Detection of a pH-dependent conformational change in azurin by time-resolved phosphorescence.

Azurin, a blue copper protein from the bacterial species Pseudomonas aeruginosa, contains a single tryptophan residue. Previous fluorescence measurements indicate that this residue is highly constrained and unusually inaccessible to water. In the apoprotein this residue also possesses a long-lived room-temperature phosphorescence (RTP), the nonexponential decay of which can be resolved into two major components associated with lifetimes of 417 and 592 ms, which likely originate from at least two conformations of the protein. The relative weights of these two decay components change with pH in good correlation with a change in protonation of His-35, which has been studied in Cu(II) azurin. Interestingly, the structural changes characterized in earlier work have little effect on the fluorescence decay and appear to occur away from the tryptophan residue. However, in the present work, the two RTP lifetimes suggest conformations with different structural rigidities in the vicinity of the tryptophan residue. The active conformation that predominates below a pH of 5.6 has the shorter lifetime and is less rigid. Phosphorescence decays of several metal derivatives of azurin were also measured and revealed strong similarities to that of apoazurin, indicating that the structural constraints upon the metal-binding site are imposed predominately by the protein.     

Characterization of slow conformational dynamics in solids: dipolar CODEX

A solid state NMR experiment is introduced for probing relatively slow conformational exchange, based on dephasing and refocusing dipolar couplings. The method is closely related to the previously described Centerband-Only Detection of Exchange or CODEX experiment. The use of dipolar couplings for this application is advantageous because their values are known a priori from molecular structures, and their orientations and reorientations relate in a simple way to molecular geometry and motion. Furthermore the use of dipolar couplings in conjunction with selective isotopic enrichment schemes is consistent with selection for unique sites in complex biopolymers. We used this experiment to probe the correlation time for the motion of ¹³C, ¹⁵N enriched urea molecules within their crystalline lattice.     

Backbone dynamics of oxidized and reduced D. vulgaris flavodoxin in solution

Recombinant Desulfovibrio vulgaris flavodoxin was produced inEscherichia coli. A complete backbone NMR assignment for the two-electronreduced protein revealed significant changes of chemical shift valuescompared to the oxidized protein, in particular for the flavinemononucleotide (FMN)-binding site. A comparison of homo- and heteronuclearNOESY spectra for the two redox states led to the assumption that reductionis not accompanied by significant changes of the global fold of the protein.The backbone dynamics of both the oxidized and reduced forms of D. vulgarisflavodoxin were investigated using two-dimensional¹⁵N-¹H correlation NMR spectroscopy.T₁, T₂ and NOE data are obtained for 95%of the backbone amide groups in both redox states. These values wereanalysed in terms of the model-free approach introduced by Lipari andSzabo [(1982) J. Am. Chem. Soc., 104, 4546-;4559, 4559-;4570]. Acomparison of the two redox states indicates that in the reduced speciessignificantly more flexibility occurs in the two loop regions enclosing FMN.Also, a higher amplitude of local motion could be found for the N(3)H groupof FMN bound to the reduced protein compared to the oxidized state.     

NMR detection of slow conformational dynamics in an endonuclease toxin

The cytotoxic activity of the secreted bacterial toxin colicin E9 is due to a non-specific DNase housed in the C-terminus of the protein. Double-resonance and triple-resonance NMR studies of the 134-amino acid¹⁵ N- and ¹³C/¹⁵N-labelled DNase domain are presented. Extensive conformational heterogeneity was evident from the presence of far more resonances than expected based on the amino acid sequence of the DNase, and from the appearance of chemical exchange cross-peaks in TOCSY and NOESY spectra. EXSY spectra were recorded to confirm that slow chemical exchange was occurring. Unambiguous sequence-specific resonance assignments are presented for one region of the protein, Pro⁶⁵-Asn⁷², which exists in two slowly exchanging conformers based on the identification of chemical exchange cross-peaks in 3D ¹H-¹H-¹⁵N EXSY-HSQC, NOESY-HSQC and TOCSY-HSQC spectra, together with C and C chemical shifts measured in triple-resonance spectra and sequential NH NOEs. The rates of conformational exchange for backbone amide resonances in this stretch of amino acids, and for the indole NH of either Trp²² or Trp⁵⁸, were determined from the intensity variation of the appropriate diagonal and chemical exchange cross-peaks recorded in 3D¹ H-¹H-¹⁵N NOESY-HSQC spectra. The data fitted a model in which this region of the DNase has two conformers, N_A and N_B, which interchange at 15 °C with a forward rate constant of 1.61 ± 0.5 s^-1 and a backward rate constant of 1.05 ± 0.5 s^-1. Demonstration of this conformational equilibrium has led to a reappraisal of a previously proposed kinetic scheme describing the interaction of E9 DNase with immunity proteins [Wallis et al. (1995) Biochemistry, 34, 13743–13750 and 13751–13759]. The revised scheme is consistent with the specific inhibitor protein for the E9 DNase, Im9, associating with both the N_A and N_B conformers of the DNase and with binding only to the N_B conformer detected because the rate of dissociation of the complex of Im9 and the N_A conformer, N_AI, is extremely rapid. In this model stoichiometric amounts of Im9 convert, the E9 DNase is converted wholly into the N_BI form. The possibility that cis–trans isomerisation of peptide bonds preceding proline residues is the cause of the conformational heterogeneity is discussed. E9 DNase contains 10 prolines, with two bracketing the stretch of amino acids that have allowed the N_A N_B interconversion to be identified, Pro⁶⁵ and Pro⁷³. The model assumes that one or both of these can exist in either the cis or trans form with strong Im9 binding possible to only one form.     

Backbone dynamics of green fluorescent protein and the effect of histidine 148 substitution

Green fluorescent protein (GFP) and its mutants have become valuable tools in molecular biology. GFP has been regarded as a very stable and rigid protein with the beta-barrel shielding the chromophore from the solvent. Here, we report the 15N nuclear magnetic resonance (NMR) studies on the green fluorescent protein (GFPuv) and its mutant His148Gly. 15N NMR relaxation studies of GFPuv show that most of the beta-barrel of GFP is rigid on the picosecond to nanosecond time scale. For several regions, including the first alpha-helix and beta-sheets 3, 7, 8, and 10, increased hydrogen-deuterium exchange rates suggest a substantial conformational flexibility on the microsecond to millisecond time scales. Mutation of residue 148 located in beta-sheet 7 is known to have a strong impact on the fluorescence properties of GFPs. UV absorption and fluorescence spectra in combination with 1H-15N NMR spectra indicate that the His148Gly mutation not only reduces the absorption of the anionic chromophore state but also affects the conformational stability, leading to the appearance of doubled backbone amide resonances for a number of residues. This suggests the presence of two conformations in slow exchange on the NMR time scale in this mutant.     

Time-resolved fluorescence study of azurin variants: conformational heterogeneity and tryptophan mobility.

Time-resolved fluorescence and time resolved fluorescence anisotropy studies have been performed on wild-type azurin from Pseudomonas aeruginosa and two variants to study the mobility of Trp48. The two azurin variants in which the microenvironment of Trp48 was changed comprised the single mutations Ile7Ser and Phe110Ser. The experiments were performed on the holo-Cu(I), holo-Cu(II), and apo- forms at various pH values, viscosities, and temperatures; two distinct parts of the emission spectrum were selected for detection. Two prominent subnanosecond lifetimes in the fluorescence decays of the Cu(II) proteins could be observed. The decay of apo-azurin also consists of more than one component. The occurrence of more than one component in the fluorescence decays is explained by conformational heterogeneity. The anisotropy decay results appeared to be different for wild-type and mutated azurins. Phe110Ser and Ile7Ser azurin show more mobility of the Trp48 residue, as reflected in the order parameter.     

Molecular dynamics simulation in vacuo and in solution of cyclolinopeptide A: a conformational study.

The conformation of cyclolinopeptide A [c-(Pro-Pro-Phe-Phe-Leu-Ile-Ile-Leu-Val)], a naturally occurring peptide with remarkable cytoprotective activity, has been investigated by means of molecular dynamics simulations in various molecular environments. Structural and dynamical properties have been analyzed and compared with those experimentally determined. A detailed analysis of hydrogen bonds is reported.     

Backbone flexibility, conformational change, and catalysis in a phosphohexomutase from Pseudomonas aeruginosa

The enzyme phosphomannomutase/phosphoglucomutase (PMM/PGM) from the bacterium Pseudomonas aeruginosa is involved in the biosynthesis of several complex carbohydrates, including alginate, lipopolysaccharide, and rhamnolipid. Previous structural studies of this protein have shown that binding of substrates produces a rotation of the C-terminal domain, changing the active site from an open cleft in the apoenzyme into a deep, solvent inaccessible pocket where phosphoryl transfer takes place. We report herein site-directed mutagenesis, kinetic, and structural studies in examining the role of residues in the hinge between domains 3 and 4, as well as residues that participate in enzyme-substrate contacts and help form the multidomain "lid" of the active site. We find that the backbone flexibility of residues in the hinge region (e.g., mutation of proline to glycine/alanine) affects the efficiency of the reaction, decreasing k cat by approximately 10-fold and increasing K m by approximately 2-fold. Moreover, thermodynamic analyses show that these changes are due primarily to entropic effects, consistent with an increase in the flexibility of the polypeptide backbone leading to a decreased probability of forming a catalytically productive active site. These results for the hinge residues contrast with those for mutants in the active site of the enzyme, which have profound effects on enzyme kinetics (10 (2)-10 (3)-fold decrease in k cat/ K m) and also show substantial differences in their thermodynamic parameters relative to those of the wild-type (WT) enzyme. These studies support the concept that polypeptide flexibility in protein hinges may evolve to optimize and tune reaction rates.     

Gamma-secretase activity is associated with a conformational change of nicastrin

Gamma-secretase is a high molecular weight multicomponent protein complex with an unusual intramembrane-cleaving aspartyl protease activity. Gamma-secretase is intimately associated with Alzheimer disease because it catalyzes the proteolytic cleavage, which leads to the liberation of amyloid beta-peptide. At least presenilin (PS), Nicastrin (Nct), APH-1, and PEN-2 are constituents of the gamma-secretase complex, with PS apparently providing the active site of gamma-secretase. Expression of gamma-secretase complex components is tightly regulated, however little is known about the assembly of the complex. Here we demonstrate that Nct undergoes a major conformational change during the assembly of the gamma-secretase complex. The conformational change is directly associated with gamma-secretase function and involves the entire Nct ectodomain. Loss of function mutations generated by deletions failed to undergo the conformational change. Furthermore, the conformational alteration did not occur in the absence of PS. Our data thus suggest that gamma-secretase function critically depends on the structural "activation" of Nct.     

Mutagenic studies on histidine 98 of methylglyoxal synthase: effects on mechanism and conformational change

Two detailed mechanisms [Marks et al. (2001) Biochemistry 40, 6805] have been proposed to explain the activity of methylglyoxal synthase (MGS), a homohexameric allosterically regulated enzyme that catalyzes the elimination of phosphate from DHAP to form enol pyruvaldehyde. This enol then tautomerizes to methylglyoxal in solution. In one of these mechanisms His 98 plays an obligate role in the transfer of a proton from the O(3) oxygen of DHAP to the O2 oxygen. To test this hypothesized mechanism, the variants H98N and H98Q were expressed and purified. Relative to the wild-type enzyme, the H98N variant shows a 50-fold decrease in k(cat) with all other kinetic parameters (i.e., K(m), K(PGA), etc.) being nearly the same. By contrast, the apparent catalytic rate for the H98Q variant is 250-fold lower than that of the wild-type enzyme. Inorganic phosphate acts as a competitive inhibitor (with a K(i) of 15 microM) rather than as an allosteric-type inhibitor as it does in the wild-type enzyme, and the competitive inhibitor phosphoglyolate (PGA) acts as an activator of this variant. These facts are explained by a shift in the conformational equilibrium toward an "inactive" state. When activation by PGA is accounted for, the catalytic rate for the "active" state of H98Q is estimated to be only 6-fold less than that of the wild-type enzyme, and thus His 98 is not essential for catalysis. Primary deuterium isotope effect data were measured for the wild-type enzyme and the two variants. At pH 7.0, the (D)V isotope effect (1.5) and the absence of a (D)(V/K) isotope effect for the wild-type enzyme suggest that the rate for the isotopically sensitive step is partially rate limiting but greater than the rate of substrate dissociation. Both the (D)V (2.0) and (D)(V/K) (3.4) isotope effects were more pronounced in the H98N variant, while the H98Q variant displayed an unusual inverse (D)V (0.8) isotope effect and a normal (D)(V/K) (1.5) isotope effect. The X-ray crystal structures of PGA bound to the H98Q and H98N variants were both determined to a resolution of 2.2 A. These mutations had little effect on the overall structure. However, the pattern of hydrogen bonding in the active site suggests an explanation as to how in the wild-type and H98N mutated enzymes the "inactive to active" equilibrium lies toward the active state, while with the H98Q mutated enzyme the equilibrium lies toward the inactive state. Thus, the role of His 98 appears to be more as a regulator of the enzyme's conformation rather than as a critical contributor to the catalytic mechanism.     

Structural dynamics associated with intermediate formation in an archetypal conformational disease

In conformational diseases, native protein conformers convert to pathological intermediates that polymerize. Structural characterization of these key intermediates is challenging. They are unstable and minimally populated in dynamic equilibria that may be perturbed by many analytical techniques. We have characterized a forme fruste deficiency variant of α(1)-antitrypsin (Lys154Asn) that forms polymers recapitulating the conformer-specific neo-epitope observed in polymers that form in?vivo. Lys154Asn α(1)-antitrypsin populates an intermediate ensemble along the polymerization pathway at physiological temperatures. Nuclear magnetic resonance spectroscopy was used to report the structural and dynamic changes associated with this. Our data highlight an interaction network likely to regulate conformational change and do not support the recent contention that the disease-relevant intermediate is substantially unfolded. Conformational disease intermediates may best be defined using powerful but minimally perturbing techniques, mild disease mutants, and physiological conditions.     

pH dependence of the reduction-oxidation reaction of azurin with cytochrome c-551: role of histidine-35 of azurin in electron transfer

A fluorescence quenching experiment confirms that in the redox reaction between cytochrome c-551 and azurin, protein complexing is negligible. Azurin-pH indicator T-jump experiments show that Pseudomonas aeruginosa (Ps.) azurin exhibits a slow time constant, tau, in its return to pH equilibrium but Alcaligenes faecalis (Alc.) azurin does not. The decrease of l/tau with increasing pH shows that the rate-determining process is a slow transformation of the imidazolium form of histidine-35 from a conformation where it cannot ionize to one in which it can. The fast relaxation time constant of the redox reaction varies little with pH, but the slow time constant increased by a factor of approximately 2.5 increasing pH between pH 5 and pH 8. The corresponding amplitudes, especially the slow one, vary with pH. On the basis of all the present evidence it is concluded that, while some differences of redox reactivity do occur on protonation, these differences are not major. In general, the two proteins cyt c-551 and azurin react with each other with rates only weakly dependent upon pH. A classical pH titration was carried out on the reduced and oxidized form of Ps. and Alc. azurin with the result that two protons were released between pH 6 and pH 8, in the former from His-35 and -83 and in the latter from His-83 and Ala-1.     

Involvement of the histidine residues in the pH-induced conformational change of histone H5

Comparative studies on the conformational stability of histones H1 and H5 have been carried out by monitoring the pH-induced conformational transitions of the proteins by CD and 1H NMR spectroscopies. The transition point of H1 agrees with the pKa of the carboxyl groups of the acidic residues. In contrast, the transition of H5 is associated with the ionization of the histidine residues which exist exclusively in H5, as well as the deionization of the acidic residues. These observations, combined with the result of the deuterium exchange rates of the histidine C-2 protons, led us to conclude that His-25 and His-62, which are buried in the globular domain, play an important role in the conformational stability of histone H5.     

Light-induced global conformational change of photoactive yellow protein in solution

The light-induced global conformational change of photoactive yellow protein was directly observed by small-angle X-ray scattering (SAXS). The N-terminal 6, 15, or 23 amino acid residues were enzymatically truncated (T6, T15, or T23, respectively), and their near-UV intermediates were accumulated under continuous illumination for SAXS measurements. The Kratky plot demonstrated that illumination induced partial loss of globularity. The change in globularity was marked in T6 but very small in T15 and T23, suggesting that structural change in positions 7-15 mainly reduces the globularity. The radius of gyration (R(g)) estimated by Guinier plot was increased by 1.1 A for T6 and 0.7 A for T15 and T23 upon illumination. As T23 lacks most of the N-terminal loop, structural change in the main part composed of the PAS core, helical connector, and beta-scaffold caused an increase of R(g) by 0.7 A. The structural change of positions 7-15 caused an additional increase by 0.4 A. The decrease of R(g) upon truncation of positions 7-15 for dark state was 0.3 A, while that for the intermediate was 0.7 A, suggesting that this region moves outward on formation of the intermediate. These results indicate that a light-induced structural change of PYP takes place in the main part and N-terminal 15 amino acid residues. The former induces only dimensional increase, but the latter results in additional change in shape.     

Nanosecond pulse fluorometry of conformational change in phenylalanine hydroxylase associated with activation

Conformational change in rat liver phenylalanine hydroxylase associated with activation by phenylalanine or N-(1-anilinonaphth-4-yl)maleimide was investigated by measuring fluorescence spectra and fluorescence lifetimes of tryptophanyl residues as well as the probe fluorophore conjugated with SH groups of the hydroxylase. The fluorescence spectrum of tryptophan exhibited its maximum at 342 nm. It shifted by 8 nm toward longer wavelength accompanied by an increase in its intensity, by preincubation with 1 mM phenylalanine. The fluorescence intensity of tryptophan increased by 36% upon the activation. On the other hand, the binding of (6R)-L-erythro-tetrahydrobiopterin, a natural cofactor of the enzyme, induced a decrease in the fluorescence intensity by 79% without a shift of the maximum wavelength. The fluorescence lifetime of tryptophan of phenylalanine hydroxylase exhibited two components with lifetimes of 1.7 and 4.1 ns. The values of the lifetimes changed to 1.4 and 5.6 ns, respectively, upon the activation. It is considered that the change in the longer lifetime is correlated with the shift of the emission peak upon the activation. The values of both the lifetimes decreased to 0.64 and 3.6 ns upon the binding of (6R)-L-erythro-tetrahydrobiopterin, which is coincident with the decrease in the fluorescence intensity. Conjugation of N-(1-anilinonaphth-4-yl)maleimide with SH of phenylalanine hydroxylase brought about a decrease in both the fluorescence intensity and the value of the shorter lifetime of the tryptophanyl residues, while the longer lifetime remained unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chaperone-mediated reduction of RepA dimerization is associated with RepA conformational change

RepA, the initiator protein of plasmid P1, binds to multiple sites (iterons) in the origin. The binding normally requires participation of chaperones, DnaJ, DnaK and GrpE. When purified, RepA appears dimeric and is inactive in iteron binding. On reaction with chaperones, a species active in iteron binding is formed and found to be monomeric. To test whether the chaperones can reduce dimerization, RepA was used to replace the dimerization domain of the λ repressor. The hybrid protein repressed the λ operator efficiently, indicating that RepA can dimerize in vivo . A further increase in repressor activity was seen in dnaJ mutant cells. These results are consistent with a chaperone-mediated reduction of RepA dimerization. We also found that RepA mutants defective in dimerization still depend on DnaJ for iteron binding. Conversely, RepA mutants that no longer require chaperones for iteron binding remain dimerization proficient. These results indicate that the chaperone dependence of RepA activity is not solely owing to RepA dimerization. Our results are most simply explained by a chaperone-mediated conformational change in RepA protomer that activates iteron binding. This conformational change also results in reduced RepA dimerization.     

HLA-B27 subtypes differentially associated with disease exhibit conformational differences in solution

Human leukocyte antigen (HLA) class I molecules consist of a heavy chain, β₂-microglobulin, and a peptide that are noncovalently bound. Certain HLA-B27 subtypes are associated with ankylosing spondylitis (such as HLA-B*2705), whereas others (such as HLA-B*2709) are not. Both differ in only one residue (Asp116 and His116, respectively) in the F pocket that accommodates the peptide C-terminus. An isotope-edited IR spectroscopy study of these HLA-B27 subtypes complexed with the self-peptide RRKWRRWHL was carried out, revealing that the heavy chain is more flexible in the HLA-B*2705 than in the HLA-B*2709 subtype. In agreement with these experimental data, molecular dynamics simulations showed an increased flexibility of the HLA-B*2705 binding groove in comparison with that of the HLA-B*2709 subtype. This difference correlates with an opening of the HLA-B*2705 binding groove, accompanied by a partial detachment of the C-terminal peptide anchor. These combined results demonstrate how the deeply embedded polymorphic heavy-chain residue 116 influences the flexibility of the peptide binding groove in a subtype-dependent manner, a feature that could also influence the recognition of the HLA-B27 complexes by effector cells.