The binding of 8-anilino-1-naphthalene sulfonate (ANS) to fish myosin and the effect of salts on the thermal transitions of fish myosin-ANS complex

Myosin prepared from tilapia (Serotherodon aureus) was complexed with 8-anilino-1-naphthalene sulfonate (ANS) and continuously heated at 1 degree C/min. A large increase in fluorescence was observed with a transition temperature of 34 degrees C. The effect of several salts on the transition temperature was tested. A plot based on the equation of E. E. Schrier and E. B. Schrier [(1967) J. Phys. Chem. 71, 1851-1860] gave a value of less than or equal to 500 cal/mol-deg for the change in enthalpy per residue due to exposure to solvent. The ratio of hydrophobic group to amide group exposure to solvent was intermediate compared with the ratio of RNase and gelatin. Fluorescence titrations yielded one high affinity site with a Kb of 2 X 10(6) M-1 and at least 200 low affinity sites with an average value of 1 X 10(5) M-1. The parameters did not change significantly with temperature. We propose that the increase in ANS fluorescence reflects changes in conformation of myosin as monitored by these low affinity sites, resulting in an increase in surface hydrophobicity and representing a small enthalpic change in the conformation of the myosin molecule. As a consequence, the change in conformation accelerates polymerization of myosin oligomers.     

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.     

Effect of pH and ionic strength on the cytolytic toxin Cyt1A: a fluorescence spectroscopy study

Cyt1A is a cytolytic toxin produced by Bacillus thuringiensis var. israelensis. Due to its toxicity in vivo against mosquitoes and black flies, it is used as an environmentally friendly insecticide, although its mode of action is not completely understood. The toxin is membrane-active, but its membrane-bound conformation is unknown. In the absence of direct structural data, fluorescence spectroscopy was used to obtain indirect information on Cyt1A conformation changes in the environment mimicking the vicinity of the lipid membrane (lower pH and increased ionic strength). With decreasing pH, Cyt1A's surface hydrophobicity increased, which is consistent with an increased interaction with model membranes at low pH values, as observed previously. The pK(a) value of this conformation change is 4.4+/-0.1. Intrinsic tryptophan fluorescence decreased with decreasing pH, and the pK(a) value was the same as the one determined with synthetic probes. The protein has two types of hydrophobic binding sites, and at low pH these sites bind more probe molecules (bis-ANS) with a higher affinity than at pH 7.4. When bound to the lipid, the toxin exhibited conformation similar to the molten-globule state and showed some characteristics also observed at low pH. However, the conformation of the lipid-bound toxin did not depend on pH. Neutral salts like NaCl and KCl induced conformational changes at neutral pH, but not at low pH. These changes were most probably due to specific interactions of the salt ions with the charged amino acids on the protein surface rather than due to general effects such as Hofmeister and Debye-Hückel. Our results might contribute to elucidating the mode of action of Cyt1A, and perhaps also to improving the formulation of the insecticidal preparations.     

Design, synthesis and structure of an amphipathic peptide with pH-inducible haemolytic activity.

A synthetic, 26-residue peptide having a strong helix forming potential in the protonated state was designed to interact with lipid bilayers in a pH-dependent way. On the basis of this concept a cluster of four glutamic acid residues was inserted in the central region of the amphipathic peptide to promote helix destabilization by mutual charge repulsion at neutral pH. Protonation of these residues might then bring about both a pH-mediated change in hydrophobicity and conformation forming a membrane-active amphiphilic helix. The sequence GLGTLLTLLEFLLEELLEFLKRKRQQamide produced by the design strategy induced pH-triggered lysis of human erythrocytes. A molecular model correlating the lytic activity to the formation of transmembrane pores which were detected by electron microscopy in erythrocyte membranes is discussed. Circular dichroism studies indicated a self-association of the monomeric random coil form with increasing peptide concentration leading to the apparent induction of strong alpha-helix formation (approximately 100% helicity) in the fully aggregated state. However, no pH-dependent helix-random coil transition was observed, implying that interhelical hydrophobic and ionic interactions not only govern the self-association but also decisively influence the conformational stability of the peptide.     

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.     

Conformation and model membrane interactions of diphtheria toxin fragment A

Low pH is believed to play a critical role in the penetration of membranes by diphtheria toxin in vivo. In this report, the pH dependence of the conformation of fragment A of diphtheria toxin has been studied using fluorescence techniques. As pH is decreased, fragment A in solution undergoes a reversible conformational change beginning below pH 5. The conformational change occurs rapidly upon exposure to low pH. It involves both an increase in the exposure of tryptophanyl residues to solution and a switch from a hydrophilic state to a hydrophobic state as judged by fragment A binding to micelles of a mild detergent (Brij 96). At low pH fragment A also rapidly and tightly binds to and penetrates model membranes. Binding is reversed when pH is neutralized. The transition pH, the apparent midpoint of the change between the hydrophilic state and the membrane-penetrating hydrophobic state, occurs at about pH 3.5 in the presence of Brij 96 micelles, pH 4 in the presence of small unilamellar vesicles (SUV) composed of zwitterionic phosphatidylcholine, and pH 5 in the presence of SUV composed of 25 mol % anionic phosphatidylglycerol and 75% phosphatidylcholine. The effects of high temperature provide an important clue as to the nature of the changes at low pH. At neutral pH and high temperature, i.e. in the thermally denatured state, a conformational change similar to that observed at low pH occurs, although fragment A does not become hydrophobic. In addition, the effects of low pH and high temperature on the stability of the native state are cumulative. This indicates that the changes in fragment A both at high temperature and at low pH involve denaturation, although there appears to be only partial unfolding under these conditions. Based on the results of this study, the role of fragment A in diphtheria toxin membrane penetration and translocation is evaluated.     

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)     

Structure and stability of Ricinus communis haemagglutinin.

The molecular properties of the haemagglutinin of Ricinus communis (RCA I or RCA 120) were evaluated by analytical ultracentrifugation, light-scattering, c.d. and fluorescence. The native molecule had a fairly expanded structure (f/f0 = 1.43) and dissociated into two subunits of equal size in 6 M-guanidinium chloride. This native structure was stable in alkali (up to pH 11) and resistant to thermal denaturation at neutrality. A pH-triggered change in the haemagglutinin conformation was observed and characterized by analytical ultracentrifugation, c.d. and fluorescence between pH 7 and 4.5, the range in which its affinity for galactosides decreased [Yamasaki, Absar & Funatsu (1985) Biochim, Biophys. Acta 828, 155-161]. These results are discussed in relation to those reported in the literature for other lectins and more especially ricin, for which a pH-dependent conformation transition has been observed in the same range of low pH.     

Circular dichroism studies of the HIV-1 Rev protein and its specific RNA binding site

The circular dichroism (CD) spectrum of the Rev protein from HIV-1 indicates that Rev contains about 50% alpha helix and 25% beta sheet at 5 degrees C in potassium phosphate buffer, pH 3, and 300 mM KF. The spectrum is independent of protein concentration over a 20-fold range. At neutral pH, Rev is relatively insoluble but can be brought into solution by binding to its specific RNA binding site, the Rev-responsive element (RRE), at a Rev:RNA ratio of about 3:1. Nonspecific binding to tRNA does not solubilize Rev. As judged by difference CD spectra, the conformation of Rev when bound to the RRE at neutral pH is similar to the conformation of unbound Rev at pH 3, although changes in the RNA may also contribute to the difference spectrum. Indeed, some difference is observed near 260 nm, consistent with a conformational change of the RRE upon Rev binding. Rev alone at pH 3 shows irreversible aggregation as the temperature is raised, while Rev bound to the RRE at neutral pH shows a reversible transition with a Tm of 68 degrees C.     

Titration of the phase transition of phosphatidylserine bilayer membranes. Effects of pH, surface electrostatics, ion binding, and head-group hydration

The dependence of the gel-to-fluid phase transition temperature of dimyristoyl- and dipalmitoylphosphatidylserine bilayers on pH, NaCl concentration, and degree of hydration has been studied with differential scanning calorimetry and with spin-labels. On protonation of the carboxyl group (pK2app = 5.5), the transition temperature increases from 36 to 44 degrees C in the fully hydrated state of dimyristoylphosphatidylserine (from 54 to 62 degrees C for dipalmitoylphosphatidylserine), at ionic strength J = 0.1. In addition, at least two less hydrated states, differing progressively by 1 H2O/PS, are observed at low pH with transition temperatures of 48 and 52 degrees C for dimyristoyl- and 65 and 68.5 degrees C for dipalmitoylphosphatidylserine. On deprotonation of the amino group (pK3app = 11.55) the transition temperature decreases to approximately 15 degrees C for dimyristoyl- and 32 degrees C for dipalmitoylphosphatidylserine, and a pretransition is observed at approximately 6 degrees C (dimyristoylphosphatidylserine) and 21.5 degrees C (dipalmitoylphosphatidylserine), at J = 0.1. No titration of the transition is observed for the fully hydrated phosphate group down to pH less than or equal to 0.5, but it affinity for water binding decreases steeply at pH greater than or equal to 2.6. Increasing the NaCl concentration from 0.1 to 2.0 M increases the transition temperature of dimyristoyphosphatidylserine by approximately 8 degrees C at pH 7, by approximately 5 degrees at pH 13, and by approximately 0 degrees C at pH 1. These increases are attributed to the screening of the electrostatic titration-induced shifts in transition temperature. On a further increase of the NaCl concentration to 5.5 M, the transition temperature increases by an additional 9 degree C at pH 7, 13 degree C at pH 13, approximately 7 degree C in the fully hydrated state at pH 1, and approximately 4 and approximately 0 degree C in the two less hydrated states. These shifts are attributed to displacement of water of hydration by ion binding. From the salt dependence it is deduced that the transition temperature shift at the carboxyl titration can be accounted for completely by the surface charge and change in hydration of approximately 1 H2O/lipid, whereas that of the amino group titration arises mostly from other sources, probably hydrogen bonding. The shifts in pK (delta pK2 = 2.85, delta pK3 = 1.56) are consistent with a reduced polarity in the head-group region, corresponding to an effective dielectric constant epsilon approximately or equal to 30, together with surface potentials of psi congruent to -100 and -150 mV at the carboxyl and amino group pKs, respectively. The transition temperature of dimyristoylphosphatidylserine-water mixtures decreases by approximately 4 degree C each water/lipid molecule added, reaching a limiting value at a water content of approximately 9-10 H2O/lipid molecule.     

Effects of low pH on influenza virus. Activation and inactivation of the membrane fusion capacity of the hemagglutinin

The hemagglutinin of influenza virus undergoes a conformational change at low pH, which results in exposure of a hydrophobic segment of the molecule, crucial to expression of viral fusion activity. We have studied the effects of incubation of the virus at low pH either at 37 or 0 degrees C. Treatment of the virus alone at pH 5.0 induces the virus particles to become hydrophobic, as assessed by measuring the binding of zwitterionic liposomes to the virus. At 37 degrees C this hydrophobicity is transient, electron microscopic examination of the virus reveals a highly disorganized spike layer, and fusion activity toward ganglioside-containing zwitterionic liposomes, measured at 37 degrees C with a kinetic fluorescence assay, is irreversibly lost. By contrast, after preincubation of the virus alone at pH 5.0 and 0 degrees C fusion activity remains unaffected. Yet, the preincubation at 0 degrees C does result in exposure of the hydrophobic segment of hemagglutinin, but now hydrophobicity is sustained and viral spike morphology unaltered. Hydrophobicity also remains to a significant extent upon pH neutralization, but fusion activity is negligible under these conditions. It is concluded that for optimal expression of fusion activity the virus must be bound to the target membrane before exposure to low pH. Furthermore, even after exposure of the hydrophobic segment of hemagglutinin, fusion occurs only at low pH. Finally, fusion occurs only at elevated temperature, possibly reflecting the unfolding of hemagglutinin trimers or the cooperative action of several hemagglutinin trimers in the reaction.     

Stability and physicochemical properties of the bovine brain phosphatidylethanolamine-binding protein.

The equilibrium behaviour of the bovine phosphatidylethanolamine-binding protein (PEBP) has been studied under various conditions of pH, temperature and urea concentration. Far-UV and near-UV CD, fluorescence and Fourier transform infrared spectroscopies indicate that, in its native state, PEBP is mainly composed of beta-sheets, with Trp residues mostly localized in a hydrophobic environment; these results suggest that the conformation of PEBP in solution is similar to the three-dimensional structure determined by X-ray crystallography. The pH-induced conformational changes show a transition midpoint at pH 3.0, implying nine protons in the transition. At neutral pH, the thermal denaturation is irreversible due to protein precipitation, whereas at acidic pH values the protein exhibits a reversible denaturation. The thermal denaturation curves, as monitored by CD, fluorescence and differential scanning calorimetry, support a two-state model for the equilibrium and display coincident values with a melting temperature Tm = 54 degrees C, an enthalpy change DeltaH = 119 kcal.mol-1 and a free energy change DeltaG(H2O, 25 degrees C) = 5 kcal.mol-1. The urea-induced unfolding profiles of PEBP show a midpoint of the two-state unfolding transition at 4.8 M denaturant, and the stability of PEBP is 4.5 kcal.mol-1 at 25 degrees C. Moreover, the surface active properties indicate that PEBP is essentially a hydrophilic protein which progressively unfolds at the air/water interface over the course of time. Together, these results suggest that PEBP is well-structured in solution but that its conformation is weakly stable and sensitive to hydrophobic conditions: the PEBP structure seems to be flexible and adaptable to its environment.     

Effect of physical environment on the conformation of ricin. Influence of low pH.

The molecular properties of ricin (the toxic lectin from Ricinus communis seeds, RCA II or RCA 60) were evaluated by analytical ultracentrifugation, viscosimetry, c.d., fluorescence and equilibrium dialysis. Measurements of sedimentation (S0(20,W) = 4.60 S) and viscosity (eta = 2.96 X 10(-2) dl/g) indicated that, at neutral pH, the ricin molecule is very compact. Various transitions were explored, and a pH-triggered change in the ricin conformation was observed between pH 7 and 4. In this range, the sedimentation coefficient, far-u.v. c.d. and fluorescence altered simultaneously without unfolding. Below pH 7 the change in the ricin conformation was accompanied by a decrease in the affinity of ricin for galactosides, and at pH 4.0 by an alteration in its binding capacity. These effects of low pH are discussed in relation to the physical conditions encountered by ricin molecules during their entry into living cells.     

Energetics of diphtheria toxin membrane insertion and translocation: calorimetric characterization of the acid pH induced transition

The pH and temperature stabilities of diphtheria toxin and its fragments have been studied by high-sensitivity differential scanning calorimetry. These studies demonstrate that the pH-induced conformational transition associated with the mechanism of membrane insertion and translocation of the toxin involves a massive unfolding of the toxin molecule. At physiological temperatures (37 degrees C), this process is centered at pH 4.7 at low ionic strength and at pH 5.4 in the presence of 0.2 M NaCl. At pH 8, the thermal unfolding of the nucleotide-bound toxin is centered at 58.2 degrees C whereas that of the nucleotide-free toxin is centered at 51.8 degrees C, indicating that nucleotide binding (ApUp) stabilizes the native conformation of the toxin. The unfolding profile of the toxin is consistent with two transitions most likely corresponding to the A fragment (Tm = 54.5 degrees C) and the B fragment (Tm = 58.4 degrees C), as inferred from experiments using the isolated A fragment. These two transitions are not independent, judging from the fact that the isolated A fragment unfolds at much lower temperatures (Tm = 44.2 degrees C) and that the B fragment is insoluble in aqueous solutions when separated from the A fragment. Interfragment association contributes an extra -2.6 kcal/mol to the free energy of stabilization of the A fragment. Whereas the unfolding of the entire toxin is irreversible, the unfolding of the A fragment is a reversible process. These findings provide a thermodynamic basis for the refolding of the A fragment after reexposure to neutral pH immediately following translocation across the lysosomal membrane.     

Study of the effect of melittin on the thermotropism of dipalmitoylphosphatidylcholine by Raman spectroscopy

The effect of amphiphilic toxin melittin (Mel) on the thermotropic behavior of dipalmitoylphosphatidylcholine (DPPC) has been studied by Raman spectroscopy. The spectra show that for complexes that were incubated above 40 degrees C, melittin does not penetrate DPPC bilayers in the gel state as an intrinsic protein since the conformation of the lipid acyl chains is just slightly perturbed by the toxin. Instead, at the DPPC/Mel molar ratios investigated (Ri = 5 and 15), Raman results suggest the formation of discoidal particles as complexes of apolipoproteins with phosphatidylcholines. These lipid/protein assemblies are characterized by a high conformational order, low intermolecular chain-chain interactions due to the size of the particles, and a low cooperativity of the gel to liquid-crystalline transition. The latter is biphasic for samples studied. It is believed that aggregation of these particles into larger ones occurs when the bilayers become less stable at higher temperature and that melittin is partially embedded into the hydrophobic core of the larger lipid/protein units. The freezing of the dispersion at approximately 0 degrees C also causes a reversible aggregation of the particles that leads to the formation of domains in which the interchain interactions are very similar to that of the pure lipid. The small particles of DPPC/Mel are also metastable, and with time, they form larger aggregates from which melittin is expulsed.     

Role of the C-terminal chain in human interferongamma stability: an electrostatic study

Electrostatic interactions in two structures of human interferon gamma (hIFNgamma), corresponding to interferon molecule alone and bound to its receptor, were analyzed on the basis of a continuum dielectric model. It was found that a number of titratable groups, mainly basic, show large pK shifts and remain in their neutral forms at physiologically relevant pH. The fact that these groups are largely common to both structures and that most of them belong to the set of most conserved sites suggests that this is a property inherent to the hIFNgamma molecule rather than an artifact of the crystal packing. His111 was also found deprotonated at neutral pH. It was concluded that receptor recognition involving His111 is driven by aromatic coupling of His111 and Tyr52 from the receptor rather than by electrostatic interactions. The structure corresponding to hIFNgamma in complex with its receptor shows a reduction in number and in degree of desolvation of the buried titratable sites. This finding suggested that on receptor binding, hIFNgamma adopts energetically more favorable, relaxed, conformation. It was experimentally shown that in contrast to the full-size hIFNgamma, the construct having 21 amino acid residues deleted from the C-terminus is soluble. The hydrophobicity profile analysis suggested that factors other than the exposure of hydrophobic parts of the molecule are responsible for the low stability and propensity for aggregation. On the basis of these results, it was assumed that the electrostatic influence of the C-terminal part contributes particularly to the low solvent exposure of the titratable groups, and hence to the low structural stability and propensity for aggregation of the recombinant hIFNgamma. Proteins 2001;43:125-133.     

Standardization of salt aggregation test for reproducible determination of cell-surface hydrophobicity with special reference to Staphylococcus species

The laboratory conditions for reproducible routine determination of staphylococcal cell-surface hydrophobicity by the salt aggregation test were standardized. Fresh bacterial suspensions standardized to 5 x 10(9) cfu/ml gave the most reproducible results with both Staphylococcus aureus and coagulase-negative staphylococci. For relatively hydrophobic strains a 5-min reading time was necessary to detect bacterial aggregation in ammonium sulphate solutions ranging from 0.1 M to 1.5 M, pH 6.8. A x 10 hand lens facilitated reading aggregations. Overnight storage of bacterial suspensions at 20 degrees C reduced cell-surface hydrophobicity of all species, while storage at 4 degrees C reduced the hydrophobic nature of Staph. aureus strains. The hydrophobicity of coagulase-negative staphylococci rarely changed at 4 degrees C. A 10-fold dilution of fresh, standardized bacterial suspensions made it impossible to detect bacterial aggregation in ammonium sulphate solutions even with a hand lens. Under standardized conditions three types of staphylococcal cell aggregations were observed. The first looked like the slide agglutination for O antigens of Enterobacteriaceae, the second resembled H-agglutination, while the third had a filamentous appearance. These patterns indicated that more than one component might contribute to cell-surface hydrophobicity of both Staph. aureus and coagulase-negative staphylococci, or the same component might have different position on the cell surface.     

The acid-triggered entry pathway of Pseudomonas exotoxin A

In this study we examined the pH requirements and reversibility of early events in the Pseudomonas toxin entry pathway, namely, membrane binding, insertion, and translocation. At pH 7.4, toxin binding to vesicles and insertion into the bilayer are very inefficient. Decreasing the pH greatly increases the efficiencies of these processes. Acid-treated toxin exhibits pH 7.4 binding and insertion levels. This indicates that hydrophobic regions that become exposed upon toxin acidficiation become buried again when the pH is raised to 7.4. In contrast, the change in toxin conformation that occurs upon membrane binding is irreversible. Returning samples to pH 7.4, incubation with excess toxin, or dilution with buffer up to 1000-fold leads to very little loss of bound toxin. Bound toxin exhibits an extremely high susceptibility to trypsin compared to free toxin (at both pH 4 and pH 7.4). At pH 4, membrane-associated toxin slowly proceeds to a trypsin-protected state; neutralization halts this process. At low pH, toxin was found to bind and insert into DMPC vesicles very efficiently at temperatures both above and below 23 degrees C, the lipid melting point. With fluid targets, the proportion of bound toxin that was photolabeled from within the bilayer peaked rapidly and then decreased with time. With frozen targets, the efficiency of photolabeling peaked but then remained fairly constant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alternatively folded states of an immunoglobulin

Well-defined, non-native protein structures of low stability have been increasingly observed as intermediates in protein folding or as equilibrium structures populated under specific solvent conditions. These intermediate structures, frequently referred to as molten globule states, are characterized by the presence of secondary structure, a lack of significant tertiary contacts, increased hydrophobicity and partial specific volume as compared to native structures, and low cooperativity in thermal unfolding. The present study demonstrates that under acidic conditions (pH less than 3) the antibody MAK33 can assume a folded stable conformation. This A-state is characterized by a high degree of secondary structure, increased hydrophobicity, a native-like maximum wavelength of fluorescence emission, and a tendency toward slow aggregation. A prominent feature of this low-pH conformation is the stability against denaturant and thermal unfolding that is manifested in highly cooperative reversible phase transitions indicative of the existence of well-defined tertiary contacts. These thermodynamic results are corroborated by the kinetics of folding from the completely unfolded chain to the alternatively folded state at pH 2. The given data suggest that MAK33 at pH 2 adopts a cooperative structure that differs from the native immunoglobulin fold at pH 7. This alternatively folded state exhibits certain characteristics of the molten globule but differs distinctly from it by its extraordinary structural stability that is characteristic for native protein structures.     

Involvement of denaturation-like changes in Pseudomonas exotoxin a hydrophobicity and membrane penetration determined by characterization of pH and thermal transitions. Roles of two distinct conformationally altered states

Previous investigators have shown that exotoxin A undergoes a conformational switch to a hydrophobic state at low pH. This change appears to play a role in exotoxin A entry into cells by facilitating its penetration of the membranes of acidic organelles. We have examined the effects of pH, temperature, and denaturants in order to define the role of conformational changes in membrane penetration by the exotoxin. We find that two distinct low pH conformations exist. An intermediate low pH state (LI) dominates at pH 3.7-5.4 and is distinguished by blue-shifted fluorescence and weak or no hydrophobicity. The second low pH state (LII) is dominant below pH 3.7 and is characterized by red shifted fluorescence and strong hydrophobicity. LI is a folded state as judged by its spectroscopic properties and the observation that it undergoes distinct and cooperative thermal and denaturant induced unfolding transitions. LII appears to be more like a denatured state, as it shows no cooperative thermal or denaturant induced transitions and has spectroscopic properties very similar to exotoxin A that has been thermally denatured at pH 7. Exotoxin A in the LII state strongly binds detergent micelles and binds and inserts into model membranes. Therefore, denaturation-like conformational changes appear to play an important role in membrane insertion. The pH of the transition to a membrane-inserting state is influenced by the composition of the model membranes and is close to pH 5 in the presence of vesicles containing a phosphatidylglycerol/phosphatidylcholine mixture. These vesicles probably promote formation of the LII state via mass action effects. The implication of these results for membrane penetration and translocation of proteins without apparent hydrophobic regions, such as exotoxin A, is discussed.