Kinetic coupling of folding and prolyl isomerization of beta2-microglobulin studied by mutational analysis

β₂-Microglobulin (β2-m), a protein responsible for dialysis-related amyloidosis, adopts a typical immunoglobulin domain fold with the N-terminal peptide bond of Pro32 in a cis isomer. The refolding of β2-m is limited by the slow trans-to-cis isomerization of Pro32, implying that intermediates with a non-native trans-Pro32 isomer are precursors for the formation of amyloid fibrils. To obtain further insight into the Pro-limited folding of β2-m, we studied the Gdn-HCl-dependent unfolding/refolding kinetics using two mutants (W39 and P32V β2-ms) as well as the wild-type β2-m. W39 β2-m is a triple mutant in which both of the authentic Trp residues (Trp60 and Trp95) are replaced by Phe and a buried Trp common to other immunoglobulin domains is introduced at the position of Leu39 (i.e., L39W/W60F/W95F). W39 β2-m exhibits a dramatic quenching of fluorescence upon folding, enabling a detailed analysis of Pro-limited unfolding/refolding. On the other hand, P32V β2-m is a mutant in which Pro32 is replaced by Val, useful for probing the kinetic role of the trans-to-cis isomerization of Pro32. A comparative analysis of the unfolding/refolding kinetics of these mutants including three types of double-jump experiments revealed the prolyl isomerization to be coupled with the conformational transitions, leading to apparently unusual kinetics, particularly for the unfolding. We suggest that careful consideration of the kinetic coupling of unfolding/refolding and prolyl isomerization, which has tended to be neglected in recent studies, is essential for clarifying the mechanism of protein folding and, moreover, its biological significance.     

Energetic coupling between native-state prolyl isomerization and conformational protein folding

In folded proteins, prolyl peptide bonds are usually thought to be either trans or cis because only one of the isomers can be accommodated in the native folded protein. For the N-terminal domain of the gene-3 protein of the filamentous phage fd (N2 domain), Pro161 resides at the tip of a beta hairpin and was found to be cis in the crystal structure of this protein. Here we show that Pro161 exists in both the cis and the trans conformations in the folded form of the N2 domain. We investigated how conformational folding and prolyl isomerization are coupled in the unfolding and refolding of N2 domain. A combination of single-mixing and double-mixing unfolding and refolding experiments showed that, in unfolded N2 domain, 7% of the molecules contain a cis-Pro161 and 93% of the molecules contain a trans-Pro161. During refolding, the fraction of molecules with a cis-Pro161 increases to 85%. This implies that 10.3 kJ mol(-1) of the folding free energy was used to drive this 75-fold change in the Pro161 cis/trans equilibrium constant during folding. The stabilities of the forms with the cis and the trans isomers of Pro161 and their folding kinetics could be determined separately because their conformational folding is much faster than the prolyl isomerization reactions in the native and the unfolded proteins. The energetic coupling between conformational folding and Pro161 isomerization is already fully established in the transition state of folding, and the two isomeric forms are thus truly native forms. The folding kinetics are well described by a four-species box model, in which the N2 molecules with either isomer of Pro161 can fold to the native state and in which cis/trans isomerization occurs in both the unfolded and the folded proteins.     

Role of the single disulphide bond of beta(2)-microglobulin in amyloidosis in vitro

The aggregation of beta(2)-microglobulin (beta(2)m) into amyloid fibrils occurs in the condition known as dialysis-related amyloidosis (DRA). The protein has a beta-sandwich fold typical of the immunoglobulin family, which is stabilized by a highly conserved disulphide bond linking Cys25 and Cys80. Oxidized beta(2)m forms amyloid fibrils rapidly in vitro at acidic pH and high ionic strength. Here we investigate the role of the single disulphide bond of beta(2)m in amyloidosis in vitro. We show that reduction of the disulphide bond destabilizes the native protein such that non-native molecules are populated at neutral pH. These species are prone to oligomerization but do not form amyloid fibrils when incubated for up to 8 mo at pH 7.0 in 0.4 M NaCl. Over the pH range 4.0-1.5 in the presence of 0.4 M NaCl, however, amyloid fibrils of reduced beta(2)m are formed. These fibrils are approximately 10 nm wide, but are shorter and assemble more rapidly than those produced from the oxidized protein. These data show that population of non-native conformers of beta(2)m at neutral pH by reduction of its single disulphide bond is not sufficient for amyloid formation. Instead, association of one or more specific partially unfolded molecules formed at acid pH are necessary for the formation of beta(2)m amyloid in vitro. Further experiments will now be needed to determine the role of different oligomeric species of beta(2)m in the toxicity of the protein in vivo.     

Parallel channels and rate-limiting steps in complex protein folding reactions: prolyl isomerization and the alpha subunit of Trp synthase,a TIM barrel protein

A kinetic folding mechanism for the alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli, involving four parallel channels with multiple native, intermediate and unfolded forms, has recently been proposed. The hypothesis that cis/trans isomerization of several Xaa-Pro peptide bonds is the source of the multiple folding channels was tested by measuring the sensitivity of the three rate-limiting phases (tau(1), tau(2), tau(3)) to catalysis by cyclophilin, a peptidyl-prolyl isomerase. Although the absence of catalysis for the tau(1) (fast) phase leaves its assignment ambiguous, our previous mutational analysis demonstrated its connection to the unique cis peptide bond preceding proline 28. The acceleration of the tau(2) (medium) and tau(3) (slow) refolding phases by cyclophilin demonstrated that cis/trans prolyl isomerization is also the source of these phases. A collection of proline mutants, which covered all of the remaining 18 trans proline residues of alphaTS, was constructed to obtain specific assignments for these phases. Almost all of the mutant proteins retained the complex equilibrium and kinetic folding properties of wild-type alphaTS; only the P217A, P217G and P261A mutations caused significant changes in the equilibrium free energy surface. Both the P78A and P96A mutations selectively eliminated the tau(1) folding phase, while the P217M and P261A mutations eliminated the tau(2) and tau(3) folding phases, respectively. The redundant assignment of the tau(1) phase to Pro28, Pro78 and Pro96 may reflect their mutual interactions in non-random structure in the unfolded state. The non-native cis isomers for Pro217 and Pro261 may destabilize an autonomous C-terminal folding unit, thereby giving rise to kinetically distinct unfolded forms. The nature of the preceding amino acid, the solvent exposure, or the participation in specific elements of secondary structure in the native state, in general, are not determinative of the proline residues whose isomerization reactions can limit folding.     

Real-time NMR studies on a transient folding intermediate of barstar.

The refolding of barstar, the intracellular inhibitor of barnase, is dominated by the slow formation of a cis peptidyl prolyl bond in the native protein. The triple mutant C40/82A P27A in which two cysteine residues and one trans proline were replaced by alanine was used as model system to investigate the kinetics and structural consequences of the trans/cis interconversion of Pro48. One- and two-dimensional real-time NMR spectroscopy was used to follow the trans/cis interconversion after folding was initiated by rapid dilution of the urea denatured protein. Series of 1H, 15N HSQC spectra acquired with and without the addition of peptidyl prolyl isomerase unambiguously revealed the accumulation of a transient trans-Pro48 intermediate within the dead time of the experiment. Subtle chemical shift differences between the native state and the intermediate spectra indicate that the intermediate is predominantly native-like with a local rearrangement in the Pro48 loop and in the beta-sheet region including residues Tyr47, Ala82, Thr85, and Val50.     

Core and heterogeneity of beta2-microglobulin amyloid fibrils as revealed by H/D exchange

Dialysis-related amyloidosis, which occurs in the patients receiving a long-term hemodialysis with high frequency, accompanies the deposition of amyloid fibrils composed of beta(2)-microglobulin (beta2-m). In vitro, beta2-m forms two kinds of fibrous structures at acidic pH. One is a rigid "mature fibril", and the other is a flexible thin filament often called an "immature fibril". In addition, a 22-residue peptide (K3 peptide) corresponding to Ser20 to Lys41 of intact beta2-m forms rigid amyloid-like fibrils similar to mature fibrils. We compared the core of these three fibrils at single-residue resolution using a recently developed hydrogen/deuterium (H/D) exchange method with the dissolution of fibrils by dimethylsulfoxide (DMSO). The exchange time-course of these fibrils showed large deviations from a single exponential curve showing that, because of the supramolecular structures, the same residue exists in different environments from molecule to molecule, even in a single fibril. The exchange profiles revealed that the core of the immature fibril is restricted to a narrow region compared to that of the mature fibril. In contrast, all residues were protected from exchange in the K3 fibril, indicating that a whole region of the peptide is engaged in the beta-sheet network. These results suggest the mechanism of amyloid fibril formation, in which the core beta-sheet formed by a minimal sequence propagates to form a rigid and extensive beta-sheet network.     

Conformation of amyloid fibrils of beta2-microglobulin probed by tryptophan mutagenesis

Beta2-microglobulin (beta2-m), a protein responsible for dialysis-related amyloidosis, adopts an immunoglobulin domain fold in its native state. Although beta2-m has Trp residues at positions 60 and 95, both are located near the surface of the domain. Hence, beta2-m does not have a conserved Trp common to other immunoglobulin domains, which is buried in close proximity to the disulfide bond. To study the structure of amyloid fibrils in relation to their native fold, we prepared a series of Trp mutants. Trp60 and Trp95 were both replaced with Phe, and a single Trp was introduced at various positions. Among various mutants, W39-beta2-m, in which a Trp was introduced at the position corresponding to the conserved Trp, exhibited a remarkable quenching of fluorescence in the native state, as observed for other immunoglobulin domains. An x-ray structural analysis revealed that W39-beta2-m assumes the native fold with Trp39 located in the vicinity of the disulfide bond. Comparison of the fluorescence spectra of various mutants for the native and fibrillar forms indicated that, while the Trp residues introduced in the middle of the beta2-m sequence tend to be buried in the fibrils, those located in the C-terminal region are more exposed. In addition, the fluorescence spectra of fibrils prepared at pH 2.5 and 7.0 revealed a large difference in the fluorescence intensity for W60-beta2-m, implying a major structural difference between them.     

Prolyl isomerases show low sequence specificity toward the residue following the proline

Prolyl isomerases catalyze the cis/trans isomerization of peptide bonds preceding proline. Previously, we had determined the specificity toward the residue before the proline for cyclophilin-, FKBP-, and parvulin-type prolyl isomerases by using proline-containing oligopeptides and refolding proteins as model substrates. Here, we report the specificities of members of these three prolyl isomerase families for the residue following the proline, again in short peptide and in refolding protein chains. Human cyclophilin 18 and parvulin 10 from Escherichia coli show high activity, but low specificity, with respect to the residue following the proline. Human FKBP12 prefers hydrophobic residues at this position in the peptide assays and shows a very low activity in the protein folding assays. This activity was strongly improved, and the sequence specificity was virtually eliminated after the insertion of a chaperone domain into the prolyl isomerase domain of human FKBP12.     

Bioactivity of folding intermediates studied by the recovery of enzymatic activity during refolding

The peptide bond preceding proline residues realizes a cis/trans conformational switch with high switching resistance in native proteins and folding intermediates. Therefore, individual isomers have the potential to differ in bioactivity. However, information about isomer-specific bioactivities is difficult to obtain because of the risk of affecting isomeric distribution by bioactivity assay components.Here we present an approach that allows for the measurement of the recovery of enzymatic activities of wild-type RNase T₁ and RNase T₁ variants during refolding under conditions where the population of enzyme-substrate or enzyme-product complexes is negligible. Recovery of enzymatic activity was continuously monitored within the visible range of the spectrum by addition of a fluorescence-labeled nucleotide substrate to the refolding sample. We found that a nonnative trans conformation at Pro39 renders the RNase T₁ almost completely inactive. A folding intermediate having a nonnative trans conformation at Pro55 shows about 46% of the enzymatic activity referred to the native state. Pro55, in contrast to the active site located Pro39, is situated in a solvent-exposed loop region remote from active-site residues. In both cases, peptidyl prolyl cis/trans isomerases accelerate the regain of nucleolytic activity. Our findings show that even if there is a considerable distance between the site of isomerization and the active site, conformational control of the bioactivity of proteins is likely to occur, and that the surface location of prolyl bonds suffices for the control of buried active sites mediated by peptidyl prolyl cis/trans isomerases.     

Amyloid fibril formation in the context of full-length protein: effects of proline mutations on the amyloid fibril formation of beta2-microglobulin

Beta2-microglobulin (beta2-m), a typical immunoglobulin domain made of seven beta-strands, is a major component of amyloid fibrils formed in dialysis-related amyloidosis. To understand the mechanism of amyloid fibril formation in the context of full-length protein, we prepared various mutants in which proline (Pro) was introduced to each of the seven beta-strands of beta2-m. The mutations affected the amyloidogenic potential of beta2-m to various degrees. In particular, the L23P, H51P, and V82P mutations significantly retarded fibril extension at pH 2.5. Among these, only L23P is included in the known "minimal" peptide sequence, which can form amyloid fibrils when isolated as a short peptide. This indicates that the residues in regions other than the minimal sequence, such as H51P and V82P, determine the amyloidogenic potential in the full-length protein. To further clarify the mutational effects, we measured their stability against guanidine hydrochloride of the native state at pH 8.0 and the amyloid fibrils at pH 2.5. The amyloidogenicity of mutants showed a significant correlation with the stability of the amyloid fibrils, and little correlation was observed with that of the native state. It has been proposed that the stability of the native state and the unfolding rate to the amyloidogenic precursor as well as the conformational preference of the denatured state determine the amyloidogenicity of the proteins. The present results reveal that, in addition, stability of the amyloid fibrils is a key factor determining the amyloidogenic potential of the proteins.     

Single proline residues can dictate the oxidative folding pathways of cysteine-rich peptides

The cysteine-rich N and C-terminal domains of minicollagen-1 from Hydra nematocysts fold with excesses of oxidized/reduced glutathione (10:1) into globular structures with distinct cystine frameworks despite their identical cysteine sequence pattern. An additional main difference is the cis conformation of a conserved proline residue in the N-terminal and the trans conformation of this residue in the C-terminal domain. Comparative analysis of the oxidative folding revealed for the C-terminal domain a fast and highly cooperative formation of a single disulfide isomer. Conversely, oxidation of the N-terminal domain proceeds mainly via an intermediate that results from the fast quasi-stochastic disulfide formation according to the proximity rule. The rate of conversion of the bead-like isomer into the globular end-product is largely dominated by the trans-to-cis isomerization of the critical proline residue as well assessed by its replacement with (4R)- and (4S)-fluoroproline known to exhibit distinct propensities for the trans and cis conformation, respectively. Independently, whether the trans or cis conformation is favored by these substitutions, both analogues retain sufficient sequence-encoded information to fold almost quantitatively into the identical cystine framework and thus spatial structure of the parent peptide with the critical proline residue as cis isomer, but at rates significantly lower for the (4R) than for the (4S)-fluoroproline analogue. Correspondingly, other sequence-encoded structural elements have to act as a driving force for these unidirectional folding pathways despite the rather simple sequence composition consisting only of aliphatic residues, some proline and only one aromatic residue (tyrosine) in the core parts of the C and N-terminal domains. The two cysteine-rich domains of minicollagen-1 may well represent ideal targets for ab initio structure calculations in order to learn more about the elementary information encoded in such primordial molecules.     

A novel method of analyzing proline synonymous codons in E. coli

Proline is a special imino acid in protein and the isomerization of the prolyl peptide bond has notable biological significance and influences the final structure of protein greatly, so the correlation between proline synonymous codon usage and local amino acid, the correlation between proline synonymous codon usage and the isomerization of the prolyl peptide bond were both investigated in the Escherichia coli genome by using a novel method based on information theory. The results show that in peptide chain, the residue at the first position C-terminal influences the usage of proline synonymous codon greatly and proline synonymous codons contain some factors influencing the isomerization of the prolyl peptide bond.     

The scFv fragment of the antibody hu4D5-8: evidence for early premature domain interaction in refolding

Fluorescence spectroscopy and 1H/2H-exchange techniques have been applied to characterize the folding of an scFv fragment, derived from the humanized anti-HER2 antibody hu4D5-8. A stable intermediate, consisting of a native VL domain and an unfolded VH domain, is populated under equilibrium unfolding conditions. A partially structured intermediate, with 1H/2H-exchange protection significantly less than that of the two isolated domains together, is detectable upon refolding the equilibrium-denatured scFv fragment. This means that the domains in the heterodimer do not fold independently. Rather, they associate prematurely before full 1H/2H-exchange protection can be gained. The formation of the native heterodimer from the non-native intermediate is a slow, cooperative process, which is rate-limited by proline cis/trans-isomerization. Unproductive domain association is also detectable after short-term denaturation, i.e. with the proline residues in native conformation. Only a fraction of the short-term denatured protein folds into the native protein in a fast, proline-independent reaction, because of spontaneous proline cis/trans-reisomerization in the early non-native intermediate. The comparison with the previously studied antibody McPC603 has now allowed us to delineate similarities in the refolding pathway of scFv fragments.     

Main-chain dominated amyloid structures demonstrated by the effect of high pressure

It has been suggested that, while the globular native forms of proteins are a side-chain-dominated compact structure evolved by pursuing a unique fold with optimal packing of amino acid residues, amyloid fibrils are a main-chain-dominated structure with an extensive hydrogen bond network. To address this issue, the effects of hydrostatic pressure on amyloid fibrils of beta2-microglobulin (beta2-m), involved in dialysis-related amyloidosis, were studied. A systematic analysis at various pressures and concentrations of guanidine hydrochloride conducted by monitoring thioflavin T fluorescence, light-scattering, and tryptophan fluorescence revealed contrasting conformational changes occurring consecutively: first, a pressure-induced reorganization of fibrils and then a pressure-induced unfolding. The changes in volume as well as the observed structural changes indicate that the beta2-m amyloid fibrils under ambient pressure are less tightly packed with a larger number of cavities, consistent with the main-chain-dominated amyloid structure. Moreover, the amyloid structure without optimal packing will enable various isoforms to form, suggesting the structural basis of multiple forms of amyloid fibrils in contrast to the unique native-fold.     

Molecular Determinants of a Native-State Prolyl Isomerization

Prolyl cis/trans isomerizations determine the rates of many protein-folding reactions, and they can serve as molecular switches and timers. The energy required to shift the prolyl cis/trans equilibrium during these processes originates from conformational reactions that are linked structurally and energetically with prolyl isomerization. We used the N2 domain of the gene-3-protein of phage fd to elucidate how such an energetic linkage develops in the course of folding. The Asp160-Pro161 bond at the tip of a β hairpin of N2 is cis in the crystal structure, but in fact, it exists as a mixture of conformers in folded N2. During refolding, about 10 kJ mol^− 1 of conformational energy becomes available for a 75-fold shift of the cis/trans equilibrium constant at Pro161, from 7/93 in the unfolded to 90/10 in the folded form. We combined single- and double-mixing kinetic experiments with a mutational analysis to identify the structural origin of this proline shift energy and to elucidate the molecular path for the transfer of this energy to Pro161. It originates largely, if not entirely, from the two-stranded β sheet at the base of the Pro161 hairpin. The two strands improve their stabilizing interactions when Pro161 is cis, and this stabilization is propagated to Pro161, because the connector peptides between the β strands and Pro161 are native-like folded when Pro161 is cis. In the presence of a trans-Pro161, the connector peptides are locally unfolded, and thus, Pro161 is structurally and energetically uncoupled from the β sheet. Such interrelations between local folding and prolyl isomerization and the potential modulation by prolyl isomerases might also be used to break and reestablish slow communication pathways in proteins.     

The crystal structure of the cis-proline to glycine variant (P114G) of ribonuclease A

Replacement of a cis-proline by glycine at position 114 in ribonuclease A leads to a large decrease in thermal stability and simplifies the refolding kinetics. A crystallographic approach was used to determine whether the decrease in thermal stability results from the presence of a cis glycine peptide bond, or from a localized structural rearrangement caused by the isomerization of the mutated cis 114 peptide bond. The structure was solved at 2.0 A resolution and refined to an R-factor of 19.5% and an R(free) of 21.9%. The overall conformation of the protein was similar to that of wild-type ribonuclease A; however, there was a large localized rearrangement of the mutated loop (residues 110-117-a 9.3 A shift of the Calpha atom of residue 114). The peptide bond before Gly114 is in the trans configuration. Interestingly, a large anomalous difference density was found near residue 114, and was attributed to a bound cesium ion present in the crystallization experiment. The trans isomeric configuration of the peptide bond in the folded state of this mutant is consistent with the refolding kinetics previously reported, and the associated protein conformational change provides an explanation for the decreased thermal stability.     

Role of two proline-containing turns in the folding of porcine ribonuclease

Unfolded ribonuclease (RNase) from porcine pancreas consists of a mixture of fast and slow-refolding species. The equilibrium distribution of these species differs strongly from other homologous RNases, because an additional proline residue is present at position 115 of the porcine protein. The major slow-folding species of porcine RNase contains incorrect proline isomers at Pro93 and at Pro114-Pro115. Both positions are presumably part of beta-turn structures in the native protein, as deduced from the structure of the homologous bovine RNase A. The folding kinetics of these molecules depend strongly on the conditions used. Under unfavorable conditions (near the unfolding transition), refolding is virtually blocked by the presence of the incorrect proline peptide bonds and partially folded intermediates with incorrect isomers could not be detected. As a consequence, folding is very slow under such conditions and the re-isomerization of Pro114-Pro115 is the first and rate-limiting step of folding. Under strongly native conditions (such as in the presence of ammonium sulfate), refolding is much faster. A largely folded intermediate accumulates with the turns around Pro93 and Pro114-Pro115 still in the non-native conformation. These results suggest that incorrect proline isomers strongly influence protein folding and that, under favorable conditions, the polypeptide chain can fold with two beta-turns locked into a non-native conformation. We conclude, therefore, that early formation of correct turn structure is not necessarily required for protein folding. However, the presence of incorrect turns, locked-in by non-native proline isomers, strongly decreases the rate of refolding. Alternative pathways of folding exist. The choice of pathway depends on the number and distribution of incorrect proline isomers and on the folding conditions.     

Structural mechanism governing cis and trans isomeric states and an intramolecular switch for cis/trans isomerization of a non-proline peptide bond observed in crystal structures of scorpion toxins

Non-proline cis peptide bonds have been observed in numerous protein crystal structures even though the energetic barrier to this conformation is significant and no non-prolyl-cis/trans-isomerase has been identified to date. While some external factors, such as metal binding or co-factor interaction, have been identified that appear to induce cis/trans isomerization of non-proline peptide bonds, the intrinsic structural basis for their existence and the mechanism governing cis/trans isomerization in proteins remains poorly understood. Here, we report the crystal structure of a newly isolated neurotoxin, the scorpion alpha-like toxin Buthus martensii Karsch (BmK) M7, at 1.4A resolution. BmK M7 crystallizes as a dimer in which the identical non-proline peptide bond between residues 9 and 10 exists either in the cis conformation or as a mixture of cis and trans conformations in either monomer. We also determined the crystal structures of several mutants of BmK M1, a representative scorpion alpha-like toxin that contains an identical non-proline cis peptide bond as that observed in BmK M7, in which residues within or neighboring the cis peptide bond were altered. Substitution of an aspartic acid residue for lysine at residue 8 in the BmK M1 (K8D) mutant converted the cis form of the non-proline peptide bond 9-10 into the trans form, revealing an intramolecular switch for cis-to-trans isomerization. Cis/trans interconversion of the switch residue at position 8 appears to be sequence-dependent as the peptide bond between residues 9 and 10 retains its wild-type cis conformation in the BmK M1 (K8Q) mutant structure. The structural interconversion of the isomeric states of the BmK M1 non-proline cis peptide bond may relate to the conversion of the scorpion alpha-toxins subgroups.     

A nonessential role for Arg 55 in cyclophilin18 for catalysis of proline isomerization during protein folding

The protein folding process is often in vitro rate‐limited by slow cis‐trans proline isomerization steps. Importantly, the rate of this process in vivo is accelerated by prolyl isomerases (PPIases). The archetypal PPIase is the human cyclophilin 18 (Cyp18 or CypA), and Arg 55 has been demonstrated to play a crucial role when studying short peptide substrates in the catalytic action of Cyp18 by stabilizing the transition state of isomerization. However, in this study we show that a R55A mutant of Cyp18 is as efficient as the wild type to accelerate the refolding reaction of human carbonic anhydrase II (HCA II). Thus, it is evident that the active‐site located Arg 55 is not required for catalysis of the rate‐limiting prolyl cis‐trans isomerization steps during the folding of a protein substrate as HCA II. Nevertheless, catalysis of cis‐trans proline isomerization in HCA II occurs in the active‐site of Cyp18, since binding of the inhibitor cyclosporin A abolishes rate acceleration of the refolding reaction. Obviously, the catalytic mechanisms of Cyp18 can differ when acting upon a simple model peptide, four residues long, with easily accessible Pro residues compared with a large protein molecule undergoing folding with partly or completely buried Pro residues. In the latter case, the isomerization kinetics are significantly slower and simpler mechanistic factors such as desolvation and/or strain might operate during folding‐assisted catalysis, since binding to the hydrophobic active site is still a prerequisite for catalysis.     

Solution structure of the single-domain prolyl cis/trans isomerase PIN1At from Arabidopsis thaliana

The 119-amino acid residue prolyl cis/trans isomerase from Arabidopsis thaliana (PIN1At) is similar to the catalytic domain of the human hPIN1. However, PIN1At lacks the N-terminal WW domain that appears to be essential for the hPIN1 function. Here, the solution structure of PIN1At was determined by three-dimensional nuclear magnetic resonance spectroscopy. The PIN1At fold could be superimposed on that of the catalytic domain of hPIN1 and had a 19 residue flexible loop located between strand beta1 and helix alpha1. The dynamical features of this beta1/alpha1-loop, which are characteristic for a region involved in protein-protein interactions, led to exchange broadening in the NMR spectra. When sodium sulfate salt was added to the protein sample, the beta1/alpha1 loop was stabilized and, hence, a complete backbone resonance assignment was obtained. Previously, with a phospho-Cdc25 peptide as substrate, PIN1At had been shown to catalyze the phosphoserine/phosphothreonine prolyl cis/trans isomerization specifically. To map the catalytic site of PIN1At, the phospho-Cdc25 peptide or sodium sulfate salt was added in excess to the protein and chemical shift changes in the backbone amide protons were monitored in the (1)H(N)-(15)N heteronuclear single quantum coherence spectrum. The peptide caused perturbations in the loops between helix alpha4 and strand beta3, between strands beta3 and beta4, in the alpha3 helix, and in the beta1/alpha1 loop. The amide groups of the residues Arg21 and Arg22 showed large chemical shift perturbations upon phospho-Cdc25 peptide or sulfate addition. We conclude that this basic cluster formed by Arg21 and Arg22, both located in the beta1/alpha1 loop, is homologous to that found in the hPIN1 crystal structure (Arg68 and Arg69), which also is involved in sulfate ion binding. We showed that the sulfate group competed for the interaction between PIN1At and the phospho-Cdc25 peptide. In the absence of the WW domain, three hydrophobic residues (Ile33, Ile34, and Leu35) located in the long flexible loop and specific for the plant PIN-type peptidyl prolyl cis/trans isomerases (PPIases) could be an additional interaction site in PIN1At. However, phospho-peptide addition did not affect the resonances of these residues significantly. Electrostatic potential calculations revealed a negatively charged area not found in hPIN1 on the PIN1At molecular surface, which corresponds to the surface shielded by the WW domain in hPIN1. Based on our experimental results and the molecular specificities of the PIN1At enzyme, functional implications of the lack of WW domains in this plant PIN-type PPIase will be discussed.