Folding mechanism of an ankyrin repeat protein: scaffold and active site formation of human CDK inhibitor p19(INK4d)

The p19(INK4d) protein consists of five ankyrin repeats (ANK) and controls the human cell cycle by inhibiting the cyclin D-dependent kinases (CDK) 4 and 6. We investigated the folding of p19(INK4d) by urea-induced unfolding transitions, kinetic analyses of unfolding and refolding, including double-mixing experiments and a special assay for folding intermediates. Folding is a sequential two-step reaction via a hyperfluorescent on-pathway intermediate. This intermediate is present under all conditions, during unfolding, refolding and at equilibrium. The folding mechanism was confirmed by a quantitative global fit of a consistent set of equilibrium and kinetic data revealing the thermodynamics and intrinsic folding rates of the different states. Surprisingly, the N<-->I transition is much faster compared to the I<-->U transition. The urea-dependence of the intrinsic folding rates causes population of the intermediate at equilibrium close to the transition midpoint. NMR detected hydrogen/deuterium exchange and the analysis of truncated variants showed that the C-terminal repeats ANK3-5 are already folded in the on-pathway intermediate, whereas the N-terminal repeats 1 and 2 are not folded. We suggest that during refolding, repeats ANK3-ANK5 first form the scaffold for the subsequent assembly of repeats ANK1 and ANK2. The binding function of p19(INK4d) resides in the latter repeats. We propose that the graded stability and the facile unfolding of repeats 1 and 2 is a prerequisite for the down-regulation of the inhibitory activity of p19(INK4d) during the cell-cycle.     

Effects of multiple replacements at a single position on the folding and stability of dihydrofolate reductase from Escherichia coli

We have made multiple replacements (alanine, arginine, cysteine, histidine, isoleucine, serine, tyrosine) of valine-75 in dihydrofolate reductase from Escherichia coli to examine the relative importance to protein folding of the position that is substituted and the specific character of the amino acid replacement. Valine-75 is part of the eight-stranded beta sheet that forms the structural core of the protein. The isopropyl side chain participates in van der Waals interactions with a number of nonpolar residues, helping to establish a large hydrophobic cluster. Equilibrium studies showed that arginine, histidine, isoleucine, serine, and tyrosine destabilize the protein by 1.9-2.8 kcal mol-1. Alanine and cysteine substitutions have little or no effect. Contrary to other recent studies of the effect of multiple replacements at a hydrophobic site, there is no observed correlation between the changes of the free energy of folding and the changes of the free energy of transfer for the individual amino acids from water to an organic solvent when they are inserted into this site. The effects observed in kinetic studies are both consistent with and extend the equilibrium results; these data indicate that position 75 participates in a rate-limiting step of folding. Some of the equilibrium and kinetic properties of the tyrosine-75 mutant deviated significantly from those of wild-type protein and the other mutants at position 75. (1) The tyrosine variant displayed a complex banding pattern when analyzed by native gel electrophoresis; the wild-type protein and all other mutants at position 75 migrated as single, discrete bands. (2) Comparison of the difference ultraviolet and circular dichroism transition curves showed that a third species is populated at equilibrium; the wild-type protein and all other mutants at position 75 follow a two-state model involving only native and unfolded forms. (3) A third kinetic phase appeared in the unfolding reaction; the wild-type protein and all other mutants at position 75 only showed two kinetic phases in unfolding. Properties 1 and 3 suggest that the tyrosine mutation significantly alters the distribution of native conformers in the protein. These effects on the equilibrium and kinetic data readily display an overriding pattern: residues that would require hydrogen bonding or lead to an expansion of the tightly packed hydrophobic environment in which valine-75 resides destabilize the protein and alter relaxation times of kinetic phases in a consistent manner.(ABSTRACT TRUNCATED AT 400 WORDS)     

Revealing a Concealed Intermediate that Forms after the Rate-limiting Step of Refolding of the SH3 Domain of PI3 Kinase

Kinetic and equilibrium studies of the folding and unfolding of the SH3 domain of the PI3 kinase, have been used to identify a folding intermediate that forms after the rate-limiting step on the folding pathway. Folding and unfolding, in urea as well as in guanidine hydrochloride (GdnHCl), were studied by monitoring changes in the intrinsic fluorescence or in the far-UV circular dichroism (CD) of the protein. The two probes yield non-coincident equilibrium transitions for unfolding in urea, indicating that an intermediate, I, exists in equilibrium with native (N) and unfolded (U) protein, during unfolding. Hence, the equilibrium unfolding data were analyzed according to a three-state N ↔ I ↔ U mechanism. An intermediate is observed also in kinetic unfolding studies, and its presence leads to the unfolding reaction in urea as well as in GdnHCl, occurring in two steps. The fast step is complete within the initial 11 ms of unfolding and manifests itself in a burst phase change in fluorescence. At high concentrations of GdnHCl, the entire change in fluorescence during unfolding occurs during the 11 ms burst phase. CD measurements indicate, however, that I retains N-like secondary structure. An analysis of the kinetic and thermodynamic data, according to a minimal three-state N ↔ I ↔ U mechanism, positions I after the rate-limiting transition state, TS1, of folding, on the reaction coordinate of folding in GdnHCl. Hence, I is not revealed when folding is commenced from U, regardless of the nature of the probe used to follow the folding reaction. Interrupted unfolding experiments, in which the protein is unfolded transiently in GdnHCl for various lengths of time before being refolded, showed that I refolds to N much faster than does U, confirms the analysis of the direct folding and unfolding experiments, that I is formed after the rate-limiting step of refolding in GdnHCl.     

Kinetic Folding Mechanism of Erythropoietin

This report describes what to our knowledge is the first kinetic folding studies of erythropoietin, a glycosylated four-helical bundle cytokine responsible for the regulation of red blood cell production. Kinetic responses for folding and unfolding reactions initiated by manual mixing were monitored by far-ultraviolet circular dichroism and fluorescence spectroscopy, and folding reactions initiated by stopped-flow mixing were monitored by fluorescence. The urea concentration dependence of the observed kinetics were best described by a three-state model with a transiently populated intermediate species that is on-pathway and obligatory. This folding scheme was further supported by the excellent agreement between the free energy of unfolding and m-value calculated from the microscopic rate constants derived from this model and these parameters determined from separate equilibrium unfolding experiments. Compared to the kinetics of other members of the four-helical bundle cytokine family, erythropoietin folding and unfolding reactions were slower and less susceptible to aggregation. We tentatively attribute these slower rates and protection from association events to the large amount of carbohydrate attached to erythropoietin at four sites.     

Unique fluorophores in the dimeric archaeal histones hMfB and hPyA1 reveal the impact of nonnative structure in a monomeric kinetic intermediate

Homodimeric archaeal histones and heterodimeric eukaryotic histones share a conserved structure but fold through different kinetic mechanisms, with a correlation between faster folding/association rates and the population of kinetic intermediates. Wild-type hMfB (from Methanothermus fervidus) has no intrinsic fluorophores; Met35, which is Tyr in hyperthermophilic archaeal histones such as hPyA1 (from Pyrococcus strain GB-3A), was mutated to Tyr and Trp. Two Tyr-to-Trp mutants of hPyA1 were also characterized. All fluorophores were introduced into the long, central alpha-helix of the histone fold. Far-UV circular dichroism (CD) indicated that the fluorophores did not significantly alter the helical content of the histones. The equilibrium unfolding transitions of the histone variants were two-state, reversible processes, with DeltaG degrees (H2O) values within 1 kcal/mol of the wild-type dimers. The hPyA1 Trp variants fold by two-state kinetic mechanisms like wild-type hPyA1, but with increased folding and unfolding rates, suggesting that the mutated residues (Tyr-32 and Tyr-36) contribute to transition state structure. Like wild-type hMfB, M35Y and M35W hMfB fold by a three-state mechanism, with a stopped-flow CD burst-phase monomeric intermediate. The M35 mutants populate monomeric intermediates with increased secondary structure and stability but exhibit decreased folding rates; this suggests that nonnative interactions occur from burial of the hydrophobic Tyr and Trp residues in this kinetic intermediate. These results implicate the long central helix as a key component of the structure in the kinetic monomeric intermediates of hMfB as well as the dimerization transition state in the folding of hPyA1.     

Equilibrium and kinetic studies of protein cooperativity using urea-induced folding/unfolding of a Ubq-UIM fusion protein

Understanding the origins of cooperativity in proteins remains an important topic in protein folding. This study describes experimental folding/unfolding equilibrium and kinetic studies of the engineered protein Ubq-UIM, consisting of ubiquitin (Ubq) fused to the sequence of the ubiquitin interacting motif (UIM) via a short linker. Urea-induced folding/unfolding profiles of Ubq-UIM were monitored by far-UV circular dichroism and fluorescence spectroscopies and compared to those of the isolated Ubq domain. It was found that the equilibrium data for Ubq-UIM is inconsistent with a two-state model. Analysis of the kinetics of folding shows similarity in the folding transition state ensemble between Ubq and Ubq-UIM, suggesting that formation of Ubq domain is independent of UIM. The major contribution to the stabilization of Ubq-UIM, relative to Ubq, was found to be in the rates of unfolding. Moreover, it was found that the kinetic m-values for Ubq-UIM unfolding, monitored by different probes (far-UV circular dichroism and fluorescence spectroscopies), are different; thereby, further supporting deviations from a two-state behavior. A thermodynamic linkage model that involves four states was found to be applicable to the urea-induced unfolding of Ubq-UIM, which is in agreement with the previous temperature-induced unfolding study. The applicability of the model was further supported by site-directed variants of Ubq-UIM that have altered stabilities of Ubq/UIM interface and/or stabilities of individual Ubq- and UIM-domains. All variants show increased cooperativity and one variant, E43N_Ubq-UIM, appears to behave very close to an equilibrium two-state.     

The tetrameric α-helical membrane protein GlpF unfolds via a dimeric folding intermediate

Many membrane proteins appear to be present and functional in higher-order oligomeric states. While few studies have analyzed the thermodynamic stability of α-helical transmembrane (TM) proteins under equilibrium conditions in the past, oligomerization of larger polytopic monomers has essentially not yet been studied. However, it is vital to study the folding of oligomeric membrane proteins to improve our understanding of the general mechanisms and pathways of TM protein folding. To investigate the folding and stability of the aquaglyceroporin GlpF from Escherichia coli, unfolding of the protein in mixed micelles was monitored by steady-state fluorescence and circular dichroism spectroscopy as well as by seminative sodium dodecyl sulfate-polyacrylamide gel electrophoresis analyses. On the basis of our results, it appears most likely that GlpF unfolds in a two-step process, involving the equilibrium of tetrameric, dimeric, and monomeric GlpF species. A kinetic analysis also indicates an intermediate along the kinetic GlpF unfolding pathway, and thus, two phases are involved in GlpF unfolding. While three-state unfolding pathways and a dimeric folding intermediate are not uncommon for water-soluble proteins, a stable (un)folding intermediate with a decreased oligomeric structure has not been detected or reported for any α-helical membrane protein.     

Folding/unfolding kinetics of mutant forms of iso-1-cytochrome c with replacement of proline-71

Proline-71, an evolutionally conserved residue that separates two short alpha-helical regions, is replaced by valine, threonine, or isoleucine in at least partially functional forms of iso-1-cytochrome c from Saccharomyces cerevisiae [Ernst, J. F., Hampsey, D. M., Stewart, J. W., Rackovsky, S., Goldstein, D., & Sherman, F. (1985) J. Biol. Chem. 260, 13225-13236]. To assign the effects of perturbations at position 71 to steps in the process of protein folding, the kinetic properties of the folding/unfolding reactions of normal protein and the three mutant forms are compared. At pH 6.0, 20 degrees C, fluorescence-detected folding/unfolding kinetics are monitored below, within, and above the equilibrium transition zone by using stopped-flow mixing to perform guanidine hydrochloride concentration jumps. Three kinetic phases are detected for each of the four proteins. The fastest of these phases (tau 3) differs in rate for the wild type and mutant proteins. The remaining kinetic phases (tau 1 and tau 2) have similar rates for all four proteins over the entire range of folding/unfolding conditions. The guanidine hydrochloride dependence of the relative amplitudes of the kinetic phases is complex and is sensitive to the nature of the substituent at position 71: each of the four proteins shows differences in the fraction of folding/unfolding associated with the two fastest rate processes. The results suggest that it is the location of the mutation in the primary structure rather than the nature of the substituent that determines which kinetic step (or steps) is changed in rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Predicting repeat protein folding kinetics from an experimentally determined folding energy landscape

The Notch ankyrin domain is a repeat protein whose folding has been characterized through equilibrium and kinetic measurements. In previous work, equilibrium folding free energies of truncated constructs were used to generate an experimentally determined folding energy landscape (Mello and Barrick, Proc Natl Acad Sci USA 2004;101:14102–14107). Here, this folding energy landscape is used to parameterize a kinetic model in which local transition probabilities between partly folded states are based on energy values from the landscape. The landscape‐based model correctly predicts highly diverse experimentally determined folding kinetics of the Notch ankyrin domain and sequence variants. These predictions include monophasic folding and biphasic unfolding, curvature in the unfolding limb of the chevron plot, population of a transient unfolding intermediate, relative folding rates of 19 variants spanning three orders of magnitude, and a change in the folding pathway that results from C‐terminal stabilization. These findings indicate that the folding pathway(s) of the Notch ankyrin domain are thermodynamically selected: the primary determinants of kinetic behavior can be simply deduced from the local stability of individual repeats.     

Detection of a hidden folding intermediate of the third domain of PDZ

The folding pathway of the third domain of PDZ from the synaptic protein PSD-95 was characterized using kinetic and equilibrium methods by monitoring the fluorescence signal from a Trp residue that is incorporated at a near-surface position. Kinetic folding of this domain showed multiple exponential phases, whereas unfolding showed a single exponential phase. The slow kinetic phases were attributed to isomerization of proline residues, since there are five proline residues in this domain. We found that the logarithms of the rate constants for the fast phase of folding and unfolding are linearly dependent on the concentrations of denaturant. The unfolding free energy derived from these rate constants at zero denaturant was close to the value measured using the equilibrium method, suggesting the absence of detectable sub-millisecond folding intermediates. However, native-state hydrogen exchange experiments detected a partially unfolded intermediate under native conditions. It was further confirmed by a protein engineering study. These data suggest that a hidden intermediate exists after the rate-limiting step in the folding of the third domain of PDZ.     

Folding mechanism of the (H3-H4)2 histone tetramer of the core nucleosome

To further understand oligomeric protein assembly, the folding and unfolding kinetics of the H3-H4 histone tetramer have been examined. The tetramer is the central protein component of the core nucleosome, which is the basic unit of DNA compaction into chromatin in the eukaryotic nucleus. This report provides the first kinetic folding studies of a protein containing the histone fold dimerization motif, a motif observed in several protein-DNA complexes. Previous equilibrium unfolding studies have demonstrated that, under physiological conditions, there is a dynamic equilibrium between the H3-H4 dimer and tetramer species. This equilibrium is shifted predominantly toward the tetramer in the presence of the organic osmolyte trimethylamine-N-oxide (TMAO). Stopped-flow methods, monitoring intrinsic tyrosine fluorescence and far-UV circular dichroism, have been used to measure folding and unfolding kinetics as a function of guanidinium hydrochloride (GdnHCl) and monomer concentrations, in 0 and 1 M TMAO. The assignment of the kinetic phases was aided by the study of an obligate H3-H4 dimer, using the H3 mutant, C110E, which destabilizes the H3-H3' hydrophobic four-helix bundle tetramer interface. The proposed kinetic folding mechanism of the H3-H4 system is a sequential process. Unfolded H3 and H4 monomers associate in a burst phase reaction to form a dimeric intermediate that undergoes a further, first-order folding process to form the native dimer in the rate-limiting step of the folding pathway. H3-H4 dimers then rapidly associate with a rate constant of > or =10(7) M(-1)sec(-1) to establish a dynamic equilibrium between the fully assembled tetramer and folded H3-H4 dimers.     

Detection and structure determination of an equilibrium unfolding intermediate of Rd-apocytochrome b562: native fold with non-native hydrophobic interactions

The absence of detectable kinetic and equilibrium folding intermediates by optical probes is commonly taken to indicate that protein folding is a two-state process. However, for some small proteins with apparent two-state behavior, unfolding intermediates have been identified in native-state hydrogen exchange or kinetic unfolding experiments monitored by nuclear magnetic resonance. Rd-apocytochrome b(562), a four-helix bundle, is one such protein. Here, we found another unfolding intermediate for Rd-apocytochrome b(562). It is based on a cooperative transition of (15)N chemical shifts of amide protons as a function of urea concentrations before the global unfolding. We have solved the high-resolution structure of the protein at 2.8 M urea, which is after this cooperative transition but before the global unfolding. All four helices remained intact, but a number of hydrophobic core residues repacked. This intermediate provides a possible structural interpretation for the kinetic unfolding intermediates observed using nuclear magnetic resonance methods for several proteins and has important implications for theoretical studies of protein folding.     

An Overlapping Region between the Two Terminal Folding Units of the Outer Surface Protein A (OspA) Controls Its Folding Behavior

Although many naturally occurring proteins consist of multiple domains, most studies on protein folding to date deal with single-domain proteins or isolated domains of multi-domain proteins. Studies of multi-domain protein folding are required for further advancing our understanding of protein folding mechanisms. Borrelia outer surface protein A (OspA) is a β-rich two-domain protein, in which two globular domains are connected by a rigid and stable single-layer β-sheet. Thus, OspA is particularly suited as a model system for studying the interplays of domains in protein folding. Here, we studied the equilibria and kinetics of the urea-induced folding–unfolding reactions of OspA probed with tryptophan fluorescence and ultraviolet circular dichroism. Global analysis of the experimental data revealed compelling lines of evidence for accumulation of an on-pathway intermediate during kinetic refolding and for the identity between the kinetic intermediate and a previously described equilibrium unfolding intermediate. The results suggest that the intermediate has the fully native structure in the N-terminal domain and the single layer β-sheet, with the C-terminal domain still unfolded. The observation of the productive on-pathway folding intermediate clearly indicates substantial interactions between the two domains mediated by the single-layer β-sheet. We propose that a rigid and stable intervening region between two domains creates an overlap between two folding units and can energetically couple their folding reactions.     

Role of entropy in protein thermostability: folding kinetics of a hyperthermophilic cold shock protein at high temperatures using 19F NMR

We used (19)F NMR to extend the temperature range accessible to detailed kinetic and equilibrium studies of a hyperthermophilic protein. Employing an optimized incorporation strategy, the small cold shock protein from the bacterium Thermotoga maritima (TmCsp) was labeled with 5-fluorotryptophan. Although chaotropically induced unfolding transitions revealed a significant decrease in the stabilization free energy upon fluorine labeling, the protein's kinetic folding mechanism is conserved. Temperature- and guanidinium chloride-dependent equilibrium unfolding transitions monitored by (19)F NMR agree well with the results from optical spectroscopy, and provide a stringent test of the two-state folding character of TmCsp. Folding and unfolding rate constants at high temperatures were determined from the (19)F NMR spectra close to the midpoint of thermal unfolding by global line shape analysis. In combination with results from stopped-flow experiments at lower temperatures, they show that the folding rate constant of TmCsp and its temperature dependence closely resemble those of its mesophilic homologue from Bacillus subtilis, BsCspB. However, the unfolding rate constant of TmCsp is two orders of magnitude lower over the entire temperature range that was investigated. Consequently, the difference in conformational stability between the two proteins is solely due to the unfolding rate constant over a wide temperature range. A thermodynamic analysis points to an important role of entropic factors in the stabilization of TmCsp relative to its mesophilic homologues.     

Presence of the cofactor speeds up folding of Desulfovibrio desulfuricans flavodoxin

Flavodoxin is an alpha/beta protein with a noncovalently bound flavin-mononucleotide (FMN) cofactor. The apo-protein adopts a structure identical to that of the holo-form, although there is more dynamics in the FMN-binding loops. The equilibrium unfolding processes of Azotobacter vinelandii apo-flavodoxin, and Desulfovibrio desulfuricans ATCC strain 27774 apo- and holo-flavodoxins involve rather stable intermediates. In contrast, we here show that both holo- and apo-forms of flavodoxin from D. desulfuricans ATCC strain 29577 (75% sequence similarity with the strain 27774 protein) unfold in two-state equilibrium processes. Moreover, the FMN cofactor remains bound to the unfolded holo-protein. The folding and unfolding kinetics for holo-flavodoxin exhibit two-state behavior, albeit an additional slower phase is present at very low denaturant concentrations. The extrapolated folding time in water for holo-flavodoxin, approximately 280 microsec, is in excellent agreement with that predicted from the protein's native-state topology. Unlike the holo-protein behavior, the folding and unfolding reactions for apo-flavodoxin are best described by two kinetic phases, with rates differing approximately 15-fold, suggesting the presence of a kinetic intermediate. Both folding phases for apo-flavodoxin are orders of magnitude slower (40- and 530-fold, respectively) than that for the holo-protein. We conclude that polypeptide-cofactor interactions in the unfolded state of D. desulfuricans strain 29577 flavodoxin alter the kinetic-folding path towards two-state and speed up the folding reaction.     

The folding of dimeric cytoplasmic malate dehydrogenase. Equilibrium and kinetic studies.

Porcine heart cytoplasmic malate dehydrogenase (s-MDH) is a dimeric protein (2 x 35 kDa). We have studied equilibrium unfolding and refolding of s-MDH using activity assay, fluorescence, far-UV and near-UV circular dichroism (CD) spectroscopy, hydrophobic probe-1-anilino-8-napthalene sulfonic acid binding, dynamic light scattering, and chromatographic (HPLC) techniques. The unfolding and refolding transitions are reversible and show the presence of two equilibrium intermediate states. The first one is a compact monomer (MC) formed immediately after subunit dissociation and the second one is an expanded monomer (ME), which is little less compact than the native monomer and has most of the characteristic features of a 'molten globule' state. The equilibrium transition is fitted in the model: 2U <--> 2M(E) <--> 2M(C) <--> D. The time course of kinetics of self- refolding of s-MDH revealed two parallel folding pathways [Rudolph, R., Fuchs, I. & Jaenicke, R. (1986) Biochemistry 25, 1662-1669]. The major pathway (70%) is 2U-->2M*-->2M-->D, the rate limiting step being the isomerization of the monomers (K1 = 1.7 x 10(-3) s(-1)). The minor pathway (30%) involves an association step leading to the incorrectly folding dimers, prior to the very slow D*-->D folding step. In this study, we have characterized the folding-assembly pathway of dimeric s-MDH. Our kinetic and equilibrium experiments indicate that the folding of s-MDH involves the formation of two folding intermediates. However, whether the equilibrium intermediates are equivalent to the kinetic ones is beyond the scope of this study.     

Comparison of the folding mechanism of highly homologous proteins in the lipid‐binding protein family

The folding mechanism of two closely related proteins in the intracellular lipid‐binding protein family, human bile acid‐binding protein (hBABP), and rat bile acid‐binding protein (rBABP) were examined. These proteins are 77% identical (93% similar) in sequence. Both of these single domain proteins fit well to a two‐state model for unfolding by fluorescence and circular dichroism at equilibrium. Three phases were observed during the unfolding of rBABP by fluorescence but only one phase was observed during the unfolding of hBABP, suggesting that at least two kinetic intermediates accumulate during the unfolding of rBABP that are not observed during the unfolding of hBABP. Fluorine NMR was used to examine the equilibrium unfolding behavior of the W49 side chain in 6‐fluorotryptophan‐labeled rBABP and hBABP. The structure of rBABP appears to be more dynamic than that of hBABP in the vicinity of W49 in the absence of denaturant, and urea has a greater effect on this dynamic behavior for rBABP than for hBABP. As such, the folding behavior of highly sequence related proteins in this family can be quite different. These differences imply that moderately sized proteins with high sequence and structural similarity can still populate quite different structures during folding. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Evidence for a Shared Mechanism in the Formation of Urea-Induced Kinetic and Equilibrium Intermediates of Horse Apomyoglobin from Ultrarapid Mixing Experiments

In this study, the equivalence of the kinetic mechanisms of the formation of urea-induced kinetic folding intermediates and non-native equilibrium states was investigated in apomyoglobin. Despite having similar structural properties, equilibrium and kinetic intermediates accumulate under different conditions and via different mechanisms, and it remains unknown whether their formation involves shared or distinct kinetic mechanisms. To investigate the potential mechanisms of formation, the refolding and unfolding kinetics of horse apomyoglobin were measured by continuous- and stopped-flow fluorescence over a time range from approximately 100 μs to 10 s, along with equilibrium unfolding transitions, as a function of urea concentration at pH 6.0 and 8°C. The formation of a kinetic intermediate was observed over a wider range of urea concentrations (0–2.2 M) than the formation of the native state (0–1.6 M). Additionally, the kinetic intermediate remained populated as the predominant equilibrium state under conditions where the native and unfolded states were unstable (at ~0.7–2 M urea). A continuous shift from the kinetic to the equilibrium intermediate was observed as urea concentrations increased from 0 M to ~2 M, which indicates that these states share a common kinetic folding mechanism. This finding supports the conclusion that these intermediates are equivalent. Our results in turn suggest that the regions of the protein that resist denaturant perturbations form during the earlier stages of folding, which further supports the structural equivalence of transient and equilibrium intermediates. An additional folding intermediate accumulated within ~140 μs of refolding and an unfolding intermediate accumulated in <1 ms of unfolding. Finally, by using quantitative modeling, we showed that a five-state sequential scheme appropriately describes the folding mechanism of horse apomyoglobin.     

Glutamine deamidation destabilizes human gammaD-crystallin and lowers the kinetic barrier to unfolding

Human eye lens transparency requires life long stability and solubility of the crystallin proteins. Aged crystallins have high levels of covalent damage, including glutamine deamidation. Human gammaD-crystallin (HgammaD-Crys) is a two-domain beta-sheet protein of the lens nucleus. The two domains interact through interdomain side chain contacts, including Gln-54 and Gln-143, which are critical for stability and folding of the N-terminal domain of HgammaD-Crys. To test the effects of interface deamidation on stability and folding, single and double glutamine to glutamate substitutions were constructed. Equilibrium unfolding/refolding experiments of the proteins were performed in guanidine hydrochloride at pH 7.0, 37 degrees C, or urea at pH 3.0, 20 degrees C. Compared with wild type, the deamidation mutants were destabilized at pH 7.0. The proteins populated a partially unfolded intermediate that likely had a structured C-terminal domain and unstructured N-terminal domain. However, at pH 3.0, equilibrium unfolding transitions of wild type and the deamidation mutants were indistinguishable. In contrast, the double alanine mutant Q54A/Q143A was destabilized at both pH 7.0 and 3.0. Thermal stabilities of the deamidation mutants were also reduced at pH 7.0. Similarly, the deamidation mutants lowered the kinetic barrier to unfolding of the N-terminal domain. These data indicate that interface deamidation decreases the thermodynamic stability of HgammaD-Crys and lowers the kinetic barrier to unfolding due to introduction of a negative charge into the domain interface. Such effects may be significant for cataract formation by inducing protein aggregation or insolubility.     

Trigger factor assisted folding of green fluorescent protein

Guanidine induced equilibrium and kinetic folding of a variant of green fluorescent protein (F99S/M153T/V163A, GFPuv) was studied. Using manual mixing and stopped-flow techniques, we combined different probes, including tryptophan fluorescence, chromophore fluorescence and reactivity with DTNB, to trace the spontaneous and TF-assisted folding of guanidine denatured GFPuv. We found that both unfolding and refolding of GFPuv occurred in a stepwise manner and a stable intermediate was populated under equilibrium conditions. The thermodynamic parameters obtained show that the intermediate state of GFPuv is quite compact compared to the denatured state and most of the green fluorescence is retained in this state. By studying GFPuv folding assisted by TF and a number of TF mutants, we found that wild-type TF catalyzes proline isomerization and accelerates the folding rate at low TF concentrations, but retards GFPuv folding and decelerates the folding rate at high TF concentrations. This reflects the two activities of TF, as an enzyme and as a chaperone. A general mechanism of TF assisted protein folding is discussed.