Analysing functional connectivity in brain slices by a combination of infrared video microscopy, flash photolysis of caged compounds and scanning methods

The equilibrium unfolding and the kinetics of unfolding and refolding of equine lysozyme, a Ca2+-binding protein, were studied by means of circular dichroism spectra in the far and near-ultraviolet regions. The transition curves of the guanidine hydrochloride-induced unfolding measured at 230 nm and 292.5 nm, and for the apo and holo forms of the protein have shown that the unfolding is well represented by a three-state mechanism in which the molten globule state is populated as a stable intermediate. The molten globule state of this protein is more stable and more native-like than that of alpha-lactalbumin, a homologous protein of equine lysozyme. The kinetic unfolding and refolding of the protein were induced by concentration jumps of the denaturant and measured by stopped-flow circular dichroism. The observed unfolding and refolding curves both agreed well with a single-exponential function. However, in the kinetic refolding reactions below 3 M guanidine hydrochloride, a burst-phase change in the circular dichroism was present, and the burst-phase intermediate in the kinetic refolding is shown to be identical with the molten globule state observed in the equilibrium unfolding. Under a strongly native condition, virtually all the molecules of equine lysozyme transform the structure from the unfolded state into the molten globule, and the subsequent refolding takes place from the molten globule state. The transition state of folding, which may exist between the molten globule and the native states, was characterized by investigating the guanidine hydrochloride concentration-dependence of the rate constants of refolding and unfolding. More than 80% of the hydrophobic surface of the protein is buried in the transition state, so that it is much closer to the native state than to the molten globule in which only 36% of the surface is buried in the interior of the molecule. It is concluded that all the present results are best explained by a sequential model of protein folding, in which the molten globule state is an obligatory folding intermediate on the pathway of folding.     

The equilibrium intermediate of beta-lactoglobulin with non-native alpha-helical structure

It is generally considered that intermediates of protein folding contain partially formed native-like secondary structures. In contrast, we recently reported that the kinetic folding intermediate of bovine beta-lactoglobulin contains non-native alpha-helical structures. To understand the mechanism that stabilizes the non-native intermediate, we characterized by circular dichroism (CD) the equilibrium unfolding transition of beta-lactoglobulin induced by guanidine hydrochloride (Gdn-HCl) at pH 2 and 4 degrees C. The unfolding transition measured by near-UV CD preceded the transition measured by far-UV CD, indicating the accumulation of the intermediate state. The far-UV CD spectrum of the intermediate, obtained by global fitting analysis of the CD spectra in the presence of various concentrations of Gdn-HCl, was similar to the burst-phase intermediate observed in the refolding kinetics, and contained non-native alpha-helical structures. Addition of 10% (v/v) 2,2,2-trifluoroethanol (TFE) increased the helical content of the equilibrium intermediate, although the protein still assumed the native structure in the absence of Gdn-HCl. A phase diagram of the conformational states, i.e. the alpha-helical intermediate, unfolded and native states, against the concentration of TFE and Gdn-HCl was constructed. This indicated that, because of the high helical preference of the amino acid sequence of beta-lactoglobulin, the helical region protrudes into the boundary between the native and unfolded states, resulting in non-monotonic accumulation of the helical intermediate upon equilibrium unfolding of the native beta-sheet structure. This is the first observation to indicate that a non-native alpha-helical intermediate accumulates during equilibrium unfolding of a predominantly beta-sheet protein.     

Tetracyclines induce changes in accessibility of ribosomal proteins to proteases

It is generally assumed that folding intermediates contain partially formed native-like secondary structures. However, if we consider the fact that the conformational stability of the intermediate state is simpler than that of the native state, it would be expected that the secondary structures in a folding intermediate would not necessarily be similar to those of the native state. beta-Lactoglobulin is a predominantly beta-sheet protein, although it has a markedly high intrinsic preference for alpha-helical structure. We have studied the refolding kinetics of bovine beta-lactoglobulin using stopped-flow circular dichroism and find that a partly alpha-helical intermediate accumulates transiently before formation of the native beta-sheets. The present results suggest that the folding reaction of beta-lactoglobulin follows a non-hierarchical mechanism, in which non-native alpha-helical structures play important roles.     

Proline isomerization-independent accumulation of an early intermediate and heterogeneity of the folding pathways of a mixed alpha/beta protein, Escherichia coli thioredoxin

Oxidized Escherichia coli thioredoxin (Trx) is a small protein of 108 residues with one disulfide bond (C32-C35 essentially involved in the activity) and no prosthetic moieties, which folds into a structural motif containing a central twisted beta-sheet flanked by helices that is found in many larger proteins. The kinetics of refolding of Trx in vitro have been investigated using a newly developed active site titration assay and continuous or stopped-flow (SF) methods in conjunction with circular dichroism (CD) and fluorescence (Fl) spectroscopy. These studies revealed the presence of early folding intermediates with "molten globule or pre-molten globule" characteristics. Measurements of the ellipticity at 222 nm indicated that about 68% of the total change associated with refolding occurred during the dead time (4 ms) of the stopped-flow instrument, suggesting the formation of substantial secondary structure. The reconstruction of the far-UV CD spectrum of the burst intermediate using combined continuous and stopped-flow methods showed the formation of a defined secondary structure that contains more beta-structure than the native state. Kinetic measurements using SF far-UV CD and Fl over a wide range (0.087-6 M) of GuHCl concentrations at two temperatures (6 and 20 degreesC) demonstrated that the population formed during the 4 ms dead time contained multiple species that are stabilized mainly by hydrophobic interactions and undergo further folding along alternative pathways. One of these species leads directly and rapidly to the native state as demonstrated by active site titration, while the two others fold into a fourth intermediate that is slowly converted to the native protein. Double-jump experiments suggest that the heterogeneity in folding behavior results from proline isomerizations occurring in the unfolded state. Conversely, the accumulation of the burst intermediate does not depend on proline isomerizations.     

Unfolding and refolding of dimeric creatine kinase equilibrium and kinetic studies

Equilibrium and kinetic studies of the guanidine hydrochloride induced unfolding-refolding of dimeric cytoplasmic creatine kinase have been monitored by intrinsic fluorescence, far ultraviolet circular dichroism, and 1-anilinonaphthalene-8-sulfonate binding. The GuHCl induced equilibrium-unfolding curve shows two transitions, indicating the presence of at least one stable equilibrium intermediate in GuHCl solutions of moderate concentrations. This intermediate is an inactive monomer with all of the thiol groups exposed. The thermodynamic parameters obtained by analysis using a three-state model indicate that this intermediate is similar in energy to the fully unfolded state. There is a burst phase in the refolding kinetics due to formation of an intermediate within the dead time of mixing (15 ms) in the stopped-flow apparatus. Further refolding to the native state after the burst phase follows biphasic kinetics. The properties of the burst phase and equilibrium intermediates were studied and compared. The results indicate that these intermediates are similar in some respects, but different in others. Both are characterized by pronounced secondary structure, compact globularity, exposed hydrophobic surface area, and the absence of rigid side-chain packing, resembling the "molten globule" state. However, the burst phase intermediate shows more secondary structure, more exposed hydrophobic surface area, and more flexible side-chain packing than the equilibrium intermediate. Following the burst phase, there is a fast phase corresponding to folding of the monomer to a compact conformation. This is followed by rapid assembly to form the dimer. Neither of the equilibrium unfolding transitions are protein concentration dependent. The refolding kinetics are also not concentration dependent. This suggests that association of the subunits is not rate limiting for refolding, and that under equilibrium conditions, dissociation occurs in the region between the two unfolding transitions. Based upon the above results, schemes of unfolding and refolding of creatine kinase are proposed.     

Successful coping with declining objective life style by institutionalized long-term patients. Results of a follow-up analysis of quality of life in long-term care institutions with the Zurich Quality of Life Inventory

Folding of cytochrome c from its low pH guanidine hydrochloride (Gdn-HCl) denatured state revealed a new intermediate, a five-coordinate high spin species with a water molecule coordinated to the heme. Incorporation of this five-coordinated intermediate into the previously reported ligand exchange model can quantitatively account for the observed folding kinetics. In this new model, unfolded cytochrome c is converted to its native structure through an obligatory folding intermediate, the histidine-water coordination state, whereas the five-coordinate state and a bis-histidine state are off-pathway intermediates. When the concentration of Gdn-HCl in the refolding solution was increased, an acceleration of the conversion from the bis-histidine coordinated state to the histidine-water coordinated state was observed, demonstrating that the reaction requires unfolding of the mis-organized polypeptide structure associated with the bis-histidine state.     

Refolding of urea-denatured tubulin: recovery of nativelike structure and colchicine binding activity from partly unfolded states

Tubulin unfolding in urea proceeds via the formation of a partially unfolded intermediate state, stable in 2 M urea, that unfolds further in higher urea concentrations. The intermediate state had spectroscopic properties reminiscent of a molten globule and negligible colchicine binding activity. Refolding of totally unfolded tubulin in 8 M urea yielded an intermediatelike state characterized by partial burial of tryptophans and partial recovery of secondary and tertiary structures, although colchicine-binding activity of the protein was not regained. Further folding of this intermediatelike state, toward the native conformation, with respect to both structural and functional parameters did not occur. However, a significant percentage of colchicine binding activity and nativelike tertiary structure was recovered when refolding was initiated from partially denatured protein samples, viz., from <1.2 M urea. Thus, although high concentration of urea induced loss of structure and activity was irreversible, the conformational changes induced in restricted regions of tubulin by lower concentrations of urea, which are probably crucial for its various functional properties, could be reversed.     

GroEL-mediated folding of structurally homologous dihydrofolate reductases

Using stopped-flow fluorescence techniques, we have examined both the refolding and unfolding reactions of four structurally homologous dihydrofolate reductases (murine DHFR, wild-type E. coli DHFR, and two E. coli DHFR mutants) in the presence and absence of the molecular chaperonin GroEL. We show that GroEL binds the unfolded conformation of each DHFR with second order rate constants greater than 3 x 10(7) M(-1)s(-1) at 22 degrees C. Once bound to GroEL, the proteins refold with rate constants similar to those for folding in the absence of GroEL. The overall rate of formation of native enzyme is decreased by the stability of the complex between GroEL and the last folding intermediate. For wild-type E. coli DHFR, complex formation is transient while for the others, a stable complex is formed. The stable complexes are the same regardless of whether they are formed from the unfolded or folded DHFR. When complex formation is initiated from the native conformation, GroEL binds to a pre-existing non-native conformation, presumably a late folding intermediate, rather than to the native state, thus shifting the conformational equilibrium toward the non-native species by mass action. The model presented here for the interaction of these four proteins with GroEL quantitatively describes the difference between the formation of a transient complex and a stable complex as defined by the rate constants for release and rebinding to GroEL relative to the rate constant for the last folding step. Due to this kinetic partitioning, three different mechanisms can be proposed for the formation of stable complexes between GroEL and either murine DHFR or the two E. coli DHFR mutants. These data show that productive folding of GroEL-bound proteins can occur in the absence of nucleotides or the co-chaperonin GroES and suggest that transient complex formation may be the functional role of GroEL under normal conditions.     

The mechanism of folding of globular proteins. Equilibria and kinetics of conformational transitions of penicillinase from Staphylococcus aureus involving a state of intermediate conformation

1. The thermodynamically reversible unfolding and refolding of penicillinase between the native and fully unfolded states were followed by using guanidinium chloride as denaturant. 2. The equilibria, studied by optical rotation, u.v. absorption, viscosity and enzyme activity, show the presence of a state of intermediate conformation, termed state H, which is stable at 20 degrees C in 0.8 M-guanidinium chloride. 3. The physical properties of this state show that it is slightly expanded with an intrinsic viscosity of 8 ml-g-1, that the 13 tyrosine residues, which are distributed through the primary sequence, are maximally exposed to the solvent and that the helix content is the same as that of the native state. 4. The kinetics of the transition between the native state, state H and the fully unfolded state were followed by u.v. absorption and by optical rotation. They are interpreted as showing that state H lies on the folding pathway between the native and fully unfolded states. 5. The transition between the native state and state H exhibits monophasic unfolding kinetics and biphasic refolding kinetics. This indicates that there must be at least two intermediate states in this process, at least one of which lies on the folding pathway which may also involve cul-de-sac paths. 6. The results are discussed in terms of a mechanism involving rapid stabilization of nucleation regions in a moderately compact but internally solvated structure, with 'native format' [Anfinsen (1973) Science 181, 233-230] secondary structure stabilized by tertiary interaction. The final and rate-limiting step in refolding involves shuffling of these structural elements into the native state. 7. This model is discussed in relation to folding in vivo.     

Characterization of a partially unfolded structure of cytochrome c induced by sodium dodecyl sulphate and the kinetics of its refolding

The mechanism of unfolding of ferricytochrome c induced by the surfactant sodium dodecyl sulfate has been studied by heme absorption, tryptophan fluorescence, circular dichroism, resonance Raman scattering, stopped-flow and time-resolved resonance energy transfer to obtain a comprehensive view of the whole process. Unfolding occurred at an almost specific molecular ratio of SDS/cytochrome c in the concentration range (20-50 microM) studied here. However there appears to be a point at approximately 0.6 mM SDS where unfolding begins to occur for lower cytochrome c concentrations. The kinetics of unfolding revealed only a single transition with a rate constant of 33 s(-1) (at 298 K, [SDS] = 8.7 mM) and activation energy barrier of approximately 16 kJ/mol, indicating that other associated steps, if any, are too fast to be significantly populated. The free energy change (deltaG(o)) involved with the unfolding transition was estimated to be about 16.8 kJ/mol. The CD spectrum at 220 nm of SDS-unfolded cytochrome c shows only a partial decrease (25%), indicating that a significant amount of helical structure remains folded in contrast to a complete loss of helical structure in GdnHCl-denatured cytochrome c. The heme structure in SDS-unfolded cytochrome c, as deduced from heme absorption and resonance Raman spectra, shows a major population (approximately 95%) of mis-ligated histidine to the heme which acts as a kinetic trap in the folding process. The structural changes associated with cytochrome c unfolding were also monitored by time-resolved resonance energy transfer which shows a drastic increase in tryptophan fluorescence lifetime from 12 ps in the native protein to 0.63 ns in the unfolded one, associated with a movement of Trp59 by 10 A away from heme. The maximum entropy method analysis of fluorescence decay indicated the growth of various conformational substates in SDS-unfolded cytochrome c in contrast to narrowly distributed conformations in the native protein. The refolding was comprised of three kinetic steps; the first was significantly fast (approximately 8 ms) and was assigned to the dissociation of His26 that paves the protein towards correct folding pathway. The other two slower steps probably arise from chain misorganization and prolyl isomerization. The absence of a burst-phase amplitude supports the idea that the burst phase observed in the folding from completely unfolded cytochrome c corresponds to a molecular collapse that produces significant secondary structure. The partially unfolded state represents a unique intermediate state in the folding pathway.     

Detection and characterization of an ovine placental lactogen stable intermediate in the urea-induced unfolding process

The urea-induced equilibrium unfolding of ovine placental lactogen, purified from ovine placenta, was followed by size-exclusion chromatography, far-UV CD, and intrinsic tryptophan fluorescence. The data obtained by each of these methods showed a poor fit to a two-state model involving only a native and an unfolded form. A satisfactory fit required, instead, a model that involved a stable, partially folded form in addition to the native and unfolded ones. The results obtained from the best-fitting theoretical curves for the three-state model indicated that this intermediate state, which is the predominant species in solution at 3.6 M of urea activity, is compact, largely alpha-helical, and changes considerably the native-like tertiary packing around its tryptophan residues. These findings suggest that this stable intermediate exhibits properties similar to those that characterize the molten globule state.     

Refolding rate of stability-enhanced cytochrome c is independent of thermodynamic driving force

N52I iso-2 cytochrome c is a variant of yeast iso-2 cytochrome c in which asparagine substitutes for isoleucine 52 in an alpha helical segment composed of residues 49-56. The N52I substitution results in a significant increase in both stability and cooperativity of equilibrium unfolding, and acts as a "global suppressor" of destabilizing mutations. The equilibrium m-value for denaturant-induced unfolding of N52I iso-2 increases by 30%, a surprisingly large amount for a single residue substitution. The folding/unfolding kinetics for N52I iso-2 have been measured by stopped-flow mixing and by manual mixing, and are compared to the kinetics of folding/unfolding of wild-type protein, iso-2 cytochrome c. The results show that the observable folding rate and the guanidine hydrochloride dependence of the folding rate are the same for iso-2 and N52I iso-2, despite the greater thermodynamic stability of N52I iso-2. Thus, there is no linear free-energy relationship between mutation-induced changes in stability and observable refolding rates. However, for N52I iso-2 the unfolding rate is slower and the guanidine hydrochloride dependence of the unfolding rate is smaller than for iso-2. The differences in the denaturant dependence of the unfolding rates suggest that the N52I substitution decreases the change in the solvent accessible hydrophobic surface between the native state and the transition state. Two aspects of the results are inconsistent with a two-state folding/unfolding mechanism and imply the presence of folding intermediates: (1) observable refolding rate constants calculated from the two-state mechanism by combining equilibrium data and unfolding rate measurements deviate from the observed refolding rate constants; (2) kinetically unresolved signal changes ("burst phase") are observed for both N52I iso-2 and iso-2 refolding. The "burst phase" amplitude is larger for N52I iso-2 than for iso-2, suggesting that the intermediates formed during the "burst phase" are stabilized by the N52I substitution.     

Automated fluorescent analysis procedure for enzymatic mutation detection

Whereas bovine beta-lactoglobulin is a predominantly beta-sheet protein, it has a marked alpha-helical preference and can be considered to be a useful model of the alpha-->beta transition, a key issue for understanding the folding and biological function of a number of proteins. In order to understand the mechanism of the alpha-->beta transition, the backbone structures of the recombinant bovine beta-lactoglobulin A in the native state and in the highly helical state induced by 2,2,2-trifluoroethanol were characterized by 1H, 13C and 15N multidimensional NMR spectroscopy. Overall, the secondary structures in the native state were similar to those of the crystal structure. On the other hand, beta-lactoglobulin in the 2,2,2-trifluoroethanol state was composed of many alpha-helical segments. The presence of the persistent alpha-helices in the helical state and the core beta-sheet in the native state suggested that during folding native-like core beta-sheet and several non-native helices are formed first and the remaining beta-sheet is subsequently "induced" through interaction with the pre-existing beta-sheet.     

Three-state model for lysozyme folding: triangular folding mechanism with an energetically trapped intermediate

We investigated the role of a partially folded intermediate that transiently accumulates during lysozyme folding. Previous studies had shown that the partially folded intermediate is located on a slow-folding pathway and that an additional fast direct pathway from the unfolded state to the native state exists. Kinetic double-jump experiments showed that the two folding pathways are not caused by slow equilibration reactions in the unfolded state. Rather, kinetic partitioning occurs very early in lysozyme refolding, giving the molecules the chance to enter the direct pathway or a slow-folding channel. Fitting the guanidinium chloride dependencies of the refolding and unfolding reactions to analytical solutions for different folding scenarios enables us to propose a triangular mechanism as the minimal model for lysozyme folding explaining all observed kinetic reactions: [diagram in text]. All microscopic rate constants and their guanidinium chloride dependencies could be obtained from the experimental data. The results suggest that population of the intermediate during refolding increases the free energy of activation of the folding process. This effect is due to the increased stability of the intermediate state compared to the unfolded state leading to an increase in the free energy of activation (deltaG0) compared to folding in the absence of populated intermediate states. The absolute energy of the transition state is identical on both pathways. The results imply that pre-formed secondary structure in the folding intermediate obstructs formation of the transition state of folding but does not change the nature of the rate-limiting step in the folding process.     

A partially folded intermediate during tubulin unfolding: its detection and spectroscopic characterization

The unfolding reaction of the dimeric protein tubulin, isolated from goat brain, was studied using fluorescence and circular dichroism techniques. The unfolding of the tubulin dimer was found to be a two-step process at pH 7. The first step leads to the formation of an intermediate conformation, stable at around 1-2 M urea, followed by a second step that was due to unfolding of the intermediate state. At pH 3, the urea-induced biphasic unfolding profiles obtained at pH 7 became a one-step process indicating that a stable intermediate was also formed at this pH. The intermediate at pH 3 was more stable toward urea denaturation than that at pH 7. The intermediate state has about 60% secondary structure, partially exposed aromatic residues, and less tertiary structure as compared to the native states. Also, hydrophobic surfaces were more exposed in the intermediate than in the native or unfolded states. These results indicate that the intermediate state observed during tubulin unfolding is not only distinct from both the native and unfolded forms but also possesses some properties characteristic of a molten globule.     

The origin of the alpha-domain intermediate in the folding of hen lysozyme

Stopped-flow fluorescence and circular dichroism spectroscopy have been used in conjunction with quenched-flow hydrogen exchange labelling, monitored by electrospray ionization mass spectrometry, to compare the refolding kinetics of hen egg-white lysozyme at 20 degrees C and 50 degrees C. At 50 degrees C there is clear evidence for distinct fast and slow refolding populations, as observed at 20 degrees C, although folding occurs significantly more rapidly. The folding process is, however, substantially more cooperative at the higher temperature. In particular, the transient intermediate on the major refolding pathway at 20 degrees C, having persistent native-like structure in the alpha-helical domain of the protein, is not detected by hydrogen exchange labelling at 50 degrees C. In addition, the characteristic maximum in negative ellipticity and the minimum in fluorescence intensity observed in far UV CD and intrinsic fluorescence experiments at 20 degrees C, respectively, are not seen at 50 degrees C. Addition of 2 M NaCl to the refolding buffer at 50 degrees C, however, regenerates both the hydrogen exchange and optical properties associated with the alpha-domain intermediate but has no significant effect on the overall refolding kinetics. Together with previous findings, these results indicate that non-native interactions within the alpha-domain intermediate are directly responsible for the unusual optical properties observed during refolding, and that this intermediate accumulates as a consequence of its intrinsic stability in a folding process where the formation of stable structure in the beta-domain constitutes the rate-limiting step for the majority of molecules.     

Determination of the volume changes for pressure-induced transitions of apomyoglobin between the native, molten globule, and unfolded states

The volume change for the transition from the native state of horse heart apomyoglobin to a pressure-induced intermediate with fluorescence properties similar to those of the well-established molten globule or I form was measured to be -70 ml/mol. Complete unfolding of the protein by pressure at pH 4.2 revealed an upper limit for the unfolding of the intermediate of -61 ml/mol. At 0.3 M guanidine hydrochloride, the entire transition from native to molten globule to unfolded state was observed in the available pressure range below 2.5 kbar. The volume change for the N-->I transition is relatively large and does not correlate well with the changes in relative hydration for these transitions derived from measurements of the changes in heat capacity, consistent with the previously observed lack of correlation between the m-value for denaturant-induced transitions and the measured volume change of unfolding for cooperativity mutants of staphylococcal nuclease (Frye et al. 1996. Biochemistry. 35:10234-10239). Our results support the hypothesis that the volume change associated with the hydration of protein surface upon unfolding may involve both positive and negative underlying contributions that effectively cancel, and that the measured volume changes for protein structural transitions arise from another source, perhaps the elimination of void volume due to packing defects in the structured chains.     

Compactness of the kinetic molten globule of bovine alpha-lactalbumin: a dynamic light scattering study

During folding of globular proteins, the molten globule state was observed as an equilibrium intermediate under mildly denaturing conditions as well as a transient intermediate in kinetic refolding experiments. While the high compactness of the equilibrium intermediate of alpha-lactalbumin has been verified, direct measurements of the compactness of the kinetic intermediate have not been reported until now. Our dynamic light scattering measurements provide a complete set of the hydrodynamic dimensions of bovine alpha-lactalbumin in different conformational states, particularly in the kinetic molten globule state. The Stokes radii for the native, kinetic molten globule, equilibrium molten globule, and unfolded states are 1.91, 1.99, 2.08, and 2.46 nm, respectively. Therefore, the kinetic intermediate appears to be even more compact than its equilibrium counterpart. Remarkable differences in the concentration dependence of the Stokes radius exist revealing strong attractive but repulsive intermolecular interactions in the kinetic and equilibrium molten globule states, respectively. This underlines the importance of extrapolation to zero protein concentration in measurements of the molecular compactness.     

A stable, molten-globule-like cytochrome c

Expression of cytochrome c from Thermus thermophilus in Escherichia coli (E. coli) leads to a protein with characteristics of a molten globule. Unfolding induced by guanidine hydrochloride (GdHCl) shows that E. coli-expressed cytochrome c has lower stability (and less cooperativity of unfolding) compared to the protein extracted from Thermus thermophilus, even though the two proteins have identical amino-acid sequences. Moreover, Soret and far-UV circular dichroism signals differ for the two proteins, suggesting a distorted heme environment and more side-chain dynamics of E. coli-expressed cytochrome c. Still, tryptophan fluorescence in E. coli-expressed cytochrome c is quenched as in native protein, and the iron coordinates in a low-spin form. Amino-acid sequencing indicates the presence of only one covalent cysteine-linkage to the heme in E. coli-expressed cytochrome c (normally, there are two linkages), a possible explanation for the trapped, molten-globule-like structure. The features of this non-native protein may be of interest for interpretation of cytochrome c folding kinetics in vitro, since a molten globule may be an intermediate on the folding pathway.     

Refolding of [6-19F]tryptophan-labeled Escherichia coli dihydrofolate reductase in the presence of ligand: a stopped-flow NMR spectroscopy study

Escherichia coli dihydrofolate reductase contains five tryptophan residues that are spatially distributed throughout the protein and located in different secondary structural elements. When these tryptophans are replaced with [6-19F]tryptophan, distinct native and unfolded resonances can be resolved in the 1-D 19F NMR spectra. Using site-directed mutagenesis, these resonances have been assigned to individual tryptophans [Hoeltzli, S. D., and Frieden, C. (1994) Biochemistry 33, 5502-5509], allowing both the native and unfolded environments of each tryptophan to be monitored during the refolding process. We have previously used these assignments and stopped-flow NMR to investigate the behavior of specific regions of the protein during refolding of apo dihydrofolate reductase from urea in real time. These studies now have been extended to investigate the real time behavior of specific regions of the protein during refolding of dihydrofolate reductase in the presence of either NADP+ or dihydrofolate. As observed for the apoprotein, in the presence of either ligand, unfolded resonance intensities present at the first observed time point (1.5 s) disappear in two phases similar to those monitored by either stopped-flow fluorescence or circular dichroism spectroscopy. The existence of unfolded resonances which disappear slowly indicates that an equilibrium exists between the unfolded side chain environment and one or more intermediates, and that formation of at least one intermediate is cooperative. The results of this study are consistent with previous fluorescence studies demonstrating that dihydrofolate binds at an earlier step in the folding process than does NADP+ [Frieden, C. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4413-4416] and provide a structural interpretation of the previous results. In the apoprotein as well as in the presence of either ligand, the protein folds via at least one cooperatively formed, solvent-protected intermediate which contains secondary structure. In the presence of NADP+, a stable native-like side chain environment forms in the regions around tryptophans 30, 133, and 47 in an intermediate which cannot bind NADP+ tightly. Native side chain environment forms in the regions around tryptophans 22 and 74 only in the structure which is able to bind NADP+ tightly. In the presence of dihydrofolate, stable native-like side chain environment forms cooperatively in the regions around each tryptophan in a non-native intermediate which must undergo a conformational change prior to binding NADP+. The presence of ligands influences the processes which occur during the folding of dihydrofolate reductase, and the ligand may in effect serve as part of the hydrophobic core.