Stability of aprA-subtilisin in sodium dodecyl sulfate

The effect of sodium dodecyl sulfate (SDS) on the structure and activity of aprA-subtilisin, a secreted bacterial serine protease which is 85% homologous to subtilisin BPN', was examined. The addition of SDS resulted in the slow conversion of the subtilisin from the intact protein to the completely unfolded form of the enzyme. No intermediates between these two populations were detected. This conversion was accompanied by decreased activity, disruption of tertiary structure, a change in the mobility of the protein when subjected to SDS-polyacrylamide gel electrophoresis, and an increase in the apparent Stokes radius of the protein. After 2 h in 1% SDS at 20 degrees C, 25% of the subtilisin was still intact and active. The amount of protein existing in the unfolded form was increased by increasing the length of time in SDS, by increasing the concentration of SDS, and by increasing the temperature of the subtilisin-SDS solution. Analysis of the dependence of the rate of unfolding on SDS concentration indicated that one SDS micelle can destroy two protein molecules. The activation energy for the SDS-induced denaturation of aprA-subtilisin was 20 kcal mol-1, indicating that unfolding of the protein could be the rate-limiting step.     

Characterization of molten globule state of cytochrome c at alkaline, native and acidic pH induced by butanol and SDS

In our earlier communications, we had studied the acid induced unfolding of stem bromelain, glucose oxidase and fetuin [Eur. J. Biochem. 269 (2002) 47; Biochem. Biophys. Res. Comm. 303 (2003) 685; Biochim. Biophys. Acta 1649 (2003) 164] and effect of salts and alcohols on the acid unfolded state of alpha-chymotrypsinogen and stem bromelain [Biochim. Biophy. Acta 1481 (2000) 229; Arch. Biochem. Biophys. 413 (2) (2003) 199]. Here, we report the presence of molten globule like equilibrium intermediate state under alkaline, native and acid conditions in the presence of SDS and butanol. A systematic investigation of sodium dodecyl sulphate and butanol induced conformational alterations in alkaline (U(1)) and acidic (U(2)) unfolded states of horse heart ferricytochrome c was examined by circular dichroism (CD), tryptophan fluorescence and 1-anilino-8-napthalene sulfonate (ANS) binding. The cytochrome c (cyt c) at pH 9 and 2 shows the loss of approximately 61% and 65% helical secondary structure. Addition of increasing concentrations of butanol (0-7.2 M) and sodium dodecyl sulphate (0-5 mM) led to an increase in ellipticity value at 208 and 222 nm, which is the characteristic of formation of alpha-helical structure. Cyt c is a heme protein in which the tryptophan fluorescence is quenched in the native state by resonance energy transfer to the heme group attached to cystines at positions 14 and 17. At alkaline and acidic pH protein shows enhancement in tryptophan fluorescence and quenched ANS fluorescence. Addition of increasing concentration of butanol and SDS to alkaline or acid unfolded state leads to decrease in tryptophan and increase in ANS fluorescence with a blue shift in lambda(max), respectively. In the presence of 7.2 M butanol and 5 mM SDS two different intermediate states I(1) and I(2) were obtained at alkaline and acidic pH, respectively. States I(1) and I(2) have native like secondary structure with disordered side chains (loss of tertiary structure) as predicted from tryptophan fluorescence and high ANS binding. These results altogether imply that the butanol and SDS induced intermediate states at alkaline and acid pH lies between the unfolded and native state. At pH 6, in the presence of 7.2 M butanol or 5 mM SDS leads to the loss of CD bands at 208 and 222 nm with the appearance of trough at 228 nm also with increase in tryptophan and ANS fluorescence in contrast to native protein. This partially unfolded intermediate state obtained represents the folding pathway from native to unfolded structure. To summarize; the 7.2 M butanol and 5 mM SDS stabilizes the intermediate state (I(1) and I(2)) obtained at low and alkaline pH. While the same destabilizes the native structure of protein at pH 6, suggesting a difference in the mechanism of conformational stability.     

Equilibrium dissociation and unfolding of the Arc repressor dimer

The equilibrium unfolding reaction of Arc repressor, a dimeric DNA binding protein encoded by bacteriophage P22, can be monitored by fluorescence or circular dichroism changes. The stability of Arc is concentration dependent, and the unfolding reaction is well described as a two-state transition from folded dimer to unfolded monomer. The stability of the protein is decreased at low pH and increased by high salt concentration. The salt dependence suggests that two ions bind preferentially to the folded protein. In 10 mM potassium phosphate (pH 7.3) and 100 mM KCl, the unfolding free energy reaches a maximum near room temperature. The results suggest that at the low protein concentrations where operator DNA binding is normally measured, Arc is predominantly monomeric and unfolded.     

Escherichia coli OmpA retains a folded structure in the presence of sodium dodecyl sulfate due to a high kinetic barrier to unfolding.

Escherichia coli OmpA can be solubilized by sodium dodecyl sulfate (SDS) in its folded structure, and it unfolds upon heating. Although the heat-denatured OmpA remains unfolded after lowering the temperature, the addition of a non-ionic surfactant, octyl glucoside results in refolding of unfolded OmpA. In the present study, we investigated the refolding kinetics of OmpA in a mixed surfactant system of SDS and octyl glucoside using far- and near-UV circular dichroism and fluorescence spectroscopies. We found four kinetic phases in the refolding reaction, which logarithmically depended on the weight fraction of octyl glucoside. We also examined the unfolding kinetics of OmpA upon heating in the presence of SDS by temperature jump experiments. A comparison of the rate constants for the refolding and the unfolding reactions in SDS-only solution at 30 degrees C revealed that the folded form of OmpA in SDS solution is less stable than the unfolding form, and that the unfolding is virtually unobservable near room temperature due to a high kinetic barrier.     

Stabilization of partially folded states of cytochrome c in aqueous surfactant: effects of ionic and hydrophobic interactions

The interaction of submicellar concentrations of sodium dodecyl sulfate (SDS) with horse heart cytochrome c has been found to stabilize two spectroscopically distinct partially folded intermediates at pH 7. The first intermediate is formed by the interaction of SDS with native cytochrome c, and this intermediate retains the majority of the secondary structure while the tertiary structure of the protein is lost. The unfolding of this intermediate with urea leads to the formation of a second intermediate, which is also formed on refolding of the unfolded protein (unfolded by urea) by SDS. The second intermediate retains about 50% of the native secondary structure with no tertiary structure of the protein. The second intermediate was found to be absent at low pH. While induction of helical structure of a protein by SDS in the native condition has been reported earlier, this is possibly the first report of the refolding of a protein in a strongly denaturing condition (in the presence of 10 M urea). The relative contributions of the hydrophobic and the electrostatic interactions of the surfactants with cytochrome c have been determined from the formation of the molten globule species from the acid-induced unfolded protein in the presence of SDS or lauryl maltoside.     

Quantifying the kinetic stability of hyperstable proteins via time-dependent SDS trapping

Globular proteins are usually in equilibrium with unfolded conformations, whereas kinetically stable proteins (KSPs) are conformationally trapped by their high unfolding transition state energy. Kinetic stability (KS) could allow proteins to maintain their activity under harsh conditions, increase a protein's half-life, or protect against misfolding-aggregation. Here we show the development of a simple method for quantifying a protein's KS that involves incubating a protein in SDS at high temperature as a function of time, running the unheated samples on SDS-PAGE, and quantifying the bands to determine the time-dependent loss of a protein's SDS resistance. Six diverse proteins, including two monomer, two dimers, and two tetramers, were studied by this method, and the kinetics of the loss of SDS resistance correlated linearly with their unfolding rate determined by circular dichroism. These results imply that the mechanism by which SDS denatures proteins involves conformational trapping, with a trapping rate that is determined and limited by the rate of protein unfolding. We applied the SDS trapping of proteins (S-TraP) method to superoxide dismutase (SOD) and transthyretin (TTR), which are highly KSPs with native unfolding rates that are difficult to measure by conventional spectroscopic methods. A combination of S-TraP experiments between 75 and 90 °C combined with Eyring plot analysis yielded an unfolding half-life of 70 ± 37 and 18 ± 6 days at 37 °C for SOD and TTR, respectively. The S-TraP method shown here is extremely accessible, sample-efficient, cost-effective, compatible with impure or complex samples, and will be useful for exploring the biological and pathological roles of kinetic stability.     

Folding studies on muscle type of creatine kinase from Pelodiscus sinensis

A folding study of creatine kinase from Pelodiscus sinensis has not yet been reported. To gain more insight into structural and folding mechanisms of P. sinensis CK (PSCK), denaturants such as SDS, guanidine HCl, and urea were applied in this study. We purified PSCK from the muscle of P. sinensis and conducted inhibition kinetics with structural unfolding studies under various conditions. The results revealed that PSCK was completely inactivated at 1.8 mM SDS, 1.05 M guanidine HCl, and 7.5 M urea. The kinetics via time-interval measurements showed that the inactivation by SDS, guanidine HCl, and urea were all first-order reactions with kinetic processes shifting from monophase to biphase at increasing concentrations. With respect to tertiary structural changes, PSCK was unfolded in different ways; SDS increased the hydrophobicity but retained the most tertiary structural conformation, while guanidine HCl and urea induced conspicuous changes in tertiary structures and initiated kinetic unfolding mechanisms. Our study provides information regarding PSCK and enhances our knowledge of the reptile-derived enzyme folding.     

Sodium dodecyl sulfate polyacrylamide gel electrophoresis as a method for studying the stability of subtilisin

A simple method has been developed to study the stability of subtilisin. Protein incubated at various temperatures in the presence of proteinase inhibitor was subjected to sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and showed a transition from the intact state to the unfolded state between 55 degrees C and 65 degrees C. Additionally, autolysis was also observed above 65 degrees C. In the absence of inhibitor, similar results were obtained below 55 degrees C; however, above 65 degrees C no protein of any size was observed due to extensive autolysis. These results demonstrate that SDS-PAGE can trap subtilisin in the state in which the protein existed prior to the analysis. It can be used to identify the different forms, including autolysis products, of the protein generated by heat denaturation. This method was used to study SDS-induced unfolding of aprA-subtilisin. When the protein was incubated with 0.25% SDS at different NaCl concentrations, a gradual increase in unfolding was observed with increasing NaCl concentration. This change paralleled a decrease in the critical micelle concentration of SDS, indicating that the rate of unfolding of aprA-subtilisin increases with increasing SDS micelle concentration. No detectable unfolding was observed below the critical micelle concentration.     

Stability of fungal α-amylase in sodium dodecylsulfate

Unfolding of a fungal -amylase in aqueous sodium dodecylsulfate (SDS) solution was examined by SDS-polyacrylamide gel electrophoresis (PAGE). When the -amylase was incubated with 1% SDS at room temperature and subjected to SDS-PAGE, it showed a much higher mobility than expected from the molecular weight. Circular dichroic and gel filtration analyses indicated that the protein is apparently in the native conformation upon incubation with 1% SDS. When the protein was heated in the presence of 1% SDS at 90°C for 10 min, it had a lower mobility in SDS-PAGE and showed characteristics of an unfolded protein by circular dichroism and gel filtration. The melting temperatures of the protein were determined in the absence and presence of SDS by incubating it for 10 min at various temperatures. The melting temperatures were 70, 55, and 49°C in the presence of 0, 1, and 2% SDS, respectively. The observed small shift of the melting temperatures by SDS suggests that the destabilizing action of SDS on the -amylase is weak. However, the unfolding in SDS is not reversible process, since prolonged incubation of the protein with 1% SDS at 50°C gradually increased the amount of unfolded protein. This indicates that the SDS-induced unfolding of the -amylase is a slow process.     

Kinetic traps in the folding/unfolding of procaspase-1 CARD domain

We have examined the folding and unfolding of the caspase recruitment domain of procaspase-1 (CP1-CARD), a member of the alpha-helical Greek key protein family. The equilibrium folding/unfolding of CP1-CARD is described by a two-state mechanism, and the results show CP1-CARD is marginally stable with a DeltaG(H2O) of 1.1 +/- 0.2 kcal/mole and an m-value of 0.65 +/- 0.06 kcal/mole/M (10 mM Tris-HCl at pH 8.0, 1 mM DTT, 25 degrees C). Consistent with the equilibrium folding data, CP1-CARD is a monomer in solution when examined by size exclusion chromatography. Single-mixing stopped-flow refolding and unfolding studies show that CP1-CARD folds and unfolds rapidly, with no detectable slow phases, and the reactions appear to reach equilibrium within 10 msec. However, double jump kinetic experiments demonstrate the presence of an unfolded-like intermediate during unfolding. The intermediate converts to the fully unfolded conformation with a half-time of 10 sec. Interrupted refolding studies demonstrate the presence of one or more nativelike intermediates during refolding, which convert to the native conformation with a half-time of about 60 sec. Overall, the data show that both unfolding and refolding processes are slow, and the pathways contain kinetically trapped species.     

Probing membrane protein unfolding with pulse proteolysis

Technical challenges have greatly impeded the investigation of membrane protein folding and unfolding. To develop a new tool that facilitates the study of membrane proteins, we tested pulse proteolysis as a probe for membrane protein unfolding. Pulse proteolysis is a method to monitor protein folding and unfolding, which exploits the significant difference in proteolytic susceptibility between folded and unfolded proteins. This method requires only a small amount of protein and, in many cases, may be used with unpurified proteins in cell lysates. To evaluate the effectiveness of pulse proteolysis as a probe for membrane protein unfolding, we chose Halobacterium halobium bacteriorhodopsin (bR) as a model system. The denaturation of bR in SDS has been investigated extensively by monitoring the change in the absorbance at 560 nm (A₅₆₀). In this work, we demonstrate that denaturation of bR by SDS results in a significant increase in its susceptibility to proteolysis by subtilisin. When pulse proteolysis was applied to bR incubated in varying concentrations of SDS, the remaining intact protein determined by electrophoresis shows a cooperative transition. The midpoint of the cooperative transition (C_m) shows excellent agreement with that determined by A₅₆₀. The C_m values determined by pulse proteolysis for M56A and Y57A bRs are also consistent with the measurements made by A₅₆₀. Our results suggest that pulse proteolysis is a quantitative tool to probe membrane protein unfolding. Combining pulse proteolysis with Western blotting may allow the investigation of membrane protein unfolding in situ without overexpression or purification.     

Detection and characterization of partially unfolded oligomers of the SH3 domain of alpha-spectrin

For the purpose of equilibrium and kinetic folding-unfolding studies, the SH3 domain of alpha-spectrin (spc-SH3) has long been considered a classic two-state folding protein. In this work we have indeed observed that the thermal unfolding curves of spc-SH3 measured at pH 3.0 by differential scanning calorimetry, circular dichroism, and NMR follow apparently the two-state model when each unfolding profile is considered individually. Nevertheless, we have found that protein concentration has a marked effect upon the thermal unfolding profiles. This effect cannot be properly explained in terms of the two-state unfolding model and can only be interpreted in terms of the accumulation of intermediate associated states in equilibrium with the monomeric native and unfolded states. By chemical cross-linking and pulsed-field gradient NMR diffusion experiments we have been able to confirm the existence of associated states formed during spc-SH3 unfolding. A three-state model, in which a dimeric intermediate state is assumed to be significantly populated, provides the simplest interpretation of the whole set of thermal unfolding data and affords a satisfactory explanation for the concentration effects observed. Whereas at low concentrations the population of the associated intermediate state is negligible and the unfolding process consequently takes place in a two-state fashion, at concentrations above approximately 0.5 mM the population of the intermediate state becomes significant at temperatures between 45 degrees C and 80 degrees C and reaches up to 50% at the largest concentration investigated. The thermodynamic properties of the intermediate state implied by this analysis fall in between those of the unfolded state and the native ones, indicating a considerably disordered conformation, which appears to be stabilized by oligomerization.     

Neutron scattering studies of nucleosome structure at low ionic strength

Ionic strength studies using homogeneous preparations of chicken erythrocyte nucleosomes containing either 146 or 175 base pairs of DNA show a single unfolding transition at about 1.5 mM ionic strength as determined by small-angle neutron scattering. The transition seen by some investigators at between 2.9 and 7.5 mM ionic strength is not observed by small-angle neutron scattering in either type of nucleosome particle. The two contrasts measured (H2O and D2O) indicate that only small conformational changes occur in the protein core, but the DNA is partially unfolded below the transition point. Patterson inversion of the data and analysis of models indicate that the DNA in both types of particle is unwinding from the ends, leaving about one turn of supercoiled DNA bound to the histone core in approximately its normal (compact) conformation. The mechanism of unfolding appears to be similar for both types of particles and in both cases occurs at the same ionic strength. The unfolding observed for nucleosomes in this study is in definite disagreement with extended superhelical models for the DNA and also disagrees with models incorporating an unfolded histone core.     

The effect of metals on SDS-induced partially folded states of CopC

In this work, the unfolding of CopC was used to elucidate details of the protein structure through different spectroscopic techniques. The interactions of CopC and its mutants with the anionic surfactant sodium dodecyl sulfate (SDS), guanidinium hydrochloride, and urea were monitored by fluorescence spectroscopy, far-UV circular dichroism spectroscopy, and fluorescence lifetime measurements. The interaction of SDS with CopC resulted in the formation of a partially folded intermediate. In this intermediate, the structure of the C-terminal is unfolded, whereas the N-terminal retains the native structure. Further, we have explored the effects of metals on the intermediate in aqueous surfactant. The results suggested that the Ag⁺ ion has a large effect on the unfolding induced by SDS. In addition, the binding capacity of the different unfolding degree protein toward Cu²⁺ indicated the high stability of the N-terminal. The protein–Cu²⁺ unfolding induced by guanidinium hydrochloride and urea caused the binding of Cu²⁺ to increase the stability of the N-terminal, which resulted in an intermediate in the unfolding process. The first transition corresponded to unfolding of the C-terminal, and the second transition was attributed to unfolding of the N-terminal. Furthermore, the anisotropy decay indicated that the motion of tryptophan occurred at a higher urea concentration, which suggested the high stability of the N-terminal. Steered molecular dynamics simulations also indicated that the structure of the N-terminal was rigid.     

Interaction of riboflavin binding protein with riboflavin, quinacrine, chlorpromazine and daunomycin

1. circular dichroism and fluorescence measurements were used to study the reversible unfolding of riboflavin-riboflavin binding protein complex. Both methods showed that the complex was unfolded according to the two-state model. 2. The results suggest that riboflavin was strongly bound in the hydrophobic cleft of the protein and that it could not be dislodged by TFE, MeOH or SDS without major unfolding of the unique tertiary structure of the protein. 3. In addition, it has been also shown that quinacrine, chlorpromazine and daunomycin did not form stereospecific complexes with riboflavin binding protein.     

Equilibrium and kinetic folding of an alpha-helical Greek key protein domain: caspase recruitment domain (CARD) of RICK

We have characterized the equilibrium and kinetic folding of a unique protein domain, caspase recruitment domain (CARD), of the RIP-like interacting CLARP kinase (RICK) (RICK-CARD), which adopts a alpha-helical Greek key fold. At equilibrium, the folding of RICK-CARD is well described by a two-state mechanism representing the native and unfolded ensembles. The protein is marginally stable, with a DeltaG(H)()2(O) of 3.0 +/- 0.15 kcal/mol and an m-value of 1.27 +/- 0.06 kcal mol(-1) M(-1) (30 mM Tris-HCl, pH 8, 1 mM DTT, 25 degrees C). While the m-value is constant, the protein stability decreases in the presence of moderate salt concentrations (below 200 mM) and then increases at higher salt concentrations. The results suggest that electrostatic interactions are stabilizing in the native protein, and the favorable Coulombic interactions are reduced at low ionic strength. Above 200 mM salt, the results are consistent with Hofmeister effects. The unfolding pathway of RICK-CARD is complex and contains at least three non-native conformations. The refolding pathway of RICK-CARD also is complex, and the data suggest that the unfolded protein folds via two intermediate conformations prior to reaching the native state. Overall, the data suggest the presence of kinetically trapped, or misfolded, species that are on-pathway both in refolding and in unfolding.     

Equilibrium unfolding of a small low-potential cytochrome, cytochrome c553 from Desulfovibrio vulgaris.

To understand general aspects of stability and folding of c-type cytochromes, we have studied the folding characteristics of cytochrome c553 from Desulfovibrio vulgaris (Hildenborough). This cytochrome is structurally similar but lacks sequence homology to other heme proteins; moreover, it has an abnormally low reduction potential. Unfolding of oxidized and reduced cytochrome c553 by guanidine hydrochloride (GuHCl) was monitored by circular dichroism (CD) and Soret absorption; the same unfolding curves were obtained with both methods supporting that cytochrome c553 unfolds by an apparent two-state process. Reduced cytochrome c553 is 7(3) kJ/mol more stable than the oxidized form; accordingly, the reduction potential of unfolded cytochrome c553 is 100(20) mV more negative than that of the folded protein. In contrast to many other unfolded cytochrome c proteins, upon unfolding at pH 7.0 both oxidized and reduced heme in cytochrome c553 become high-spin. The lack of heme misligation in unfolded cytochrome c553 implies that its unfolded structure is less constrained than those of cytochromes c with low-spin, misligated hemes.     

Unfolding pathways of goat alpha-lactalbumin as revealed in multiple alignment of molecular dynamics trajectories

Molecular dynamics simulations of protein unfolding were performed at an elevated temperature for the authentic and recombinant forms of goat alpha-lactalbumin. Despite very similar three-dimensional structures, the two forms have significantly different unfolding rates due to an extra N-terminal methionine in the recombinant protein. To identify subtle differences between the two forms in the highly stochastic kinetics of unfolding, we classified the unfolding trajectories using the multiple alignment method based on the analogy between the biological sequences and the molecular dynamics trajectories. A dendrogram derived from the multiple trajectory alignment revealed a clear difference in the unfolding pathways of the authentic and recombinant proteins, i.e. the former reached the transition state in an all-or-none manner while the latter unfolded less cooperatively. It was also found in the classification that the two forms of the protein shared a common transition state structure, which was in excellent agreement with the transition state structure observed experimentally in the Phi-value analysis.     

Comparison between denaturant- and temperature-induced unfolding pathways of protein: a lattice Monte Carlo simulation

Denaturant-induced unfolding of protein is simulated by using a Monte Carlo simulation with a lattice model for protein and denaturant. Following the binding theory for denaturant-induced unfolding, the denaturant molecules are modeled to interact with protein by nearest-neighbor interactions. By analyzing the conformational states on the unfolding pathway of protein, the denaturant-induced unfolding pathway is compared with the temperature-induced unfolding pathway under the same condition; that is, the free energies of unfolding under two different pathways are equal. The two unfoldings show markedly different conformational distributions in unfolded states. From the calculation of the free energy of protein as a function of the number fraction (Q0) of native contacts relative to the total number of contacts, it is found that the free energy of the largely unfolded state corresponding to low Q0 (0.1 < Q0 < 0.5) under temperature-induced unfolding is lower than that under denaturant-induced unfolding, whereas the free energy of the unfolded state close to the native state (Q0 > 0.5) is lower in denaturant-induced unfolding than in temperature-induced unfolding. A comparison of two unfolding pathways reveals that the denaturant-induced unfolding shows a wider conformational distribution than the temperature-induced unfolding, while the temperature-induced unfolding shows a more compact unfolded state than the denaturant-induced unfolding especially in the low Q0 region (0.1 < Q0 < 0.5).     

Unfolding study of a trimeric membrane protein AcrB

The folding of a multi‐domain trimeric α‐helical membrane protein, Escherichia coli inner membrane protein AcrB, was investigated. AcrB contains both a transmembrane domain and a large periplasmic domain. Protein unfolding in sodium dodecyl sulfate (SDS) and urea was monitored using the intrinsic fluorescence and circular dichroism spectroscopy. The SDS denaturation curve displayed a sigmoidal profile, which could be fitted with a two‐state unfolding model. To investigate the unfolding of separate domains, a triple mutant was created, in which all three Trp residues in the transmembrane domain were replaced with Phe. The SDS unfolding profile of the mutant was comparable to that of the wild type AcrB, suggesting that the observed signal change was largely originated from the unfolding of the soluble domain. Strengthening of trimer association through the introduction of an inter‐subunit disulfide bond had little effect on the unfolding profile, suggesting that trimer dissociation was not the rate‐limiting step in unfolding monitored by fluorescence emission. Under our experimental condition, AcrB unfolding was not reversible. Furthermore, we experimented with the refolding of a monomeric mutant, AcrB_Δloop, from the SDS unfolded state. The CD spectrum of the refolded AcrB_Δloop superimposed well onto the spectra of the original folded protein, while the fluorescence spectrum was not fully recovered. In summary, our results suggested that the unfolding of the trimeric AcrB started with a local structural rearrangement. While the refolding of secondary structure in individual monomers could be achieved, the re‐association of the trimer might be the limiting factor to obtain folded wild‐type AcrB.