Behavior of the N-terminal helices of the diphtheria toxin T domain during the successive steps of membrane interaction

During intoxication of a cell, the translocation (T) domain of the diphtheria toxin helps the passage of the catalytic domain across the membrane of the endosome into the cytoplasm. We have investigated the behavior of the N-terminal region of the T domain during the successive steps of its interaction with membranes at acidic pH using tryptophan fluorescence, its quenching by brominated lipids, and trypsin digestion. The change in the environment of this region was monitored using mutant W281F carrying a single native tryptophan at position 206 at the tip of helix TH1. The intrinsic propensity to interact with the membrane of each helix of the N-terminus of the T domain, TH1, TH2, TH3, and TH4, was also studied using synthetic peptides. We showed the N-terminal region of the T domain was not involved in the binding of the domain to the membrane, which occurred at pH 6 mainly through hydrophobic effects. At that stage of the interaction, the N-terminal region remained strongly solvated. Further acidification eliminated repulsive electrostatic interactions between this region and the membrane, allowing its penetration into the membrane by attractive electrostatic interactions and hydrophobic effects. The peptide study indicated the nature of forces contributing to membrane penetration. Overall, the data suggested that the acidic pH found in the endosome not only triggers the formation of the molten globule state of the T domain required for membrane interaction but also governs a progressive penetration of the N-terminal part of the T domain in the membrane. We propose that these physicochemical properties are necessary for the translocation of the catalytic domain.     

Accessibility changes within diphtheria toxin T domain upon membrane penetration probed by hydrogen exchange and mass spectrometry

The translocation domain of diphtheria toxin inserts in membrane and becomes functional when the pH inside endosomes is acid. At that stage, the domain is in a partially folded state; this prevents the use of high-resolution methods for the characterization of its functional structure. On that purpose, we report here the use of hydrogen/deuterium exchange experiments coupled to mass spectrometry. The conformation changes during the different steps of insertion into lipid bilayer are monitored with a resolution of few residues. Three parts of the translocation domain can be distinguished. With a high protection against exchange, the C-terminal hydrophobic helical hairpin is embedded in the membrane. Despite a lower protection, a significant effect in the presence of lipid vesicles shows that the N-terminal part is in interaction with the membrane interface. The sensitivity to the ionic strength indicates that electrostatic interactions are important for the binding. The middle part of the domain has an intermediate protection; this suggests that this part of the domain can be embedded within the membrane but remains quite dynamic. These results provide unprecedented insight into the structure reorganization of the protein to go from a soluble state to a membrane-inserted one.     

Acid destabilization of the solution conformation of Bcl-xL does not drive its pH-dependent insertion into membranes

Regulation of programmed cell death by Bcl-xL is dependent on both its solution and integral membrane conformations. A conformational change from solution to membrane is also important in this regulation. This conformational change shows a pH-dependence similar to the translocation domain of diphtheria toxin, where an acid-induced molten globule conformation in the absence of lipid vesicles mediates the change from solution to membrane conformations. By contrast, Bcl-xL deltaTM in the absence of lipid vesicles exhibits no gross conformational changes upon acidification as observed by near- and far-UV circular dichroism spectropolarimetry. Additionally, no significant local conformational changes upon acidification were observed by heteronuclear NMR spectroscopy of Bcl-xL deltaTM. Under conditions that favor the solution conformation (pH 7.4), the free energy of folding for Bcl-xL deltaTM (deltaG(o)) was determined to be 15.8 kcal x mol(-1). Surprisingly, under conditions that favor a membrane conformation (pH 4.9), deltaG(o) was 14.6 kcal x mol(-1). These results differ from those obtained with many other membrane-insertable proteins where acid-induced destabilization is important. Therefore, other contributions must be necessary to destabilize the solution conformation Bcl-xL and favor the membrane conformation at pH 4.9. Such contributions might include the presence of a negatively charged membrane or an electrostatic potential across the membrane. Thus, for proteins that adopt both solution and membrane conformations, an obligatory molten globule intermediate may not be necessary. The absence of a molten globule intermediate might have evolved to protect Bcl-xL from intracellular proteases as it undergoes this conformational change essential for its activity.     

Acid induced unfolding of anthrax protective antigen

Acidic pH plays an important role in the membrane insertion of protective antigen (PA) of anthrax toxin leading to the translocation of the catalytic moieties. The structural transitions occurring in PA as a consequence of change in pH were investigated by fluorescence and circular dichroism measurements. Our studies revealed the presence of two intermediates on-pathway of acid induced unfolding; one at pH 2.0 and other at pH 4-5. Intrinsic fluorescence measurements of these intermediates showed a red shift in the wavelength of emission maximum with a concomitant decrease in fluorescence intensity, indicative of the exposure of tryptophan residues to the bulk solvent. Furthermore, no significant change was seen in the secondary structure of PA at a pH of 2.0, as indicated by far UV-CD spectra. The low pH intermediate of PA was characterized using the hydrophobic dye, 8-anilino-1-naphthalenesulfonate, and was found to have properties similar to those of a molten globule state.     

Concerted protonation of key histidines triggers membrane interaction of the diphtheria toxin T domain

The translocation domain (T domain) of the diphtheria toxin contributes to the transfer of the catalytic domain from the cell endosome to the cytosol, where it blocks protein synthesis. Translocation is initiated when endosome acidification induces the interaction of the T domain with the membrane of the compartment. We found that the protonation of histidine side chains triggers the conformational changes required for membrane interaction. All histidines are involved in a concerted manner, but none is indispensable. However, the preponderance of each histidine varies according to the transition observed. The pair His(223)-His(257) and His(251) are the most sensitive triggers for the formation of the molten globule state in solution, whereas His(322)-His(323) and His(251) are the most sensitive triggers for membrane binding. Interestingly, the histidines are located at key positions throughout the structure of the protein, in hinges and at the interface between each of the three layers of helices forming the domain. Their protonation induces local destabilizations, disrupting the tertiary structure and favoring membrane interaction. We propose that the selection of histidine residues as triggers of membrane interaction enables the T domain to initiate translocation at the rather mild pH found in the endosome, contributing to toxin efficacy.     

Membrane Interaction of botulinum neurotoxin A translocation (T) domain. The belt region is a regulatory loop for membrane interaction

The translocation of the catalytic domain through the membrane of the endosome to the cell cytoplasm is a key step of intoxication by botulinum neurotoxin (BoNT). This step is mediated by the translocation (T) domain upon endosome acidification, although the mechanism of interaction of the T domain with the membrane is still poorly understood. Using physicochemical approaches and spectroscopic methods, we studied the interaction of the BoNT/A T domain with the membrane as a function of pH. We found that the interaction with membranes does not involve major secondary or tertiary structural changes, as reported for other toxins like diphtheria toxin. The T domain becomes insoluble around its pI value and then penetrates into the membrane. At that stage, the T domain becomes able to permeabilize lipid vesicles. This occurs for pH values lower than 5.5, in agreement with the pH encountered by the toxin within endosomes. Electrostatic interactions are also important for the process. The role of the so-called belt region was investigated with four variant proteins presenting different lengths of the N-extremity of the T domain. We observed that this part of the T domain, which contains numerous negatively charged residues, limits the protein-membrane interaction. Indeed, interaction with the membrane of the protein deleted of this extremity takes place for higher pH values than for the entire T domain. Overall, the data suggest that acidification eliminates repulsive electrostatic interactions between the T domain and the membrane, allowing its penetration into the membrane without triggering detectable structural changes.     

Membrane-protein interaction and the molten globule state: Interaction of α-lactalbumin with membranes

The insertion of soluble proteins into membranes has been a topic of considerable interest. We have studied the insertion of bovineα-lactalbumin into single-bilayer vesicles prepared from egg phosphatidylcholine (PC). Fluoresence studies indicated rapid and tight binding of apo-α-lactalbumin (apo-α-LA) to PC vesicles as a function of pH. The binding was maximal at pH values which favor the formation of the molten globule state. As an increase of hydrophobic surface is observed in the molten globule state, this conformational state can provide a molecular basis for insertion of soluble proteins into membranes. The membrane-bound complex formed at low pH (3.0) could be isolated and was found to be stable at neutral pH. The structural characterization of the apo-α-LA-PC complex was studied by fluorescence quenching using iodide, acrylamide, and 9,10-dibromostearic acid. The results obtained indicated that some of the tryptophans of apo-α-LA were buried in the membrane interior and some were exposed on the outer side. Fluorescence quenching and CD studies indicated the membrane-bound conformation of apo-α-LA was some conformational state that is between the soluble, fully folded conformation and the molten globule state.     

The molten globule intermediate for protein insertion or translocation through membranes

Insertion of some protein toxins into membranes proceeds through an unfolding step. The unfolding trigger can be the low pH in endosomes, exposure to body temperature, reduction of disulphide bonds or proteolytic cleavage occurring at the membrane surface. The insertion intermediates are not fully unfolded but have the features of a 'molten globule state' that is also observed at early stages of polypeptide folding. In this article, we review the evidence supporting these ideas and speculate about the implications of the molten globule intermediate for understanding the general mechanisms of protein insertion and translocation across membranes.     

Botulinum Neurotoxin Light Chain Refolds at Endosomal pH for its Translocation

Botulinum neurotoxins (BoNTs), the most poisonous member of class A biothreat agent, cause neuroparalysis by blocking neurotransmitter release at the neuromuscular junctions. In its mechanism of action, the catalytic domain (light chain (LC) of BoNT) is transported to the cytosol by the heavy chain (HC) in order to reach its proteolytic substrates. The BoNT HC forms a membrane channel under acidic conditions encountered in endosomes to serve as a passageway for LC to enter into cytosol. We demonstrate here that BoNT/A LC undergoes unique structural changes under the low pH conditions, and adopts a molten globule state, exposing substantial number of hydrophobic groups. The flexibility of the molten globular structure combined with retention of the secondary structure and exposure of specific residues of LC for interaction with the HC, allows its translocation through the narrow endosomal membrane channel.     

Acid-triggered membrane insertion of Pseudomonas exotoxin A involves an original mechanism based on pH-regulated tryptophan exposure

Exposure to low endosomal pH during internalization of Pseudomonas exotoxin A (PE) triggers membrane insertion of its translocation domain. This process is a prerequisite for PE translocation to the cytosol where it inactivates protein synthesis. Although hydrophobic helices enable membrane insertion of related bacterial toxins such as diphtheria toxin, the PE translocation domain is devoid of hydrophobic stretches and the structural features triggering acid-induced membrane insertion of PE are not known. Here we have identified a molecular device that enables PE membrane insertion. This process is promoted by exposure of a key tryptophan residue. At neutral pH, this Trp is buried in a hydrophobic pocket closed by the smallest alpha-helix of the translocation domain. Upon acidification, protonation of the Asp that is the N-cap residue of the helix leads to its destabilization, enabling Trp side chain insertion into the endosome membrane. This tryptophan-based membrane insertion system is surprisingly similar to the membrane-anchoring mechanism of human annexin-V and could be used by other proteins as well.     

pH induced structural alterations in an aspartic protease from Vigna radiata indicating an alkali induced molten globule state

pH-dependent transitions in secondary and tertiary structure are described for a plant aspartic protease from Vigna radiata. The enzyme was pH stable with pH optima of 3.0. The Lineweaver Burk analysis at various pH yielded pKa values of 3.3 and 4.29 indicating acidic amino acids at the active site of the enzyme. The structural changes exemplified compact secondary structure collapsed tertiary structure and exposure of hydrophobic patches at pH 10. The changes at pH 10 are typical of a molten globule state. This alkali induced molten globule is novel since acid induced molten globule state is more reported.     

Topography of the hydrophilic helices of membrane-inserted diphtheria toxin T domain: TH1-TH3 as a hydrophilic tether

After low pH-triggered membrane insertion, the T domain of diphtheria toxin helps translocate the catalytic domain of the toxin across membranes. In this study, the hydrophilic N-terminal helices of the T domain (TH1-TH3) were studied. The conformation triggered by exposure to low pH and changes in topography upon membrane insertion were studied. These experiments involved bimane or BODIPY labeling of single Cys introduced at various positions, followed by the measurement of bimane emission wavelength, bimane exposure to fluorescence quenchers, and antibody binding to BODIPY groups. Upon exposure of the T domain in solution to low pH, it was found that the hydrophobic face of TH1, which is buried in the native state at neutral pH, became exposed to solution. When the T domain was added externally to lipid vesicles at low pH, the hydrophobic face of TH1 became buried within the lipid bilayer. Helices TH2 and TH3 also inserted into the bilayer after exposure to low pH. However, in contrast to helices TH5-TH9, overall TH1-TH3 insertion was shallow and there was no significant change in TH1-TH3 insertion depth when the T domain switched from the shallowly inserting (P) to deeply inserting (TM) conformation. Binding of streptavidin to biotinylated Cys residues was used to investigate whether solution-exposed residues of membrane-inserted T domain were exposed on the external or internal surface of the bilayer. These experiments showed that when the T domain is externally added to vesicles, the entire TH1-TH3 segment remains on the cis (outer) side of the bilayer. The results of this study suggest that membrane-inserted TH1-TH3 form autonomous segments that neither deeply penetrate the bilayer nor interact tightly with the translocation-promoting structure formed by the hydrophobic TH5-TH9 subdomain. Instead, TH1-TH3 may aid translocation by acting as an A-chain-attached flexible tether.     

pH-induced domain interaction and conformational transitions of lipoxygenase-1

The multidomain structure of soybean LOX1 was examined over the pH range 1-12. Lipoxygenase-1 activity was reversible over broad pH range of 4-10 due to the reversibility of conformational states of the molecule. Below pH 4.0, due to collapse in hydrophobic interactions, the enzyme unfolded to an irreversible conformation with the properties of molten globule state with a mid point of transition at pH 2.4. This intermediate state lost iron irreversibly. In alkaline pH at 11.5, LOX1 underwent partial unfolding with the exposure of cysteine residues with subsequent oxidation of a pair of cysteine residues in the C-terminal domain and this intermediate showed some properties of molten globule state and retained 35% of activity. Beyond pH 12.0, the enzyme was completely inactivated irreversibly due to irreversible conformational changes. The pH-dependent urea-induced unfolding of LOX1 suggested that LOX1 was more stable at pH 7.0 and least stable at pH 9.0. Furthermore, the urea-induced unfolding of LOX1 indicated that the unfolding was biphasic due to pH-dependent domain interactions and involved sequential unfolding of domains. The loss of enzyme activity at pH 4. 0 and 7.0 occurred much earlier to unfolding of the C-domain at all pHs studied. The combination of urea-induced unfolding measurements and limited proteolysis experiments suggested that at pH 4.0, the domains in LOX1 were less interactive and existed as tightly folded units. Furthermore, these results confirmed the contribution of ionic interactions in the interdomain contacts.     

Reversible refolding of the diphtheria toxin T-domain on lipid membranes

The catalytic domain of diphtheria toxin (DT) is translocated across endosomal membranes by the T-domain (DTT) in response to acidification. Understanding the energetics of translocation, besides clarifying the mechanism of translocation, should provide insights into general principles of membrane protein stability and assembly. As a first step, we have evaluated the energetics of DTT binding to lipid vesicles using three single-cysteine mutants (L350C, Q369C, and Y280C) labeled with a 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) fluorophore sensitive to polarity changes. Remarkably strong association with the vesicles was detected for all mutants, even at pH 7 at which DTT is believed to be in a fully folded membrane-incompetent state. Lowering the pH in the presence of anionic membranes resulted in a strong but reversible increase in emission of NBD-labeled mutants, consistent with reversible membrane insertion. This reversibility permitted free energies of DTT interactions with vesicles to be determined for the first time. Free energy values for the three mutants ranged from -8 to -10 kcal mol(-1) at pH 4.3 and from -7 to -8 kcal mol(-1) at pH 7. Insights into the disposition of DTT on membranes were obtained using a novel hydropathy analysis that considers the relative free energies of transmembrane and interfacial interactions as a function of pH. This analysis suggests that interactions at the membrane interface dominate pH-triggered insertion of DTT, implying that the folding pathway involves interfacial intermediates.     

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.     

Formation of the molten globule-like state of cytochrome c induced by n-alkyl sulfates at low concentrations

The molten globule state of cytochrome c is the major intermediate of protein folding. Elucidation of the thermodynamic mechanism of conformational stability of the molten globule state would enhance our understanding of protein folding. The formation of the molten globule state of cytochrome c was induced by n-alkyl sulfates including sodium octyl sulfate, SOS; sodium decyl sulfate, SDeS; sodium dodecyl sulfate, SDS; and sodium tetradecyl sulfate, STS, at low concentrations. The refolding states of the protein were monitored by spectroscopic techniques including circular dichroism (CD), visible absorbance and fluorescence. The effect of n-alkyl sulfates on the structure of acid-unfolded horse cytochrome c at pH 2 was utilized to investigate the contribution of hydrophobic interactions to the stability of the molten globule state. The addition of n-alkyl sulfates to the unfolded state of cytochrome c appears to support the stabilized form of the molten globule. The m-values of the refolded state of cytochrome c by SOS, SDeS, SDS, and STS showed substantial variation. The enhancement of m-values as the stability criterion of the molten globule state corresponded with increasing chain length of the cited n-alkyl sulfates. The compaction of the molten globule state induced by SDS, as a prototype for other n-alkyl sulfates, relative to the unfolded state of cytochrome c was confirmed by Stokes radius and thermal transition point (T(m)) measured by microviscometry and differential scanning calorimetry (DSC), respectively. Thus, hydrophobic interactions play an important role in stabilizing the molten globule state.     

The molten globule state of a chimera of human alpha-lactalbumin and equine lysozyme.

The molten globule state of equine lysozyme is more stable than that of alpha-lactalbumin and is stabilized by non-specific hydrophobic interactions and native-like hydrophobic interactions. We constructed a chimeric protein which is produced by replacing the flexible loop (residues 105-110) in human alpha-lactalbumin with the helix D (residues 109-114) in equine lysozyme to investigate the possible role of the helix D for the high stability and native-like packing interaction in the molten globule state of equine lysozyme. The stability of the molten globule state formed by the chimeric protein to guanidine hydrochloride-induced unfolding is the same as that of equine lysozyme and is substantially greater than that of human alpha-lactalbumin, although only six residues come from equine lysozyme. Our results also suggest that the non-native interaction in the molten globule state of alpha-lactalbumin changes to the native-like packing interaction due to helix substitution. The solvent-accessibility of the Trp residues in the molten globule state of the chimeric protein is similar to that in the molten globule state of equine lysozyme in which packing interaction around the Trp residues in the native state is partially preserved. Therefore, the helix D in equine lysozyme is one of the contributing factors to the high stability and native-like packing interaction in the molten globule state of equine lysozyme. Our results indicate that the native-like packing interaction can stabilize the rudimentary intermediate which is stabilized by the non-specific hydrophobic interactions.     

Characterization of acid-induced unfolding intermediates of glucose/xylose isomerase.

Acid-induced unfolding of the tetrameric glucose/xylose isomerase (GXI) from Streptomyces sp. NCIM 2730 has been investigated using intrinsic fluorescence, fluorescence quenching, second derivative spectroscopy, hydrophobic dye (1-anilino-8-naphthalene-sulfonate) binding and CD techniques. The pH dependence of tryptophanyl fluorescence of GXI at different temperatures indicated the presence of two stable intermediates at pH 5.0 and pH 3.0. The pH 3.2 intermediate was a dimer and exhibited molten globule-like characteristics, such as the presence of native-like secondary structure, loss of tertiary structure, increased exposure of hydrophobic pockets, altered microenvironment of tyrosine residues and increased accessibility to quenching by acrylamide. Fluorescence and CD studies on GXI at pH 5.0 suggested the involvement of a partially folded intermediate state in the native to molten globule state transition. The partially folded intermediate state retained considerable secondary and tertiary structure compared to the molten globule state. This state was characterized by its hydrophobic dye binding capacity, which is smaller than the molten globule state, but was greater than that of the native state. This state shared the dimeric status of the molten globule state but was prone to aggregate formation as evident by the Rayleigh light scattering studies. Based on these results, the unfolding pathway of GXI can be illustrated as: N-->PFI-->MG-->U; where N is the native state at pH 7.5; PFI is the partially folded intermediate state at pH 5.0; MG is the molten globule state at pH 3.2 and U is the monomeric unfolded state of GXI obtained in the presence of 6 M GdnHCl. Our results demonstrate the existence of a partially folded state and molten globule state on the unfolding pathway of a multimeric alpha/beta barrel protein.     

Lipid interaction of diphtheria toxin and mutants with altered fragment B. 2. Hydrophobic photolabelling and cell intoxication

The membrane insertion of diphtheria toxin and of its B chain mutants crm 45, crm 228 and crm 1001 has been followed by hydrophobic photolabelling with photoactivatable phosphatidylcholine analogues. It was found that diphtheria toxin binds to the lipid bilayer surface at neutral pH while at low pH both its A and B chains also interact with the hydrocarbon chains of phospholipids. The pH dependence of photolabelling of the two protomers is different: the pKa of fragment B is around 5.9 while that of fragment A is around 5.2. The latter value correlates with the pH of half-maximal intoxication of cells incubated with the toxin in acidic mediums. These results suggest that fragment B penetrates into the bilayer first and assists the insertion of fragment A and that the lipid insertion of fragment B is not the rate-controlling step in the process of membrane translocation of diphtheria toxin. crm 45 behaves as diphtheria toxin in the photolabelling assay but, nonetheless, it is found to be three orders of magnitude less toxic than diphtheria toxin on acid-treated cells, suggesting that the 12-kDa COOH-terminal segment of diphtheria toxin is important not only for its binding to the cell receptor but also for the membrane translocation of the toxin. It is suggested that crm 1001 is non-toxic because of a defect in its membrane translocation which occurs at a lower extent and at a lower pH than that of the native toxin; as a consequence crm 1001 may be unable to escape from the endosome lumen into the cytoplasm before the fusion of the endosome with lysosomes.     

Does fusion of domains from unrelated proteins affect their folding pathways and the structural changes involved in their function? A case study with the diphtheria toxin T domain

We investigated whether the structural and functional behaviors of two unrelated protein domains were modified when fused. The IgG-binding protein ZZ derived from staphylococcal protein A was fused to the N- and/or C-terminus of the diphtheria toxin transmembrane domain (T). T undergoes a conformational change from a soluble native state at neutral pH to a molten globule-like state at acidic pH, leading to its interaction with membranes. We found that this molten globule state was not connected to the GdnHCl-induced unfolding pathway of T. The pH-induced transition of T, and also the unfolding of T and ZZ at neutral and acidic pH, were unchanged whether the domains were isolated or fused. The position of ZZ, however, influenced the solubility of T near its pK(i). SPR measurements revealed that T has a high affinity for membranes, isolated or within the fusion proteins (K(D)< 10(-11) M). This work shows that in the case of T and ZZ, the fusion of protein domains with different stabilities does not alter the structural changes involved in folding and function. This supports the use of T as a soluble membrane anchor.