Conformational changes of disulfide isomerase C induced by guanidine hydrochloride

Unfolding--refolding of Escherichia coli disulfide isomerase C (DsbC) induced by GdnHCl was studied by intrinsic fluorescence. Interpretation of experimental fluorescence data was done together with the analysis of protein 3D structure. It is shown that although Cys 141 is the next neighbour of a single tryptophan residue Trp 140, sulfur atoms of the disulfide bond Cys 141--Cys 163 are far apart from the indole ring and cannot quench its fluorescence, while the potential quenchers are Met 136 and His 170. It has been revealed that, though each subunit of DsbC contains eight tyrosine residues, only three tyrosine residues (Tyr 171, Tyr 38 and Tyr 52) contribute to the bulk fluorescence of the molecule. The character of intrinsic fluorescence intensity changes induced by GdnHCl (equilibrium and kinetic data), the character of parametric dependencies between fluorescence intensity recorded at 320 and 365 nm, and the existence of an isosbestic point of protein fluorescence spectra in solutions with different GdnHCl concentrations, allowed suggesting a one-step character of DsbC denaturation. The reversibility of this process is also shown.     

Unfolding and refolding of the glutamine-binding protein from Escherichia coli and its complex with glutamine induced by guanidine hydrochloride

The aim of this work was to study the conformational changes of the Escherichia coli glutamine-binding protein (GlnBP) induced by GdnHCl and the effect of the binding of glutamine (Gln) on these processes. To this end, GdnHCl-induced unfolding of GlnBP alone and its GlnBP-Gln complex was studied by protein intrinsic fluorescence, ANS emission fluorescence, and far- and near-UV circular dichroism spectroscopy. The obtained spectroscopic data were interpreted taking into the account the peculiarities of protein three-dimensional structure. In particular, the fact that formation of a complex of GlnBP and Gln, which essentially changes the global structure of protein, affects only insignificantly the microenvironments of tryptophan residues elucidates the similarity of the emission spectra of GlnBP and the GlnBP-Gln complex, and the existence of quenching groups near tyrosine residues and an effective nonradiative Tyr --> Trp and/or Tyr --> Tyr --> Trp energy transfer provide an explanation for the negligibly small contribution of tyrosine to the bulk fluorescence of the native protein and for its increase in protein unfolding. The use of the parametric presentation of fluorescence data showed that both GlnBP unfolding and GlnBP-Gln unfolding are three-step processes (N --> I(1) --> I(2) --> U), though in the case of the GlnBP-Gln complex these stages essentially overlap. Despite the complex character, GlnBP unfolding is completely reversible. The dramatic shift of the N --> I(1) process to higher GdnHCl concentrations for the GlnBP-Gln complex in comparison with GlnBP was shown.     

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.     

The structure and stability of the glutamine-binding protein from Escherichia coli and its complex with glutamine

A study was made of the conformational changes in the Escherichia coli glutamine-binding potein (GlnBP) induced by GdnHCl, and of the effect of glutamine (Gln) binding on these processes. Intrinsic fluorescence, ANS emission fluorescence, and far- and near-UV circular dichroism spectroscopy were used. The obtained experimental data were interpreted, taking into the account results of the analysis of tryptophan and tyrosine residues microenvironments. This enabled us to explain the negligible contribution of Tyr residues to the bulk fluorescence of the native protein, the similarity of fluorescence characteristics of GlnBP and GlnBP/Gln, and an uncommon effect of the excess of fluorescence intensity at 365 nm (Trp emission) upon excitation at 297 nm compared to the excitation at 280 nm. The latter effect is explained by the spectral dependence of Trp 32 and Trp 220 contributions to protein absorption. The dependence of Trp fluorescence of protein on the excitation wavelength must be taken into account for the evaluation of Tyr residues contribution to the bulk fluorescence of protein, and in principle, it may also be used for the development of an approach to decomposition of multi-component protein fluorescence spectrum. The parametric presentation of fluorescence data showed that both GlnBP unfolding and GlnBP/Gln unfolding are three-step processes (N-->I1-->I2-->U), though in the case of the GlnBP/Gln complex these stages essentially overlap. Despite its complex character, GlnBP unfolding is completely reversible. In comparison with GlnBP, in the case of GlnBP/Gln the dramatic shift of N-->I1 process to higher GdHCl concentrations is shown.     

Disulfide-dependent folding and export of Escherichia coli DsbC

DsbC, a member of the Dsb family in the periplasm of Gram-negative bacteria, is not only a disulfide isomerase but also a chaperone. Five DsbC mutants with Cys in the active site sequence of Cys(98)-Gly-Tyr-Cys(101) and the nonactive site disulfide Cys(141)-Cys(163) replaced by Ser have been studied. The results show that the active site Cys residues are necessary for enzyme activities but not required for chaperone activity, while the lack of the nonactive site disulfide results in a decreased chaperone activity in assisting the reactivation of denatured d-glyceraldehyde-3-phosphate dehydrogenase but has no effect on enzyme activities. Wild-type DsbC was overexpressed and correctly processed as a soluble periplasmic protein. Mutation in one of these Cys residues results in aggregation or extracellular/membrane locations, but does not affect the proper processing. DsbC mutated in either Cys residue of nonactive site disulfide shows higher sensitivity to unfolding by guanidine hydrochloride and slower refolding compared with wild-type DsbC and the active site Cys mutants. The above results provide experimental evidence for structural role of the nonactive site disulfide in folding and biological activities of DsbC.     

Functional conformation changes in the TF(1)-ATPase beta subunit probed by 12 tyrosine residues.

The effect of nucleotide binding on the structure of the F(1)-ATPase beta subunit from thermophilic bacillus PS-3 (TF(1)beta) was investigated by monitoring the NMR signals of the 12 tyrosine residues. The 3,5-proton resonances of 12 tyrosine residues could be observed for the specifically deuterated beta subunit. The assignment of 3,5-proton resonances of all of the tyrosine residues was accomplished using 14 mutant proteins, in each of which one or two tyrosine residues were replaced by phenylalanine. Binding of Mg. ATP induced an upfield shift of Tyr(341) resonance, suggesting that their aromatic rings are stacked to each other. Besides Tyr(341), the signal shift observed on Mg.ATP binding was restricted to the resonances of Tyr(148), Tyr(199), Tyr(238), and Tyr(307), suggesting that Mg.ATP induces a conformational change in the hinge region. This can be correlated to the change from the open to closed conformations as implicated in the crystal structure. Mg.ADP induced a similar but distinctly different conformational change. Therefore, the intrinsic conformational change in the beta subunit induced by the nucleotide binding is proposed to be one of the essential driving forces for the F(1) rotation. Reconstitution experiments showed that Tyr(277), one of the four conserved tyrosines, is essential to the formation of the alpha(3)beta(3)gamma complex.     

Two conserved tryptophan residues are responsible for intrinsic fluorescence enhancement in Rubisco activase upon ATP binding

Two species-invariant tryptophan residues at positions 109 and 250 of tobacco Rubisco activase were identified by site-directed mutagenesis as being responsible for the increase in intrinsic fluorescence upon addition of ATP, which has been previously attributed to increased self-association. Substitution of W109, which is immediately prior to a ‘P-loop’ sequence in the ATP catalytic motif, with aromatic residues (Tyr or Phe), Cys or Lys eliminated both ATP hydrolysis and the intrinsic fluorescence enhancement. Although the W109 mutants bound ATP, ATP did not provide a partial protection against proteolysis by trypsin that was observed with the recombinant wild-type enzyme. In contrast, substitution of W250 with Tyr or Phe abolished about half (44%) of the increase in intrinsic fluorescence with ATP, but had little effect on ATP hydrolysis, ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) activation or proteolytic protection with ATP. The substitution of the other tryptophan residues, W16 and W305, with phenylalanine did not significantly alter the change in intrinsic fluorescence upon addition of ATP. Therefore, W109 and W250 are the residues reporting the conformational change that increases the intrinsic fluorescence.     

Quenching of the fluorescence of Tyr and Trp residues of firefly luciferase from <Emphasis Type="Italic">Luciola mingrelica</Emphasis> by the substrates

Luciferase of the firefly Luciola mingrelica is characterized by fluorescence of not only the unique Trp residue (lambda(em) = 340 nm), but also that of Tyr residues (lambda(em) = 308 nm). Quenching of the intrinsic fluorescence of the luciferase by its substrates luciferin and ATP (AMP) has been studied. Luciferin (LH2) quenches Trp fluorescence more efficiently than the fluorescence of Tyr residues. Two centers of quenching of Tyr fluorescence by ATP have been found corresponding apparently to the allosteric and active sites of the luciferase with K(s(ATP)) = 20 and 110 microM, respectively. The influence of one substrate on the affinity of luciferase to the second was investigated using fluorescence. ATP (AMP) binding to the allosteric sites of the luciferase significantly affects the affinity of luciferase to LH2. Formation of the complex between the luciferase and LH2 affects the affinity of both allosteric and active sites of the luciferase to ATP (AMP). The observed effects are probably connected with conformational changes in the luciferase molecule upon its interaction with the substrates.     

Tyr740 and Tyr751 residues of platelet-derived growth factor beta receptor are responsible for the redox regulation of phosphatase and tensin homolog in the cells stimulated with platelet-derived growth factor

Exposure of cells to hydrogen peroxide or platelet-derived growth factor (PDGF) induced Akt phosphorylation and oxidation of phosphatase and tensin homolog (PTEN). The Cys124 and Cys71 residues of PTEN were critical for the formation of a disulfide bond and the intermediate glutathionylation in the process of reduction of the disulfide bond. To determine which specific tyrosine residues of the PDGF beta receptor (PDGFβR) is involved in PDGF-induced PTEN oxidation and Akt phosphorylation, we investigated a kinase activity-deficient mutant and PDGFβR mutants where the tyrosine residues in the binding site for phosphoinositide 3-kinase (PI3K), GTPase-activating protein of Ras, Src homology 2 domain containing protein-tyrosine phosphatase-2, and phospholipase C-1 were replaced by Phe. Both PTEN oxidation and Akt phosphorylation did not occur in response to PDGF in the kinase-deficient mutant and in the PDGFβR mutant with a mutation in the PI3K binding site (Tyr740 and Tyr751). Thus, the kinase activity and the constituent Tyr740 and Tyr751 residues of PDGFβR in the cells stimulated with PDGF are responsible for the oxidation of PTEN and the Akt phosphorylation.     

Structure and stability of gamma-crystallins: tryptophan, tyrosine, and cysteine accessibility

The solute perturbation techniques of fluorescence of tryptophan (Trp) and dye-labeled thiol groups of cysteine as well as phosphorescence of tyrosine (Tyr) were utilized to obtain information on the relative solvent exposure and accessibility of these residues in gamma-crystallins. Both acrylamide and iodide quenchers were used to evaluate the quenching parameters in terms of accessibility and charge characteristics of the proteins. Stern-Volmer plots reveal the presence of more than one class of Trp residues in gamma-III and gamma-IV, and these residues in gamma-II are least accessible compared to the other two. Both steady-state and lifetime quenching studies of the dye-labeled fluorescence indicate that distinct differences also exist among these crystallins in cysteine (Cys) accessibilities. All three proteins, gamma-II, gamma-III, and gamma-IV, show two distinct lifetime components of the dye-labeled Cys residues. Both components of gamma-II undergo dynamic quenching, whereas only the major component of the other two crystallins is affected by the quenchers. Addition of acrylamide causes a decrease in Tyr phosphorescence of gamma-III and gamma-IV, but no change in the emission of gamma-II. The decrease is attributed to the formation of a nonemittive ground-state complex between the acrylamide and Tyr of the proteins; the association constant, Ka, calculated from the emission data, has been considered as a measure of Tyr accessibility. Ka values indicate that Tyr residues in gamma-III are most exposed and accessible compared to those in the other two proteins. Results of quenching by iodide ion reveal significant differences in the surface charge of the proteins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the molecular mechanisms by which the diterpenoid salvinorin A binds to kappa-opioid receptors

Salvinorin A is a naturally occurring hallucinogenic diterpenoid from the plant Salvia divinorumthat selectively and potently activates kappa-opioid receptors (KORs). Salvinorin A is unique in that it is the only known lipid-like molecule that selectively and potently activates a G-protein coupled receptor (GPCR), which has as its endogenous agonist a peptide; salvinorin A is also the only known non-nitrogenous opioid receptor agonist. In this paper, we identify key residues in KORs responsible for the high binding affinity and agonist efficacy of salvinorin A. Surprisingly, we discovered that salvinorin A was stabilized in the binding pocket by interactions with tyrosine residues in helix 7 (Tyr313 and Tyr320) and helix 2 (Tyr119). Intriguingly, activation of KORs by salvinorin A required interactions with the helix 7 tyrosines Tyr312, Tyr313, and Tyr320 and with Tyr139 in helix 3. In contrast, the prototypical nitrogenous KOR agonist U69593 and the endogenous peptidergic agonist dynorphin A (1-13) showed differential requirements for these three residues for binding and activation. We also employed a novel approach, whereby we examined the effects of cysteine-substitution mutagenesis on the binding of salvinorin A and an analogue with a free sulfhydryl group, 2-thiosalvinorin B. We discovered that residues predicted to be in close proximity, especially Tyr313, to the free thiol of 2-thiosalvinorin B when mutated to Cys showed enhanced affinity for 2-thiosalvinorin B. When these findings are taken together, they imply that the diterpenoid salvinorin A utilizes unique residues within a commonly shared binding pocket to selectively activate KORs.     

Effects of guanidine hydrochloride on the conformation and enzyme activity of streptomycin adenylyltransferase monitored by circular dichroism and fluorescence spectroscopy

Equilibrium denaturation of streptomycin adenylyltransferase (SMATase) has been studied by CD spectroscopy, fluorescence emission spectroscopy, and binding of the hydrophobic dye 1-anilino-8-naphthalene sulfonic acid (ANS). Far-UV CD spectra show retention of 90% native-like secondary structure at 0.5 M guanidine hydrochloride (GdnHCl). The mean residue ellipticities at 222 nm and enzyme activity plotted against GdnHCl concentration showed loss of about 50 and 75% of secondary structure and 35 and 60% of activity at 0.75 and 1.5 M GdnHCl, respectively. At 6 M GdnHCl, there was loss of secondary structure and activity leading to the formation of GdnHCl-induced unfolded state as evidenced by CD and fluorescence spectroscopy as well as by measuring enzymatic activity. The denaturant-mediated decrease in fluorescence intensity and 5 nm red shift of λ_max point to gradual unfolding of SMATase when GdnHCl is added up from 0.5 M to a maximum of 6 M. Decreasing of ANS binding and red shift (∼5 nm) were observed in this state compared to the native folded state, indicating the partial destruction of surface hydrophobic patches of the protein molecule on denaturation. Disruption of disulfide bonds in the protein resulted in sharp decrease in surface hydrophobicity of the protein, indicating that the surface hydrophobic patches are held by disulfide bonds even in the GdnHCl denatured state. Acrylamide and potassium iodide quenching of the intrinsic tryptophan fluorescence of SMATase showed that the native protein is in folded conformation with majority of the tryptophan residues exposed to the solvent, and about 20% of them are in negatively charged environment. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 11, pp. 1514–1523.     

Kinetics of actin unfolding induced by guanidine hydrochloride.

The kinetics of actin unfolding induced by guanidine hydrochloride has been studied. On the basis of obtained experimental data a new kinetic pathway of actin unfolding was proposed. We have shown that the transition from native to inactivated actin induced by guanidine hydrochloride (GdnHCl) passes through essential unfolding of the protein. This means that inactivated actin should be considered as the off-pathway species rather than an intermediate conformation between native and completely unfolded states of actin, as has been assumed earlier. The rate constants of the transitions that give rise to the inactivated actin were determined. At 1.0-2.0 M GdnHCl the value of the rate constant of the transition from native to essentially unfolded actin exceeds that of the following step of inactivated actin formation. It leads to the accumulation of essentially unfolded macromolecules early in the unfolding process, which in turn causes the minimum in the time dependencies of tryptophan fluorescence intensity, parameter A, characterizing the intrinsic fluorescence spectrum position, and tryptophan fluorescence anisotropy.     

Intrinsic fluorescence of globular actin. Features of localization of tryptophan residues

The contribution of individual Trp residues to alpha-actin fluorescence was evaluated by means of an analysis of their microenvironment, which was done on the basis of PIR-International protein sequence database information. The contribution of Trp79 and Trp86 was shown to be low due to an effective nonradiating energy transfer according to the inductive resonance mechanism between the Trp residues and the fluorescence quenching of Trp86 by S gamma of Cys10, an efficient fluorescence quencher. The intrinsic fluorescence of actin was found to be determined mainly by Trp340 and Trp356, which are internal, inaccessible to solvent, and have a high density microenvironment formed mainly by nonpolar groups of protein. It is possible that the side chain conformation of Trp340 (t-isomer; chi 1 190 degrees, chi 2 89 degrees), aromatic rings of Tyr and Phe residues, and Pro residues in the microenvironment of Trp340 and Trp356 substantially contribute to the short-wavelength fluorescence spectrum of actin.     

Chaperone activity of DsbC.

DsbC, a periplasmic disulfide isomerase of Gram-negative bacteria, displays about 30% of the activities of eukaryotic protein disulfide isomerase (PDI) as isomerase and as thiol-protein oxidoreductase. However, DsbC shows more pronounced chaperone activity than does PDI in promoting the in vitro reactivation and suppressing aggregation of denatured D-glyceraldehyde-3-phosphate dehydrogenase (GAPDH) during refolding. Carboxymethylation of DsbC at Cys98 decreases its intrinsic fluorescence, deprives of its enzyme activities, but lowers only partly its chaperone activity in assisting GAPDH reactivation. Simultaneous presence of DsbC and PDI in the refolding buffer shows an additive effect on the reactivation of GAPDH. The assisted reactivation of GAPDH and the protein disulfide oxidoreductase activity of DsbC can both be inhibited by scrambled and S-carboxymethylated RNases, but not by shorter peptides, including synthetic 10- and 14-mer peptides and S-carboxymethylated insulin A chain. In contrast, all the three peptides and the two nonnative RNases inhibit PDI-assisted GAPDH reactivation and the reductase activity of PDI. DsbC assists refolding of denatured and reduced lysozyme to a higher level than does PDI in phosphate buffer and does not show anti-chaperone activity in HEPES buffer. Like PDI, DsbC is also a disulfide isomerase with chaperone activity but may recognize different folding intermediates as does PDI.     

Stability and dynamics of the porcine odorant-binding protein

The denaturation process of porcine odorant-binding protein (pOBP) was studied by intrinsic fluorescence analysis and far- and near-UV circular dichroism measurements. Our results showed that a reversible one-step process described the denaturation by GdnHCl. The midpoint of the transition, that is, the point where the free energies of protein in the native and unfolded states are equal, corresponds to 2.3 M GdnHCl. The difference in free energy between native and unfolded states of pOBP is -5.95 kcal/mol in the absence of GdnHCl, indicating that the protein molecule is very stable to the denaturing action of GdnHCl. A 15% increase in fluorescence intensity accompanied by a 25% decrease of fluorescence decay lifetime recorded in the range of 0.0-1.4 M GdnHCl was explained by the destruction of the complex between Trp 16 and the positively charged atom NZ of Lys 120, localized over the center of the Trp 16 indole ring, with concurrent formation of complex between Trp 16 and bound water molecules also located in its close vicinity.     

Structural and functional differentiation of three groups of tyrosine residues by acetylation of N-acetylimidazole in manganese stabilizing protein

To study its contribution to the assembly of the green plant manganese stabilizing protein (MSP) into photosystem II (PSII), tyrosine residues were specifically acetylated using N-acetylimidazole (NAI). In soluble MSP, three groups of Tyr residues could be differentiated by NAI acetylation: approximately 5 (actually approximately 5.2) Tyr residues could be easily acetylated (superficial), 1-2 Tyr residues could be acetylated when the NAI concentration was sufficiently high (superficially buried), and 1-2 Tyr residues could only be acetylated in the presence of the denaturant, urea (deeply buried). Acetylation of the 5.2 Tyr residues did not affect the reconstitution or oxygen-evolving activities of the MSP, and far-UV circular dichroism (CD) analysis showed that the altered MSP retained most of its native secondary structure. These results suggested that the 5.2 Tyr residues are not absolutely essential to the function of MSP. However, further modification of the 1-2 superficially buried Tyr residues (for a total acetylation of approximately 6.4 Tyr residues) completely abrogated the MSP rebinding and oxygen evolution activities. Finally, at least one tyrosine residue was inaccessible to NAI until MSP was completely unfolded by 8 M urea. Deacetylation of MSP with 6.4 or 8 acetylated Tyr residues with hydroxylamine restored most of the rebinding and oxygen-evolving activities. A prominent red shift in fluorescence spectra of MSP (excited at 280 or 295 nm) was observed after modification of 6.4 Tyr residues, and a further shift could be found after all 8 Tyr residues were modified, indicating a great loss of native secondary structure. Far-UV CD revealed that MSP was mostly unfolded when 6.4 Tyr residues were modified and completely unfolded when all 8 Tyr residues were modified. Fluorescence and far-UV CD studies revealed that loss of MSP rebinding to PSII membranes following NAI modification correlated well with conformational changes in MSP. Together, these results indicate that different tyrosine residues have different contributions to the binding and assembly of MSP into PSII.     

Participation of tyrosine residues of myoglobin in the disproportionateness reaction of heme iron (II) and (IV)]

By means of the comparison of the constant oxidation reactions of both the myoglobin modified by N-acetylimidazole and the intact myoglobin in the presence of H2O2 or ferrylmyoglobin we characterized the role of the tyrosine residues (Tyr) of myoglobin in the synproportionation reaction between heme iron (II) of one molecule and heme iron (IV)--of another. It was demonstrated that Tyr derivatization resulted in the decrease of the velocity of redox interaction between deoxymyoglobin (II) and ferrylmyoglobin (IV) and led to the decrease of the efficiency of oxymyoglobin deoxygenation. The effects were shown to be independent on Tyr quantity in myoglobin molecule and to have the same character for both the sperm-whale myoglobin and the horse myoglobin.     

Structural alterations and inhibition of unisite and multisite ATP hydrolysis in soluble mitochondrial F1 by guanidinium chloride

The effect of guanidinium chloride (GdnHCl) on the ATPase activity and structure of soluble mitochondrial F1 was studied. At high ATP concentrations, hydrolysis is carried by the three catalytic sites of F1; this reaction was strongly inhibited by GdnHCl concentrations of <50 mM. With substoichiometric ATP concentrations, hydrolysis is catalyzed exclusively by the site with the highest affinity. Under these conditions, ATP binding and hydrolysis took place with GdnHCl concentrations of >100 mM; albeit at the latter concentration, the rate of hydrolysis of bound ATP was lower. Similar results were obtained with urea, although nearly 10-fold higher concentrations were required to inhibit multisite hydrolysis. GdnHCl inhibited multisite ATPase activity by diminishing the V(max) of the reaction without significant alterations of the Km for MgATP. GdnHCl prevented the effect of excess ATP on hydrolysis of ATP that was already bound to the high-affinity catalytic site. With and without 100 mM GdnHCl and 100 microM [3H]ATP in the medium, F1 bound 1.6 and 2 adenine nucleotides per F1, respectively. The effect of GdnHCl on some structural features of F1 was also examined. GdnHCl at concentrations that inhibit multisite ATP hydrolysis did not affect the exposure of the cysteines of F1, nor its intrinsic fluorescence. With 100 mM GdnHCl, a concentration at which unisite ATP hydrolysis was still observed, 0.7 cysteine per F1 became solvent-exposed and small changes in its intrinsic fluorescence of F1 were detected. GdnHCl concentrations on the order of 500 mM were required to induce important decreases in intrinsic fluorescence. These changes accompanied inhibition of unisite ATP hydrolysis. The overall data indicate that increasing concentrations of GdnHCl bring about distinct and sequential alterations in the function and structure of F1. With respect to the function of F1, the results show that at low GdnHCl concentrations, only the high-affinity site expresses catalytic activity, and that inhibition of multisite catalysis is due to alterations in the transmission of events between catalytic sites.     

Autophosphorylation dependent destabilization of the insulin receptor kinase domain: tryptophan-1175 reports changes in the catalytic cleft

Protein kinases are regulated by conformational or chemical changes which facilitate access of substrates to the active site and promote correct orientations of catalytically essential residues and water molecules. The switch between basal and activated states of the insulin receptor's kinase domain (IRKD) results from autophosphorylation. We investigated the effects of IRKD autophosphorylation on the conformational stability by guanidine hydrochloride (GdnHCl) dependent denaturation and by iodide quenching of intrinsic fluorescence. Tryptophan residues of the recombinant soluble IRKD (residues R953-S1355) were excited at a lambdaex of 295 nm, and emission spectra were analyzed for centroid (a characteristic of average polarity of the indole rings' environments) and integrated fluorescence intensity over the lambdaem range of 310-420 nm. Denaturation profiles of both apo- and phospho-IRKD forms are complex with at least three distinct unfolding transitions. The first and last transitions were reversible and cooperative and had midpoints at 0.4 or 0.7 M GdnHCl and 2.4 or 2.7 M GdnHCl, respectively; transitions of phospho-IRKD occurred at lower GdnHCl concentrations. Calculations of free energy of unfolding suggested a loss of approximately 2.3 kcal/mol of stabilization for the first transition and approximately 1.5 kcal/mol for the third transition. Circular dichroism showed subtle changes in secondary structure over the first transition and global unfolding over the last transition. The first transition reports changes primarily in the local environment of W1175, which is near the catalytic loop and is conserved among protein tyrosine kinases. W1175 is also the dominant fluorophore of the native emission spectrum. Iodide quenching of W1175 was virtually undetectable in the apo-IRKD but significant in the phospho-IRKD, suggesting that W1175 exposure to small solutes is strongly dependent on the conformation of the activation loop. These studies indicate that autophosphorylation, while exposing the catalytic center, also produces a conformer less stable than the apoenzyme.