Friction-Limited Folding of Disulfide-Reduced Monomeric SOD1.

The folding reaction of a stable monomeric variant of Cu/Zn superoxide dismutase (mSOD1), an enzyme responsible for the conversion of superoxide free radicals into hydrogen peroxide and oxygen, is known to be among the slowest folding processes that adhere to two-state behavior. The long lifetime, ∼10 s, of the unfolded state presents ample opportunities for the polypeptide chain to transiently sample nonnative structures before the formation of the productive folding transition state. We recently observed the formation of a nonnative structure in a peptide model of the C-terminus of SOD1, a sequence that might serve as a potential source of internal chain friction-limited folding. To test for friction-limited folding, we performed a comprehensive thermodynamic and kinetic analysis of the folding mechanism of mSOD1 in the presence of the viscogens glycerol and glucose. Using a, to our knowledge, novel analysis of the folding reactions, we found the disulfide-reduced form of the protein that exposes the C-terminal sequence, but not its disulfide-oxidized counterpart that protects it, experiences internal chain friction during folding. The sensitivity of the internal friction to the disulfide bond status suggests that one or both of the cross-linked regions play a critical role in driving the friction-limited folding. We speculate that the molecular mechanisms giving rise to the internal friction of disulfide-reduced mSOD1 might play a role in the amyotrophic lateral sclerosis-linked aggregation of SOD1.

Rough energy landscapes in protein folding: dimeric E. coli Trp repressor folds through three parallel channels.

The folding mechanism of the dimeric Escherichia coli Trp repressor (TR) is a kinetically complex process that involves three distinguishable stages of development. Following the formation of a partially folded, monomeric ensemble of species, within 5 ms, folding to the native dimer is controlled by three kinetic phases. The rate-limiting step in each phase is either a non-proline isomerization reaction or a dimerization reaction, depending on the final denaturant concentration. Two approaches have been employed to test the previously proposed folding mechanism of TR through three parallel channels: (1) unfolding double-jump experiments demonstrate that all three folding channels lead directly to native dimer; and (2) the differential stabilization of the transition state for the final step in folding and the native dimer, by the addition of salt, shows that all three channels involve isomerization of a dimeric species. A refined model for the folding of Trp repressor is presented, in which all three channels involve a rapid dimerization reaction between partially folded monomers followed by the isomerization of the dimeric intermediates to yield native dimer. The ensemble of partially folded monomers can be captured at equilibrium by low pH; one-dimensional proton NMR spectra at pH 2.5 demonstrate that monomers exist in two distinct, slowly interconverting conformations. These data provide a potential structural explanation for the three-channel folding mechanism of TR: random association of two different monomeric forms, which are distinguished by alternative packing modes of the core dimerization domain and the DNA-binding, helix-turn-helix, domain. One, perhaps both, of these packing modes contains non-native contacts.

Testing the role of chain connectivity on the stability and structure of dihydrofolate reductase from E. coli: fragment complementation and circular permutation reveal stable, alternatively folded forms.

The effects of chain cleavage and circular permutation on the structure, stability, and activity of dihydrofolate reductase (DHFR) from Escherichia coli were investigated by various spectroscopic and biochemical methods. Cleavage of the backbone after position 86 resulted in two fragments, (1--86) and (87--159) each of which are poorly structured and enzymatically inactive. When combined in a 1 : 1 molar ratio, however, the fragments formed a high-affinity (K(a) = 2.6 x 10(7) M(-1)) complex that displays a weakly cooperative urea-induced unfolding transition at micromolar concentrations. The retention of about 15% of the enzymatic activity of full-length DHFR is surprising, considering that the secondary structure in the complex is substantially reduced from its wild-type counterpart. In contrast, a circularly permuted form with its N-terminus at position 86 has similar overall stability to full-length DHFR, about 50% of its activity, substantial secondary structure, altered side-chain packing in the adenosine binding domain, and unfolds via an equilibrium intermediate not observed in the wild-type protein. After addition of ligand or the tight-binding inhibitor methotrexate, both the fragment complex and the circular permutant adopt more native-like secondary and tertiary structures. These results show that changes in the backbone connectivity can produce alternatively folded forms and highlight the importance of protein-ligand interactions in stabilizing the active site architecture of DHFR.

Mapping the energy surface for the folding reaction of the coiled-coil peptide GCN4-p1.

The energy surface for the folding/unfolding reactions of the homodimeric coiled-coil peptide M2V GCN4-p1, a 33-residue segment comprising the leucine zipper domain of the transcriptional activator GCN4, was mapped by equilibrium and kinetic methods. Circular dichroism (CD) spectroscopy was used to monitor the urea-induced unfolding reaction at a series of temperatures and temperature-induced unfolding at a series of urea concentrations. A global analysis of the urea- and temperature-induced equilibrium unfolding data provides strong support for a two-state mechanism. The absence of a detectable population of intermediate states is also consistent with differential scanning calorimetry and thermal CD melts as a function of peptide concentration. Furthermore, a global analysis of stopped-flow CD kinetic data is consistent with a kinetic two-state mechanism as well. The urea dependence of the apparent folding and unfolding rate constants at a series of temperatures reveals that the activation enthalpy and entropy for unfolding in the absence of denaturant are both significantly greater than those for the refolding reaction. Although the unfolding barrier is dominated by the activation enthalpy, the activation entropy dominates the refolding barrier. The relative magnitudes of the urea dependence of the unfolding and refolding rate constants indicate that 55-65% of the surface area is buried in the transition state. The activation parameters imply a partially organized transition state and are consistent with a previous model in which the pair of C-terminal heptad repeats are docked in a coiled-coil-like motif [Zitzewitz et al. (2000) J. Mol. Biol. 296, 1105-1116].

Rehospitalization among home healthcare patients: results of a prospective study.

Reduction in rehospitalization is an outcome measure used to evaluate home care services, especially in Outcome Based Quality Management using OASIS data; however, practitioners and managers must carefully analyze the reasons patients return to the hospital. This study examines events leading to rehospitalization of patients with CHF, whether it is possible to determine upon admission which patients are at risk, and whether the readmissions were necessary and/or preventable. Among the study's important findings are that half of the patients developed a new problem that required the rehospitalization. This and other research outcomes should be considered when analyzing adverse event reports.

Multistate equilibrium unfolding of Escherichia coli dihydrofolate reductase: thermodynamic and spectroscopic description of the native, intermediate, and unfolded ensembles.

The thermodynamic and spectroscopic properties of a cysteine-free variant of Escherichia coli dihydrofolate reductase (AS-DHFR) were investigated using the combined effects of urea and temperature as denaturing agents. Circular dichroism (CD), absorption, and fluorescence spectra were recorded during temperature-induced unfolding at different urea concentrations and during urea-induced unfolding at different temperatures. The first three vectors obtained by singular-value decomposition of each set of unfolding spectra were incorporated into a global analysis of a unique thermodynamic model. Although individual unfolding profiles can be described as a two-state process, a simultaneous fit of 99 vectors requires a three-state model as the minimal scheme to describe the unfolding reaction along both perturbation axes. The model, which involves native (N), intermediate (I), and unfolded (U) states, predicts a maximum apparent stability, DeltaG degrees (NU), of 6 kcal mol(-)(1) at 15 degrees C, an apparent m(NU) value of 2 kcal mol(-)(1) M(-)(1), and an apparent heat capacity change, DeltaC(p)()(-NU), of 2.5 kcal mol(-)(1) K(-)(1). The intermediate species has a maximum stability of approximately 2 kcal mol(-)(1) and a compactness closer to that of the native than to that of the unfolded state. The population of the intermediate is maximal ( approximately 70%) around 50 degrees C and falls below the limits of detection of > or =2 M urea or at temperatures of <35 or >65 degrees C. The fluorescence properties of the equilibrium intermediate resemble those of a transient intermediate detected during refolding from the urea-denatured state, suggesting that a tryptophan-containing hydrophobic cluster in the adenosine-binding domain plays a key role in both the equilibrium and kinetic reactions. The CD spectroscopic properties of the native state reveal the presence of two principal isoforms that differ in ligand binding affinities and in the packing of the adenosine-binding domain. The relative populations of these species change slightly with temperature and do not depend on the urea concentration, implying that the two native isoforms are well-structured and compact. Global analysis of data from multiple spectroscopic probes and several methods of unfolding is a powerful tool for revealing structural and thermodynamic properties of partially and fully folded forms of DHFR.

Preformed secondary structure drives the association reaction of GCN4-p1, a model coiled-coil system.

The structure of the transition state for the rate-limiting step in the folding and association of the homodimeric coiled-coil peptide GCN4-p1, was probed by mutational analysis. A series of quadruple amino acid replacements that spanned the helix propensity scale were made at the four external f positions in the heptad repeat. Equilibrium and kinetic circular dichroism studies demonstrate that both the stability and the unfolding and refolding rate constants vary with helix propensity but also reflect interactions of the altered side-chains with their local environments. Pairwise replacements and fragment studies show that the two C-terminal heptads are the likely source of the nucleating helices. Helix-helix recognition between preformed elements of secondary structure plays an important role in this fundamental folding reaction.

Apparent radii of the native, stable intermediates and unfolded conformers of the alpha-subunit of tryptophan synthase from E. coli, a TIM barrel protein.

The urea-induced equilibrium unfolding of the alpha-subunit of tryptophan synthase (alphaTS) from Escherichia coli can be described by a four-state model, N right harpoon over left harpoon I1 right harpoon over left harpoon I2 right harpoon over left harpoon U, involving two highly populated intermediates, I1 and I2 [Gualfetti, P. J., Bilsel, O., and Matthews, C. R. (1999) Protein Sci. 8, 1623-1635]. To extend the physical characterization of these stable forms, the apparent radius was measured by several techniques. Size-exclusion chromatography (SEC), analytical ultracentrifugation (UC), and dynamic light scattering (DLS) experiments yield an apparent Stokes radius, R(s), of approximately 24 A for the native state of alphaTS. The small-angle X-ray scattering (SAXS) experiment yields a radius of gyration, R(g), of 19.1 A, consistent with the value predicted from the X-ray structure and the Stokes radius. As the equilibrium is shifted to favor I1 at approximately 3.2 M and I2 at 5.0 M urea, SEC and UC show that R(s) increases from approximately 38 to approximately 52 A. Measurements of the radius by DLS and SAXS between 2 and 4.5 M urea were complicated by the self-association of the I1 species at the relatively high concentrations required by those techniques. Above 6 M urea, SEC and UC reveal that R(s) increases linearly with increasing urea concentration to approximately 54 A at 8 M urea. The measurements of R(s) by DLS and R(g) by SAXS are sufficiently imprecise that both values appear to be identical for the I2 and U states and, considering the errors, are in good agreement with the results from SEC and UC. Thermodynamic parameters extracted from the SEC data for the N right harpoon over left harpoon I1 and I1 right harpoon over left harpoon I2 transitions agree with those from the optical data, showing that this technique accurately monitors a part of the equilibrium model. The lack of sensitivity to the I2 right harpoon over left harpoon U transition, beyond a simple swelling of both species with increasing urea concentration, implies that the Stokes radii for the I2 and U states are not distinguishable. Surprisingly, the hydrophobic core known to stabilize I2 at 5.0 M urea [Saab-Rincón, G., Gualfetti, P. J., and Matthews, C. R. (1996) Biochemistry 35, 1988-1994] develops without a significant contraction of the polypeptide, i.e., beyond that experienced by the unfolded form at decreasing urea concentrations. Kratky plots of the SAXS data, however, reveal that I2, similar to N and I1, has a globular structure while U has a more random coil-like form. By contrast, the formation of substantial secondary structure and the burial of aromatic side chains in I1 and, eventually, N are accompanied by substantial decreases in their Stokes radii and, presumably, the size of their respective conformational ensembles.

Molecular dissection of the folding mechanism of the alpha subunit of tryptophan synthase: an amino-terminal autonomous folding unit controls several rate-limiting steps in the folding of a single domain protein.

The alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli is a 268-residue 8-stranded beta/alpha barrel protein. Two autonomous folding units, comprising the first six strands (residues 1-188) and the last two strands (residues 189-268), have been previously identified in this single structural domain protein by tryptic digestion [Higgins, W., Fairwell, T., and Miles, E. W. (1979) Biochemistry 18, 4827-4835]. The larger, amino-terminal fragment, alphaTS(1-188), was overexpressed and independently purified, and its equilibrium and kinetic folding properties were studied by absorbance, fluorescence, and near- and far-UV circular dichroism spectroscopies. The native state of the fragment unfolds cooperatively in an apparent two-state transition with a stability of 3.98 +/- 0.19 kcal mol(-1) in the absence of denaturant and a corresponding m value of 1.07 +/- 0.05 kcal mol(-1) M(-1). Similar to the full-length protein, the unfolding of the fragment shows two kinetic phases which arise from the presence of two discrete native state populations. Additionally, the fragment exhibits a significant burst phase in unfolding, indicating that a fraction of the folded state ensemble under native conditions has properties similar to those of the equilibrium intermediate populated at 3 M urea in full-length alphaTS. Refolding of alphaTS(1-188) is also complex, exhibiting two detectable kinetic phases and a burst phase that is complete within 5 ms. The two slowest isomerization phases observed in the refolding of the full-length protein are absent in the fragment, suggesting that these phases reflect contributions from the carboxy-terminal segment. The folding mechanism of alphaTS(1-188) appears to be a simplified version of the mechanism for the full-length protein [Bilsel, O., Zitzewitz, J. A., Bowers, K.E, and Matthews, C. R.(1999) Biochemistry 38, 1018-1029]. Four parallel channels in the full-length protein are reduced to a pair of channels that most likely reflect a cis/trans proline isomerization reaction in the amino-terminal fragment. The off- and on-pathway intermediates that exist for both full-length alphaTS and alphaTS(1-188) may reflect the preponderance of local interactions in the beta/alpha barrel motif.

The progressive development of structure and stability during the equilibrium folding of the alpha subunit of tryptophan synthase from Escherichia coli.

The urea-induced equilibrium unfolding of the alpha subunit of tryptophan synthase (alphaTS), a single domain alpha/beta barrel protein, displays a stable intermediate at approximately 3.2 M urea when monitored by absorbance and circular dichroism (CD) spectroscopy (Matthews CR, Crisanti MM, 1981, Biochemistry 20:784-792). The same experiment, monitored by one-dimensional proton NMR, shows another cooperative process between 5 and 9 M urea that involves His92 (Saab-Rincón G et al., 1993, Biochemistry 32:13,981-13,990). To further test and quantify the implied four-state model, N <--> I1 <--> I2 <--> U, the urea-induced equilibrium unfolding process was followed by tyrosine fluorescence total intensity, tyrosine fluorescence anisotropy and far-UV CD. All three techniques resolve the four stable states, and the transitions between them when the FL total intensity and CD spectroscopy data were analyzed by the singular value decomposition method. Relative to U, the stabilities of the N, I1, and I2 states are 15.4, 9.4, and 4.9 kcal mol(-1), respectively. I2 partially buries one or more of the seven tyrosines with a noticeable restriction of their motion; it also recovers approximately 6% of the native CD signal. This intermediate, which is known to be stabilized by the hydrophobic effect, appears to reflect the early coalescence of nonpolar side chains without significant organization of the backbone. I1 recovers an additional 43% of the CD signal, further sequesters tyrosine residues in nonpolar environments, and restricts their motion to an extent similar to N. The progressive development of a higher order structure as the denaturant concentration decreases implies a monotonic contraction in the ensemble of conformations that represent the U, I2, I1, and N states of alphaTS.

Identifying the structural boundaries of independent folding domains in the alpha subunit of tryptophan synthase, a beta/alpha barrel protein.

Two equilibrium intermediates have previously been observed in the urea denaturation of the alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli, an eight-stranded beta/alpha barrel protein. In the current study, a series of amino-terminal fragments were characterized to probe the elementary folding units that may be in part responsible for this complex behavior. Stop-codon mutagenesis was used to produce eight fragments ranging in size from 105-214 residues and containing incremental elements of secondary structure. Equilibrium studies by circular dichroism indicate that all of these fragments are capable of adopting secondary structure. All except for the shortest fragment fold cooperatively. The addition of the fourth, sixth, and eighth beta-strands leads to distinct increases in structure, cooperativity, and/or stability, suggesting that folding involves the modular assembly of betaalphabeta supersecondary structural elements. One-dimensional NMR titrations at high concentrations of urea, probing the environment around His92, were also performed to test for the presence of residual structure in the fragments. All fragments that contained the first four betaalpha units of structure exhibited a cooperative unfolding transition at high concentrations of urea with significant but reduced stability relative to the full-length protein. These results suggest that the residual structure in alphaTS requires the participation of hydrophobic residues in multiple beta-strands that span the entire sequence.

Time-resolved fluorescence anisotropy study of the refolding reaction of the alpha-subunit of tryptophan synthase reveals nonmonotonic behavior of the rotational correlation time.

Time-resolved fluorescence anisotropy of a bound extrinsic probe was studied in an effort to characterize dynamic properties of the transient partially folded forms that appear during the folding of the alpha-subunit of tryptophan synthase (alphaTS) from Escherichia coli. Previous studies have shown that alphaTS, a single structural domain, can be cleaved into autonomously folding amino- and carboxy-folding units comprising residues 1-188 and 189-268, respectively [Higgins, W., Fairwell, T., and Miles, E. W. (1979) Biochemistry 18, 4827-4835]. By use of a double-kinetic approach [Jones, B. E., Beechem, J. M., and Matthews, C. R. (1995) Biochemistry 34, 1867-1877], the rotational correlation time of 1-anilino-8-naphthalene sulfonate bound to nonpolar surfaces of folding intermediates was measured by time-correlated single photon counting at varying time delays following initiation of folding from the urea-denatured form by stopped-flow techniques. Comparison of the rotational correlation times for the full-length alphaTS and the amino-terminal fragment suggests that folding of the amino-terminal fragment and carboxy-terminal fragment is coordinated, not autonomous, on the milliseconds to seconds time scale. If a spherical shape is assumed, the apparent hydrodynamic radius of alphaTS after 5 ms is 26.8 A. The radius increases to 28.5 A by 1 s before decreasing to the radius for native alphaTS, 24.7 A, on a longer time scale (>25 s). Viewed within the context of the kinetic folding model of alphaTS [Bilsel, O., Zitzewitz, J. A., Bowers, K. E. , and Matthews, C. R. (1999) Biochemistry 38, 1018-1029], the initial collapse reflects the formation of an off-pathway burst-phase intermediate in which at least part of the carboxy folding unit interacts with the amino folding unit. The subsequent increase in rotational correlation time corresponds to the formation of an on-pathway intermediate that leads to the native conformation. The apparent increase in the radius for the on-pathway intermediate may reflect a change in the interaction of the two-folding units, thereby forming a direct precursor for the alpha/beta barrel structure.

Folding mechanism of the alpha-subunit of tryptophan synthase, an alpha/beta barrel protein: global analysis highlights the interconversion of multiple native, intermediate, and unfolded forms through parallel channels.

A variety of techniques have been used to investigate the urea-induced kinetic folding mechanism of the alpha-subunit of tryptophan synthase from Escherichia coli. A distinctive property of this 29 kDa alpha/beta barrel protein is the presence of two stable equilibrium intermediates, populated at approximately 3 and 5 M urea. The refolding process displays multiple kinetic phases whose lifetimes span the submillisecond to greater than 100 s time scale; unfolding studies yield two relaxation times on the order of 10-100 s. In an effort to understand the populations and structural properties of both the stable and transient intermediates, stopped-flow, manual-mixing, and equilibrium circular dichroism data were globally fit to various kinetic models. Refolding and unfolding experiments from various initial urea concentrations as well as forward and reverse double-jump experiments were critical for model discrimination. The simplest kinetic model that is consistent with all of the available data involves four slowly interconverting unfolded forms that collapse within 5 ms to a marginally stable intermediate with significant secondary structure. This early intermediate is an off-pathway species that must unfold to populate a set of four on-pathway intermediates that correspond to the 3 M urea equilibrium intermediate. Reequilibrations among these conformers act as rate-limiting steps in folding for a majority of the population. A fraction of the native conformation appears in less than 1 s at 25 degrees C, demonstrating that even large proteins can rapidly traverse a complex energy surface.

Mechanism of folding of the dimeric core domain of Escherichia coli trp repressor: a nearly diffusion-limited reaction leads to the formation of an on-pathway dimeric intermediate.

A polypeptide corresponding to the core/dimerization domain of E. coli Trp repressor (TR), [2-66]2 TR, was constructed by insertion of a pair of stop codons into the trpR gene. The kinetic properties of the urea-induced folding of this core fragment were examined by intrinsic tryptophan fluorescence (FL) and circular dichroism (CD) spectroscopy. The kinetic response of wild-type TR (WT TR) is very complicated and has been interpreted to involve three parallel channels with multiple folding and isomerization reactions (Mann et al. (1995) Biochemistry 34, 14573-14580). The refolding of [2-66]2 TR can be described by a much simpler mechanism, involving an association reaction followed by a urea-dependent first-order folding reaction. The second-order rate constant for the association reaction approaches that of the diffusion limit, 3 x 10(8) M-1 s-1 in 1 M urea at 15 degreesC. Double-jump experiments demonstrate that >/=93% of the unfolded monomers proceed to the native dimer via the dimeric intermediate; several lines of evidence demonstrate that this dimeric species is an on-pathway intermediate. The subsequent first-order folding reaction of the dimeric intermediate to the native species involves development of additional secondary structure and tertiary structure. The kinetic folding mechanism of [2-66]2 TR suggests that: (1) the complexity of the folding kinetics of full-length WT TR arises from alternative interactions of the DNA reading heads with the dimerization core domain-not from the intertwined nature of the dimerization interface; (2) residues 2-66 contain all of the sequence information necessary to direct the near-diffusion-limited association reaction in a TR folding reaction; and (3) the formation of secondary and tertiary structure is concurrent with or precedes dimerization, and further development certainly follows the formation of quaternary structure.

The barriers in the bimolecular and unimolecular folding reactions of the dimeric core domain of Escherichia coli Trp repressor are dominated by enthalpic contributions.

The kinetic folding mechanism of the isolated dimerization domain of E. coli Trp repressor, [2-66]2 TR, consists of a nearly diffusion-limited association reaction to form a dimeric intermediate, I2, which is then converted to the native, folded dimeric species, N2 by a first-order folding step (preceding paper in this issue). The two transition states traversed in the folding of [2-66]2 TR were characterized by monitoring the folding and unfolding reactions by stopped-flow fluorescence as a function of temperature and urea. For both transition states, the barriers are dominated by the enthalpic component; the entropic component accelerates the association reaction but has little effect on the subsequent rearrangement reaction. The transition state between I2 and N2 is relatively nativelike, as determined by the sensitivity of the rate constants to denaturant. This study also highlights the key role of solvent entropy in determining the magnitude of the relative free energy of the transition states and the ground states. The positive entropy change for the I2 to N2 reaction, presumably arising from the release of solvent from hydrophobic surfaces, is the driving force for this final folding step, offsetting an unfavorable enthalpic term.

Ligand binding is the principal determinant of stability for the p21(H)-ras protein.

p21(H-ras) is a 21 kDa, alpha/beta sheet protein that, as a member of the GTPase superfamily, acts as a molecular switch in signal transduction pathways. The essential role of GDP and Mg2+ in maintaining the inactive conformation of p21(H-ras) prompted a study of the influence of these ligands on its structure and stability. The urea-induced equilibrium unfolding transitions for the ternary (p21.GDP.Mg2+), binary (p21.GDP) and apo (p21) forms of p21(H-ras) at pH 7.5 and 25 degreesC were monitored by absorbance and circular dichroism spectroscopies. The cooperative disruptions of the secondary and tertiary structures for all three forms are well-described by a two-state model. Global analysis of the equilibrium unfolding data yields a free energy of folding in the absence of urea and under standard state conditions of 14.1 +/- 0.2 kcal mol-1, 7.5 +/- 0.4 kcal mol-1 and 1.8 +/- 0.2 kcal mol-1 for ternary, binary and apo forms, respectively. Near- and far-UV circular dichroism spectra of these three forms of p21(H-ras) show that removal of the Mg2+ from the ternary complex loosens the aromatic side chain packing but leaves the secondary structure largely unchanged. The removal of both GDP and Mg2+ completely releases the side chain packing but leaves a substantial fraction of the secondary structure intact. These results demonstrate that ligands play a significant role in the stability and structure of the p21.GDP.Mg2+ complex. The amino acid sequence itself only contains sufficient information to direct the formation of a large portion of the secondary structure in a molten globule-like state. Ligand binding is required to drive the formation of specific tertiary structure.

The role of ligand binding in the kinetic folding mechanism of human p21(H-ras) protein.

p21(H-ras) plays a critical role in signal transduction pathways by cycling between an active, GTP/Mg2+ ternary complex and an inactive, GDP/Mg2+ complex. Urea-induced equilibrium unfolding studies [Zhang and Matthews (1998) Biochemistry 37, 14881-14890] have shown that GDP and Mg2+ play essential roles in stabilizing the protein. To probe the mechanism of folding and to examine the effects of these ligands on the kinetic folding reaction, unfolding and refolding experiments were performed at a variety of urea and ligand concentrations. A burst phase intermediate with substantial secondary structure and marginal stability was observed during refolding by stopped-flow circular dichroism spectroscopy. Three subsequent refolding phases were detected using a combination of absorbance, circular dichroism, and fluorescence spectroscopy. The fastest phase involves ligand binding and appears to directly form the fully folded enzyme. The intermediate and slow phases do not depend on either urea or ligand concentration under strongly refolding conditions and appear to reflect isomerization or rearrangement reactions. Double- jump experiments demonstrated that the intermediate and slow refolding phases both lead to the native conformation and correspond to parallel rather than sequential reactions. Unfolding is controlled by two phases that involve the release of the ligands when the ligands are in excess. At stoichiometric ligand concentrations, however, the rate-limiting steps in unfolding change from ligand release to isomerization or rearrangement reactions at high urea concentrations. Only the faster unfolding reaction is observed in the absence of Mg2+, suggesting that this reaction corresponds to the unfolding of the binary complex, p21(H-ras)*GDP. The slower unfolding reaction presumably corresponds to the unfolding of the ternary complex, p21(H-ras)*GDP. Mg2+. The kinetic data show that the refolding/unfolding of p21(H-ras) occurs through parallel channels that are strongly influenced by the binding/release of GDP and Mg2+ to/from a pair of native conformers.

Single-tryptophan mutants of monomeric tryptophan repressor: optical spectroscopy reveals nonnative structure in a model for an early folding intermediate.

A monomeric version of the dimeric tryptophan repressor from Escherichia coli, L39E TR, has previously been shown to resemble a transient intermediate that appears in the first few milliseconds of folding [Shao, X., Hensley, P., and Matthews, C. R. (1997) Biochemistry 36, 9941-9949]. In the present study, the optical properties of the two intrinsic tryptophans were used to compare the structure and dynamics of the monomeric form with those of the native, dimeric form. The urea-induced unfolding equilibria of Trp19/L39E TR (Trp99 replaced with Phe) and Trp99/L39E TR (Trp19 replaced with Phe) mutants were monitored by circular dichroism and fluorescence spectroscopies at pH 7.6 and 25 degrees C. Coincident normalized transitions show that the urea denaturation process for each single-tryptophan mutant follows a two-state model involving monomeric native and unfolded forms. The free energies at standard state in the absence of denaturant for Trp19/L39E TR and Trp99/L39E TR are less than that for L39E TR, indicating that both tryptophans are involved in stabilizing the monomer. Fluorescence and near-UV circular dichroism spectroscopies indicate that the tryptophan side chains in monomeric Trp19/L39E TR and Trp99/L39E TR occupy hydrophobic, well-structured environments that are distinctively different from those found in their dimeric counterparts. Acrylamide quenching experiments show that both Trp19 and Trp99 are partially exposed to solvent in the native state, with Trp99 having a slightly greater degree of exposure. Measurements of the steady-state anisotropies of Trp19/L39E and Trp99/L39E TR demonstrate that the motions of both tryptophan side chains are restricted in the folded conformation. On the basis of these data, it can be concluded that this monomeric form of the tryptophan repressor adopts a well-folded, stable conformation with nonnative tertiary structure. When combined with previous results, the current findings demonstrate that the development of higher order structure during the folding of this intertwined dimer does not follow a simple hierarchical model.