i), which uncoats the virus, rather than to effect the detergent-like lysis of early endosomal membranes.

Importance of the major extracellular domain of CD9 and the epidermal growth factor (EGF)-like domain of heparin-binding EGF-like growth factor for up-regulation of binding and activity

Heparin-binding epidermal growth factor (EGF)-like growth factor (HB-EGF) is a member of the EGF family of growth factors. The membrane-anchored form of HB-EGF (proHB-EGF) is mitogenically active to neighboring cells as well as being a precursor of the soluble form. In addition to its mitogenic activity, proHB-EGF has the property of binding to diphtheria toxin (DT), serving as the specific receptor for DT. Tetramembrane-spanning protein CD9, a member of the TM4 superfamily, is physically associated with proHB-EGF at the cell surface and up-regulates both mitogenic and DT binding activities of proHB-EGF. To understand this up-regulation mechanism, we studied essential regions of both CD9 and proHB-EGF for up-regulation. Immunoprecipitation experiments revealed that not only CD9 but also other TM4 proteins including CD63, CD81, and CD82 associate with proHB-EGF on the cell surface. However, these TM4 proteins did not up-regulate DT binding activity of proHB-EGF. Transfection of a series of chimeric constructs comprising CD9 and CD81 showed that the major extracellular domain of CD9 is essential for up-regulation. Assays of DT binding activity and juxtacrine mitogenic activity of the deletion mutants of proHB-EGF and chimeric molecules, derived from proHB-EGF and TGF-alpha, showed that the essential domain of proHB-EGF for up-regulation is the EGF-like domain. These results indicate that the interaction of the extracellular domains of both molecules is important for up-regulation.

Translocation of Bacillus anthracis lethal and oedema factors across endosome membranes

The two exotoxins of Bacillus anthracis, the causative agent of anthrax, are the oedema toxin (PA-EF) and the lethal toxin (PA-LF). They exert their catalytic activities within the cytosol. The internalization process requires receptor-mediated endocytosis and passage through acidic vesicles. We investigated the translocation of EF and LF enzymatic moieties across the target cell membrane. By selective permeabilization of the plasma membrane with Clostridium perfringens delta-toxin, we observed free full-size lethal factor (LF) within the cytosol, resulting from specific translocation from early endosomes. In contrast, oedema factor (EF) remained associated with the membranes of vesicles.

Organization of diphtheria toxin in membranes. A hydrophobic photolabeling study

Diphtheria toxin (DT) is a disulfide linked AB-toxin consisting of a catalytic domain (C), a membrane-inserting domain (T), and a receptor-binding domain (R). It gains entry into cells by receptor-mediated endocytosis. The low pH ( approximately 5.5) inside the endosomes induces a conformational change in the toxin leading to insertion of the toxin in the membrane and subsequent translocation of the C domain into the cell, where it inactivates protein synthesis ultimately leading to cell death. We have used a highly reactive hydrophobic photoactivable reagent, DAF, to identify the segments of DT that interact with the membrane at pH 5.2. This reagent readily partitions into membranes and, on photolysis, indiscriminately inserts into lipids and membrane-inserted domains of proteins. Subsequent chemical and/or enzymatic fragmentation followed by peptide sequencing allows for identification of the modified residues. Using this approach it was observed that T domain helices, TH1, TH8, and TH9 insert into the membrane. Furthermore, the disulfide link was found on the trans side leaving part of the C domain on the trans side. This domain then comes out to the cis side via a highly hydrophobic patch corresponding to residues 134-141, originally corresponding to a beta-strand in the solution structure of DT. It appears that the three helices of the T domain could participate in the formation of a channel from a DT-oligomer, thus providing the transport route to the C domain after the disulfide reductase separates the two chains.

Intracellular regulation of macromolecules using pH-sensitive liposomes and nuclear localization signal: qualitative and quantitative evaluation of intracellular trafficking

The objective of this study is to present a rational strategy to target macromolecules to the nucleus via the endocytic pathway. The two major barriers in this route to the nucleus are known as endosomal escape and nuclear transport. pH-sensitive liposomes were used in order to achieve endosomal escape under the conditions of low pH in endosomes. Bovine serum albumin (alb) served as a model compound to be delivered to nucleus and was encapsulated into the pH-sensitive liposomes. The liposomes are composed of dioleoyl phosphatidyl ethanolamine: cholesterylhemisuccinate. They were taken up by rat peritoneal macrophages via endocytosis and subsequently underwent degradation, principally by lysosomal enzymes. By using pH-sensitive liposomes, intracellular degradation was reduced by a significant extent, as expected, via endosomal escape. Cytosolic delivery of FITC-labelled alb was also detected by confocal microscopy. Selective targeting to the nucleus was performed by adding the nuclear localization signal (NLS) of the SV-40 large T antigen to the FITC-alb, which were then encapsulated into the pH-sensitive liposomes. Confocal microscopy revealed that FITC-alb, in the presence of NLS was successfully delivered into nucleus, while no transport was observed in the absence of NLS. These results provide a useful strategy for the nuclear targeting of macromolecules using pH-sensitive liposomes in conjunction with NLS.