HOP is a monomer: Investigation of the oligomeric state of the co‐chaperone HOP

The co-chaperone Hsp70-Hsp90 organizing protein (HOP) plays a central role in protein folding in vivo, binding to both Hsp70 and Hsp90 and bringing them together in a functional complex. Reports in the literature concerning the oligomeric state of HOP have been inconsistent—is it a monomer, dimer, or higher order oligomer? Knowing the oligomeric state of HOP is important, because it places limits on the number and types of multiprotein complexes that can form during the folding cycle. Thus, the number of feasible models is simplified. Here, we explicitly investigate the oligomeric state of HOP using three complementary methods: gel filtration chromatography, sedimentation equilibrium analytical ultracentrifugation (AUC), and an in vivo coexpression assay. We find that HOP does not behave like a monomeric globular protein on gel filtration. Rather its behavior is consistent with it being either an elongated monomer or a dimer. We follow-up on these studies using sedimentation equilibrium AUC, which separates on the basis of molecular weight (MW), independent of shape. Sedimentation equilibrium AUC clearly shows that HOP is a monomer, with no indication of higher MW species. Finally, we use an in vivo coexpression assay that also supports the conclusion that HOP is a monomer.     

Self-association and ligand-induced conformational changes of iron regulatory proteins 1 and 2

Iron regulatory proteins (IRPs) regulate iron metabolism in mammalian cells. We used biophysical techniques to examine the solution properties of apo-IRP1 and apo-IRP2 and the interaction with their RNA ligand, the iron regulatory element (IRE). Sedimentation velocity and equilibrium experiments have shown that apo-IRP1 exists as an equilibrium mixture of monomers and dimers in solution, with an equilibrium dissociation constant in the low micromolar range and slow kinetic exchange between the two forms. However, only monomeric IRP1 is observed in complex with IRE. In contrast, IRP2 exists as monomer in both the apo-IRP2 form and in the IRP2/IRE complex. For both IRPs, sedimentation velocity and dynamic light-scattering experiments show a decrease of the Stokes radius upon binding of IRE. This conformational change was also observed by circular dichroism. Studies with an RNA molecule complementary to IRE indicate that, although specific base interactions can increase the stability of the protein/RNA complex, they are not essential for inducing this conformational change. The dynamic change of the IRP between different oligomeric and conformational states induced by interaction with IRE may play a role in the iron regulatory functions of IRPs.     

Re-examining the oligomerization state of macrophage migration inhibitory factor (MIF) in solution

The state of oligomerization of macrophage migration inhibitory factor (MIF, also known as glycosylation inhibiting factor, GIF) in solution has been variously reported as monomer, dimer, trimer, or mixtures of all three. Several crystal structures show MIF to be a trimer. Sedimentation velocity shows a recombinant human MIF sample is quite homogeneous, with 98% as a species with s(20,w)=3.07 S and D(20,w)=8.29 x 10(-7) cm(2)/s. Using the partial specific volume calculated from the amino acid composition these values imply a mass of 33.56 kDa, well above that of dimer, but also 9% below the trimer mass of 37.035 kDa. Sedimentation equilibrium data at loading concentrations from 0.01 to 1 mg/ml show unequivocally that the self-association is extremely tight. However, the apparent mass is 33.53 kDa [95% confidence 33.25-33.82], again 9% below that expected for 100% trimer. To examine the possibility this protein has an unusual partial specific volume, sedimentation equilibrium was also done in H(2)O/D(2)O mixtures, giving 0.765+/-0.017 ml/g rather than the calculated 0.735 ml/g. With this revised partial specific volume, the equilibrium and velocity data each give M=37.9+/-2.8 kDa, fully consistent with a strongly-associated trimeric quaternary structure.     

Oligomeric structure of mammalian purine nucleoside phosphorylase in solution determined by analytical ultracentrifugation

The influence of phosphate, ionic strength, temperature and enzyme concentration on the oligomeric structure of calf spleen purine nucleoside phosphorylase (PNP) in solution was studied by analytical ultracentrifugation methods. Sedimentation equilibrium analysis used to directly determine the enzyme molecular mass revealed a trimeric molecule with Mr = (90.6 +/- 2.1) kDa, regardless the conditions investigated: protein concentration in the range 0.02-1.0 mg/ml, presence of up to 100 mM phosphate and up to 200 mM NaCl, temperature in the range 4-25 degrees C. The sedimentation coefficient (6.04 +/- 0.02) S, together with the diffusion coefficient (6.15 +/- 0.11) 10(-7) cm2/s, both values obtained from the classic sedimentation velocity method at 1.0 mg/ml PNP concentration in 20 mM Hepes, pH 7.0, yielded a molecular mass of (90.2 +/- 1.6) kDa as expected for the trimeric enzyme molecule. Moreover, as shown by active enzyme sedimentation, calf spleen PNP remained trimeric even at low protein concentrations (1 microg/ml). Hence in solution, similar like in the crystalline state, calf spleen PNP is a homotrimer and previous suggestions for dissociation of this enzyme into more active monomers, upon dilution of the enzyme or addition of phosphate, are incorrect.     

An asymmetric and slightly dimerized structure for the tetanus toxoid protein used in glycoconjugate vaccines

Tetanus toxoid protein has been characterized with regard oligomeric state and hydrodynamic (low-resolution) shape, important parameters with regard its use in glycoconjugate vaccines. From sedimentation velocity and sedimentation equilibrium analysis in the analytical ultracentrifuge tetanus toxoid protein is shown to be mostly monomeric in solution (～86%) with approximately 14% dimer. The relative proportions do not appear to change significantly with concentration, suggesting the two components are not in reversible equilibrium. Hydrodynamic solution conformation studies based on high precision viscometry, combined with sedimentation data show the protein to be slightly extended conformation in solution with an aspect ratio ～3. The asymmetric structure presents a greater surface area for conjugation with polysaccharide than a more globular structure, underpinning its popular choice as a conjugation protein for glycoconjugate vaccines.     

Thermodynamic and hydrodynamic properties of human tropoelastin. Analytical ultracentrifuge and pulsed field-gradient spin-echo NMR studies

Tropoelastin is the soluble precursor of elastin that bestows tissue elasticity in vertebrates. Tropoelastin is soluble at 20 degrees C in phosphate-buffered saline, pH 7.4, but at 37 degrees C equilibrium is established between soluble protein and insoluble coacervate. Sedimentation equilibrium studies performed before (20 degrees C) and after (37 degrees C) coacervation showed that the soluble component was strictly monomeric. Sedimentation velocity experiments revealed that at both temperatures soluble tropoelastin exists as two independently sedimenting monomeric species present in approximately equal concentrations. Species 1 had a frictional ratio at both temperatures of approximately 2.2, suggesting a very highly expanded or asymmetric protein. Species 2 displayed a frictional ratio at 20 degrees C of 1.4 that increased to 1.7 at 37 degrees C, indicating a compact and symmetrical conformation that expanded or became asymmetric at the higher temperature. The slow interconversion of the two monomeric species contrasts with the rapid and reversible process of coacervation suggesting both efficiently incorporate into the coacervate. A hydrated protein of equivalent molecular weight modeled as a sphere and a flexible chain was predicted to have a frictional ratio of 1.2 and 1.6, respectively. Tropoelastin appeared as a single species when studied by pulsed field-gradient spin-echo NMR, but computer modeling showed that the method was insensitive to the presence of two species of equal concentration having similar diffusion coefficients. Scintillation proximity assays using radiolabeled tropoelastin and sedimentation analysis showed that the coacervation at 37 degrees C was a highly cooperative monomer-n-mer self-association. A critical concentration of 3.4 g/liter was obtained when the coacervate was modeled as a helical polymer formed from the monomers via oligomeric intermediates.     

Structure and dimerization of translation initiation factor aIF5B in solution

Translation initiation factor 5B (IF5B) is required for initiation of protein synthesis. The solution structure of archaeal IF5B (aIF5B) was analysed by small-angle X-ray scattering (SAXS) and dynamic light scattering (DLS) and was indicated to be in both monomeric and dimeric form. Sedimentation equilibrium (SE) analytical ultracentrifugation (AUC) of aIF5B indicated that aIF5B forms irreversible dimers in solution but only to a maximum of 5.0-6.8% dimer. Sedimentation velocity (SV) AUC at higher speed also indicated the presence of two species, and the sedimentation coefficients s(20,w)(0) were determined to be 3.64 and 5.51±0.29 S for monomer and dimer, respectively. The atomic resolution (crystallographic) structure of aIF5B (Roll-Mecak et al. [6]) was used to model monomer and dimer, and theoretical sedimentation coefficients for these models were computed (3.89 and 5.63 S, respectively) in good agreement with the sedimentation coefficients obtained from SV analysis. Thus, the structure of aIF5B in solution must be very similar to the atomic resolution structure of aIF5B. SAXS data were acquired in the same buffer with the addition of 2% glycerol to inhibit dimerization, and the resultant monomeric aIF5B in solution did indeed adopt a structure very similar to the one reported earlier for the protein in crystalline form. The p(r) function indicated an elongated conformation supported by a radius of gyration of 37.5±0.2 ? and a maximum dimension of ~130 ?. The effects of glycerol on the formation of dimers are discussed. This new model of aIF5B in solution shows that there are universal structural differences between aIF5B and the homologous protein IF2 from Escherichia coli.     

Specificity of Membrane Binding of the Neuronal Protein NAP-22

NAP-22, a major protein of neuronal rafts is known to preferentially bind to membranes containing cholesterol. In this work we establish the requirements for membrane binding of NAP-22. We find that other sterols can replace cholesterol to promote binding. In addition, bilayers containing phosphatidylethanolamine bind NAP-22 in the absence of cholesterol. Thus, there is not a specific interaction of NAP-22 with cholesterol that determines its binding to membranes. Addition of a mol fraction of phosphatidylserine of 0.05 to membranes of phosphatidylcholine and cholesterol enhances the membrane binding of NAP-22. The dependence of binding on the mol fraction of phosphatidylserine indicates that NAP-22 binds to membranes with its amino-terminal segment closer to the membrane than the remainder of the protein. We have also determined which segments of NAP-22 are required for membrane binding. A non-myristoylated form binds only weakly to membranes. Truncating the protein from 226 amino acids to the myristoylated amino-terminal 60 amino acids does not prevent binding to membranes in a cholesterol-dependent manner, but this binding is of weaker affinity. However, myristoylation is not sufficient to promote binding to cholesterol-rich domains. An N-terminal 19-amino-acid, myristoylated peptide binds to membranes but without requiring specific lipids. Thus, the remainder of the protein contributes to the lipid specificity of the membrane binding of NAP-22.     

Solution physicochemical properties of bovine beta 2-microglobulin. Aggregation states

Bovine beta 2-microglobulin (beta 2-m), the light chain of the histocompatibility antigen, was isolated in crystalline form from colostrum. Previous studies from this laboratory on the solution properties of this protein suggest the existence of a time-dependent multiple aggregation phenomenon. To clarify the molecular states of beta 2-m, its solution properties were studied by ultracentrifugation and spectropolarimetry. Sedimentation equilibrium experiments at pH 5.0 (0.08 M NaCl, 0.02 M sodium phosphate) at concentrations less than 0.3 mg/ml give Mr = 11,800. From sedimentation velocity results, we conclude that bovine beta 2-m is a much more symmetrical and compact molecule than either guinea pig or human beta 2-m. At concentrations above 0.4 mg/ml under the same conditions, sedimentation equilibrium experiments show that a monomer to tetramer reversible self-association occurs. Also, the tetramerization increases with decreasing temperature. beta 2-Microglobulin undergoes an irreversible temperature-dependent association to a much larger aggregate over a period of 7 days, as evidenced by sedimentation equilibrium and velocity results. The rate of this aggregation decreases as the pH approaches the isoelectric point (pH 7) from either side. Furthermore, circular dichroism measured at pH 5.0 under time-dependent aggregating conditions showed a marked increase in the percentage of disordered structure, leading to the conclusion that this effect is a denaturation phenomenon.     

Sedimentation equilibrium studies of human chymotrypsin II and bovine -chymotrypsin

Sedimentation equilibrium experiments indicate that neither human chymotrypsin II nor bovine δ-chymotrypsin molecules undergo association in the pH range 3–5 where dimerization occurs with α-chymotrypsin. The weight-average molecular weights of human chymotrypsin II and δ-chymotrypsin in a pH 4.4 0.1 ionic strength buffer are 26,200 and 26,400, respectively, using the measured partial specific volumes of 0.722 and 0.727 ml/g at 25 °C. Number-average molecular weight calculations also support the presence of monomeric species at this pH. In the pH range 6–7.6 where sedimentation velocity studies have shown that δ-chymotrypsin associates at concentrations above 3 mg/ml, no association was observed for either the human chymotrypsin II or bovine δ-chymotrypsin in the sedimentation equilibrium experiments where protein concentrations were below 1.2 mg/ml. These studies provide additional evidence that human chymotrypsin II is similar to bovine δ-chymotrypsin.     

The polyprotein and FAR lipid binding proteins of nematodes: shape and monomer/dimer states in ligand-free and bound forms

Nematodes produce two classes of small, helix-rich fatty acid- and retinol-binding proteins whose structures and in vivo functions remain to be elucidated. These are the polyprotein allergens (NPA) and the FAR proteins. The solution properties of recombinant forms of these proteins from parasitic [Ascaris suum (As) and Onchocerca volvulus (Ov)] and free-living [Caenorhabditis elegans (Ce)] nematodes have been examined. Analytical ultracentrifugation (AUC) showed that, contrary to previous findings, the rAs-NPA-1A polyprotein unit (approximately 15 kDa) is a monomer, and this stoichiometry is unaltered by ligand (oleic acid) binding. The rOv-FAR-1 and rCe-FAR-5 proteins differ in that the former forms a tight dimer and the latter a monomer, and these oligomeric states are also unaffected by ligand binding or protein concentration. Sedimentation equilibrium experiments showed that the partial specific volume v of the unliganded proteins agree well with the value calculated from amino acid composition extrapolated to experimental temperature, and was unaffected upon ligand binding. Data from small-angle X-ray scattering (SAXS) indicated that both of the monomeric proteins rAs-NPA-1A and rCe-FAR-5 are globular, although slightly elongated and flattened. These data are in good agreement with shapes predicted from sedimentation velocity experiments and hydrodynamic bead modelling. On the basis of functional and secondary structural homology with the ligand-binding domain of the retinoic acid receptor RXRalpha, de novo atomic resolution structures for rAs-NPA-1A and rCe-FAR-5 have been constructed which are consistent with the SAXS and hydrodynamic data.     

Self-association of band-protein from human erythrocyte membranes in aqueous solutions

Band 3, the main integral protein of the human erythrocyte membrane, was solubilized and purified in high concentrations of acetic acid. After removal of the organic solvent by dialysis, the self-association of the protein in aqueous solutions was studied by analytical ultracentrifugation. Sedimentation velocity and sedimentation equilibrium experiments clearly demonstrate that, under appropriate conditions of protein preparation, at protein concentrations c less than 200 micrograms/ml, ionic strengths 2 less than 10mM and pH values remote from the isoelectric pH of the protein, band 3 shows a monomer/dimer/tetramer-association equilibrium. With some preparations, as well as at higher values of c or I, hexamers and octamers contribute to the association equilibrium. The time needed for relaxation towards association equilibrium depends on the blood donor from whom the membranes were derived and varies between less than one minute and more than several hours. The results of analytical ultracentriguation, together with previously published data on the incorporation of band 3 into planar lipid bilayers, from chemical crosslinking and from electronmicroscopy suggest that band 3 will also show a monomer/dimer/tetramer-association equilibrium in the human erythrocyte membrane. This hypothesis contrasts the widely-held assumption that, in the membrane, band 3 is a stable dimer; however, it is consistent with nearly all known data on band 3-self-association.     

Biochemical indication for myristoylation-dependent conformational changes in HIV-1 Nef

The accessory HIV-1 Nef protein is essential for viral replication, high virus load, and progression to AIDS. These functions are mediated by the alteration of signaling and trafficking pathways and require the membrane association of Nef by its N-terminal myristoylation. However, a large portion of Nef is also found in the cytosol, in line with the observation that myristoylation is only a weak lipidation anchor for membrane attachment. We performed biochemical studies to analyze the implications of myristoylation on the conformation of Nef in aqueous solution. To establish an in vivo myristoylation assay, we first optimized the codon usage of Nef for Escherichia coli expression, which resulted in a 15-fold higher protein yield. Myristoylation was achieved by coexpression with the N-myristoyltransferase and confirmed by mass spectrometry. The myristoylated protein was soluble, and proton NMR spectra confirmed proper folding. Size exclusion chromatography revealed that myristoylated Nef appeared of smaller size than the unmodified form but not as small as an N-terminally truncated from of Nef that omits the anchor domain. Western blot stainings and limited proteolysis of both forms showed different recognition profiles and degradation pattern. Analytical ultracentrifugation revealed that myristoylated Nef prevails in a monomeric state while the unmodified form exists in an oligomeric equilibrium of monomer, dimer, and trimer associations. Finally, fluorescence correlation spectroscopy using multiphoton excitation revealed a shorter diffusion time for the lipidated protein compared to the unmodified form. Taken together, our data indicated myristoylation-dependent conformational changes in Nef, suggesting a rather compact and monomeric form for the lipidated protein in solution.     

Monomeric form of the molecular chaperone GroEL: structure, stability, and oligomerization]

The structure and stability in solution of the monomeric form of GroEL were studied by the methods of circular dichroism, binding of a hydrophobic probe, limited proteolysis, modification of thiol groups, sedimentation, and size-exclusion chromatography. The monomeric GroEL at 23 degrees C was shown to be a globular protein with a pronounced secondary and a rigid tertiary structure. It exhibited no marked tendency to oligomerization in the absence of adenine nucleotides. However, the free monomeric GroEL was substantially less stable to urea and heat than the corresponding subunit in the composition of native oligomeric particles. The monomeric form also bound the hydrophobic probe, 8-anilino-1-naphthalenesulfonic acid, by an order of magnitude better than the subunit in the oligomeric particles. The ATP-induced oligomerization process of both folded and unfolded GroEL monomers was studied. The oligomerization rate was found to be the same for both monomers, and, therefore, should be limited by the ATP-dependent "arrangement" of the sites in the folded monomers responsible for the oligomerization rather than by the spontaneous refolding of monomers.     

The effect of nucleotides on oligomeric state of human lactoferrin

A polyfunctional protein lactoferrin (LF) which is present in human barrier fluids, blood and milk and this protein of acute phase is responsible for nonspecific cells defense against microbial and viral infection and cancer diseases. Using the methods of small-angle X-ray scattering and light-scattering it was shown that LF in solution exists in oligomeric state. The level of LF oligomerization depends upon its concentration and time of keeping of no frozen neutral protein solutions. At the concentrations comparable with those in human milk (1-6 mg/ml) the average inertial radius values (Rg) of LF can reach 100-450 angstroms, while Rg for monomer LF form is 26.7 angstroms. LF was shown to complex with different nucleotides and hydrolyze them. The addition of ATP and AMP to LF demonstrating any level of oligomerization leads to increase of oligomerization processes and enhancement of the Rg values up to 600-700 angstroms According to different models of LF monomer association to its oligomeric forms (sphere, plate, cylinder) the oligomeric complexes demonstrate high Rg values which can contain from several tens up to several thousands of LF monomers. A possible role of LF oligomerization for different biological functions of the protein is discussed.     

Structural and functional analysis of the pre-pore and membrane-inserted pore of Cry1Ab toxin

Bacillus thuringiensis produces insecticidal Cry proteins that are active against different insect species. The primary action of Cry toxins is to lyse midgut epithelial cells in the target insect by forming lytic pores on the apical membrane. After interaction with cadherin receptor, Cry proteins undergo conformational changes from a monomeric structure to a pre-pore-oligomeric form that is able to interact with a second GPI-anchored aminopeptidase-N receptor and then insert into lipid membranes. Here, we review the recent advances in the understanding of the structural changes presented by Cry1Ab toxin upon membrane insertion. Based on analysis of the Trp fluorescence of pure monomeric and oligomeric Cry1Ab structures in solution and in membrane-bound state we reported that oligomerization caused 27% reduction of Trp exposed to the solvent. After membrane insertion there is another conformational change that allows an additional rearrangement of the Trp residues resulting in a total protection of these residues from exposure to the solvent. The oligomeric structure is membrane insertion competent since more than 96% of the Cry1Ab oligomer inserts into the membrane as a function of lipid:protein ratio, in contrast to the monomer of which only 5-10%, inserts into the membrane. Finally, analysis of the stability of monomeric, pre-pore and pore structures of Cry1Ab toxin after urea and thermal denaturation suggested that a more flexible conformation could be necessary for membrane insertion and this flexible structure is obtained by toxin oligomerization and by alkaline pH. Domain I is involved in the intermolecular interaction within the oligomeric Cry1Ab and this domain is inserted into the membrane in the membrane-inserted state.     

Polymerization pattern of insulin at pH 7.0.

Sedimentation equilibrium results, obtained with bovine zinc-free insulin (with and without a component of proinsulin) at pH 7.0, I o.2, 25 degrees C, and up to a total concentration of 0.8 g/l., are shown to be consistent with three different polymerization patterns, all involving an isodesmic indefinite self-association of specified oligomeric species. The analysis procedure, based on closed solutions formed by summing infinite series, yields for each pattern a set of equilibrium constants, It is shown that a distinction between the possible patterns can be made by analyzing sedimentation equilibrium results obtained in a higher total concentration range (up to 4 g/1.) with insulin freed of zinc and proinsulin, account being taken of the composition dependence of activity coefficients. The favored pattern, which differs from that previously reported in the literature, involves the dimerization of monomeric insulin (mol wt 5734), governed by a dimerization constant of 11 X 10(4) M-1 and the isodesmic indefinite self-association of the dimer, described by an association constant of 1.7 X 10(4) M-1. This polymerization pattern is also shown to be consistent with the reaction boundary observed in sedimentation velocity experiments.     

Nucleotide-dependent oligomerization of ClpB from Escherichia coli.

Self-association of ClpB (a mixture of 95- and 80-kDa subunits) has been studied with gel filtration chromatography, analytical ultracentrifugation, and electron microscopy. Monomeric ClpB predominates at low protein concentration (0.07 mg/mL), while an oligomeric form is highly populated at >4 mg/mL. The oligomer formation is enhanced in the presence of 2 mM ATP or adenosine 5'-O-thiotriphosphate (ATPgammaS). In contrast, 2 mM ADP inhibits full oligomerization of ClpB. The apparent size of the ATP- or ATPgammaS-induced oligomer, as determined by gel filtration, sedimentation velocity and electron microscopy image averaging, and the molecular weight, as determined by sedimentation equilibrium, are consistent with those of a ClpB hexamer. These results indicate that the oligomerization reactions of ClpB are similar to those of other Hsp100 proteins.     

Structure and dynamics of UBA5-UFM1 complex formation showing new insights in the UBA5 activation mechanism

Ubiquitin fold modifier 1 (UFM1) is an ubiquitin-like protein (Ubl) involved especially in endoplasmic stress response. Activation occurs via a three-step mechanism like other Ubls. Data obtained reveal that UFM1 regulates the oligomeric state of ubiquitin activating enzyme 5 (UBA5) to initiate the activation step. Mixtures of homodimers and heterotrimers are observed in solution at the equilibrium state, demonstrating that the UBA5-UFM1 complex undergoes several concentration dependent oligomeric translational states to form a final functional complex. The oligomerization state of unbound UBA5 is also concentration dependent and shifts from the monomeric to the dimeric state. Data describing different oligomeric states are complemented with binding studies that reveal a negative cooperativity for the complex formation and thereby provide more detailed insights into the complex formation mechanism.     

Folding of Escherichia coli DsbC: characterization of a monomeric folding intermediate

The homodimeric protein DsbC is a disulfide isomerase and a chaperone located in the periplasm of Escherichia coli. We have studied the guanidine hydrochloride (GdnHCl)-induced unfolding and refolding of DsbC using mutagenesis, intrinsic fluorescence, circular dichroism spectra, size-exclusion chromatography, and sedimentation velocity analysis. The equilibrium refolding and unfolding of DsbC was thermodynamically reversible. The equilibrium folding profile measured by fluorescence excited at 280 nm exhibited a three-state transition profile with a stable folding intermediate formed at 0-2.0 M GdnHCl followed by a second transition at higher GdnHCl concentrations. Sedimentation velocity data revealed dissociation of the dimer to the monomer over the concentration range of the first transition (0-2.0 M). In contrast, fluorescence emission data for DsbC excited at 295 nm showed a single two-state transition. Fluorescence emission data for the equilibrium unfolding of the monomeric G49R mutant, excited at either 295 or 280 nm, indicated a single two-state transition. Data obtained for the dimeric Y52W mutant indicated a strong protein concentration dependence of the first transition but no dependence of the second transition in equilibrium unfolding. This suggests that the fluorescence of Y52W sensitively reports conformational changes caused by dissociation of the dimer. Thus, the folding of DsbC follows a three-state transition model with a monomeric folding intermediate formed in 0-2.0 M GdnHCl. The folding of DsbC in the presence of DTT indicates an important role for the non-active site disulfide bond in stabilizing the conformation of the molecule. Dimerization ensures the performance of chaperone and isomerase functions of DsbC.