Study of conformational changes in immunoglobulin M using the method of differential spectroscopy

Using differential and solvent-perturbation spectrophotometry, the nature of conformational changes in immunoglobulin M (IgM) in different regimens was investigated. The quantities of tryptophan and tyrosine chromophores exposed on the surface of the molecule and screened, were evaluated. The changes in pH (7.8----2.0) of the surrounding medium and splitting of carbohydrate groups from IgM were shown to cause opposite effects, i. e., a "blue shift" of the spectrum and exposure of new chromophores by acidification, and a "red shift" and screening of chromophores by splitting of carbohydrate groups. The experimental results agree well with the previously made assumption on the differences in the spatial conformational changes in the IgM molecule under effects of pH of the surrounding medium and the loss of carbohydrate groups. Analysis of the spectral characteristics of some free Fab- and (Fc)5-fragments derived from the IgM molecules allowed a specification of the changes occurring in different parts of the whole molecule. The main conformational changes after acidification occur in the (Fc)5-fragment responsible for the effector function of IgM.     

Effects of acid exposure on the conformation, stability, and aggregation of monoclonal antibodies

Exposure of antibodies to low pH is often unavoidable for purification and viral clearance. The conformation and stability of two humanized monoclonal antibodies (hIgG4-A and -B) directed against different antigens and a mouse monoclonal antibody (mIgG1) in 0.1M citrate at acidic pH were studied using circular dichroism (CD), differential scanning calorimetry (DSC), and sedimentation velocity. Near- and far-UV CD spectra showed that exposure of these antibodies to pH 2.7-3.9 induced only limited conformational changes, although the changes were greater at the lower pH. However, the acid conformation is far from unfolded or so-called molten globule structure. Incubation of hIgG4-A at pH 2.7 and 3.5 at 4 degrees C over the course of 24 h caused little change in the near-UV CD spectra, indicating that the acid conformation is stable. Sedimentation velocity showed that the hIgG4-A is largely monomeric at pH 2.7 and 3.5 as well as at pH 6.0. No time-dependent changes in sedimentation profile occurred upon incubation at these low pHs, consistent with the conformational stability observed by CD. The sedimentation coefficient of the monomer at pH 2.7 or 3.5 again suggested that no gross conformational changes occur at these pHs. DSC analysis of the antibodies showed thermal unfolding at pH 2.7-3.9 as well as at pH 6.0, but with decreased melting temperatures at the lower pH. These results are consistent with the view that the antibodies undergo limited conformational change, and that incubation at 4 degrees C at low pH results in no time-dependent conformational changes. Titration of hIgG4-A from pH 3.5 to 6.0 resulted in recovery of native monomeric proteins whose CD and DSC profiles resembled those of the original sample. However, titration from pH 2.7 resulted in lower recovery of monomeric antibody, indicating that the greater conformational changes observed at this pH cannot be fully reversed to the native structure by a simple pH titration.     

Study of the irreversible conformation change of immunoglobulin M by spin-labeling at the carbohydrate and peptide moieties of the molecule

The irreversible conformational change of the immunoglobulin M (IgM) molecule (Waldenstr?m disease) at pH approximately 3 was studied by means of spin-labels introduced in the carbohydrate (2,2,6,6,-tetramethyl-4-aminopiperidine-1-oxyl) and peptide (2,2,5,5,-tetramethyl-3-(dichloro-symm.-triazinylamino)-pyrrolidine-1-oxyl) moieties of the molecule. A marked rise of structure density of IgM especially in the (Fc)5-region and some minor local conformational changes in the Fab-regions were found. Comparison of our findings with the published data shows that Fab-regions of the principal immunoglobulins are rigid structures. Steric hindrance for Fab-regions increases markedly in the row Fab--F(ab')2--IgG--IgA--IgM restricting their spatial mobility. Monomeric Fc-regions of IgM are evidently flexible and one of the domains is especially mobile. It is supposed that oligosaccharide groups of IgM are of two types which differ in their spatial mobility. It was found by ammonium sulfate precipitation of IgM spin-labeled at the peptide moiety that the relative mobility of amino acid residues coupled with spin-label is strongly restricted.     

Circular dichroism studies on the alpha-D-galactopyranosyl binding lectin isolated from the seeds of Bandeiraea simplicifolia.

The conformation of the alpha-D-galactopyranosyl binding lectin isolated from Bandeiraea simplicifolia seeds has been investigated over a broad range of pH in the presence of various solvents by circular dichroism (CD) spectroscopy in the region 200-300 nm. Analyses of the spectra obtained on the native protein show the lectin to contain a considerable proportion of beta structure (30-40%). The native conformation was found to be largely insensitive to changes in pH, but was influenced by sodium dodecyl sulfate or trifluoroethanol. Alterations in conformation in the presence of these agents were reflected in the CD spectra and show the presence of alpha helix under these conditions. These changes in conformation are accompanied by a loss in polysaccharide-precipitating activity. The protein is irreversibly denatured in 8 M urea. Neither removal of the intrinsic calcium ions from the protein nor addition of methyl alpha-D-galactopyranoside induces any appreciable change in the CD spectra of the protein although the former treatment abolishes the polysaccharide-precipitating capacity of the lectin. The conformational data obtained in the present study are compared with data available from conformational studies of other lectins and leads to the hypothesis that most lectins probably contain beta structure as the predominant conformational feature.     

Accessibility of tryptophan residues in immunoglobulin M molecule as an indicator of its conformational variability

The accessibility of tryptophan residues in immunoglobulin M to modification with the Koshland reagent (2-hydroxy-5-nitrobenzyl bromide) was used as an indicator of its conformational variability. Of 14 tryptophan residues (per HL-fragment) in the native IgM, only one (presumably Trp312 in the mu-chain) was the most accessible. Irreversible acid- or temperature-induced conformational changes of IgM increased almost 2-fold the number of accessible tryptophan residues. After partial enzymatic deglycosylation of IgM (especially by an intense splitting of mannose), all tryptophan residues became inaccessible. Modification of the most accessible tryptophan residue increased 2- to 3-fold the number of tyrosine residues accessible to nitration with tetranitromethane. Using the spin label method, it was demonstrated that modification of four tryptophan residues in IgM considerably decreased the mobility of the Cmu 3 domain together with an essential drop in. the solubility of the modified IgM.     

Localized conformational changes trigger the pH-induced fibrillogenesis of an amyloidogenic λ light chain protein

Solvent conditions modulate the expression of the amyloidogenic potential of proteins. In this work the effect of pH on the fibrillogenic behavior and the conformational properties of 6aJL2, a model protein of the highly amyloidogenic variable light chain λ6a gene segment, was examined. Ordered aggregates showing the ultrastructural and spectroscopic properties observed in amyloid fibrils were formed in the 2.0–8.0?pH range. At pH <3.0 a drastic decrease in lag time and an increase in fibril formation rate were found. In the 4.0–8.0?pH range there was no spectroscopic evidence for significant conformational changes in the native state. Likewise, heat capacity measurements showed no evidence for residual structure in the unfolded state. However, at pH <3.0 stability is severely decreased and the protein suffers conformational changes as detected by circular dichroism, tryptophan and ANS fluorescence, as well as by NMR spectroscopy. Molecular dynamics simulations indicate that acid-induced conformational changes involve the exposure of the loop connecting strands E and F. These results are compatible with pH-induced changes in the NMR spectra. Overall, the results indicate that the mechanism involved in the acid-induced increase in the fibrillogenic potential of 6aJL2 is profoundly different to that observed in κ light chains, and is promoted by localized conformational changes in a region of the protein that was previously not known to be involved in acid-induced light chain fibril formation. The identification of this region opens the potential for the design of specific inhibitors.     

Hexafluoroisopropanol-induced helix–sheet transition of stem bromelain: Correlation to function

Stem bromelain is a proteolytic phytoprotein with a variety of therapeutic effects. Understanding its structural properties could provide insight into the mechanisms underlying its clinical utility. Stem bromelain was evaluated for its conformational and folding properties at the pH conditions it encounters when administered orally. It exists as a partially folded intermediate at pH 2.0. The conformational changes to this intermediate state were evaluated using fluorinated alcohols known to induce changes similar to those seen in vivo. Studies using circular dichroism, fluorescence emission spectroscopy, binding of the hydrophobic dye 1-anilino-8-naphthalene sulfonic acid and mass spectrometry indicate that treatment with 10–30% hexafluoroisopropanol induces the partially folded intermediate to adopt much of the native protein's secondary structure, but only a rudimentary tertiary structure, characteristic of the molten globule state. Addition of slightly higher concentrations of hexafluoroisopropanol caused transformation from an α-helix to a β-sheet and induced formation of a compact nonnative structure. This nonnative form was more inhibitory of cell survival than either the native or the partially folded intermediate forms, as measured by enhanced suppression of proliferative cues (e.g., extracellular-signal-regulated kinase) and initiation of apoptotic events. The nonnative form also showed better antitumorigenic properties, as evaluated using an induced two-stage mouse skin papilloma model. In contrast, the nonnative state showed only a fraction of the proteolytic activity of the native form. This study demonstrates that hexafluoroisopropanol can induce a conformational change in stem bromelain to a form with potentially useful therapeutic properties different from those of the native protein.     

Replacement of a conserved proline and the alkaline conformational change in iso-2-cytochrome c

Although point mutations usually lead to minor localized changes in protein structure, replacement of conserved Pro-76 with Gly in iso-2-cytochrome c induces a major conformational change. The change in structure results from mutation-induced depression of the pK for transition to an alkaline conformation with altered heme ligation. To assess the importance of position 76 in stabilizing the native versus the alkaline structure, the equilibrium and kinetic properties of the pH-induced conformational change have been compared for normal and mutant iso-2-cytochrome c. The pKapp for the conformational change is reduced from 8.45 (normal iso-2) to 6.71 in the mutant protein (Gly-76 iso-2), suggesting that conservation of Pro-76 may be required to stabilize the native conformation at physiological pH. The kinetics of the conformational change for both the normal and mutant proteins are well-described by a single kinetic phase throughout most of the pH-induced transition zone. Over this pH range, a minimal mechanism proposed for horse cytochrome c [Davis, L. A., Schejter, A., & Hess, G. P. (1974) J. Biol. Chem. 249, 2624-2632] is consistent with the data for normal and mutant yeast iso-2-cytochromes c: NH KH----N + H+ kcf in equilibrium kcb A NH and N are native forms of cytochrome c with a 695-nm absorbance band, A is an alkaline form that lacks the 695-nm band, KH is a proton dissociation constant, and kcf and kcb are microscopic rate constants for the conformational change. The Gly-76 mutation increases kcf by almost 70-fold, but kcb and KH are unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational change in the pheromone-binding protein from Bombyx mori induced by pH and by interaction with membranes.

The pheromone-binding protein (PBP) from Bombyx mori was expressed in Escherichia coli periplasm. It specifically bound radiolabeled bombykol, the natural pheromone for this species. It appeared as a single band both in native and SDS-polyacrylamide gel electrophoresis and was also homogeneous in most chromatographic systems. However, in ion-exchange chromatography, multiple forms sometimes appeared. Attempts to separate them revealed that they could be converted into one another. Analysis of the protein by circular dichroism and fluorescence spectroscopy demonstrated that its tertiary structure was sensitive to pH changes and that a dramatic conformational transition occurred between pH 6.0 and 5.0. This high sensitivity to pH contrasted markedly with its thermal stability and resistance to denaturation by urea. There was also no significant change in CD spectra in the presence of the pheromone. The native protein isolated from male antennae displayed the same changes in its spectroscopic properties as the recombinant material, demonstrating that this phenomenon is not an artifact arising from the expression system. This conformational transition was reproduced by interaction of the protein with anionic (but not neutral) phospholipid vesicles. Unfolding of the PBP structure triggered by membranes suggests a plausible mechanism for ligand release upon interaction of the PBP-pheromone complex with the surface of olfactory neurons. This pH-linked structural flexibility also explains the heterogeneity reported previously for B. mori PBP and other members of this class of proteins.     

Protein denaturation during freezing and thawing in phosphate buffer systems: monomeric and tetrameric beta-galactosidase

During freezing in sodium and potassium phosphate (NaP and KP) buffer solutions, changes in pH may impact the stability of proteins. Since the degradation pathways for the model proteins, monomeric and tetrameric beta-galactosidase (beta-gal), chosen for this study are governed by conformational changes (i.e., physical instability) as opposed to chemical transformations, we explored how the stresses of freezing and thawing alter the protein's native structure and if preservation of the native conformation during freeze-thawing is a requisite for optimal recovery of activity. During freezing in NaP buffer, a significant pH decrease from 7.0 to as low as 3.8 was observed due to the selective precipitation of the disodium phosphate; however, the pH during freezing in KP buffer only increased by at most 0.3 pH units. pH-induced inactivation was evident as seen by the lower recovery of activity when freeze-thawing in NaP buffer as compared to KP buffer for both sources of beta-gal. In addition, we investigated the effects of cooling rate and warming rate on the recovery of activity for monomeric and tetrameric beta-gal. Optimal recovery of activity for the NaP samples was obtained when the processing protocol involved a fast cool/fast warm combination, which minimizes exposure to acidic conditions and concentrated solutes. Alterations in the native secondary structure of monomeric beta-gal as measured by infrared spectroscopy were more significant when freezing and thawing in NaP buffer as opposed to KP buffer. Conformational and activity analyses indicate that pH changes during freezing in NaP buffer contribute to denaturation of beta-gal. These results suggest that proteins formulated in NaP buffer should be frozen and thawed rapidly to minimize exposure to low pH and high buffer salts.     

Conformational aspects of the acid-induced fusion mechanism of influenza virus hemagglutinin. Circular dichroism and fluorescence studies

Circular dichroism and tryptophan fluorescence spectroscopy have been used to investigate the structures of the influenza virus membrane glycoprotein hemagglutinin, acid-treated hemagglutinin, and fragments of hemagglutinin derived by proteolysis. The conformational change in hemagglutinin which occurs at the pH of membrane fusion (pH 5-6) was associated with a significant change of the environment of tyrosine residues, a change in the environment of tryptophan residues, but no changes in secondary structure. Tryptic digestion of the hemagglutinin in its low pH conformation which releases one of the subunit polypeptides (HA1) caused minimal changes in tyrosine and tryptophan environments but a small secondary structural change in HA1. The secondary structure of the remainder of the molecule (HA2) was very similar to that predicted from the known x-ray crystallographic structure of the native molecule. However, fluorescence spectroscopy indicated a tertiary change in structure in the coiled coil of alpha-helices which form the fibrous central stem of the molecule. These results are consistent with a conformational change required for membrane fusion which involves a decrease of HA1/HA1, HA1/HA2 interactions and changes in tertiary structure not accompanied by changes in secondary structure.     

Alkali-induced conformational transition in different domains of bovine serum albumin

Alkaline pH induced conformational changes in different domains of bovine serum albumin were studied by using domain specific ligands: chloroform, bilirubin and diazepam for domains I, II and III respectively. The effect of alkaline pH on the secondary structure of BSA was monitored by far-UV CD in the range 250 nm to 200 nm. The pH profiles of BSA in the alkaline region showed a two-step change, one corresponding to N<-->B transition (pH 7.5 to 9.0) and the other to B --> U (pH 11.0 to 13.5). Binding of chloroform decreased continuously on increasing pH, whereas binding of diazepam, remained unchanged up to pH 9 and decreased thereafter. In contrast, binding of bilirubin gradually increased up to pH 11.0 and decreased thereafter reaching a value similar to one obtained with native BSA at pH 11.5. Above pH 11.5, bilirubin binding decreased and was abolished completely at pH 12.5. In the pH region 7.5 to 11.0, a continuous decrease in chloroform binding (pH 7.5 to 9.5) and a late decrease in diazepam binding (pH 9.5 to 11.0) suggested major loss of native conformation of domain I followed by domain III during alkaline induced unfolding of BSA. However, a significant increase in bilirubin binding showed a favorable conformational rearrangement in domain II in this pH region (pH7.5 to 11.0). Further, a nearly complete abolishment of bilirubin binding to BSA and significant loss of secondary structure around pH 12.5 indicated that domain II was more resistant to alkaline pH and unfolds only at extreme alkalinity. Taken together, these data suggest that unfolding of three domains of BSA follow the following order of susceptibility towards alkaline denaturation of BSA domain I>domain III>domain II.     

pH-induced conformational changes in the soluble manganese-stabilizing protein of photosystem II

In this paper, we analyzed the pH-induced changes in the conformational states of the manganese-stabilizing protein (MSP) of photosystem II. Distinct conformational states of MSP were identified using fluorescence spectra, far-UV circular dichroism, and pressure-induced unfolding at varying suspension pH values, and four different conformational states of MSP were clearly distinguished using the center of fluorescence spectra mass when suspension pH was altered from 2 to 12. MSP was completely unfolded at a suspension pH above 11 and partly unfolded below a pH of 3. Analysis of the center of fluorescence spectral mass showed that the MSP structure appears stably folded around pH 6 and 4. The conformational state of MSP at pH 4 seems more stable than that at pH 6. Studies of peak positions of tryptophan fluorescence and MSP-bound 1-anilinonaphthalene-8-sulfonic acid fluorescence spectra supported this observation. A decrease in the suspension pH to 2 resulted in significant alterations in the MSP structure possibly because of protonation of unprotonated residues at lower pH, suggesting the existence of a large number of unprotonated amino acid residues at neutral pH possibly useful for proton transport in oxygen evolution. The acidic pH-induced conformational changes of MSP were reversible upon increase of pH to neutral pH; however, N-bromosuccinimide modification of tryptophan (Trp241) blocks the recovery of pH-induced conformational changes in MSP, implying that Trp241 is a key residue for the unfolded protein to form a functional structure. Thus, pH-induced structural changes of stable MSP (pH 6-4) may be utilized to analyze its functionality as a cofactor for oxygen evolution.     

Evidence for impaired subunit interaction in chemically deglycosylated human choriogonadotropin

Using three different methods evidence was obtained that native and deglycosylated choriogonadotropin show differences in their conformations which might account for the antagonistic properties of deglycosylated choriogonadotropin: 1. In the deglycosylated hormone additional peptide bonds were susceptible to chymotrypsin. 2. In the far ultraviolet circular dichroism only small differences existed between native and deglycosylated choriogonadotropin. However, in 80% hexafluoropropanol the deglycosylated hormone adopted a higher degree of ordered structure. 3. At 37 degrees C the deglycosylated hormone showed a 13 fold increase of the dissociation rate into subunits at pH 3 in comparison to native choriogonadotropin. The results provide evidence that in chemically deglycosylated choriogonadotropin the subunit interactions are disturbed due to conformational changes.     

Effects of pH on structural and functional properties of porin from the outer membrane of Yersinia pseudotuberculosis. II. Characterization of pH-induced conformational intermediates of yersinin

pH-Induced intermediates of Omp F-like porin from the outer membrane of Yersinia pseudotuberculosis (yersinin) were characterized by fluorescence and fluorescent probe spectroscopy and circular dichroism. The most dramatic changes in the intrinsic fluorescence of the protein induced by pH titration correlated with different conformational states of the porin molecule. pH-induced conformational transitions of yersinin can be described in terms of a three-state model: (1) disordering of porin associates and formation of porin trimers structurally similar to the native protein; (2) unfolding of individual porin domains followed by cooperative dissociation of trimers into monomers; (3) formation of two loosely structured forms of monomer intermediates. It is assumed that one of these monomeric forms (at pH 3.0) corresponds to the molten-globule state of porin with native secondary structure, while the other one (at 2.0) represents a partly denatured (misfolded) monomer, which retains no more than 50% of the regular secondary structure. The putative mechanism of low pH-induced β-barrel unfolding is discussed in terms of a theoretical model of yersinin spatial structure.     

Alcohol-Induced Conformational Transitions in Ervatamin C. An α-Helix to β-Sheet Switchover

Alcohol-induced conformational transitions of erv C, a highly stable cysteine protease, were followed by CD, fluorescence, and activity. At acidic pH, the addition of different alcohols caused two types of conformational transitions. Increasing the concentration of nonfluorinated alkyl alcohols induced a conformational switch from α-helix to β-sheet. Under these conditions, the protein lost its proteolytic activity and tertiary structure. The switch was a sudden one, observed in 50% methanol, 45% ethanol, and 40% propanol. Under similar conditions of pH and concentration, however, glycerol and TFE enhanced the α-helicity of the protein. Methanol-induced denaturation was observed to occur in two stages; the first is the β-sheet state stabilized at low alcohol concentrations, and the other is the β-sheet state with enhanced ellipticity stabilized at high alcohol concentrations. This β-sheet conformation can be attained from the native as well as 6 M GuHCl-denatured state by addition of methanol and exhibits properties different from the native or unfolded state. This state shows loss of tertiary structure and activity, enhanced nonnative secondary structure, noncooperative temperature unfolding, and higher stability toward denaturants as compared to the native state, which are characteristic of the molten globule-like state or O-state, and thus this state may be functioning as an intermediate in the folding pathway of erv C.     

Ligand-induced conformational changes in tissue transglutaminase: Monte Carlo analysis of small-angle scattering data

Small-angle neutron and x-ray scattering experiments have been performed on type 2 tissular transglutaminase to characterize the conformational changes that bring about Ca(2+) activation and guanosine triphosphate (GTP) inhibition. The native and a proteolyzed form of the enzyme, in the presence and in the absence of the two effectors, were considered. To describe the shape of transglutaminase in the different conformations, a Monte Carlo method for calculating small-angle neutron scattering profiles was developed by taking into account the computer-designed structure of the native transglutaminase, the results of the Guinier analysis, and the essential role played by the solvent-exposed peptide loop for the conformational changes of the protein after activation. Although the range of the neutron scattering data is rather limited, by using the Monte Carlo analysis, and because the structure of the native protein is available, the distribution of the protein conformations after ligand interaction was obtained. Calcium activation promotes a rotation of the C-terminal with respect to the N-terminal domain around the solvent-exposed peptide loop that connects the two regions. The psi angle between the longest axes of the two pairs of domains is found to be above 50 degrees, larger than the psi value of 35 degrees calculated for the native transglutaminase. On the other hand, the addition of GTP makes possible conformations characterized by psi angles lower than 34 degrees. These results are in good agreement with the proposed enzyme activity regulation: in the presence of GTP, the catalytic site is shielded by the more compact protein structure, while the conformational changes induced by Ca(2+) make the active site accessible to the substrate.     

Hydrostatic pressure induces the fusion-active state of enveloped viruses.

Enveloped animal viruses must undergo membrane fusion to deliver their genome into the host cell. We demonstrate that high pressure inactivates two membrane-enveloped viruses, influenza and Sindbis, by trapping the particles in a fusion-intermediate state. The pressure-induced conformational changes in Sindbis and influenza viruses were followed using intrinsic and extrinsic fluorescence spectroscopy, circular dichroism, and fusion, plaque, and hemagglutination assays. Influenza virus subjected to pressure exposes hydrophobic domains as determined by tryptophan fluorescence and by the binding of bis-8-anilino-1-naphthalenesulfonate, a well established marker of the fusogenic state in influenza virus. Pressure also produced an increase in the fusion activity at neutral pH as monitored by fluorescence resonance energy transfer using lipid vesicles labeled with fluorescence probes. Sindbis virus also underwent conformational changes induced by pressure similar to those in influenza virus, and the increase in fusion activity was followed by pyrene excimer fluorescence of the metabolically labeled virus particles. Overall we show that pressure elicits subtle changes in the whole structure of the enveloped viruses triggering a conformational change that is similar to the change triggered by low pH. Our data strengthen the hypothesis that the native conformation of fusion proteins is metastable, and a cycle of pressure leads to a final state, the fusion-active state, of smaller volume.     

Effects of succinylation on thermal induced amyloid formation in Concanavalin A

We have recently shown that upon slight thermal destabilization the legume lectin Concanavalin A may undergo two different aggregation processes, leading, respectively, to amyloid fibrils at high pH and amorphous aggregates at low pH. Here we present an experimental study on the amyloid aggregation of Succinyl Concanavalin A, which is a dimeric active variant of Concanavalin. The results show that, as for the native protein, the fibrillation process appears to be favoured by alkaline pH, far from the isoelectric point of the protein. Moreover, it strongly depends on temperature and requires large conformational changes both at secondary and tertiary structure level. With respect to the native protein, the succinyl derivative forms amyloid fibrils in considerably longer times and with a minor exposure of hydrophobic regions. At physiological conditions, Concanavalin A still displays a sizeable tendency to form amyloid fibril, while the succinyl variant does not. A close correlation was observed between the progress of amyloid formation and a narrowing of the tryptophans fluorescence emission band, indicating a reduction of protein conformational heterogeneity in amyloid fibrils. Proceedings of the XVIII Congress of the Italian Society of Pure and Applied Biophysics (SIBPA), Palermo, Sicily, September 2006.     

Structural changes in Cry3A delta-endotoxin from Bacillus thuringiensis var. Tenebrionis in alcohol solutions at pH 2.0

Conformational changes in Cry3A delta-endotoxin caused by three different alcohols (ethanol, butanol, and isopropanol) were studied using the methods of circular dichroism, scanning microcalorimetry, and electron miscroscopy. It was shown that, in addition to the standard decrease in the native structure stability, the alcohols can cause a conformational transition that results in a sharp increase in the beta-structure content and a change in the environment of aromatic residues. The conformational transition is accompanied by intermolecular association, which leads to the appearance of oligomers in the form of short filaments. When the alcohols were removed, the oligomers dissociated again into monomers, but it is likely that the native structure either is not restored or is restored only in a small portion of molecules. The oligomer structure is rather cooperative, and its thermostability is higher than that of the initial structure. The disruption of this structure upon heating, observed as a heat absorption peak, is reversible.