Structure and dynamics of staphylococcal nuclease mutants as studied by fluorescence quenching techniques

Fluorescence techniques have been used to investigate the effect of mutations on the structure and dynamics of staphylococcal nuclease. An estimate of the accessibility to acrylamide of the enzyme's single tryptophan residue (Trp140) was obtained from the Stern-Volmer constant for fluorescence quenching. This was indicative of a partially buried tryptophan in the wild-type nuclease. Five single-site mutant nucleases (H124L, V66L, G88V, G79S and F76V) and one double mutant (V66L + G88V), with widely differing stabilities to denaturants, gave Stern-Volmer constants which were very similar to that of their parent enzyme. Studies of the temperature- and viscosity-dependence of quenching suggest that access by acrylamide to Trp140 is limited by diffusion rather than by protein structural fluctuations. Lifetime-resolved fluorescence anisotropy studies using steady-state instrumentation suggest that there is very little segmental motion of the Trp140; most of the anisotropy therefore decays due to protein rotation in the solution. Rotational correlation times for several nuclease mutants have been determined and these are very similar to that of the native nuclease. Thus it appears that these substitutions in the primary amino acid sequence, which have significant effects on the stability of the folded proteins, do not cause a significant change in the protein structure or dynamics around Trp140.     

A circular dichroism and fluorescence quenching study of the interactions between rhodium(II) complexes and human serum albumin.

Various divalent rhodium complexes Rh2(L)4 (L = acetate, propionate, butyrate, trifluoroacetate and trifluoroacetamidate) have been found to bind to non-defatted human serum albumin (HSA) at molar ratios about 8:1. The circular dichroism measurements showed that the more liposoluble carboxylates, butyrate and trifluoroacetate, caused the major alterations of the secondary structure of HSA. Stern-Volmer constants for the fluorescence quenching of the buried Trp214 residue by these complexes were also higher for the lipophilic metal compounds. In the case of the rhodium carboxylates it was observed that their denaturating and quenching properties could be explained in terms of their liposolubilities: the higher their lipophilic characters, the higher their abilities to penetrate inside the protein framework leading to structural alterations, and the closer they could get to the Trp residue causing fluorescence quenching. The liposoluble amidate complex, Rh2 (tfc)4, presented an intermediate quenching and did not cause structural alterations in the protein, presumably not penetrating inside the peptidic backbone. This study shows that it is possible to design new antitumor metal complexes which bind, to a large extent, to a transport protein causing little structural damage.     

Structural perturbation of proteins in low denaturant concentrations

The presence of very low concentrations of the widely used chemical denaturants, guanidinium chloride and urea, induce changes in the tertiary structure of proteins. We have presented results on such changes in four structurally unrelated proteins to show that such structural perturbations are common irrespective of their origin. Data representative of such structural changes are shown for the monomeric globular proteins such as horseradish peroxidase (HRP) from a plant, human serum albumin (HSA) and prothrombin from ovine blood serum, and for the membrane-associated, worm-like elongated protein, spectrin, from ovine erythrocytes. Structural alterations in these proteins were reflected in quenching studies of tryptophan fluorescence using the widely used quencher acrylamide. Stern-Volmer quenching constants measured in presence of the denaturants, even at concentrations below 100 mM, were higher than those measured in absence of the denaturants. Both steady-state and time-resolved fluorescence emission properties of tryptophan and of the extrinsic probe PRODAN were used for monitoring conformational changes in the proteins in presence of different low concentrations of the denaturants. These results are consistent with earlier studies from our laboratory indicating structural perturbations in proteins at the tertiary level, keeping their native-like secondary structure and their biological activity more or less intact.     

Structural microheterogeneity of a tryptophan residue required for efficient biological electron transfer between putidaredoxin and cytochrome P-450cam

The carboxy-terminal tryptophan of putidaredoxin, the Fe2S2.Cys4 iron-sulfur physiological redox partner of cytochrome P-450cam, is essential for maximal biological activity [Davies, M. D., Qin, L., Beck, J. L., Suslick, K. S., Koga, H., Horiuchi, T., & Sligar, S. G. (1990) J. Am. Chem. Soc. 112, 7396-7398]. This single tryptophan-containing protein thus represents an excellent system for studying the solution dynamics of a residue directly implicated in an electron-transfer pathway. Steady-state and time-resolved measurements of the tryptophan fluorescence have been conducted across the emission spectrum as a function of redox state to probe potential structural changes which might be candidates for structural gating phenomena. The steady-state emission spectrum (lambda max = 358 nm) and anisotropy (alpha = 0.04) suggest that Trp-106 is very solvent-exposed and rotating partially free of global protein constraints. The time-resolved fluorescence kinetics for both oxidized and reduced putidaredoxin are fit best with three discrete components of approximately 5, 2, and 0.3 ns. The lifetime components were assigned to physical species with iodide ion quenching experiments, where differential quenching of the longer components was observed (k tau = 2 = 5.9 X 10(8) M-1 s-1, k tau = 5 = 1.3 X 10(8) M-1 s-1). These findings suggest that the multiexponential fluorescence decay results from ground-state conformational microheterogeneity and thus demonstrate that the essential tryptophan exists in at least two distinguishable conformations. Small differences in the relative proportions of the components between redox states were observed but not cleanly resolved.(ABSTRACT TRUNCATED AT 250 WORDS)     

Engineering out motion: a surface disulfide bond alters the mobility of tryptophan 22 in cytochrome b5 as probed by time-resolved fluorescence and 1H NMR experiments

In the accompanying paper [Storch et al. (1999) Biochemistry 38, 5054-5064] equilibrium denaturation studies and molecular dynamics (MD) simulations were used to investigate localized dynamics on the surface of cytochrome b5 (cyt b5) that result in the formation of a cleft. In those studies, an S18C:R47C disulfide mutant was engineered to inhibit cleft mobility. Temperature- and urea-induced denaturation studies revealed significant differences in Trp 22 fluorescence between the wild-type and mutant proteins. On the basis of the results, it was proposed that wild type populates a conformational ensemble that is unavailable to the disulfide mutant and is mediated by cleft mobility. As a result, the solvent accessibility of Trp 22 is decreased in S18C:R47C, suggesting that the local environment of this residue is less mobile due to the constraining effects of the disulfide on cleft dynamics. To further probe the structural effects on the local environment of Trp 22 caused by inhibition of cleft formation, we report here the results of steady-state and time-resolved fluorescence quenching, differential phase/modulation fluorescence anisotropy, and 1H NMR studies. In Trp fluorescence experiments, the Stern-Volmer quenching constant increases in wild type versus the oxidized disulfide mutant with increasing temperature. At 50 degrees C, KSV is nearly 1.5-fold greater in wild type compared to the oxidized disulfide mutant. In the reduced disulfide mutant, KSV was the same as wild type. The bimolecular collisional quenching constant, kq, for acrylamide quenching of Trp 22 increases 2.7-fold for wild type and only 1.8-fold for S18C:R47C, upon increasing the temperature from 25 to 50 degrees C. The time-resolved anisotropy decay at 25 degrees C was fit to a double-exponential decay for both the wild type and S18C:R47C. Both proteins exhibited a minor contribution from a low-amplitude fast decay, consistent with local motion of Trp 22. This component was more prevalent in the wild type, and the fractional contribution increased significantly upon raising the temperature. The fast rotational component of the S18C:R47C mutant was less sensitive to increasing temperature. A comparison of the 1H NMR monitored temperature titration of the delta-methyl protons of Ile 76 for wild type and oxidized disulfide mutant, S18C:R47C, showed a significantly smaller downfield shift for the mutant protein, suggesting that Trp 22 in the mutant protein experiences comparatively decreased cleft dynamics in core 2 at higher temperatures. Furthermore, comparison of the delta'-methyl protons of Leu 25 in the two proteins revealed a difference in the ratio of the equilibrium heme conformers of 1.2:1 for S18C:R47C versus 1.5:1 for wild type at 40 degrees C. The difference in equilibrium heme orientations between wild type and S18C:R47C suggests that the disulfide bond affects heme binding within core 1, possibly through damped cleft fluctuations. Taken together, the NMR and fluorescence studies support the proposal that an engineered disulfide bond inhibits the formation of a dynamic cleft on the surface of cyt b5.     

Myb-DNA recognition: role of tryptophan residues and structural changes of the minimal DNA binding domain of c-Myb

The Myb oncoprotein specifically binds DNA by a domain composed of three imperfect repeats, R1, R2, and R3, each containing 3 tryptophans. The tryptophan fluorescence of the minimal binding domain, R2R3, of c-Myb was used to monitor structural flexibility changes occurring upon DNA binding to R2R3. The quenching of the Trp fluorescence by DNA titration shows that four out of the six tryptophans are involved in the formation of the specific R2R3-DNA complex and the environment of the tryptophan residues becomes more hydrophobic in the complex. The fluorescence intensity quenching of the tryptophans by binding of R2R3 to DNA is consistent with the decrease of the decay time: 1.46 ns for free R2R3 to 0.71 ns for the complexed protein. In the free R2R3, the six tryptophans are equally accessible to the iodide and acrylamide quenchers with a high collisional rate constant (4 x 10(9) and 3 x 10(9) M-1 s-1, respectively), indicating that R2R3 in solution is very flexible. In the R2R3-DNA complex, no Trp fluorescence quenching is observed with iodide whereas all tryptophan residues remain accessible to acrylamide with a collisional rate constant slightly slower than that in the free state. These results indicate that (i) a protein structural change occurs and (ii) the R2R3 molecule keeps a high mobility in the complex.The complex formation presents a two-step kinetics: a fast step corresponding to the R2R3-DNA association (7 x 10(5) M-1 s-1) and a slower one (0.004 s-1), which should correspond to a structural reorganization of the protein including a reordering of the water molecules at the protein-DNA interface.     

Location and dynamics of anthracyclines bound to unilamellar phosphatidylcholine vesicles

We have exploited the intrinsic fluorescence properties of the anthracycline antitumor antibiotics to study the dependence on drug structure of relative drug location and dynamics when the anthracyclines were bound to sonicated dimyristoylphosphatidylcholine (DMPC) and dipalmitoylphosphatidylcholine (DPPC) vesicles at 27.5 degrees C. Iodide quenching experiments at constant ionic strength were used to evaluate the relative accessibilities of the bound fluorophores to membrane-impermeable iodide. Iodide was found to quench the fluorescence of anthracyclines in free solution by both static and dynamic mechanisms, whereas quenching of membrane-bound fluorophores was predominantly due to the dynamic mechanism. Modified Stern-Volmer plots of anthracyclines bound to fluid-phase DMPC bilayers were linear, and the biomolecular rate constant (kq) values ranged from 0.6 X 10(9) to 1.3 X 10(9) M-1 s-1. Modified Stern-Volmer plots of anthracyclines bound to solid-phase DPPC bilayers were curved, indicative of a heterogeneous-bound drug population. A strong correlation between drug hydrophobicity and penetration of the fluorophore into the bilayer was observed for the daunosamine-containing anthracyclines. Steady-state fluorescence anisotropy measurements under iodide quenching conditions were used to investigate the diffusive motions of anthracyclines in isotropic solvent and in fluid-phase DMPC bilayers. Anthracycline derivatives free in solution exhibited limiting anisotropy (alpha infinity) values which decayed to zero at times long compared to the excited-state lifetime, in contrast to anthracyclines bound to fluid-phase DMPC bilayers, which showed nonzero alpha infinity values. Steady-state anisotropies of membrane-bound anthracyclines were found to be governed principally by alpha infinity and not by the mean rotational rate (R).(ABSTRACT TRUNCATED AT 250 WORDS)     

A photoreversible conformational change in 124 kDa Avena phytochrome

Tryptophan (Trp) fluorescence quenching of phytochrome has been studied using anionic, cationic and neutral quenchers, I-, Cs+ and acrylamide, respectively, in an effort to understand the molecular differences between the Pr and Pfr forms. The data have been analyzed using both Stern-Volmer and modified Stern-Volmer kinetic treatments. The anionic quencher, I-, was proven to be an ineffective quencher with Stern-Volmer constants, Ksv, of 0.60 and 0.63 M-1, respectively, for the Pr and Pfr forms of phytochrome. The cationic quencher, Cs+, showed about a 2-fold difference in the Ksv of Pr and Pfr, indicating a significant change in the fluorescent Trp environments during the Pr to Pfr phototransformation. However, only 25-37% of the fluorescent Trp residues were accessible to the cationic quencher. Most of the fluorescent Trp residues were accessible to acrylamide, but the quenching by acrylamide was indistinguishable for the Pr and Pfr forms. An additional quenching by acrylamide after a saturated quenching with Cs+ showed more than 40% increase in the Ksv of Pfr over Pr. These observations, along with the finding of two distinct components in the Trp fluorescence lifetime, indicate the existence of Trp residues in at least two different sets of environments in the phytochrome protein. The two components of the fluorescence had lifetimes of 1.1 ns (major) and 4.7 ns (minor) for Pr and 0.9 ns (major) and 4.6 ns (minor) for Pfr. Fluorescence quenching was found to be both static and dynamic as the Stern-Volmer constants for the steady-state fluorescence quenching were higher than for the dynamic fluorescence quenching. Based on the quenching results, in combination with the location of Trp residues in the primary structure, we conclude that the Pr to Pfr phototransformation involves a significant conformation change in the phytochrome molecule, preferentially in the 74 kDa chromophore-bearing domain.     

Ligand-induced changes in the conformational dynamics of a bacterial cytotoxic endonuclease

Knowledge about the conformational dynamics of a protein is key to understanding its biochemical and biophysical properties. In the present work we investigated the dynamic properties of the enzymatic domain of DNase colicins via time-resolved fluorescence and anisotropy decay analysis in combination with steady-state acrylamide quenching experiments. The dynamic properties of the apoenzyme were compared to those of the E9 DNase ligated to the transition metal ion Zn(2+) and the natural inhibitor Im9. We further investigated the contributions of each of the two tryptophans within the E9 DNase (Trp22 and Trp58) using two single-tryptophan mutants (E9 W22F and E9 W58F). Wild-type E9 DNase, E9 W22F, and E9 W58F, as well as Im9, showed multiple lifetime decays. The time-resolved and steady-state fluorescence results indicated that complexation of E9 DNase with Zn(2+) induces compaction of the E9 DNase structure, accompanied by immobilization of Trp22 along with a reduced solvent accessibility for both tryptophans. Im9 binding resulted in immobilization of Trp22 along with a decrease in the longest lifetime component. In contrast, Trp58 experienced less restriction on complexation of E9 DNase with Im9 and showed an increase in the longest lifetime component. Furthermore, the results point out that the Im9-induced changes in the conformational dynamics of E9 DNase are predominant and occur independently of the Zn(2+)-induced conformational effects.     

Interaction of colchicine with human serum albumin investigated by spectroscopic methods

We investigated the interaction between colchicine and human serum albumin (HSA) by fluorescence and UV-vis absorption spectroscopy. In the mechanism discussion, it was proved that the fluorescence quenching of HSA by colchicine is a result of the formation of colchicines-HSA complex; van der Waals interactions and hydrogen bonds play a major role in stabilizing the complex. The modified Stern-Volmer quenching constant K(a) and corresponding thermodynamic parameters deltaH, deltaG, deltaS at different temperatures were calculated. The distance r between donor (Trp214) and acceptor (colchicine) was obtained according to fluorescence resonance energy transfer (FRET).     

Spectroscopic studies on human serum albumin and methemalbumin: optical, steady-state, and picosecond time-resolved fluorescence studies, and kinetics of substrate oxidation by methemalbumin

The nature of the heme environment in methemalbumin, the Fe(III) protoporphyrin IX (heme)-human serum albumin (HSA) complex, was investigated by optical spectroscopy. Comparison of the optical spectra of methemalbumin, ferro-hemalbumin in the absence and presence of 2-methylimidazole, and their carbon monoxide derivatives with horseradish peroxidase (HRP) and its corresponding derivatives indicates that histidine is not present in the first coordination sphere of heme in methemalbumin and that the protein is devoid of a well-defined heme cavity. The complex exhibits peroxidase activity by catalyzing oxidation of 2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonate) by hydrogen peroxide. Its activity ( K(M)=433 microM, molar catalytic activity=0.33 s(-1)), however, is considerably lower compared to HRP, indicating differences in the heme environments. Fluorescence intensity decays of Trp214 in HSA and methemalbumin, best fitted to a three-exponential model, gave the lifetimes 7.03 ns (30%), 3.17 ns (38%), and 0.68 ns (32%) for HSA and 8.04 ns (1.7%), 2.42 ns (19.7%), and 0.64 ns (78.6%) for methemalbumin. These lifetime values were further confirmed by a model-independent maximum entropy method. Similarity in the lifetimes and variations in the amplitudes suggest that while conformational heterogeneity of HSA is unperturbed on heme binding, redistribution of the populations of the three conformations occurs and the sub-state associated with the shortest lifetime dominates the total population by approximately 80%. Decay associated spectra (DAS) indicate that the observed lifetime variation with wavelength is predominantly due to ground state heterogeneity, though solvent dipolar relaxation also contributes. Time-resolved fluorescence anisotropy measurements of the Trp214 residue yielded information on motion within the protein together with the whole protein molecule. The binding of heme did not affect the rotational correlation time of the albumin molecule (approximately 20 ns). However, the motion of tryptophan within the protein matrix increased by a factor of approximately 3 (0.46 ns to 0.15 ns). This indicates that while the overall hydrodynamic volume of the albumin molecule remained the same, tryptophan underwent a more rapid internal rotation because of the efficient energy transfer to the bound heme. Optical studies, analysis of lifetime measurements, DAS, and anisotropy measurements together suggest that heme binds to a surface residue. The rapid internal motion of Trp214 during its excited state lifetime for the approximately 80% populated conformer of methemalbumin allows the orientation factor, kappa(2), to approach the average value of 2/3. From the time-resolved fluorescence measurements and the energy transfer calculations on methemalbumin, a Trp214-heme distance of 22 A was deduced.     

Inverse effects of D-galactosamine and inorganic phosphate on glycogenolysis in isolated rat hepatocytes.

Trichloroethanol is an efficient quencher of indole fluorescence of model compounds and proteins [Eftink, M. R. and Ghiron, C. A. (1976) J. Phys. Chem. 80, 486--493]. At low quencher concentrations, the quenching follows the classical Stern-Volmer law. Bimolecular rate constants calculated from measured quenching constants and lifetimes are equal to 6 X 10(9) M-1s-1 and 1.2 X 10(9) M-1s-1 for N-acetyltrypotophanamide and wheat germ agglutinin, respectively. Upon ultraviolet irradiation in the presence of trichloroethanol, transformation of fluorescent tryptophan occurs, leading to a fluorescent photoproduct. This can be easily used as a method for the quantitative determination of fluorescent tryptophan residues in proteins. In good agreement with previous results, two fluorescent tryptophan residues per polypeptide chain are found in wheat germ agglutinin. Concomitantly with the photochemical reactions, the hemagglutinating protein activity and its affinity constant towards chitin oligomers are reduced. A probable location of tryptophan residues in the binding sites of wheat germ agglutinin is proposed.     

Fluorescence investigation of the sex steroid binding protein of rabbit serum: steroid binding and subunit dissociation

The relationship between steroid binding and protein subunit interactions of rabbit sex steroid binding protein (rSBP) has been studied by steady-state and time-resolved fluorescence spectroscopy. The high-affinity (Ka approximately 10(8) M-1 at 4 degrees C), fluorescent estrogen d-1,3,5(10),6,8-estrapentaene-3,17 beta-diol [dihydroequilenin (DHE)] was used as a fluorescent probe of the steroid-binding site. Perturbation of the binding site with guanidinium chloride (Gdm.Cl) was monitored by changes in the steady-state fluorescence anisotropy of DHE as well as by changes in fluorescence quenching of DHE with acrylamide. The results of acrylamide quenching at 11 degrees C show that, while between 0 and 1 M Gdm.Cl the steroid-binding site is completely shielded from bulk solvent, there is decreased DHE binding. To study the subunit-subunit interactions, rSBP was covalently labeled with dansyl chloride in the presence of saturating 5 alpha-dihydrotestosterone (DHT), which yielded a dansyl-conjugated protein that retained full steroid-binding activity. The protein subunit perturbation was monitored by changes in the steady-state fluorescence anisotropy of the dansyl group. At 11 degrees C, the dansyl anisotropy perturbation, reflecting changes in global and segmental motions of the dimer protein, occurs at concentrations of Gdm.Cl above 1 M. The Gdm.Cl titration in the presence of steroids with equilibrium association constants less than 10(8) M-1 shows a plateau near 3 M Gdm.Cl at 11 degrees C; at this Gdm.Cl concentration, no DHE is bound. No plateau is observed at 21 degrees C. At higher Gdm.Cl concentrations, the dansyl fluorescence anisotropy decreases further and shows no steroid dependence. Recovery of steroid-binding activity (assayed by saturation binding with [3H]DHT), under renaturation conditions, is dependent on both steroid concentration and affinity. Both unlabeled and dansyl-labeled protein recovery the same amount of activity, and according to fluorescence anisotropy, dansyl-labeled rSBP re-forms a dimer upon dilution below 1 M or removal of Gdm.Cl. From the steroid requirement for recovery of steroid-binding activity, it appears that a conformational template is required for the dimeric protein to re-form a steroid-binding site with native-like properties.     

Native fluorescence and mag-indo-1-protein interaction as tools for probing unfolding and refolding sequences of the bovine serum albumin subdomain in the presence of guanidine hydrochloride

Changes in the fluorescence spectrum of tryptophans Trp 134 and Trp 212 in bovine serum albumin (BSA) and of Trp 214 of human serum albumin in the presence of the chaotropic agent guanidine hydrochloride (Gnd) were studied. A detailed analysis of the fluorescence spectrum of native BSA yielded the fluorescence spectrum for each tryptophan of BSA. Modifications in the binding of Mag-indo-1 to BSA, which results in a specific quenching of the fluorescence spectrum of Trp 134 associated with an energy transfer from Trp 134 to the protein-bound Mag-indo-1, were also investigated. Changes occurring when the Gnd concentration is decreased stepwise cover a larger concentration scale of Gnd than the reverse protocol, allowing one to suggest that the resulting conformational changes in the subdomain IA of BSA involve at least three different steps.     

Static quenching of tryptophan fluorescence by oxidized dithiothreitol

The quenching of fluorescence of 5-methoxyindole, N-acetyl-L-tryptophanamide and two single tryptophan containing peptides, melittin and mastoparan X, by oxidized dithiothreitol was studied. The slopes of the Stern-Volmer plots for steady-state fluorescence quenching were 133 M-1, 71.2 M-1, 75.5 M-1 and 35.0 M-1 at 21 degrees C and pH 7.0 for 5-methyoxyindole, N-acetyl-L-tryptophanamide, melittin and mastoparan X respectively. Fluorescence lifetimes of indole or tryptophan in these compounds, as determined by multifrequency phase fluorometry, were decreased by 15% or less at concentrations that produced 50% or more quenching of steady-state fluorescence. Thus, quenching of fluorescence by oxidized dithiothreitol for these derivatives of indole appears to be largely static in nature, suggesting a ground-state interaction.     

Steady-state and time-resolved fluorescence studies of the intestinal fatty acid binding protein

The intestinal fatty acid binding protein contains two tryptophan residues (Trp6 and Trp82) both of which have been shown by X-ray and NMR methods to be buried in hydrophobic clusters. By using a combination of steady-state and time-resolved fluorescence experiments, we have deconvoluted the lifetime weighted contribution of each of the tryptophans to the steady-state fluorescence quantum yield. While Trp82 has been implicated in an intermediate that appears at relatively high denaturant concentrations, the variation of the lifetime weighted contribution of Trp6 with urea or guanidium hydrochloride shows formation of an intermediate state at low concentrations of the denaturant before the actual unfolding starts. Trp82 did not show similar behavior. Fluorescence quenching experiments by acrylamide show that while Trp6 in the native protein is less solvent-exposed, its accessibility is increased significantly at low urea concentration indicating that the early intermediate state is partially unfolded. Time-resolved anisotropy experiments indicate that the volume of the partially unfolded intermediates is larger than the native protein and lead to the speculation that the last step of the protein folding might be the removal of solvent molecules from the protein.     

Unfolding and conformational studies on bovine adrenodoxin probed by engineered intrinsic tryptophan fluorescence

An intrinsic steady-state fluorescent system for bovine adrenodoxin has been developed to study the protein structure in solution and the processes involved in protein unfolding. Since mature Adx contains no natural Trp residue as internal probe, all of the aromatic amino acids, tyrosine at position 82 and four phenylalanines at positions 11, 43, 59 and 64, were at each case replaced by tryptophan. The resulting single tryptophan containing mutants kept their biological function compared with the wild type. Molecular modeling studies verify thermal unfolding experiments which point to a dramatically reduced stability caused by steric hindrance only for mutant F59W. Fluorescence spectra, Stern-Volmer quenching constants, and fluorescence energy transfer calculations indicated the analyzed positions to be situated in solution in the same immediate environment as in the crystal structure. Unfolding experiments with Gdn-HCl and time-resolved stopped-flow measurements provide evidence for differential stability and a chronologically ordered unfolding mechanism of the different fluorescence probe positions in the protein.     

Steady-state and time-resolved fluorescence studies of conformational changes induced by cyclic AMP and DNA binding to cyclic AMP receptor protein from Escherichia coli.

cAMP receptor protein (CRP), allosterically activated by cAMP, regulates the expression of several genes in Escherichia coli. As binding of cAMP leads to undefined conformational changes in CRP, we performed a steady-state and time-resolved fluorescence study to show how the binding of the ligand influences the structure and dynamics of the protein. We used CRP mutants containing a single tryptophan residue at position 85 or 13, and fluorescently labeled with 1,5-I-AEDANS attached to Cys178. Binding of cAMP in the CRP-(cAMP)2 complex leads to changes in the Trp13 microenvironment, whereas its binding in the CRP-(cAMP)4 complex alters the surroundings of Trp85. Time-resolved anisotropy measurements indicated that cAMP binding in the CRP-(cAMP)2 complex led to a substantial increase in the rotational mobility of the Trp13 residue. Measurement of fluorescence energy transfer (FRET) between labeled Cys178 and Trp85 showed that the binding of cAMP in the CRP-(cAMP)2 complex caused a substantial increase in FRET efficiency. This indicates a decrease in the distance between the two domains of the protein from 26.6 A in apo-CRP to 18.7 A in the CRP-(cAMP)2 complex. The binding of cAMP in the CRP-(cAMP)4 complex resulted in only a very small increase in FRET efficiency. The average distance between the two domains in CRP-DNA complexes, possessing lac, gal or ICAP sequences, shows an increase, as evidenced by the increase in the average distance between Cys178 and Trp85 to approximately 20 A. The spectral changes observed provide new structural information about the cAMP-induced allosteric activation of the protein.     

Exposure of tryptophanyl residues in proteins. Quantitative determination by fluorescence quenching studies.

Acrylamide is an efficient quencher of tryptophanyl fluorescence which we report to be very discriminating in sensing the degree of exposure of this residue in proteins. The quenching reaction involves physical contact between the quencher and an excited indole ring, and can be kinetically described in terms of a collisional and a static component. The rate constant for the collisional component is a kinetic measure of the exposure of a residue in a protein, and values ranging from 4 X 10(9) M-1 S-1 for the fully exposed tryptophan in the polypeptide, adrenocorticotropin, to less than 5 X 10(8) M-1 S-1 for the buried residue in azurin have been found. Static quenching is readily detected in proteins that are denatured, or contain only a single fluorophor. Quenching patterns for most multi-tryptophan containing proteins are difficult to analyze precisely, but qualitative information can, nevertheless, be extracted. Applications of this probing technique for monitoring protein conformational changes, such as the acid-induced expansion of human serum albumin, and inhibitor binding to enzymes, are presented. The value of this method lies in its ability to sense not only the steady-state exposure of a residue in a protein, but also its dynamic exposure.