Intrinsic tryptophan fluorescence identifies specific conformational changes at the actomyosin interface upon actin binding and ADP release.

The helix-loop-helix (A-site) and myopathy loop (R-site) are located on opposite sides of the cleft that separates the proposed actin-binding interface of myosin. To investigate the structural features of the A- and R-sites, we engineered two mutants of the smooth muscle myosin motor domain with the essential light chain (MDE), containing a single tryptophan located either in the A-site (W546-MDE) or in the R-site (V413W MDE). W546- and V413W-MDE display actin-activated ATPase and actin-binding properties similar to those of wild-type MDE. The steady-state fluorescence properties of W546-MDE [emission peak (lambda(max)) = 344, quantum yield = 0.20, and acrylamide bimolecular quenching constant (k(q)) = 6.4 M(-)(1). ns(-)(1)] and V413W-MDE [lambda(max) = 338, quantum yield = 0.27, and k(q) = 3.6 M(-)(1).ns(-)(1)] demonstrate that Trp-546 and Trp-413 are nearly fully exposed to solvent, in agreement with the crystallographic data on these residues. In the presence of actin, Trp-546 shifts to a more buried environment in both the ADP-bound and nucleotide-free (rigor) actomyosin complexes, as indicated by an average lambda(max) of 337 or 336 nm, respectively, and protection from dimethyl(2-hydroxy-5-nitrobenzyl)sulfonium bromide (DHNBS) oxidation. In contrast, Trp-413 has a single conformation with an average lambda(max) of 338 nm in the ADP-bound complex, but in the rigor complex it is 50% more accessible to DHNBS oxidation and can adopt a range of possible conformations (lambda(max) = 341-347 nm). Our results suggest a structural model in which the A-site remains tightly bound to actin and the R-site adopts a more flexible and solvent-exposed conformation upon ADP release.     

Intrinsic fluorescence of the P-glycoprotein multidrug transporter: sensitivity of tryptophan residues to binding of drugs and nucleotides

P-glycoprotein is a member of the ATP binding cassette family of membrane proteins, and acts as an ATP-driven efflux pump for a diverse group of hydrophobic drugs, natural products, and peptides. The side chains of aromatic amino acids have been proposed to play an important role in recognition and binding of substrates by P-glycoprotein. Steady-state and lifetime fluorescence techniques were used to probe the environment of the 11 tryptophan residues within purified functional P-glycoprotein, and their response to binding of nucleotides and substrates. The emission spectrum of P-glycoprotein indicated that these residues are present in a relatively nonpolar environment, and time-resolved experiments showed the existence of at least two lifetimes. Quenching studies with acrylamide and iodide indicated that those tryptophan residues predominantly contributing to fluorescence emission are buried within the protein structure. Only small differences in Stern-Volmer quenching constants were noted on binding of nucleotides and drugs, arguing against large changes in tryptophan accessibility following substrate binding. P-glycoprotein fluorescence was highly quenched on binding of fluorescent nucleotides, and moderately quenched by ATP, ADP, and AMP-PNP, suggesting that the site for nucleotide binding is located relatively close to tryptophan residues. Drugs, modulators, hydrophobic peptides, and nucleotides quenched the fluorescence of P-glycoprotein in a saturable fashion, allowing estimation of dissociation constants. Many compounds exhibited biphasic quenching, suggesting the existence of multiple drug binding sites. The quenching observed for many substrates was attributable largely to resonance energy transfer, indicating that these compounds may be located close to tryptophan residues within, or adjacent to, the membrane-bound domains. Thus, the regions of P-glycoprotein involved in nucleotide and drug binding appear to be packed together compactly, which would facilitate coupling of ATP hydrolysis to drug transport.     

Decomposition of protein tryptophan fluorescence spectra into log-normal components. III. Correlation between fluorescence and microenvironment parameters of individual tryptophan residues

In our previous paper (Reshetnyak, Ya. K., and E. A. Burstein. 2001. Biophys. J. 81:1710-1734) we confirmed the existence of five statistically discrete classes of emitting tryptophan fluorophores in proteins. The differences in fluorescence properties of tryptophan residues of these five classes reflect differences in interactions of excited states of tryptophan fluorophores with their microenvironment in proteins. Here we present a system of describing physical and structural parameters of microenvironments of tryptophan residues based on analysis of atomic crystal structures of proteins. The application of multidimensional statistical methods of cluster and discriminant analyses for the set of microenvironment parameters of 137 tryptophan residues of 48 proteins with known three-dimensional structures allowed us to 1) demonstrate the discrete nature of ensembles of structural parameters of tryptophan residues in proteins; 2) assign spectral components obtained after decomposition of tryptophan fluorescence spectra to individual tryptophan residues; 3) find a correlation between spectroscopic and physico-structural features of the microenvironment; and 4) reveal differences in structural and physical parameters of the microenvironment of tryptophan residues belonging to various spectral classes.     

The fluorescence decay of tryptophan residues in native and denatured proteins.

The fluorescence decay kinetics at different ranges of the emission spectrum is reported for 17 proteins. Out of eight proteins containing a single tryptophan residue per molecule, seven proteins display multiexponential decay kinetics, suggesting that variability in protein structure may exist for most proteins. Tryptophan residues whose fluorescence spectrum is red shifted may have lifetimes longer than 7 ns. Such long lifetimes have not been detected in any of the denatured proteins studied, indicating that in native proteins the tryptophans having a red-shifted spectrum are affected by the tertiary structure of the protein. The fluorescence decay kinetics of ten denatured proteins studied obey multiexponential decay functions. It is therefore concluded that the tryptophan residues in denatured proteins can be grouped in two classes. The first characterized by a relatively long lifetime of about 4 ns and the second has a short lifetime of about 1.5 ns. The emission spectrum of the group which is characterized by the longer lifetime is red shifted relative to the emission spectrum of the group characterized by the shorter lifetime. A comparison of the decay data with the quantum yield of the proteins raises the possibility that a subgroup of the tryptophan residues is fully quenched. It is noteworthy that despite this heterogeneity in the environment of tryptophan residues in each denatured protein, almost the same decay kinetics has been obtained for all the denatured proteins studied in spite of the vastly different primary structures. It is therefore concluded that each tryptophan residue interacts in a more-or-less random manner with other groups on the polypeptide chain, and that on the average the different tryptophan residues in denatured proteins have a similar type of environment.     

Intrinsic UV-fluorescence of lysozyme and microenvironment of its tryptophan residues]

The localization of tryptophan residues in hen egg-white lysozyme macromolecule was studied on the basis of the known 3D structure. The polarity and packing density of their microenvironments were evaluated. All residues that can affect the tryptophan fluorescence were revealed. It was shown that the orientation of these active groups relative to the indole ring of tryptophan plays a dramatic role in the efficiency of their influence. Tryptophan--tryptophan nonradiative energy transfer was evaluated from distances between tryptophan residues and their mutual orientation. The conformation of the side chains of tryptophan residues was determined. Special attention was paid to microenvironment of Trp108 responsible for the minor absorption band at 305 nm.     

The reactivity of tryptophan residues in proteins. Stopped-flow kinetics of fluorescence quenching.

The quenching of tryptophan fluorescence by N-bromosuccinamide, studied by the fluorescence stopped-flow technique, was used to compare the reactivities of tryptophan residues in protein molecules. The reaction of N-bromosuccinamide with the indole group of N-acetyltryptophanamide, a model compound for bound tryptophan, followed second-order kinetics with a rate constant of (7.8 +/- 0.8) . 10(5) dm3 . mol-1 . s-1 at 23 degrees C. The rate does not depend on ionic strength or on the pH near neutrality. The non-fluorescent intermediate formed from N-acetyltryptophanamide on the reaction with N-bromosuccinamide appears to be a bromohydrin compound. The second-order rate constant for fluorescence quenching of tryptophan in Gly-Trp-Gly by N-bromosuccinamide was very similar, (8.8 +/- 0.8) . 10(5) dm3 . mol-1 . s-1. Apocytochrome c has the conformation of a random coil with the single tryptophan largely exposed to the solvent. The rate constant for the fluorescence quenching of the tryptophan in apocytochrome c by N-bromosuccinamide was (3.7 +/- 0.3) . 10(5) dm3 . mol-1 . s-1. The fluorescence quenching by N-bromosuccinamide of the tryptophan residues incorporated in alpha-chymotrypsin at pH 7.0 showed three exponential terms from which the following rate constants were derived: 1.74 . 10(5), 0.56 . 10(5) and 0.11 . 10(5) dm3 . mol-1 . s-1. This protein is known to have eight tryptophan residues in the native state, six residues at the surface, and two buried. Three of the surface tryptophans have the indole rings protruding out of the molecule and may account for the fastest kinetic phase of the quenching process. The intermediate phase may be due to three surface tryptophans whose indole rings point inwards, and the slowest to the two interior tryptophan residues.     

Intrinsic tryptophan fluorescence of human serum proteins and related conformational changes

The unfolding of human serum proteins (HSP) was studied by measuring the intrinsic fluorescence intensity at a wavelength of excitation corresponding to tryptophan's or typosine's fluorescence and surface hydrophobicity. The maxima emission wavelengths (_max) of human serum albumin (HSA) and human serum globulin (HSG) before beer consumption (BC) were 336.0 and 337.0 nm and after BC shifted to 335.0 and 334.0 nm, respectively. The surface hydrophobicity slightly increased after BC. In a solution of 8 M urea the _max of BSA shifted to 346.4 and that of BSG to 342.5 nm. In contrast, in the same solution but after BC the _max positions of HSA and HSG shifted to 355.9 and 357.7 nm, respectively. A decrease in fluorescence intensity, a shift in the maximum of emission, and an increase in surface hydrophobicity which reflected unfolding of proteins were observed. Here we provide evidence that the loosening of the HSP structure takes place primarily in various concentrations of urea before and after beer consumption. Differences in the fluorescence behavior of the proteins are attributed to disruption of the structure of proteins by denaturants as well as by the change in their compactability as a result of ethanol consumption.     

Resolution of the fluorescence decay of the two tryptophan residues of lac repressor using single tryptophan mutants.

We have studied the time-resolved intrinsic tryptophan fluorescence of the lac repressor (a symmetric tetramer containing two tryptophan residues per monomer) and two single-tryptophan mutant repressors obtained by site-directed mutagenesis, lac W201Y and lac W220Y. These mutant repressor proteins have tyrosine substituted for tryptophan at positions 201 and 220, respectively, leaving a single tryptophan residue per monomeric subunit at position 220 for the W201Y mutant and at position 201 in the W220Y mutant. It was found that the two decay rates recovered from the analysis of the wild type data do not correspond to the rates recovered from the analysis of the decays of the mutant proteins. Each of these residues in the mutant repressors displays at least two decay rates. Global analysis of the multiwavelength data from all three proteins, however, yielded results consistent with the fluorescence decay of the wild type lac repressor corresponding simply to the weighted linear combination of the decays from the mutant proteins. The effect of ligation by the antagonistic ligands, inducer and operator DNA, was similar for all three proteins. The binding of the inducer sugar resulted in a quenching of the long-lived species, while binding by the operator decreased the lifetime of the short components. Investigation of the time-resolved anisotropy of the intrinsic tryptophan fluorescence in these three proteins revealed that the depolarization of fluorescence resulted from a fast motion and the global tumbling of the macromolecule. Results from the simultaneous global analysis of the frequency domain data sets from the three proteins revealed anisotropic rotations for the macromolecule, consistent with the known elongated shape of the repressor tetramer. In addition, it appears that the excited-state dipole of tryptophan 220 is alighed with the long axis of the repressor.     

Intrinsic fluorescence of chloramphenicol acetyltransferase: responses to ligand binding and assignment of the contributions of tryptophan residues by site-directed mutagenesis

Replacement by tyrosine or phenylalanine was used to assign the additive contributions of each of the three tryptophan residues of chloramphenicol acetyltransferase (CAT) to its intrinsic fluorescence on excitation at 295 nm. During the assessment of the fluorescence responses of the wild-type enzyme to the binding of ligands, it was found that the overlapping absorption spectra of chloramphenicol and tryptophan, with an attendant inner filter effect, required the use of a displacement technique involving an alternative substrate (the p-cyano analogue of chloramphenicol) without significant absorption at 295 nm. By the use of two-Trp, one-Trp, and Trp-less variants, in combination with this displacement technique, it was possible to demonstrate that Trp-86 and Trp-152 are involved in the fluorescence quenching associated with the binding of chloramphenicol, most likely via nonradiative energy transfer from these residues to the bound substrate. Trp-152 is mainly responsible for the fluorescence enhancement accompanying the binding of acetyl-CoA (and CoA) through proximity effects and solvent exclusion on substrate association.     

The tryptophan residues of aspartate transcarbamylase: site-directed mutagenesis and time-resolved fluorescence spectroscopy.

Aspartate transcarbamylase (EC 2.1.3.2) contains two tryptophan residues in position 209 and 284 of the catalytic chains (c) and no such chromophore in the regulatory chains (r). Thus, as a dodecamer [(c3)2(r2)3] the native enzyme molecule contains 12 tryptophan residues. The present study of the regulatory conformational changes in this enzyme is based on the fluorescence properties of these intrinsic probes. Site-directed mutagenesis was used in order to differentiate the respective contributions of the two tryptophans to the fluorescence properties of the enzyme and to identify the mobility of their environment in the course of the different regulatory processes. Each of these tryptophan residues gives two independent fluorescence decays, suggesting that the catalytic subunit exists in two slightly different conformational states. The binding of the substrate analog N-phosphonacetyl-L-aspartate promotes the same fluorescence signal whether or not the catalytic subunits are associated with the regulatory subunits, suggesting that the substrate-induced conformational change of the catalytic subunit is the essential trigger for the quaternary structure transition involved in cooperativity. The binding of the substrate analog affects mostly the environment of tryptophan 284, while the binding of the activator ATP affects mostly the environment of tryptophan 209, confirming that this activator acts through a mechanism different from that involved in homotropic cooperativity.     

Nanosecond segmental mobilities of tryptophan residues in proteins observed by lifetime-resolved fluorescence anisotropies.

Steady-state and lifetime-resolved fluorescence anisotropy measurements of protein fluorescence were used to investigate the depolarizing motions of tryptophan residues in proteins. Lifetime resolution was achieved by oxygen quenching. The proteins investigated were carbonic anhydrase, carboxypeptidase A, alpha-chymotrypsin, trypsin, pepsin, and bovine and human serum albumin. When corrected for overall protein rotation, the steady state anisotropies indicate that, on the average, the tryptophan residues in these proteins rotate 29 degrees +/- 6 degrees during the unquenched excited state lifetimes of these proteins, which range from 1.7 to 6.1 ns. The lifetime-resolved anisotropies reveal correlation times for these displacements ranging from 1 to 12 ns. On the average these correlation times are tenfold shorter than that expected for overall protein rotation. We conclude that the tryptophan residues in these proteins display remarkable freedom of motion within the protein matrix, which implies that these matrices are highly flexible on the nanosecond time scale.     

Intrinsic tryptophan fluorescence of membranes of GH3 pituitary cells: quenching by thyrotropin-releasing hormone.

The intrinsic tryptophan fluorescence of membranes prepared from the GH₃ strain of hormone-producing pituitary cells was monitored by spectrofluorometry. Membranes of GH₃ cells have specific receptors which bind thyrotropin-releasing hormone (TRH). When TRH binds to GH₃ membranes there is quenching of tryptophan fluorescence. The kinetics of the change in fluorescence of GH₃ membranes and of TRH binding are similar. In addition, the concentration of TRH required to produce a half-maximum change in fluorescence is 10 nM, and that required for half-maximum binding of TRH to receptors is 11 nM. Inactive TRH analogs which do not bind to TRH receptors likewise do not alter GH₃ membrane fluorescence, and a pituitary cell strain which lacks TRH receptors does not change membrane fluorescence on incubation with TRH. We conclude that the TRH-receptor interaction in GH₃ membranes is associated with a change in membrane conformation that is readily measured by differential spectrofluorometry.     

Metal-enhanced fluorescence of tryptophan residues in proteins: Application toward label-free bioassays

The detection of submonolayers of proteins based on native fluorescence is a potentially valuable approach for label-free detection. We have examined the possibility of using silver nanostructures to increase the emission of tryptophan residues in proteins. Fluorescence spectra, intensities, and lifetimes of multilayers and submonolayers of proteins deposited on the surfaces of silver island films were measured. Increased fluorescence intensities from two- to three-fold and similar decreases in lifetimes were observed in the presence of the silver nanoparticles compared with the proteins on the surface of the bare quartz. The observed spectral effects of silver nanoparticles on tryptophan fluorescence indicates the possibility for the design of analytical tools for the detection of proteins without traditional labeling by extrinsic fluorophores.     

Intrinsic fluorescence of succinyl-CoA synthetase and four tryptophan mutants. Tryptophan 76 and tryptophan 248 of the beta-subunit are responsive to CoA binding

Previous studies showed that modification of an average of one of the three tryptophan residues of succinyl-CoA synthetase of Escherichia coli abolished enzyme activity, but did not prevent phosphorylation of the enzyme by ATP [Ybarra, J., Prasad, A. R. S., & Nishimura, J.S. (1986) Biochemistry 25, 7174-7178]. In the present study, single mutations in which each of the three tryptophans (beta-Trp43, beta-Trp76, and beta-Trp248) has been changed to phenylalanine (designated W43F, W76F, and W248F) have been accomplished by the technique of site-directed mutagenesis and the mutant proteins isolated. In addition, a double mutant in which beta-Trp43 and beta-Trp248 were changed to phenylalanines (W43,248F) has also been isolated. Each of the mutant enzymes was practically as active as wild type. Since the emission spectrum of beta-Trp76 reflected a low fluorescence intensity for this residue, it was possible to obtain the emission spectrum of each tryptophan residue by using W43F, W248F, and W43,248F. From the positions of the emission maxima and the results of iodide quenching of fluorescence, it was deduced that beta-Trp248 is a surface residue, beta-Trp43 is buried, and beta-Trp76 is intermediate in location. Coenzyme A, but no other substrate, protected the fluorescence of beta-Trp76 and beta-Trp248, but not of beta-Trp43, against quenching by acrylamide. These results are consistent with an interaction between beta-Trp76 and beta-Trp248 and the binding site for CoA.     

Resolution of fluorescence intensity decays of the two tryptophan residues in glutamine-binding protein from Escherichia coli using single tryptophan mutants.

Time correlated single photon counting measurements of tryptophan (Trp) fluorescence intensity decay and other spectroscopic studies were performed on glutamine-binding protein (GlnBP) from Escherichia coli. Using site-specifically mutated forms of the protein in which tyrosine (Tyr) and phenylalanine (Phe) substitute for the Trp residues at positions 32 and 220, we have examined whether wild-type (Wtyp) intensity decay components may be assigned to specific Trp residues. Results indicate that: (a) two exponential intensity decay components are recovered from the Wtyp protein (6.16 ns, 0.46 ns); (b) the long decay component arises from Trp-220 and comprises greater than 90% of the total fluorescence emission; (c) the short component arises from Trp-32 and is highly quenched; (d) all four single-Trp mutants exhibit multiexponential intensity decays, yet equimolar mixtures of two single-Trp mutants yield only two decay components which are virtually indistinguishable from the Wtyp protein; (e) the recovery of additional components in protein mixtures is obscured by statistical noise inherent in the technique of photon counting; (f) various spectroscopic measurements suggest that Trp-Trp interactions occur in the Wtyp protein, but the Wtyp intensity decay may be closely approximated by a linear combination of intensity decays from single-Trp mutants; and (g) inferences derived independently from fluorescence and NMR spectroscopy which pertain to the presence of Trp-Trp interactions and the relative solvent exposure of the two Trp residues are in agreement.     

Multisite fluorescence in proteins with multiple tryptophan residues. Apomyoglobin natural variants and site-directed mutants

Time-resolved fluorescence experiments were carried out on a variety of apomyoglobins with one or two tryptophan (Trp) residues located at invariant positions 7 and 14 in the primary sequence. In all cases, the Trp fluorescence kinetics were resolved adequately into two discrete lifetime domains, and decay-associated spectra (DAS) were obtained for each decay component. The DAS resolved for unfolded proteins were indistinguishable by position of the emission maxima and the spectral shapes. The folded proteins revealed noticeable differences in the DAS, which relate to the diverse local environments around the Trp residues in the individual proteins. Furthermore, the DAS of wild-type protein possessing two Trp residues were simulated well by that of one Trp mutants either in the native, molten globule, or unfolded states. Overall, employing Trp fluorescence and site-directed mutagenesis allowed us to highlight the conformational changes induced by the single amino acid replacement and generate novel structural information on equilibrium folding intermediates. Specifically, it was found that conformational fluctuations in the local cluster around the evolutionarily conserved Trp(14) are very similar in the native and molten globule states of apomyoglobins. This result indicates that residues in the E and B helices contributing to this cluster are most likely involved in the stabilization of the overall architecture of the structured molten globule intermediate.