Low concentrations of guanidinium chloride expose apolar surfaces and cause differential perturbation in catalytic intermediates of rhodanese

The conformations of sulfur-free and sulfur-containing rhodanese were followed with and without the detergent lauryl maltoside after guanidinium chloride (GdmCl) addition to 5 M to study the apparent irreversibility of denaturation. Without lauryl maltoside, sulfur-containing rhodanese denatured in a transition giving, at approximately 2.3 M GdmCl, 50% of the total denaturation induced change observed by activity, CD, or intrinsic fluorescence. Sulfur-free rhodanese gave more complex behavior by intrinsic fluorescence and CD. CD showed loss of secondary structure in a broad, complex, and apparently biphasic transition extending from 0.5 to 3 M GdmCl. The interpretation of the transition was complicated by time-dependent aggregation due to noncovalent interactions. Results with the apolar fluorescence probe 2-anilinonaphthalene-8-sulfonic acid, implicated apolar exposure in aggregation. Sulfhydryl reactivity indicated that low GdmCl concentrations induced intermediates affecting the active site conformation. Lauryl maltoside prevented aggregation with no effect on activity or any conformational parameter of native enzyme. Transitions induced by GdmCl were still observed and consistent with several phases. Even in lauryl maltoside, an increase in apolar exposure was detected by 2-anilinonaphthalene-8-sulfonic acid, and by protein adsorption to octyl-Sepharose well below the major unfolding transitions. These results are interpreted with a model in which apolar interdomain interactions are disrupted, thereby increasing active site accessibility, before the intradomain interactions.     

Stable intermediates can be trapped during the reversible refolding of urea-denatured rhodanese

The enzyme rhodanese (EC 2.8.1.1) could be reversibly refolded from urea in the presence of lauryl maltoside, beta-mercaptoethanol, and sodium thiosulfate. The unfolding/folding transition monitored using intrinsic fluorescence was resolved into two two-state transitions with midpoints at 3.6 and 5.0 M urea. The analysis assumed an intermediate with an emission maximum at 345 nm. Monitoring anisotropy of intrinsic fluorescence also gave an asymmetric transition. Activity followed one two-state transition centered at 3.6 M urea with no major change of secondary structure. Without thiosulfate or mercaptoethanol, there was one two-state transition at 5.0 M urea giving a species, in dilute urea, with a fluorescence maximum at 345 nm. This intermediate slowly relaxed toward 335 nm (t1/2 = 85 min) if only thiosulfate was absent but without regaining activity. Subsequent addition of thiosulfate led to a first-order recovery of activity (t1/2 = 75 min). Thus, a possible folding intermediate can be trapped which displays increased access of water and solutes to its fluorescent tryptophans. This intermediate conformer, which is flexible, has considerable secondary structure, is inactive, has exposed hydrophobic surfaces, and requires specific reducing conditions to regain full activity. Refolding probably involves an initial, rapid, hydrophobic collapse with acquisition of secondary structure to form the intermediate, followed by slower adjustment to the native global conformation. Final reactivation requires reduction localized at the active site.     

Detergent-assisted refolding of guanidinium chloride-denatured rhodanese. The effect of lauryl maltoside

For the first time, the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase; EC 2.8.1.1) has been renatured from 6 M guanidinium chloride (GdmCl) by direct dilution of the denaturant at relatively high protein concentrations. This has been made possible by using the nonionic detergent dodecyl-beta-D-maltoside (lauryl maltoside). Lauryl maltoside concentration dependence of the renaturation and reactivation time courses were studied using 50 micrograms/ml rhodanese. There was no renaturation at lauryl maltoside (less than 0.1 mg/ml), and the renaturability increased, apparently cooperatively, up to 5 mg/ml detergent. This may reflect weak binding of lauryl maltoside to intermediate rhodanese conformers. The renaturability began to decrease above 5 mg/ml lauryl maltoside and was significantly reduced at 20 mg/ml. Individual progress curves of product formation, for rhodanese diluted into lauryl maltoside 90 min before assay, showed induction phases as long as 7 min before an apparently linear steady state. The induction phase increased with lauryl maltoside concentration and could even be observed in native controls above 1 mg/ml detergent. These results are consistent with suggestions that refolding of GdmCl-denatured rhodanese involves an intermediate with exposed hydrophobic surfaces that can partition into active and inactive species. Further, lauryl maltoside can stabilize those surfaces and prevent aggregation and other hydrophobic interaction-dependent events that reduce the yield of active protein. The rhodanese-lauryl maltoside complex could also form with native enzyme, thus explaining the induction phase with this species. Finally, it is suggested that renaturation of many proteins might be assisted by lauryl maltoside or other "nondenaturing" detergents.     

The detection of kinetic intermediate(s) during refolding of rhodanese

Recent studies showed that the enzyme rhodanese could be reversibly unfolded in guanidinium chloride (GdmCl) if aggregation and oxidation were minimized. Further, these equilibrium studies suggested the presence of intermediate(s) during refolding (Tandon, S., and Horowitz, P. (1989) J. Biol. Chem. 264, 9859-9866). The present work shows that native and refolded enzymes are very similar in structural and functional characteristics. Kinetics of denaturation/renaturation were used to detect the folding intermediate(s). The shift in fluorescence wavelength maximum was used to monitor the structural changes during the process. First order plots of the structural changes during unfolding and refolding show nonlinear curves. The refolding occurs in at least two phases. The first phase is very fast (t1/2 much less than 30 s) and accounts for the partial regain in the structure but not in the activity. The second phase is slow (t1/2 = 2.9 h) during which the enzyme fully regains its structure along with the activity. The fractional renaturation of rhodanese due to the fast phase, monitored in various concentrations of GdmCl, describes a transition centered at 3.5 M GdmCl which is very similar to the higher of the two transitions observed in the reversible refolding. All of these findings support the presence of detectable intermediate(s) during folding of rhodanese.     

Acid pH-induced conformational changes in bovine liver rhodanese.

The enzyme rhodanese is greatly stabilized in the range pH 4-6, and samples at pH 5 are fully active after several days at 23 degrees C. This is very different from results at pH greater than 7, where there is significant loss of activity within 1 h. A pH-dependent conformational change occurs below pH 4 in a transition centered around pH 3.25 that leads slowly to inactive rhodanese at pH 3 (t 1/2 = 22 min at pH3). The inactive rhodanese can be reactivated by incubation under conditions required for detergent-assisted refolding of denatured rhodanese. The inactive enzyme at pH 3 has the maximum of its intrinsic fluorescence spectrum shifted to 345 nm from 335 nm, which is characteristic of native rhodanese at pH greater than 4. At pH 3, rhodanese shows increased exposure of organized hydrophobic surfaces as measured by 1,1'-bis(4-anilino)naphthalene-5,5'-disulfonic acid binding. The secondary structure is maintained over the entire pH range studied (pH 2-7). Fluorescence anisotropy measurements of the intrinsic fluorescence provide evidence suggesting that the pH transition produces a state that does not display greatly increased average flexibility at tryptophan residues. Pepsin digestibility of rhodanese follows the pH dependence of conformational changes reported by activity and physical methods. Rhodanese is resistant to proteolysis above pH 4 but becomes increasingly susceptible as the pH is lowered. The form of the enzyme at pH 3 is cleaved at discrete sites to produce a few large fragments. It appears that pepsin initially cleaves close to one end of the protein and then clips at additional sites to produce species of a size expected for the individual domains into which rhodanese is folded. Overall, it appears that in the pH range between pH 3 and 4, titration of groups on rhodanese leads to opening of the structure to produce a conformation resembling, but more rigid than, the molten globule state that is observed as an intermediate during reversible unfolding of rhodanese.     

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.     

Thermally perturbed rhodanese can be protected from inactivation by self-association

A fluorescence-detected structural transition occurs in the enzyme rhodanese between 30–40°C that leads to inactivation and aggregation, which anomalously decrease with increasing protein concentration. Rhodanese at 8 µg/ml is inactivated at 40°C after 50 min of incubation, but it is protected as its concentration is raised, such that above 200 µg/ml, there is only slight inactivation for at least 70 min. Inactivation is increased by lauryl maltoside, or by low concentrations of 2-mercaptoethanol. The enzyme is protected by high concentrations of 2-mercaptoethanol or by the substrate, thiosulfate. The fluorescence of 1,8-anilinonaphthalene sulfonate reports the appearance of hydrophobic sites between 30–40°C. Light scattering kinetics at 40°C shows three phases: an initial lag, a relatively rapid increase, and then a more gradual increase. The light scattering decreases under several conditions: at increased protein concentration; at high concentrations of 2-mercaptoethanol; with lauryl maltoside; or with thiosulfate. Aggregated enzyme is inactive, although enzyme can inactivate without significant aggregation. Gluteraldehyde cross-linking shows that rhodanese can form dimers, and that higher molecular weight species are formed at 40°C but not at 23°;C. Precipitates formed at 40°C contain monomers with disulfide bonds, dimers, and multimers. We propose that thermally perturbed rhodanese has increased hydrophobic exposure, and it can either: (a) aggregate after a rate-limiting inactivation; or (b) reversibly dimerize and protect itself from inactivation and the formation of large aggregates.     

Characterization of a molten globule state of bovine carbonic anhydrase III: loss of asymmetrical environment of the aromatic residues has a profound effect on both the near- and far-UV CD spectrum

Bovine muscle carbonic anhydrase (isoenzyme III; BCAIII) exhibited a three-state unfolding process at equilibrium upon denaturation in guanidine hydrochloride (GuHCl). The stable folding intermediate appeared to be of molten globule type. The stability towards GuHCl in terms of mid-point concentrations of denaturation were very similar for BCAIII and human CAII (HCAII). It was further demonstrated that the aromatic amino acid residues contributed significantly to the circular dichroism (CD) spectrum in the far-UV wavelength region during the native-->molten globule state transition. Thus, the ellipiticity change at 218 nm was shown to monitor the loss of tertiary interactions of aromatic side chains at the first unfolding transition as well as the rupture of secondary structure at the second unfolding transition. Similar aromatic contributions to the far-UV CD spectrum, but with varying magnitudes, were also noted for BCAII and HCAII, further emphasizing that interference of aromatic residues should not be neglected at wavelengths that normally are assigned to secondary structural changes.     

Human glycine N-methyltransferase is unfolded by urea through a compact monomer state

Human recombinant glycine N-methyltransferase (GNMT) unfolding by urea was studied by enzyme activity, size-exclusion chromatography, fluorescence spectroscopy, and circular dichroism. Urea unfolding of GNMT is a two-step process. The first transition is a reversible dissociation of the GNMT tetramer to compact monomers in 1.0-3.5M urea with enzyme inactivation. The compact monomers were characterized by Stokes radius (R(s)) of 40.7A equal to that of globular proteins with the same molecular mass as GNMT monomers, absence of exposure of tryptophan residues into solvent, and presence of about 50% of secondary structure of native protein. The second step of GNMT unfolding is a reversible transition of monomers from compact to a fully unfolded state with R(s) of 50A, exposed tryptophan residues, and disrupted secondary structure in 8M urea.     

Involvement of cysteine residues and domain interactions in the reversible unfolding of lipoxygenase-1

Urea-induced unfolding of lipoxygenase-1 (LOX1) at pH 7.0 was followed by enzyme activity, spectroscopic measurements, and limited proteolysis experiments. Complete unfolding of LOX1 in 9 M urea in the presence of thiol reducing or thiol modifying reagents was observed. The aggregation and oxidative reactions prevented the reversible unfolding of the molecule. The loss of enzyme activity was much earlier than the structural loss of the molecule during the course of unfolding, with the midpoint concentrations being 4.5 and 7.0 M for activity and spectroscopic measurements, respectively. The equilibrium unfolding transition could be adequately fitted to a three-state, two-step model (N left arrow over right arrow I left arrow over right arrow U) and the intermediate fraction was maximally populated at 6.3 M urea. The free energy change (DeltaG(H(2)O)) for the unfolding of native (N) to intermediate (I) was 14.2 +/- 0.28 kcal/mol and for the intermediate to the unfolded state (U) was 11.9 +/- 0.12 kcal/mol. The ANS binding measurements as a function of urea concentration indicated that the maximum binding of ANS was in 6.3 M urea due to the exposure of hydrophobic groups; this intermediate showed significant amount of tertiary structure and retained nearly 60% of secondary structure. The limited proteolysis measurements showed that the initiation of unfolding was from the C-terminal domain. Thus, the stable intermediate observed could be the C-terminal domain unfolded with exposed hydrophobic domain-domain interface. Limited proteolysis experiments during refolding process suggested that the intermediate refolded prior to completely unfolded LOX1. These results confirmed the role of cysteine residues and domain-domain interactions in the reversible unfolding of LOX1. This is the first report of the reversible unfolding of a very large monomeric, multi-domain protein, which also has a prosthetic group.     

Local and long-range interactions in the thermal unfolding transition of bovine pancreatic ribonuclease A

This research was undertaken to distinguish between local and global unfolding in the reversible thermal denaturation of bovine pancreatic ribonclease A (RNase A). Local unfolding was monitored by steady-state and time-resolved fluorescence of nine mutants in each of which a single tryptophan was substituted for a wild-type residue. Global unfolding was monitored by far-UV circular dichroism and UV absorbance. All the mutants (except F8W and D38W) exhibited high specific enzymatic activity, and their far-UV CD spectra were very close to that of wild-type RNase A, indicating that the tryptophan substitutions did not affect the structure of any of the mutants (excluding K1W and Y92W) under folding conditions at 20 degrees C. Like wild-type RNase A, the various mutants exhibited reversible cooperative thermal unfolding transitions at pH 5, with transition temperatures 2.5-11 degrees C lower than that of the wild-type transition, as detected by far-UV CD or UV absorbance. Even at 80 degrees C, well above the cooperative transition of all the RNase A mutants, a considerable amount of secondary and tertiary structure was maintained. These studies suggest the following two-stage mechanism for the thermal unfolding transition of RNase A as the temperature is increased. First, at temperatures lower than those of the main cooperative transition, long-range interactions within the major hydrophobic core are weakened, e.g., those involving residues Phe-8 (in the N-terminal helix) and Lys-104 and Tyr-115 (in the C-terminal beta-hairpin motif). The structure of the chain-reversal loop (residues 91-95) relaxes in the same temperature range. Second, the subsequent higher-temperature cooperative unfolding transition is associated with a loss of secondary structure and additional changes in the tertiary contacts of the major hydrophobic core, e.g., those involving residues Tyr-73, Tyr-76, and Asp-38 on the other side of the molecule. The hydrophobic interactions of the C-terminal loop of the protein are enhanced by high temperature, and perhaps are responsible for the preservation of the local structural environment of Trp-124 at temperatures slightly above the major cooperative transition. The results shed new light on the thermal unfolding transitions, generally supporting the thermal unfolding hypothesis of Burgess and Scheraga, as modified by Matheson and Scheraga.     

Micelle-assisted protein folding. Denatured rhodanese binding to cardiolipin-containing lauryl maltoside micelles results in slower refolding kinetics but greater enzyme reactivation.

Unfolded (inactive) rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) can be reactivated in the presence of detergents, e.g. lauryl maltoside (LM). Here, we report the reactivation of urea-unfolded rhodanese in the presence of mixed micelles containing LM and the anionic mitochondrial phospholipid, cardiolipin (CL). Reactivation times increased as the number of CL molecules/micelle was increased. A maximum of 94% of the activity was recovered at 2.2 CL/micelle. Only 71% of the activity was recovered in the absence of CL. The major zwitterionic mitochondrial phospholipid, phosphatidylcholine (PC), had no effect on the LM-assisted reactivation of rhodanese. Size exclusion chromatography showed that denatured, but not native, rhodanese apparently binds to micellar amounts of LM and CL/LM, but not to PC/LM micelles. The lifetime of the enzyme-micelle complex increased with the number of CL molecules/micelle. Furthermore, chromatographic fractions containing micelle-bound enzyme had no activity, while renatured rhodanese-containing fractions were active. These results suggest that transient complexes form between enzyme and both LM and CL/LM micelles, and that this complex formation may be necessary for reactivation. For CL/LM micelles, interactions may occur between the positively charged amino-terminal sequence of rhodanese and the negatively charged CL phosphate. Finally, this work shows that there are similarities between "micelle-assisted" and chaperonin-assisted rhodanese refolding.     

Reducing sugars can induce the oxidative inactivation of rhodanese.

The enzyme rhodanese (thiosulfate sulfurtransferase, EC 2.8.1.1) is inactivated on incubation with reducing sugars such as glucose, mannose, or fructose, but is stable with non-reducing sugars or related polyhydroxy compounds. The enzyme is inactivated with (ES) or without (E) the transferable sulfur atom, although E is considerably more sensitive, and inactivation is accentuated by cyanide. Inactivation of E is accompanied by increased proteolytic susceptibility, a decreased sulfhydryl titer, a red-shift and quenching of the protein fluorescence, and the appearance of hydrophobic surfaces. Superoxide dismutase and/or catalase protect rhodanese. Inactive enzyme can be partially reactivated during assay and almost completely reactivated by incubation with thiosulfate, lauryl maltoside, and 2-mercaptoethanol. These results are similar to those observed when rhodanese is inactivated by hydrogen peroxide. These observations, as well as the cyanide-dependent, oxidative inactivation by phenylglyoxal, are explained by invoking the formation of reactive oxygen species such as superoxide or hydrogen peroxide from autooxidation of alpha-hydroxy carbonyl compounds, which can be facilitated by cyanide.     

Alteration around the active site of rhodanese during urea-induced denaturation and its implications for folding

The enzyme rhodanese contains two globular domains connected by a tether region and associated by strong hydrophobic interactions. The protein has proven to be very difficult to refold without assistance to prevent oxidation and aggregation. For this study, the active site cysteine 247, near the interdomain region, was modified with the environmentally sensitive fluorescent probe, 2-(4'-(iodoacetamido)anilino)naphthalene-6-sulfonic acid (IAANS), to yield a derivative that reversibly unfolds. Structural transitions during urea unfolding/refolding were complex and multiphasic. Increasing urea concentrations increased the IAANS fluorescence intensity and polarization. Both values reached maxima at approximately 4 m urea, where there is a concomitant large exposure of hydrophobic sites as reported by both IAANS and the noncovalent fluorescent probe, bis-ANS. The exposure of the hydrophobic sites arises from the decrease in strong interaction between the domain interfaces, which lead to their partial separation. This correlates with the loss of activity of the unlabeled enzyme. Above 4.5 m urea, there is progressive loss of rigid, hydrophobic surfaces, and both fluorescence and polarization of IAANS decrease, with accompanying loss of secondary structure. These results are consistent with a folding model in which there is an initial, rapid hydrophobic collapse of the denatured form to an intermediate with native like secondary structure, with exposed interdomain, hydrophobic surfaces. This step is followed by adjustment of the domain-domain interactions and the proper positioning of reduced cysteine 247 at the active site.     

Unassisted refolding of urea unfolded rhodanese

In vitro refolding after urea unfolding of the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) normally requires the assistance of detergents or chaperonin proteins. No efficient, unassisted, reversible unfolding/folding transition has been demonstrated to date. The detergents or the chaperonin proteins have been proposed to stabilize folding intermediates that kinetically limit folding by aggregating. Based on this hypothesis, we have investigated a number of experimental conditions and have developed a protocol for refolding, without assistants, that gives evidence of a reversible unfolding transition and leads to greater than 80% recovery of native enzyme. In addition to low protein concentration (10 micrograms/ml), low temperatures are required to maximize refolding. Otherwise optimal conditions give less than 10% refolding at 37 degrees C, whereas at 10 degrees C the recovery approaches 80%. The unfolding/refolding phases of the transition curves are most similar in the region of the transition, and refolding yields are significantly reduced when unfolded rhodanese is diluted to low urea concentrations, rather than to concentrations near the transition region. This is consistent with the formation of "sticky" intermediates that can remain soluble close to the transition region. Apparently, nonnative structures, e.g. aggregates, can form rapidly at low denaturant concentrations, and their subsequent conversion to the native structure is slow.     

Characterization of the unfolding of ribonuclease A in aqueous methanol solvents

The effect of methanol on the thermal denaturation of ribonuclease A has been investigated over the -40 to 70 degrees C range. The transition was fully reversible to at least 60% (v/v) methanol at an apparent pH of cryosolvent (pH) of 3.0 and was examined at methanol concentrations as high as 80%. The unfolding transition, as monitored by absorbance change at 286 nm, became progressively broader and occurred at increasingly lower temperatures as the alcohol concentration increased. In 50% methanol, increasing the pH from 2 to 6 shifted the transition to higher temperature. A substantial decrease in cooperativity was noted at the more acidic conditions. On the other hand, increasing concentrations of guanidine hydrochloride in 50% methanol caused the transition to shift to lower temperatures with little effect on the cooperativity. The observed effects on the cooperativity of the unfolding transition suggest that methanol and lower temperatures may increase the concentration of partially folded intermediate states in the unfolding of ribonuclease. Comparison of the transition in 50% methanol as determined by absorbance or fluorescence, which monitor the degree of exposure of buried tyrosines and hence the tertiary structure, to that determined by far-UV circular dichroism, which monitors secondary structure, indicated that the major unfolding transition occurred at a higher temperature in the latter case. Thus, the tertiary structure is lost at a lower temperature than the secondary structure. This observation is consistent with a model of protein folding in which initially formed regions of secondary structure pack together, predominantly by hydrophobic interactions, to give the tertiary structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiple-probe analysis of folding and unfolding pathways of human serum albumin. Evidence for a framework mechanism of folding.

The changes in the far-UV CD signal, intrinsic tryptophan fluorescence and bilirubin absorbance showed that the guanidine hydrochloride (GdnHCl)-induced unfolding of a multidomain protein, human serum albumin (HSA), followed a two-state process. However, using environment sensitive Nile red fluorescence, the unfolding and folding pathways of HSA were found to follow a three-state process and an intermediate was detected in the range 0.25-1.5 m GdnHCl. The intermediate state displayed 45% higher fluorescence intensity than that of the native state. The increase in the Nile red fluorescence was found to be due to an increase in the quantum yield of the HSA-bound Nile red. Low concentrations of GdnHCl neither altered the binding affinity of Nile red to HSA nor induced the aggregation of HSA. In addition, the secondary structure of HSA was not perturbed during the first unfolding transition (<1.5 m GdnHCl); however, the secondary structure was completely lost during the second transition. The data together showed that the half maximal loss of the tertiary structure occurred at a lower GdnHCl concentration than the loss of the secondary structure. Further kinetic studies of the refolding process of HSA using multiple spectroscopic techniques showed that the folding occurred in two phases, a burst phase followed by a slow phase. An intermediate with native-like secondary structure but only a partial tertiary structure was found to form in the burst phase of refolding. Then, the intermediate slowly folded into the native state. An analysis of the refolding data suggested that the folding of HSA could be best explained by the framework model.     

Equilibrium unfolding of dimeric desulfoferrodoxin involves a monomeric intermediate: iron cofactors dissociate after polypeptide unfolding

Here we report the conformational stability of homodimeric desulfoferrodoxin (dfx) from Desulfovibrio desulfuricans (ATCC 27774). The dimer is formed by two dfx monomers linked through beta-strand interactions in two domains; in addition, each monomer contains two different iron centers: one Fe-(S-Cys)(4) center and one Fe-[S-Cys+(N-His)(4)] center. The dissociation constant for dfx was determined to be 1 microM (DeltaG = 34 kJ/mol of dimer) from the concentration dependence of aromatic residue emission. Upon addition of the chemical denaturant guanidine hydrochloride (GuHCl) to dfx, a reversible fluorescence change occurred at 2-3 M GuHCl. This transition was dependent upon protein concentration, in accord with a dimer to monomer reaction [DeltaG(H(2)O) = 46 kJ/mol of dimer]. The secondary structure did not disappear, according to far-UV circular dichroism (CD), until 6 M GuHCl was added; this transition was reversible (for incubation times of < 1 h) and independent of dfx concentration [DeltaG(H(2)O) = 50 kJ/mol of monomer]. Thus, dfx equilibrium unfolding is at least three-state, involving a monomeric intermediate with native-like secondary structure. Only after complete polypeptide unfolding (and incubation times of > 1 h) did the iron centers dissociate, as monitored by disappearance of ligand-to-metal charge transfer absorption, fluorescence of an iron indicator, and reactivity of cysteines to Ellman's reagent. Iron dissociation took place over several hours and resulted in an irreversibly denatured dfx. It appears as if the presence of the iron centers, the amino acid composition, and, to a lesser extent, the dimeric structure are factors that aid in facilitating dfx's unusually high thermodynamic stability for a mesophilic protein.     

Characterization of rhodanese-tetracyanonickelate. An active site complex that slows sulfur-free rhodanese conversion to inert conformers

The structure of the rhodanese-tetracyanonickelate (E X Ni(CN)2-4) complex has been characterized here in spectral and physical studies using urea as a structural perturbant. UV difference absorption, sedimentation velocity ultracentrifugation, fluorescence, and circular dichroism data show no significant conformational differences between sulfur-free rhodanese (E) and the E X Ni(CN)2-4 complex. The urea-induced enzyme structural transition curves were noncoincident when different structural parameters were monitored. For E, the urea concentrations giving half-maximal change (Cm) were: Cm = 3.0 M for activity measurement; Cm = 2.8 M for protein intrinsic fluorescence intensity; Cm = 4.3 M for ellipticity at 220 nm; and Cm = 3.3 M for wavelength of fluorescence emission maximum. For the E X Ni(CN)2-4 complex, Cm was shifted to a higher urea concentration relative to that found for E when activity (Cm = 3.6 M) and native protein fluorescence (Cm = 3.6 M) were the measured parameters but not when the wavelength of the emission maximum and ellipticity were monitored. Furthermore, urea-induced rhodanese structural changes were time-dependent and Ni(CN)2-4 binding on E slowed enzyme inactivation that is associated with structural relaxations. These findings, that Ni(CN)2-4 affects structural relaxations in rhodanese, are of particular interest in light of the recent suggestion that the E X Ni(CN)2-4 complex mimics a normally inaccessible intermediate in catalysis.     

Four-state equilibrium unfolding of an scFv antibody fragment

The conformational stability of a single-chain Fv antibody fragment against a hepatitis B surface antigen (anti-HBsAg scFv) has been studied by urea and temperature denaturation followed by fluorescence and circular dichroism. At neutral pH and low protein concentration, it is a well-folded monomer, and its urea and thermal denaturations are reversible. The noncoincidence of the fluorescence and circular dichroism transitions indicates the accumulation in the urea denaturation of an intermediate (I(1)) not previously described in scFv molecules. In addition, at higher urea concentrations, a red-shift in the fluorescence emission maximum reveals an additional intermediate (I(2)), already reported in the denaturation of other scFvs. The urea equilibrium unfolding of the anti-HBsAg scFv is thus four-state. A similar four-state behavior is observed in the thermal unfolding although the intermediates involved are not identical to those found in the urea denaturation. Global analysis of the thermal unfolding data suggests that the first intermediate displays substantial secondary structure and some well-defined tertiary interactions while the second one lacks well-defined tertiary interactions but is compact and unfolds at higher temperature in a noncooperative fashion. Global analysis of the urea unfolding data (together with the modeled structure of the scFv) provides insights into the conformation of the chemical denaturation intermediates and allows calculation of the N-I(1), I(1)-I(2), and I(2)-D free energy differences. Interestingly, although the N-D free energy difference is very large, the N-I(1) one, representing the "relevant" conformational stability of the scFv, is small.