Functional promiscuity correlates with conformational heterogeneity in A-class glutathione S-transferases

The structurally related glutathione S-transferase isoforms GSTA1-1 and GSTA4-4 differ greatly in their relative catalytic promiscuity. GSTA1-1 is a highly promiscuous detoxification enzyme. In contrast, GSTA4-4 exhibits selectivity for congeners of the lipid peroxidation product 4-hydroxynonenal. The contribution of protein dynamics to promiscuity has not been studied. Therefore, hydrogen/deuterium exchange mass spectrometry (H/DX) and fluorescence lifetime distribution analysis were performed with glutathione S-transferases A1-1 and A4-4. Differences in local dynamics of the C-terminal helix were evident as expected on the basis of previous studies. However, H/DX demonstrated significantly greater solvent accessibility throughout most of the GSTA1-1 sequence compared with GSTA4-4. A Phe-111/Tyr-217 aromatic-aromatic interaction in A4-4, which is not present in A1-1, was hypothesized to increase core packing. "Swap" mutants that eliminate this interaction from A4-4 or incorporate it into A1-1 yield H/DX behavior that is intermediate between the wild type templates. In addition, the single Trp-21 residue of each isoform was exploited to probe the conformational heterogeneity at the intrasubunit domain-domain interface. Excited state fluorescence lifetime distribution analysis indicates that this core residue is more conformationally heterogeneous in GSTA1-1 than in GSTA4-4, and this correlates with greater stability toward urea denaturation for GSTA4-4. The fluorescence distribution and urea sensitivity of the mutant proteins were intermediate between the wild type templates. The results suggest that the differences in protein dynamics of these homologs are global. The results suggest also the possible importance of extensive conformational plasticity to achieve high levels of functional promiscuity, possibly at the cost of stability.     

A fluorescence investigation of the active site of Pseudomonas aeruginosa exotoxin A.

Single tryptophan mutant proteins of a catalytically active domain III recombinant protein (PE24) from Pseudomonas aeruginosa exotoxin A were prepared by site-directed mutagenesis. The binding of the dinucleotide substrate, NAD+, to the PE24 active site was studied by exploiting intrinsic tryptophan fluorescence for the wild-type, single Trp, and tryptophan-deficient mutant proteins. Various approaches were used to study the substrate binding process, including dynamic quenching, CD spectroscopy, steady-state fluorescence emission analysis, NAD+-glycohydrolase activity, NAD+ binding analysis, protein denaturation experiments, fluorescence lifetime analysis, steady-state anisotropy measurement, stopped flow fluorescence spectroscopy, and quantum yield determination. It was found that the conservative replacement of tryptophan residues with phenylalanine had little or no effect on the folded stability and enzyme activity of the PE24 protein. Dynamic quenching experiments indicated that when bound to the active site of the enzyme, the NAD+ substrate protected Trp-558 from solvent to a large extent but had no effect on the degree of solvent exposure for tryptophans 417 and 466. Also, upon substrate binding, the anisotropy of the Trp-417(W466F/W558F) protein showed the largest increase, followed by Trp-466(W417F/W558F), and there was no effect on Trp-558(W417F/W466F). Furthermore, the intrinsic tryptophan fluorescence exhibited the highest degree of substrate-induced quenching for the wild-type protein, followed in decreasing order by Trp-417(W466F/W558F), Trp-558(W417F/W466F), and Trp-466(W417F/W558F). These data provide evidence for a structural rearrangement in the enzyme domain near Trp-417 invoked by the binding of the NAD+ substrate.     

The C-terminus of glutathione S-transferase A1-1 is required for entropically-driven ligand binding

Binding of a hydrophobic glutathione product conjugate to rGST A1-1 proceeds via a two-step mechanism, including rapid ligand docking, followed by a slow isomerization to the final [GST.ligand] complex, which involves the localization of the flexible C-terminal helix. These kinetically resolved steps have been observed previously by stopped-flow fluorescence with the wild-type rGST A1-1, which contains a native Trp-21 approximately 20 A from the ligand binding site at the intrasubunit domain-domain interface. To confirm this binding mechanism, as well as elucidate the effects of truncation of the C-terminus, we have further characterized the binding and dissociation of the glutathione-ethacrynic acid product conjugate (GS-EA) to wild-type, F222W:W21F, and Delta209-222 rGST A1-1 and wild-type hGST A1-1. Although modest kinetic differences were observed between the hGST A1-1 and rGST A1-1, stopped-flow binding studies with GS-EA verified that the two-step mechanism of ligand binding is not unique to the GST A1-1 isoform from rat. An F222W:W21F rGST A1-1 double mutant provides a direct fluorescence probe of changes in the environment of the C-terminal residue. The observation of two relaxation times during ligand binding and dissociation to F222W:W21F suggests that the C-terminus has an intermediate conformation following ligand docking, which is distinct from its conformation in the apoenzyme or localized helical state. For the wild-type, Delta209-222, and F222W:W21F proteins, variable-temperature stopped-flow experiments were performed and activation parameters calculated for the individual steps of the binding reaction. Activation parameters for the binding reaction coordinate illustrate that the C-terminus provides a significant entropic contribution to ligand binding, which is completely realized within the initial docking step of the binding mechanism. In contrast, the slow isomerization step is enthalpically driven. The partitioning of entropic and enthalpic components of binding energy was confirmed by isothermal titration calorimetry with wild-type and Delta209-222 rGST A1-1.     

High-affinity binding of fatty acyl-CoAs and peroxisome proliferator-CoA esters to glutathione S-transferases effect on enzymatic activity.

Acyl-CoAs are present at high concentrations within the cell, yet are strongly buffered by specific binding proteins in order to maintain a low intracellular unbound acyl-CoA concentration, compatible with their metabolic role, their importance in cell signaling, and as protection from their detergent properties. This intracellular regulation may be disrupted by nonmetabolizables acyl-CoA esters of xenobiotics, such as peroxisome proliferators, which are formed at relatively high concentration within the liver cell. The low molecular mass acyl-CoA binding protein (ACBP) and fatty acyl-CoA binding protein (FABP) have been proposed as the buffering system for fatty acyl-CoAs. Whether these proteins also bind xenobiotic-CoA is not known. Here we have identified new liver cytosolic fatty acyl-CoA and xenobiotic-CoA binding sites as glutathione S-transferase (GST), using fluorescent polarization and a acyl-etheno-CoA derivative of the peroxisome proliferator nafenopin as ligand. Rat liver GST and human liver recombinant GSTA1-1, GSTP1-1 and GSTM1-1 were used. Only class alpha rat liver GST and human GSTA1-1 bind xenobiotic-CoAs and fatty acyl-CoAs, with Kd values ranging from 200 nM to 5 microM. One mol of acyl-CoA is bound per mol of dimeric enzyme, and no metabolization or hydrolysis was observed. Binding results in strong inhibition of rat liver GST and human recombinant GSTA1-1 (IC50 at the nanomolar level for palmitoyl-CoA) but not GSTP1-1 and GSTM1-1. Acyl-CoAs do not interact with the GSTA1-1 substrate binding site, but probably with a different domain. Results suggest that under increased acyl-CoA concentration, as occurs after exposure to peroxisome proliferators, acyl-CoA binding to the abundant class alpha GSTs may result in strong inhibition of xenobiotic detoxification. Analysis of the binding properties of GSTs and other acyl-CoA binding proteins suggest that under increased acyl-CoA concentration GSTs would be responsible for xenobiotic-CoA binding whereas ACBP would preferentially bind fatty acyl-CoAs.     

Activity and spectroscopic properties of bacterial D-amino acid transaminase after multiple site-directed mutagenesis of a single tryptophan residue

One of the three tryptophan residues per subunit of thermostable D-amino acid transaminase, Trp-139, is close to the active-site Lys-145 in the sequence of the protein. This tryptophan has been changed to several other types of residues by site-directed mutagenesis. The only mutant protein that was sufficiently active and stable for study had Phe substituted for Trp (W139F). The spectroscopic properties of this mutant enzyme differed from those of the wild-type transaminase. For example, denatured W139F showed the expected decrease in fluorescence emission intensity at 350 nm due to the deletion of one Trp residue, but the fluorescence emission of the wild-type and W139F enzymes in the native state did not differ in intensity. This result suggests that the fluorescence of Trp-139 in the native, wild-type enzyme is not manifested perhaps due to its proximity to the coenzyme, pyridoxal phosphate. Results of energy-transfer studies at several wavelengths could also be interpreted as due to the proximity of Trp-139 and the coenzyme. Circular dichroism studies indicated that the negative Cotton effect at 420 nm due to the coenzyme was still present in W139F. However, the 280-nm optically active band present in the wild-type enzyme was greatly diminished in W139F. The mutant protein with Asp at position 139 (W139D) could not be isolated presumably because it was degraded. The other mutant enzymes, W139P, W139A, and W139H, were isolated with partial activities (15-35%) that were slowly lost upon storage at 4 degrees C. Overall, these results indicate the importance of Trp-139 in the thermostable D-amino acid transaminase.     

Local and long-range interactions in the thermal unfolding transition of bovine pancreatic ribonuclease A

This research was undertaken to distinguish between local and global unfolding in the reversible thermal denaturation of bovine pancreatic ribonclease A (RNase A). Local unfolding was monitored by steady-state and time-resolved fluorescence of nine mutants in each of which a single tryptophan was substituted for a wild-type residue. Global unfolding was monitored by far-UV circular dichroism and UV absorbance. All the mutants (except F8W and D38W) exhibited high specific enzymatic activity, and their far-UV CD spectra were very close to that of wild-type RNase A, indicating that the tryptophan substitutions did not affect the structure of any of the mutants (excluding K1W and Y92W) under folding conditions at 20 degrees C. Like wild-type RNase A, the various mutants exhibited reversible cooperative thermal unfolding transitions at pH 5, with transition temperatures 2.5-11 degrees C lower than that of the wild-type transition, as detected by far-UV CD or UV absorbance. Even at 80 degrees C, well above the cooperative transition of all the RNase A mutants, a considerable amount of secondary and tertiary structure was maintained. These studies suggest the following two-stage mechanism for the thermal unfolding transition of RNase A as the temperature is increased. First, at temperatures lower than those of the main cooperative transition, long-range interactions within the major hydrophobic core are weakened, e.g., those involving residues Phe-8 (in the N-terminal helix) and Lys-104 and Tyr-115 (in the C-terminal beta-hairpin motif). The structure of the chain-reversal loop (residues 91-95) relaxes in the same temperature range. Second, the subsequent higher-temperature cooperative unfolding transition is associated with a loss of secondary structure and additional changes in the tertiary contacts of the major hydrophobic core, e.g., those involving residues Tyr-73, Tyr-76, and Asp-38 on the other side of the molecule. The hydrophobic interactions of the C-terminal loop of the protein are enhanced by high temperature, and perhaps are responsible for the preservation of the local structural environment of Trp-124 at temperatures slightly above the major cooperative transition. The results shed new light on the thermal unfolding transitions, generally supporting the thermal unfolding hypothesis of Burgess and Scheraga, as modified by Matheson and Scheraga.     

Unfolding of triosephosphate isomerase from Trypanosoma brucei: identification of intermediates and insight into the denaturation pathway using tryptophan mutants

The unfolding of triosephosphate isomerase (TIM) from Trypanosoma brucei (TbTIM) induced by guanidine hydrochloride (GdnHCl) was characterized. In contrast to other TIMs, where unfolding is a two or three state process, TbTIM showed two intermediates. The solvent exposure of different regions of the protein in the unfolding process was characterized spectroscopically with mutant proteins in which tryptophans (W) were changed to phenlylalanines (F). The midpoints of the transitions measured by circular dichroism, intrinsic fluorescence, and catalytic activity, as well as the increase in 1-aniline 8-naphthalene sulfonate fluorescence, show that the native state was destabilized in the W12F and W12F/W193F mutants, relative to the wild-type enzyme. Using the hydrodynamic profile for the unfolding of a monomeric TbTIM mutant (RMM0-1TIM) measured by size-exclusion chromatography as a standard, we determined the association state of these intermediates: D*, a partially expanded dimer, and M*, a partially expanded monomeric intermediate. High-molecular-weight aggregates were also detected. At concentrations over 2.0 M GdnHCl, the hydrodynamic properties of TbTIM and RMM0-1TIM are the same, suggesting that the dimeric intermediate dissociates and the unfolding proceeds through the denaturation of an expanded monomeric intermediate. The analysis of the denaturation process of the TbTIM mutants suggests a sequence for the gradual exposure of W residues: initially the expansion of the native dimer to form D* affects the environments of W12 and W159. The dissociation of D* to M* and further unfolding of M* to U induces the exposure of W170. The role of protein concentration in the formation of intermediates and aggregates is discussed considering the irreversibility of this unfolding process.     

The omega-loop region of the human prothrombin gamma-carboxyglutamic acid domain penetrates anionic phospholipid membranes

The hydrophobic omega-loop within the prothrombin gamma-carboxyglutamic acid-rich (Gla) domain is important in membrane binding. The role of this region in membrane binding was investigated using a synthetic peptide, PT-(1-46)F4W, which includes the N-terminal 46 residues of human prothrombin with Phe-4 replaced by Trp providing a fluorescent probe. PT-(1-46)F4W and PT-(1-46) bind calcium ions and phospholipid membranes, and inhibit the prothrombinase complex. PT-(1-46)F4W, but not PT-(1-46), exhibits a blue shift (5 nm) and red-edge excitation shift (28 nm) in the presence of phosphatidylserine (PS)-containing vesicles, suggesting Trp-4 is located within the motionally restricted membrane interfacial region. PS-containing vesicles protect PT-(1-46)F4W, but not PT-(1-46), fluorescence from potassium iodide-induced quenching. Stern-Volmer analysis of the quenching of PT-(1-46)F4W in the presence and absence of 80% phosphatidylcholine/20% PS vesicles suggested that Trp-4 is positioned within the membrane and protected from aqueous quenching agents whereas Trp-41 remains solvent-accessible in the presence of PS-containing vesicles. Fluorescence quenching of membrane-bound PT-(1-46)F4W is optimal with 7- and 10-doxyl-labeled lipids, indicating that Trp-4 is inserted 5 to 7 A into the bilayer. This report demonstrates that the omega-loop region of prothrombin specifically interacts with PS-containing membranes within the interfacial membrane region.     

TEM-1 beta-lactamase folds in a nonhierarchical manner with transient non-native interactions involving the C-terminal region

The conformational stability and kinetics of refolding and unfolding of the W290F mutant of TEM-1 beta-lactamase have been determined as a function of guanidinium chloride concentration. The activity and spectroscopic properties of the mutant enzyme did not differ significantly from those of the wild type, indicating that the mutation has only a very limited effect on the structure of the protein. The stability of the folded protein is reduced, however, by 5-10 kJ mol-1 relative to that of the molten globule intermediate (H), but the values of the folding rate constants are unchanged, suggesting that Trp-290 becomes organized in its nativelike environment only after the rate-limiting step; i.e., the C-terminal region of the enzyme folds very late. In contrast to the significant increase in fluorescence intensity seen in the dead time (3-4 ms) of refolding of the wild-type protein, no corresponding burst phase was observed with the mutant enzyme, enabling the burst phase to be attributed specifically to the C-terminal Trp-290. This residue is suggested to be buried in a nonpolar environment from which it has to escape during subsequent folding steps. With both proteins, fast early collapse leads to a folding intermediate in which the C-terminal region of the polypeptide chain is trapped in a non-native structure, consistent with a nonhierarchical folding process.     

Effects of tryptophan to phenylalanine substitutions on the structure, stability, and enzyme activity of the IIAB(Man) subunit of the mannose transporter of Escherichia coli.

The hydrophilic subunit of the mannose transporter (IIAB(Man)) of Escherichia coli is a homodimer that contains four tryptophans per monomer, three in the N-terminal domain (Trp12, Trp33, and Trp69) and one in the C-terminal domain (Trp182). Single and double Trp-Phe mutants of IIABMan and of the IIA domain were produced. Fluorescence emission studies revealed that Trp33 and Trp12 are the major fluorescence emitters, Trp69 is strongly quenched in the native protein and Trp182 strongly blue shifted, indicative of a hydrophobic environment. Stabilities of the Trp mutants of dimeric IIA(Man) and IIAB(Man) were estimated from midpoints of the GdmHCl-induced unfolding transitions and from the amount of dimers that resisted dissociation by SDS (sodium dodecyl sulfate), respectively. W12F exhibited increased stability, but only 6% of the wild-type phosphotransferase activity, whereas W33F was marginally and W69F significantly destabilized, but fully active. Second site mutations W33F and W69F in the background of the W12F mutation reduced protein stability and suppressed the functional defect of W12F. These results suggest that flexibility is required for the adjustments of protein-protein contacts necessary for the phosphoryltransfer between the phosphorylcarrier protein HPr, IIA(Man), IIB(Man), and the incoming mannose bound to the transmembrane IIC(Man)-IID(Man) complex.     

The specific interaction of dinitrosyl-diglutathionyl-iron complex,a natural NO carrier,with the glutathione transferase superfamily: suggestion for an evolutionary pressure in the direction of the storage of nitric oxide

The interaction of dinitrosyl-diglutathionyl-iron complex (DNDGIC), a natural carrier of nitric oxide, with representative members of the human glutathione transferase (GST) superfamily, i.e. GSTA1-1, GSTM2-2, GSTP1-1, and GSTT2-2, has been investigated by means of pre-steady and steady state kinetics, fluorometry, electron paramagnetic resonance, and radiometric experiments. This complex binds with extraordinary affinity to the active site of all these dimeric enzymes; GSTA1-1 shows the strongest interaction (KD congruent with 10-10 m), whereas GSTM2-2 and GSTP1-1 display similar and slightly lower affinities (KD congruent with 10-9 m). Binding of the complex to GSTA1-1 triggers structural intersubunit communication, which lowers the affinity for DNDGIC in the vacant subunit and also causes a drastic loss of enzyme activity. Negative cooperativity is also found in GSTM2-2 and GSTP1-1, but it does not affect the catalytic competence of the second subunit. Stopped-flow and fluorescence data fit well to a common minimal binding mechanism, which includes an initial interaction with GSH and a slower bimolecular interaction of DNDGIC with one high and one low affinity binding site. Interestingly, the Theta class GSTT2-2, close to the ancestral precursor of GSTs, shows very slow binding kinetics and hundred times lowered affinity (KD congruent with 10-7 m), whereas the bacterial GSTB1-1 is not inhibited by DNDGIC. Molecular modeling and EPR data reveal structural details that may explain the observed kinetic data. The optimized interaction with this NO carrier, developed in the more recently evolved GSTs, may be related to the acquired capacity to utilize NO as a signal messenger.     

Electrostatic association of glutathione transferase to the nuclear membrane. Evidence of an enzyme defense barrier at the nuclear envelope

The possible nuclear compartmentalization of glutathione S-transferase (GST) isoenzymes has been the subject of contradictory reports. The discovery that the dinitrosyl-diglutathionyl-iron complex binds tightly to Alpha class GSTs in rat hepatocytes and that a significant part of the bound complex is also associated with the nuclear fraction (Pedersen, J. Z., De Maria, F., Turella, P., Federici, G., Mattei, M., Fabrini, R., Dawood, K. F., Massimi, M., Caccuri, A. M., and Ricci, G. (2007) J. Biol. Chem. 282, 6364-6371) prompted us to reconsider the nuclear localization of GSTs in these cells. Surprisingly, we found that a considerable amount of GSTs corresponding to 10% of the cytosolic pool is electrostatically associated with the outer nuclear membrane, and a similar quantity is compartmentalized inside the nucleus. Mainly Alpha class GSTs, in particular GSTA1-1, GSTA2-2, and GSTA3-3, are involved in this double modality of interaction. Confocal microscopy, immunofluorescence experiments, and molecular modeling have been used to detail the electrostatic association in hepatocytes and liposomes. A quantitative analysis of the membrane-bound Alpha GSTs suggests the existence of a multilayer assembly of these enzymes at the outer nuclear envelope that could represent an amazing novelty in cell physiology. The interception of potentially noxious compounds to prevent DNA damage could be the possible physiological role of the perinuclear and intranuclear localization of Alpha GSTs.     

Amino acid substitutions at tryptophan-51 of cytochrome c peroxidase: effects on coordination, species preference for cytochrome c, and electron transfer.

Amino acid replacements of an aromatic residue, Trp-51, which is in contact with the heme of yeast cytochrome c peroxidase have a number of significant effects on the kinetics and coordination state of the enzyme. Six mutants at this site (W51F, W51M, W51T, W51C, W51A, and W51G) were examined. Optical and EPR spectra show that each of these mutations introduces a shift from the 5-coordinate to 6-coordinate form, and slightly increases the asymmetry of the heme ligand field. Conversion from a 6-coordinate high-spin form at pH 5 to a 6-coordinate low-spin form at pH 7 is observed for several of the variants (W51F, W51T, and W51A), while W51G and W51C appear as predominantly low-spin species between pH 5 and 7. Addition of 50% glycerol prevents the facile conversion to the low-spin conformation for W51F, W51T, and W51A, and only W51F can be stabilized in a 5-coordinate configuration by glycerol. For the oxidation of cytochrome c by H2O2, three of the variants (W51F, W51M, and W51T) exhibit values of kcat(app) that are greater than for the wild-type enzyme, while the other mutations give decreased rates of enzyme turnover. Unlike the wild-type enzyme, which functions more efficiently with cytochrome c from yeast than with the horse heart protein, the mutant W51F does not show a preference for substrate from its native organism. The three mutants which exhibit increased values of kcat(app) show a pH optimum at 6.8 compared with that of 5.25 for the wild-type enzyme when measured with horse heart cytochrome c. This shift in pH optimum is not observed with yeast cytochrome c. Construction of single and multiple mutations at Trp-51, Ile-53, and Gly-152 shows that these kinetic properties are not due to natural amino acid variations observed at these sites. Pre-steady-state kinetics show that the bimolecular rate constant for the fast phase of the reaction of the enzyme with H2O2 is only slightly decreased from 3.03 (0.09) X 10(7) to 2.2 (0.1) X 10(7) M-1 s-1 for W51F and to 1.5 (0.1) X 10(7) M-1 s-1 for W51A. The slow phase of the reaction (4.9 s-1) which contributes approximately 30% to the amplitude of the change for the wild-type enzyme is not observed for W51F or W51A.(ABSTRACT TRUNCATED AT 400 WORDS)     

Stability and unfolding of reduced Escherichia coli glutaredoxin 2: a monomeric structural homologue of the glutathione transferase family

Glutaredoxin 2 (Grx2) from Escherichia coli is monomeric and an atypical glutaredoxin that takes part in the monothiol deglutathionylation of proteins. Unlike its orthologs, Grx2 is a larger molecule with a canonical glutathione transferase (GST) fold that consists of two structurally distinct domains, an N-terminal glutaredoxin domain and a C-terminal alpha-helical domain. While GSTs are dimeric proteins, the conformational stability and unfolding kinetics of Grx2 were investigated to establish the contribution made by the domain interface to the stability of the tertiary structure of GST-like proteins without any influence from quaternary interactions. Equilibrium unfolding transitions for Grx2, using urea as a denaturant, are monophasic and exhibit coincidence of the fluorescence and CD data indicative of a concerted loss or formation of tertiary and secondary structure. The data fit well to a two-state N <--> U model with no evidence that an intermediate is being formed. The experimental m value [2.7 kcal mol (-1) (M urea) (-1)] is in excellent agreement with a predicted value of 2.5 kcal mol (-1) (M urea) (-1) based on the amount of surface area expected to become exposed during unfolding. These findings provide evidence that the two structurally distinct domains of Grx2 behave as a single cooperative folding unit. The unfolding kinetics are complex which, as a result of native-state heterogeneity, are characterized by two observable unfolding reactions that occur in parallel. A major population representing one distinct nativelike form unfolds on a fast track to denatured Grx2 with cis-Pro49. This is followed by a spectroscopically silent cis-trans proline isomerization reaction as determined by interrupted unfolding experiments. A minor population representing the other distinct nativelike form unfolds slowly with its rate being limited by an undetermined structural isomerization reaction. Further, there is no evidence indicating that unfolding proceeds via a high-energy intermediate that might suggest independent unfolding of the two nonidentical domains in Grx2. The kinetics data are, therefore, consistent with the existence of cooperativity between the domains, in agreement with the equilibrium data.     

Spatial relationship between the prodan site,Trp-214, and Cys-34 residues in human serum albumin and loss of structure through incremental unfolding

Prodan (6-propionyl-2-(dimethylamino)-naphthalene), a competitive inhibitor of warfarin binding to human serum albumin (HSA) at drug site I, was used to determine the inter- and intradomain distances of HSA. The fluorescence resonance energy transfer (FRET) distances between prodan and Trp-214, prodan and 7-(diethyl amino)-4-methylcoumarin 3-maleimide (CM)-modified Cys-34, and Trp-214 and CM-Cys-34 were determined to be 25.5 +/- 0.5 A, 33.1 +/- 0.8 A, and 32.4 +/- 1 A, respectively. FRET analysis showed that low concentration of palmitic acid (5 microM) increased the interdomain distance between the Trp-214 in domain II and CM-Cys-34 in domain I by approximately 5 A without perturbing the secondary structure of HSA and the immediate environment of Trp-214. Palmitic acid (5 microM) increased the prodan fluorescence by increasing the quantum yield of bound prodan without altering the tryptophan environment. However, palmitic acid (>10 microM) decreased the prodan fluorescence and increased the tryptophan fluorescence. Our results indicate that the high affinity palmitic acid binding site is located at the interface of domains I and II. On the basis of our measurements, a schematic model representing the drug site-1, Trp-214, and Cys-34 along with the palmitic acid sites has been constructed. In addition, prodan fluorescence, FRET, and ligand binding were used to monitor guanidine hydrochloride-induced denaturation of HSA. An analysis of the equilibrium unfolding data suggests that HSA undergoes a two-state unfolding transition with no detectable intermediate. However, kinetic analysis using multiple probes and thermal denaturation studies showed that the unfolding of the prodan site in HSA preceded the unfolding of tryptophan environment. In addition, the separation of domain I and II occurred before the global unfolding of the protein. The data support the idea that HSA loses its structure incrementally during its unfolding.     

Impact of domain interchange on conformational stability and equilibrium folding of chimeric class micro glutathione transferases

Rat micro class glutathione transferases M1-1 and M2-2 are homodimers that share a 78% sequence identity but display differences in stability. M1-1 is more stable at the secondary and tertiary structural levels, whereas its quaternary structure is less stable. Each subunit in these proteins consists of two structurally distinct domains with intersubunit contacts occurring between domain 1 of one subunit and domain 2 of the other subunit. The chimeric subunit variants M(12), which has domain 1 of M1 and domain 2 of M2, and its complement M(21), were used to investigate the conformational stability of the chimeric homodimers M(12)-(12) and M(21)-(21) to determine the contribution of each domain toward stability. Exchanging entire domains between class micro GSTs is accommodated by the GST fold. Urea-induced equilibrium unfolding data indicate that whereas the class micro equilibrium unfolding mechanism (i.e., N(2) <--> 2I <--> 2U) is not altered, domain exchanges impact significantly on the conformational stability of the native dimers and monomeric folding intermediates. Data for the wild-type and chimeric proteins indicate that the order of stability for the native dimer (N(2)) is M2-2 > M(12)-(12) M1-1 approximately M(21)-(21), and that the order of stability of the monomeric intermediate (I) is M1 > M2 approximately M(12) > M(21). Interactions involving Arg 77, which is topologically conserved in GSTs, appear to play an important role in the stability of both the native dimeric and folding monomeric structures.     

Optical spectroscopic characterization of single tryptophan mutants of chicken skeletal troponin C: evidence for interdomain interaction.

The effects of metal ion binding on the optical spectroscopic properties and temperature stability of two single tryptophan mutants of chicken skeletal TnC, F78W and F154W, have been examined. The absence of tyrosine and other tryptophan residues allowed the unambiguous assignment of the spectral signal from the introduced Trp residue. Changes in the molar ellipticity values in the far-UV CD spectra of the mutant proteins on metal ion binding were similar to those of wild-type TnC suggesting that the introduction of the Trp residue had no effect on the total secondary structure content. The fluorescence and near-UV absorbance data reveal that, in the apo state, Trp-78 is buried while Trp-154 is exposed to solvent. Additionally, the highly resolved (1)L(b) band of Trp-78 seen in the near-UV absorbance and CD spectra of the apo state of F78W suggest that this residue is likely in a rigid molecular environment. In the calcium-saturated state, Trp-154 becomes buried while the solvent accessibility of Trp-78 increases. The fluorescence emission and near-UV CD of Trp-78 in the N-terminal domain were sensitive to calcium binding at the C-terminal domain sites. Measurements of the temperature stability reveal that events occurring in the N-terminal domain affect the stability of the C-terminal domain and vice versa. This, coupled with the titration data, strongly suggests that there are interactions between the N- and C-terminal domains of TnC.     

Asymmetric effect of domain interactions on the kinetics of folding in yeast phosphoglycerate kinase

The aim of this work is to shed more light on the effect of domain-domain interactions on the kinetics and the pathway of protein folding. A model protein system consisting of several single-tryptophan variants of the two-domain yeast phosphoglycerate kinase (PGK) and its individual domains was studied. Refolding was initiated from the guanidine-unfolded state by stopped-flow or manual mixing and monitored by tryptophan fluorescence from 1 msec to 1000 sec. Denaturant titrations of both individual domains showed apparent two-state unfolding transitions. Refolding kinetics of the individual domains from different denaturant concentrations, however, revealed the presence of intermediate structures during titration for both domains. Refolding of the same domains within the complete protein showed that domain-domain interactions direct the folding of both domains, but in an asymmetric way. Folding of the N domain was already altered within 1 msec, while detectable changes in the folding of the C domain occurred only 60-100 msec after initiating refolding. All mutants showed a hyperfluorescent kinetic intermediate. Both the disappearance of this intermediate and the completion of the folding were significantly faster in the individual N domain than in the complete protein. On the contrary, folding of the individual C domain was slower than in the complete protein. The presence of the C domain directs the refolding of the N domain along a completely different pathway than that of the individual N domain, while folding of the individual C domain follows the same path as within the complete protein.     

Cadherin conformations associated with dimerization and adhesion

To investigate conformations of C-cadherin associated with functional activity and physiological regulation, we generated monoclonal antibodies (mAbs) that bind differentially to monomeric or dimeric forms. These mAbs recognize conformational epitopes at multiple sites along the C-cadherin ectodomain aside from the well known Trp-2-mediated dimer interface in the N-terminal EC1 domain. Group 1 mAbs, which bind monomer better than dimer and the Trp-2-mutated protein (W2A) better than wild type, recognize epitopes in EC4 or EC5. Dimerization of the W2A mutant protein via a C-terminal immunoglobulin Fc domain restored the dimeric mAb-binding properties to EC4-5 and partial homophilic binding activity but did not restore full cell adhesion activity. Group 2 and Group 3 mAbs, which bind dimer better than monomer and wild type better than W2A, recognize epitopes in EC1 and the interface between EC1 and EC2, respectively. None of the mAbs could distinguish between different physiological states of C-cadherin at the cell surface of either Xenopus embryonic cells or Colo 205 cultured cells, demonstrating that changes in dimerization do not underlie regulation of adhesion activity. On the cell surface the EC3-EC5 domains are much less accessible to mAb binding than EC1-EC2, suggesting that they are masked by the state of cadherin organization or by other molecules. Thus, the EC2-EC5 domains either reflect, or are involved in, cadherin dimerization and organization at the cell surface.     

Urea induced unfolding of F isomer of human serum albumin: a case study using multiple probes

The human serum albumin is known to undergo N <==> F (neutral to fast moving) isomerization between pH 7 and 3.5. The N < ==> F isomerization involves unfolding and separation of domain III from rest of the molecule. The urea denaturation of N isomer of HSA shows two step three state transition with accumulation of an intermediate state around 4.8-5.2 M urea concentration. While urea induced unfolding transition of F isomer of HSA does not show the intermediate state observed during unfolding of N isomer. Therefore, it provides direct evidence that the formation of intermediate in the unfolding transition of HSA involves unfolding of domain III. Although urea induced unfolding of F isomer of HSA appears to be an one step process, but no coincidence between the equilibrium transitions monitored by tryptophanyl fluorescence, tyrosyl fluorescence, far-UV CD and near-UV CD spectroscopic techniques provides decisive evidence that unfolding of F isomer of HSA is not a two state process. An intermediate state that retained significant amount of secondary structure but no tertiary structure has been identified (around 4.4 M urea) in the unfolding pathway of F isomer. The emission of Trp-214 (located in domain II) and its mode of quenching by acrylamide and binding of chloroform indicate that unfolding of F isomer start from domain II (from 0.4 M urea). But at higher urea concentration (above 1.6 M) both the domain unfold simultaneously and the protein acquire random coil structure around 8.0 M urea. Further much higher KSV of NATA (17.2) than completely denatured F isomer (5.45) of HSA (8.0 M urea) suggests the existence of residual tertiary contacts within local regions in random coil conformation (probably around lone Trp-214).