The burst-phase intermediate in the refolding of beta-lactoglobulin studied by stopped-flow circular dichroism and absorption spectroscopy

The kinetics of the guanidine hydrochloride-induced unfolding and refolding of bovine beta-lactoglobulin, a predominantly beta-sheet protein in the native state, have been studied by stopped-flow circular dichroism and absorption measurements at pH 3.2 and 4.5 degrees C. The refolding reaction was a complex process composed of different kinetic phases, while the unfolding was a single-phase reaction. Most notably, a burst-phase intermediate of refolding, which was formed during the dead time of stopped-flow measurements (approximately 18 ms), showed more intense ellipticity signals in the peptide region below 240 nm than the native state, yielding overshoot behavior in the refolding curves. We have investigated the spectral properties and structural stability of the burst-phase intermediate and also the structural properties in the unfolded state in 4.0 M guanidine hydrochloride of the protein and its disulfide-cleaved derivative. The main conclusions are: (1) the more intense ellipticity of the intermediate in the peptide region arises from formation of non-native alpha-helical structure in the intermediate, apparently suggesting that the folding of beta-lactoglobulin is not represented by a simple sequential mechanism. (2) The burst-phase intermediate has, however, a number of properties in common with the folding intermediates or with the molten globule states of other globular proteins whose folding reactions are known to be represented by the sequential model. These properties include: the presence of the secondary structure without the specific tertiary structure; formation of a hydrophobic core; broad unfolding transition of the intermediate; and rapidity of formation of the intermediate. The burst-phase intermediate of beta-lactoglobulin is thus classified as the same species as the molten globule state. (3) The circular dichroism spectra of beta-lactoglobulin and its disulfide-cleaved derivative in 4.0 M guanidine hydrochloride suggests the presence of the residual beta-structure in the unfolded state and the stabilization of the beta-structure by disulfide bonds. Thus; if this residual beta-structure is part of the native beta-structure and forms a folding initiation site, the folding reaction of beta-lactoglobulin may not necessarily be inconsistent with the sequential model. The non-native alpha-helices in the burst-phase intermediate may be formed in an immature part of the protein molecule because of the local alpha-helical propensity in this part.     

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.     

Kinetic evidence for an obligatory intermediate in the folding of the membrane protein bacteriorhodopsin

A photodiode array in conjunction with a rapid stopped-flow mixing method, with a millisecond time resolution, is used here to study the refolding of the membrane protein bacteriorhodopsin from an apoprotein state with a native-like secondary structure in mixed phospholipid/detergent micelles. Refolding to the native state is initiated by the rapid mixing of all-trans-retinal and the apoprotein bacterioopsin in mixed micelles. A lag phase of several seconds is observed in the appearance of the native state, as monitored by the increase in absorbance of the native chromophore. This observation demonstrates unequivocally that an intermediate is obligatory in the formation of bacteriorhodopsin. It is further shown that this intermediate is spectroscopically distinct from free retinal (absorbance maximum approximately 380 nm) and bacteriorhodopsin (absorbance maximum approximately 560 nm) and absorbs maximally at 430 nm. Evidence for the decay of the 430 nm intermediate into bacteriorhodopsin via three distinct parallel pathways is also provided. Taken together, these findings are used to describe a model in which distinct populations of the apoprotein in mixed micelles appear to fold along separate pathways via their corresponding intermediates into the native state. How the results of this study provide new insights into the mechanisms of protein folding is discussed.     

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.     

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.     

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.     

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.     

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.     

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.     

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.     

Native-like structure of a protein-folding intermediate bound to the chaperonin GroEL

The chaperonin GroEL binds nonnative proteins in its central channel through hydrophobic interactions and initiates productive folding in this space underneath bound co-chaperone, GroES, in the presence of ATP. The questions of where along the folding pathway a protein is recognized by GroEL, and how much structure is present in a bound substrate have remained subjects of discussion, with some experiments suggesting that bound forms are fully unfolded and others suggesting that bound species are partially structured. Here we have studied a substrate protein, human dihydrofolate reductase (DHFR), observing in stopped-flow fluorescence experiments that it can rapidly bind to GroEL at various stages of folding. We have also analyzed the structure of the GroEL-bound protein using hydrogen-deuterium exchange and NMR spectroscopy. The pattern and magnitude of amide proton protection indicate that the central parallel beta-sheet found in native DHFR is present in a moderately stable state in GroEL-bound DHFR. Considering that the strands are derived from distant parts of the primary structure, this suggests that a native-like global topology is also present. We conclude that significant native-like structure is present in protein-folding intermediates bound to GroEL.     

Nature of the unfolded state of ribonuclease A: effect of cis-trans X-Pro peptide bond isomerization

The equilibrium unfolded state of disulfide-intact bovine pancreatic ribonuclease A is a heterogeneous mixture of unfolded species. Previously, four unfolded species have been detected experimentally. They are Uvf, Uf, UsII, and UsI which have refolding time constants on the millisecond, millisecond to second, second to tens of seconds, and hundreds of seconds time scales, respectively. In the current study, the refolding pathway of the protein was investigated under favorable folding conditions of 0.58 M GdnHCl, pH 5.0, and 15 degrees C. In addition to the above four unfolded species, the presence of a fifth unfolded species was detected. It has a refolding time constant on the order of 2 s under the conditions employed. This new unfolded species is labeled Um, for medium-refolding species. Single-jump refolding experiments monitored by tyrosine burial and by cytidine 2'-monophosphate inhibitor binding indicate that the different unfolded species refold to the native state along independent refolding pathways. The buildup of the different unfolded species upon unfolding of the protein from the native state was monitored by absorbance using double-jump experiments. These experiments were carried out at 15 degrees C and consisted of an unfolding step at 4.2 M GdnHCl and pH 2.0, followed, after a variable delay time, by a refolding step at 0.58 M GdnHCl and pH 5.0. The results of these experiments support the conclusion that the different unfolded species arise from cis-trans isomerizations at the X-Pro peptide bonds of Pro 93, 114, and 117 in the unfolded state of the protein. The rates of these isomerizations were obtained for each of these three X-Pro peptide bonds at 15 degrees C.     

Reaction of the NAD(P)H:flavin oxidoreductase from Escherichia coli with NADPH and riboflavin: identification of intermediates

Flavin reductase catalyzes the reduction of free flavins by NAD(P)H. As isolated, Escherichia coli flavin reductase does not contain any flavin prosthetic group but accommodates both the reduced pyridine nucleotide and the flavin substrate in a ternary complex prior to oxidoreduction. The reduction of riboflavin by NADPH catalyzed by flavin reductase has been studied by static and rapid kinetics absorption spectroscopies. Static absorption spectroscopy experiments revealed that, in the presence of riboflavin and reduced pyridine nucleotide, flavin reductase stabilizes, although to a small extent, a charge-transfer complex of NADP+ and reduced riboflavin. In addition, reduction of riboflavin was found to be essentially irreversible. Rapid kinetics absorption spectroscopy studies demonstrated the occurrence of two intermediates with long-wavelength absorption during the catalytic cycle. Such intermediate species exhibit spectroscopic properties similar to those of charge-transfer complexes of oxidized flavin and NAD(P)H, and reduced flavin and NAD(P)+, respectively, which have been identified as intermediates during the reaction of flavoenzymes of the ferredoxin-NADP+ reductase family. Thus, a minimal kinetic scheme for the reaction of flavin reductase with NADPH and riboflavin can be proposed. After formation of the Michaelis complex of flavin reductase with NADPH and riboflavin, a first intermediate, identified as a charge-transfer complex of NADPH and riboflavin, is formed. It is followed by a second charge-transfer intermediate of enzyme-bound NADP+ and reduced riboflavin. The latter decays, yielding the Michaelis complex of flavin reductase with NADP+ and reduced riboflavin, which then dissociates to complete the reaction. These results support the initial hypothesis of a structural similarity between flavin reductase and the enzymes of the ferredoxin-NADP+ reductase family and extend it at a functional level.     

A protein folding intermediate of ribonuclease T1 characterized at high resolution by 1D and 2D real-time NMR spectroscopy

The rate-limiting step during the refolding of S54G/P55N ribonuclease T1 is determined by the slow trans-->cis prolyl isomerisation of Pro39. We investigated the refolding of this variant by one-dimensional (1D) and two-dimensional (2D) real-time NMR spectroscopy, initiated by a tenfold dilution from 6 M guanidine hydrochloride at 10 degreesC. Two intermediates could be resolved with the 1D approach. The minor intermediate, which is only present early during refolding, is largely unfolded. The major intermediate, with an incorrect trans Pro39 peptide bond, is highly structured with 33 amide protons showing native chemical shifts and native NOE patterns. They could be assigned in a real-time 2D-NOESY (nuclear Overhauser enhancement spectroscopy) by using a new assignment strategy to generate positive and negative signal intensities for native and non-native NOE cross-peaks, respectively. Surprisingly, amide protons with non-native environments are located not only close to Tyr38-Pro39, but are spread throughout the entire protein, including the C-terminal part of the alpha-helix, beta-strands 3 and 4 and several loop regions. Native secondary and tertiary structure was found for the major intermediate in the N-terminal beta-strands 1 and 2 and the C terminus (connected by the disulfide bonds), the N-terminal part of the alpha-helix, and the loops between beta-strands 4/5 and 5/6. Implications of these native and non-native structure elements of the intermediate for the refolding of S54G/P55N ribonuclease T1 and for cis/trans isomerizations are discussed.     

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.     

Kinetics of lysozyme refolding: structural characterization of a non-specifically collapsed state using time-resolved X-ray scattering

We report time-resolved small angle X-ray scattering (SAXS) studies of the structural characteristics of the collapsed state of lysozyme from henegg white (HEL) obtained on initiating refolding by rapidly changing solvent conditions from 8 M to 1.1 M urea at pH 2.9. At this reduced pH the lifetime, of about one second, of the non-specifically collapsed ensemble is considerably prolonged relative to its value at pH 5.2. The SAXS studies are combined with time resolved measurements of tryptophan fluorescence and of the rate of formation of native molecules using interrupted refolding experiments. We observe large burst phase changes in intrinsic tryptophan fluorescence and in the radius of gyration (Rg) which is reduced from 22 A in the fully unfolded state to approximately 19 to 20 A. Subsequent decrease of the Rg to the value for native lysozyme (15 A) follows the time course of formation of native molecules. Single exponential fits to the singular value decomposition (SVD) components of the SAXS data allow reconstruction of the SAXS profile at early time points of refolding. The results of this analysis suggest a globular shape of the collapsed state. A similar fit to the forward scattering amplitude, I(0), suggests that the collapsed state has a solvent accessible surface area which is considerably increased relative to that of the native protein. These results show directly that the non-specifically collapsed state formed during the burst phase in lysozyme refolding indeed represents a molecular compaction and a change in shape from a fully denatured random coil state (albeit restricted by disulfide bonds) to an ensemble of globular conformations which, however, have not yet formed a solvent-protected hydrophobic core.     

Leishmania major pteridine reductase 1 belongs to the short chain dehydrogenase family: stereochemical and kinetic evidence

Pteridine reductase 1 (PTR1) is a novel broad spectrum enzyme of pterin and folate metabolism in the protozoan parasite Leishmania. Overexpression of PTR1 confers methotrexate resistance to these protozoa, arising from the enzyme's ability to reduce dihydrofolate and its relative insensitivity to methotrexate. The kinetic mechanism and stereochemical course for the catalyzed reaction confirm PTR1's membership within the short chain dehydrogenase/reductase (SDR) family. With folate as a substrate, PTR1 catalyzes two rounds of reduction, yielding 5,6,7, 8-tetrahydrofolate and oxidizing 2 equiv of NADPH. Dihydrofolate accumulates transiently during folate reduction and is both a substrate and an inhibitor of PTR1. PTR1 transfers the pro-S hydride of NADPH to carbon 6 on the si face of dihydrofolate, producing the same stereoisomer of THF as does dihydrofolate reductase. Product inhibition and isotope partitioning studies support an ordered ternary complex mechanism, with NADPH binding first and NADP+ dissociating after the reduced pteridine. Identical kinetic mechanisms and NAD(P)H hydride chirality preferences are seen with other SDRs. An observed tritium effect upon V/K for reduction of dihydrofolate arising from isotopic substitution of the transferred hydride was suppressed at a high concentration of dihydrofolate, consistent with a steady-state ordered kinetic mechanism. Interestingly, half of the binary enzyme-NADPH complex appears to be incapable of rapid turnover. Fluorescence quenching results also indicate the existence of a nonproductive binary enzyme-dihydrofolate complex. The nonproductive complexes observed between PTR1 and its substrates are unique among members of the SDR family and may provide leads for developing antileishmanial therapeutics.     

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.