Mutations that destabilize the a' domain of human protein-disulfide isomerase indirectly affect peptide binding

Protein-disulfide isomerase (PDI) is a catalyst of folding of disulfide-bonded proteins and also a multifunctional polypeptide that acts as the beta-subunit in the prolyl 4-hydroxylase alpha(2)beta(2)-tetramer (P4H) and the microsomal triglyceride transfer protein alphabeta-dimer. The principal peptide-binding site of PDI is located in the b' domain, but all domains contribute to the binding of misfolded proteins. Mutations in the C-terminal part of the a' domain have significant effects on the assembly of the P4H tetramer and other functions of PDI. In this study we have addressed the question of whether these mutations in the C-terminal part of the a' domain, which affect P4H assembly, also affect peptide binding to PDI. We observed a strong correlation between P4H assembly competence and peptide binding; mutants of PDI that failed to form a functional P4H tetramer were also inactive in peptide binding. However, there was also a correlation between inactivity in these assays and indicators of conformational disruption, such as protease sensitivity. Peptide binding activity could be restored in inactive, protease-sensitive mutants by selective proteolytic removal of the mutated a' domain. Hence we propose that structural changes in the a' domain indirectly affect peptide binding to the b' domain.     

Alternative conformations of the x region of human protein disulphide-isomerase modulate exposure of the substrate binding b' domain

Protein disulphide isomerase (PDI) is a key multi-domain protein folding catalyst in the endoplasmic reticulum. The b’ domain of PDI is essential for the non-covalent binding of incompletely folded protein substrates. Earlier, we defined the substrate binding site in the b’ domain of human PDI by modelling and mutagenesis studies. Here, we show by fluorescence and NMR that recombinant human PDI b’x (comprising the b’ domain and the subsequent x linker region) can assume at least two different conformations in solution. We have screened mutants in the b’x region to identify mutations that favour one of these conformers in recombinant b'x, and isolated and characterised examples of both types. We have crystallised one mutant of b’x (I272A mutation) in which one conformer is stabilized, and determined its crystal structure to a resolution of 2.2 Å. This structure shows that the b’ domain has the typical thioredoxin fold and that the x region can interact with the b’ domain by ”capping” a hydrophobic site on the b’ domain. This site is most likely the substrate binding site and hence such capping will inhibit substrate binding. All of the mutations we previously reported to inhibit substrate binding shift the equilibrium towards the capped conformer. Hence, these mutations act by altering the natural equilibrium and decreasing the accessibility of the substrate binding site. Furthermore, we have confirmed that the corresponding structural transition occurs in the wild type full-length PDI. A cross-comparison of our data with that for other PDI-family members, Pdi1p and ERp44, suggests that the x region of PDI can adopt alternative conformations during the functional cycle of PDI action and that these are linked to the ability of PDI to interact with folding substrates.     

Human protein-disulfide isomerase is a redox-regulated chaperone activated by oxidation of domain a'

Protein-disulfide isomerase (PDI), with domains arranged as abb'xa'c, is a key enzyme and chaperone localized in the endoplasmic reticulum (ER) catalyzing oxidative folding and preventing misfolding/aggregation of proteins. It has been controversial whether the chaperone activity of PDI is redox-regulated, and the molecular basis is unclear. Here, we show that both the chaperone activity and the overall conformation of human PDI are redox-regulated. We further demonstrate that the conformational changes are triggered by the active site of domain a', and the minimum redox-regulated cassette is located in b'xa'. The structure of the reduced bb'xa' reveals for the first time that domain a' packs tightly with both domain b' and linker x to form one compact structural module. Oxidation of domain a' releases the compact conformation and exposes the shielded hydrophobic areas to facilitate its high chaperone activity. Thus, the study unequivocally provides mechanistic insights into the redox-regulated chaperone activity of human PDI.     

Crystal structure of the outer membrane protein RcsF, a new substrate for the periplasmic protein-disulfide isomerase DsbC

The bacterial Rcs phosphorelay is a stress-induced defense mechanism that controls the expression of numerous genes, including those for capsular polysaccharides, motility, and virulence factors. It is a complex multicomponent system that includes the histidine kinase (RcsC) and the response regulator (RcsB) and also auxiliary proteins such as RcsF. RcsF is an outer membrane lipoprotein that transmits signals from the cell surface to RcsC. The physiological signals that activate RcsF and how RcsF interacts with RcsC remain unknown. Here, we report the three-dimensional structure of RcsF. The fold of the protein is characterized by the presence of a central 4-stranded β sheet, which is conserved in several other proteins, including the copper-binding domain of the amyloid precursor protein. RcsF, which contains four conserved cysteine residues, presents two nonconsecutive disulfides between Cys(74) and Cys(118) and between Cys(109) and Cys(124), respectively. These two disulfides are not functionally equivalent; the Cys(109)-Cys(124) disulfide is particularly important for the assembly of an active RcsF. Moreover, we show that formation of the nonconsecutive disulfides of RcsF depends on the periplasmic disulfide isomerase DsbC. We trapped RcsF in a mixed disulfide complex with DsbC, and we show that deletion of dsbC prevents the activation of the Rcs phosphorelay by signals that function through RcsF. The three-dimensional structure of RcsF provides the structural basis to understand how this protein triggers the Rcs signaling cascade.     

Replacement of domain b of human protein disulfide isomerase-related protein with domain b' of human protein disulfide isomerase dramatically increases its chaperone activity

We have reported that human protein disulfide isomerase-related protein (hPDIR) has isomerase and chaperone activities that are lower than those of the human protein disulfide isomerase (hPDI), and that the b domain of hPDIR is critical for its chaperone activity [J. Biol. Chem. 279 (2004) 4604]. To investigate the basis of the differences between hPDI and hPDIR, and to determine the functions of each hPDIR domain in detail, we constructed several hPDIR domain mutants. Interestingly, when the b domain of hPDIR was replaced with the b' domain of hPDI, a dramatic increase in chaperone activity that was close to that of hPDI itself was observed. However, this mutant showed decreased oxidative refolding of alpha1-antitrypsin. The replacement of the b domain of hPDIR with the c domain of hPDI also increased its chaperone activity. These observations suggest that putative peptide-binding sites of hPDI determine both its chaperone activity and its substrate specificity.     

A structural disulfide of yeast protein-disulfide isomerase destabilizes the active site disulfide of the N-terminal thioredoxin domain

Protein-disulfide isomerase (PDI) is an essential catalyst of disulfide formation and isomerization in the eukaryotic endoplasmic reticulum. PDI has two active sites at either end of the molecule, each containing two cysteines that facilitate thiol-disulfide exchange. In addition to its four catalytic cysteines, PDI possesses two non-active site cysteines whose location and separation distance varies by organism. In higher eukaryotes, the non-active site cysteines are located in the C-terminal half of the protein sequence and are separated by 30 amino acids. In contrast, the internal cysteines of PDI from lower eukaryotes are located near the N-terminal active site and are much closer together in sequence. The function of these cysteines and the significance of their unique location in yeast PDI have been unclear. Previous data (Xiao, R., Wilkinson, B., Solovyov, A., Winther, J. R., Holmgren, A., Lundstrom-Ljung, J., and Gilbert, H. F. (2004) J. Biol. Chem. 279, 49780-49786) suggest that the internal cysteines exist as a disulfide in the endoplasmic reticulum of Saccharomyces cerevisiae. By coupling mass spectrometry with a gel-shift technique that allows us to measure the redox potentials of the PDI active sites in the presence and absence of the non-active site cysteines, we find that the non-active site cysteines form a disulfide that is stable even in a very reducing environment and demonstrate that this disulfide exists to destabilize the N-terminal active site disulfide, making it a better oxidant by 18-fold. Consistent with this finding, we show that mutating the non-active site cysteines to alanines disrupts both the oxidase and isomerase activities of PDI in vitro.     

Reduction-reoxidation cycles contribute to catalysis of disulfide isomerization by protein-disulfide isomerase

Protein-disulfide isomerase (PDI) catalyzes the formation and isomerization of disulfides during oxidative protein folding. This process can be error-prone in its early stages, and any incorrect disulfides that form must be rearranged to their native configuration. When the second cysteine (CGHC) in the PDI active site is mutated to Ser, the isomerase activity drops by 7-8-fold, and a covalent intermediate with the substrate accumulates. This led to the proposal that the second active site cysteine provides an escape mechanism, preventing PDI from becoming trapped with substrates that isomerize slowly (Walker, K. W., and Gilbert, H. F. (1997) J. Biol. Chem. 272, 8845-8848). Escape also reduces the substrate, and if it is invoked frequently, disulfide isomerization will involve cycles of reduction and reoxidation in preference to intramolecular isomerization of the PDI-bound substrate. Using a gel-shift assay that adds a polyethylene glycol-conjugated maleimide of 5 kDa for each sulfhydryl group, we find that PDI reduction and oxidation are kinetically competent and essential for isomerization. Oxidants inhibit isomerization and oxidize PDI when a redox buffer is not present to maintain the PDI redox state. Reductants also inhibit isomerization as they deplete oxidized PDI. These rapid cycles of PDI oxidation and reduction suggest that PDI catalyzes isomerization by trial and error, reducing disulfides and oxidizing them in a different configuration. Disulfide reduction-reoxidation may set up critical folding intermediates for intramolecular isomerization, or it may serve as the only isomerization mechanism. In the absence of a redox buffer, these steady-state reduction-oxidation cycles can balance the redox state of PDI and support effective catalysis of disulfide isomerization.     

A zinc finger-like domain of the molecular chaperone DnaJ is involved in binding to denatured protein substrates.

The Escherichia coli heat-shock protein DnaJ cooperates with the Hsp70 homolog DnaK in protein folding in vitro and in vivo. Little is known about the structural features of DnaJ that mediate its interaction with DnaK and unfolded polypeptide. DnaJ contains at least four blocks of sequence representing potential functional domains which have been conserved throughout evolution. In order to understand the role of each of these regions, we have analyzed DnaJ fragments in reactions corresponding to known functions of the intact protein. Both the N-terminal 70 amino acid 'J-domain' and a 35 amino acid glycine-phenylalanine region following it are required for interactions with DnaK. However, only complete DnaJ can cooperate with DnaK and a third protein, GrpE, in refolding denatured firefly luciferase. As demonstrated by atomic absorption and extended X-ray absorption fine structure spectroscopy (EXAFS), the 90 amino acid cysteine-rich region of DnaJ contains two Zn atoms tetrahedrally coordinated to four cysteine residues, resembling their arrangement in the C4 Zn binding domains of certain DNA binding proteins. Interestingly, binding experiments and cross-linking studies indicate that this Zn finger-like domain is required for the DnaJ molecular chaperone to specifically recognize and bind to proteins in their denatured state.     

The primary substrate binding site in the b' domain of ERp57 is adapted for endoplasmic reticulum lectin association

ERp57 is a member of the protein disulfide isomerase (PDI) family that is located in the endoplasmic reticulum (ER) and characterized by its specificity for glycoproteins. Substrate selection by ERp57 is dependent upon its formation of discrete complexes with two ER resident lectins, soluble calreticulin and membrane-bound calnexin. It is these two lectins that directly associate with glycoproteins bearing correctly trimmed oligosaccharide side chains. Thus, ERp57 is presented with a preselected set of substrates upon which it can act, and the specific binding of calreticulin and calnexin to ERp57 is pivotal to the functions of the resulting complexes. To gain further insights into the formation of these ERp57-ER lectin complexes, we have investigated the regions of ERp57 that are specifically required for its binding to calreticulin. Using a quantitative pull-down assay to investigate the binding of ERp57/PDI chimeras to calreticulin, we define the b and b' domains of ERp57 as the minimal elements that are sufficient for complex formation. This analysis further identifies a novel role for the distinctive C-terminal extension of ERp57 in reconstituting complex formation to wild type levels. Using our understanding of substrate binding to the b' domain of PDI as a paradigm, we show that alterations to specific residues in the b' domain of ERp57 dramatically reduce or completely abolish its binding to calreticulin. On the basis of these data, we propose a model where the region of ERp57 equivalent to the primary substrate binding site of archetypal PDI is occupied by calreticulin and suggest that the ER lectins act as adaptor molecules that define the substrate specificity of ERp57.     

Micropatterning proteins on polyhydroxyalkanoate substrates by using the substrate binding domain as a fusion partner

A novel strategy for micropatterning proteins on the surface of polyhydroxyalkanoate (PHA) biopolymer by microcontact printing (microCP) is described. The substrate binding domain (SBD) of the Pseudomonas stutzeri PHA depolymerase was used as a fusion partner for specifically immobilizing proteins on PHA substrate. Enhanced green fluorescent protein (EGFP) and red fluorescent protein (RFP) fused to the SBD could be specifically immobilized on the micropatterns of poly(3-hydroxybutyrate) and poly(3-hydroxybutyrate-co-3-hydroxyhexanoate). Laser scanning confocal microscopic studies suggested that two fusion proteins were micropatterned in their functionally active forms. Also, antibody binding assay by surface plasmon resonance suggested that protein-protein interaction studies could be carried out using this system.     

Functional in vitro analysis of the ERO1 protein and protein-disulfide isomerase pathway

Oxidative protein folding in the endoplasmic reticulum is supported by efficient electron relays driven by enzymatic reactions centering on the ERO1-protein-disulfide isomerase (PDI) pathway. A controlled in vitro oxygen consumption assay was carried out to analyze the ERO1-PDI reaction. The results showed the pH-dependent oxidation of PDI by ERO1α. Among several possible disulfide bonds regulating ERO1α activity, Cys(94)-Cys(131) and Cys(99)-Cys(104) disulfide bonds are dominant regulators by excluding the involvement of the Cys(85)-Cys(391) disulfide in the regulation. The fine-tuned species specificity of the ERO1-PDI pathway was demonstrated by functional in vitro complementation assays using yeast and mammalian oxidoreductases. Finally, the results provide experimental evidence for the intramolecular electron transfer from the a domain to the a' domain within PDI during its oxidation by ERO1α.     

A tandemly repeated sequence determines the binding domain for an erythrocyte receptor binding protein of P. falciparum

Erythrocyte invasion by the malarial merozoite is a receptor-mediated process, an obligatory step in the development of the parasite. The Plasmodium falciparum protein GBP-130, which binds to the erythrocyte receptor glycophorin, is shown here to encode the binding site in a domain composed of a tandemly repeated 50 amino acid sequence. The amino acid sequence of GBP-130, deduced from the cloned and sequenced gene, reveals that the protein contains 11 highly conserved 50 amino acid repeats and a charged N-terminal region of 225 amino acids. Binding studies on recombinant proteins expressing different numbers of repeats suggest that a correlation exists between glycophorin binding and repeat number. Thus, a repeat domain, a common feature of plasmodial antigens, has been shown to have a function independent of the immune system. This conclusion is further supported by the ability of antibodies directed against the repeat sequence to inhibit the in vitro invasion of erythrocytes by merozoites.     

The binding site of bisphenol A to protein disulphide isomerase

Protein disulphide isomerase (PDI) has been isolated as a binding protein of bisphenol A (BPA) in the rat brain. In this study, we determined binding sites of BPA to PDI and characterized the binding site. First, we identified the BPA-binding domain with ab, b'a'c, a, b, b' and a'c fragment peptides of PDI by surface plasmon resonance spectroscopy. BPA interacted with ab, b'a 'c, a and b', suggesting that a and b' domains are important in their interaction. Second, ab, b'a'c, a,b,b',a', abb'a', abb', b'a', Δb' and a'c fragment peptides were used for their isomerase activity with RNase as a substrate. BPA could inhibit the activity of peptide fragments including b', suggesting that b' domain contributes to inhibition of catalytic activity of PDI by BPA. Next, we investigated the BPA-binding capacity of PDI by amino acid substitution. PDI lost the BPA-binding activity by the mutation of H258 and mutation of Q245 and N300 also decreased its activity. Furthermore, acidic condition increased the BPA-binding activity of PDI. These results suggest that the charge of these amino acid especially, H258, is important for the BPA to bind to PDI.     

Recognition sequence of a highly conserved DNA binding protein RBP-J kappa.

DNA binding specificity of the RBP-J kappa protein was extensively examined. The mouse RBP-J kappa protein was originally isolated as a nuclear protein binding to the J kappa type V(D)J recombination signal sequence which consisted of the conserved heptamer (CACTGTG) and nonamer (GGTTTTTGT) sequences separated by a 23-base pair spacer. Electrophoretic mobility shift assay using DNA probes with mutations in various parts of the J kappa recombination signal sequence showed that the RBP-J kappa protein recognized the sequence outside the recombination signal in addition to the heptamer but did not recognize the nonamer sequence and the spacer length at all. Database search identified the best naturally occurring binding motif (CACTGTGGGAACGG) for the RBP-J kappa protein in the promoter region of the m8 gene in the Enhancer of split gene cluster of Drosophila. The binding assay with a series of m8 motif mutants indicated that the protein recognized mostly the GTGGGAA sequence and also interacted weakly with ACT and CG sequences flanking this hepta-nucleotide. Oligonucleotides binding to the RBP-J kappa protein were enriched from a pool of synthetic oligonucleotides containing 20-base random sequences by the repeated electrophoretic mobility shift assay. The enriched oligomer shared a common sequence of CGTGGGAA. All these data indicate that the RBP-J kappa protein recognizes a unique core sequence of CGTGGGAA and does not bind to the V(D)J recombination signal without the flanking sequence.     

The KH domain of the branchpoint sequence binding protein determines specificity for the pre-mRNA branchpoint sequence.

The yeast and mammalian branchpoint sequence binding proteins (BBP and mBBP/SF1) contain both KH domain and Zn knuckle RNA-binding motifs. The single KH domain of these proteins is sufficient for specific recognition of the pre-mRNA branchpoint sequence (BPS). However, an interaction is only apparent if one or more accessory modules are present to increase binding affinity. The Zn knuckles of BBP/mBBP can be replaced by an RNA-binding peptide derived from the HIV-1 nucleocapsid protein or by an arginine-serine (RS)7 peptide, without loss of specificity. Only the seven-nucleotide branchpoint sequence and two nucleotides to either side are necessary for RNA binding to the chimeric proteins. Therefore, we propose that all three of these accessory RNA-binding modules bind the phosphate backbone, whereas the KH domain interacts specifically with the bases of the BPS. Proteins and protein complexes with multiple RNA-binding motifs are frequent, suggesting that an intimate collaboration between two or more motifs will be a general theme in RNA-protein interactions.     

Different contributions of the three CXXC motifs of human protein-disulfide isomerase-related protein to isomerase activity and oxidative refolding

Human protein-disulfide isomerase (hPDI)-related protein (hPDIR), which we previously cloned from a human placental cDNA library (Hayano, T., and Kikuchi, M. (1995) FEBS Lett. 372, 210-214), and its mutants were expressed in the Escherichia coli pET system and purified by sequential nickel affinity resin chromatography. Three thioredoxin motifs (CXXC) of purified hPDIR were found to contribute to its isomerase activity with a rank order of CGHC > CPHC > CSMC, although both the isomerase and chaperone activities of this protein were lower than those of hPDI. Screening for hPDIR-binding proteins using a T7 phage display system revealed that alpha1-antitrypsin binds to hPDIR. Surface plasmon resonance experiments demonstrated that alpha1-antitrypsin interacts with hPDIR, but not with hPDI or human P5 (hP5). Interestingly, the rate of oxidative refolding of alpha1-antitrypsin with hPDIR was much higher than with hPDI or hP5. Thus, the substrate specificity of hPDIR differed from that associated with isomerase activity, and the contribution of the CSMC motif to the oxidative refolding of alpha1-antitrypsin was the most definite of the three (CSMC, CGHC, CPHC). Substitution of SM and PH in the CXXC motifs with GH increased isomerase activity and decreased oxidative refolding. In contrast, substitution of GH and PH with SM decreased isomerase activity and increased oxidative refolding. Because CXXC motif mutants lacking isomerase activity retain chaperone activity for the substrate rhodanese, it is clear that, similar to PDI and hP5, the isomerase and chaperone activities of hPDIR are independent. These results suggest that the central dipeptide of the CXXC motif is critical for both redox activity and substrate specificity.     

Molecular characterization of the principal substrate binding site of the ubiquitous folding catalyst protein disulfide isomerase

Disulfide bond formation in the endoplasmic reticulum of eukaryotes is catalyzed by the ubiquitously expressed enzyme protein disulfide isomerase (PDI). The effectiveness of PDI as a catalyst of native disulfide bond formation in folding polypeptides depends on the ability to catalyze disulfide-dithiol exchange, to bind non-native proteins, and to trigger conformational changes in the bound substrate, allowing access to buried cysteine residues. It is known that the b' domain of PDI provides the principal peptide binding site of PDI and that this domain is critical for catalysis of isomerization but not oxidation reactions in protein substrates. Here we use homology modeling to define more precisely the boundaries of the b' domain and show the existence of an intradomain linker between the b' and a' domains. We have expressed the recombinant b' domain thus defined; the stability and conformational properties of the recombinant product confirm the validity of the domain boundaries. We have modeled the tertiary structure of the b' domain and identified the primary substrate binding site within it. Mutations within this site, expressed both in the isolated domain and in full-length PDI, greatly reduce the binding affinity for small peptide substrates, with the greatest effect being I272W, a mutation that appears to have no structural effect.