The Steady State and Time-resolved Fluorescence Studies on the Lysozyme-Ligand Interaction

The conformational change of hen egg-white lysozyme (EC 3.2.1.17) induced by the interaction with tri-N-acetyl-D-glucosamine were investigated by steady state and time-resolved fluorescence spectroscopy. To identify more clearly the conformation of hen egg-white lysozyme interacting with the ligand, the fluorescence decay kinetics of the lysozyme and its complex with the ligand were precisely measured at their full spectral regions. The spectral analysis based on the time-resolved studies showed that the binding of the ligand affected not only the Trp62 directly linked to the ligand but its influence was extended to the vicinity of Trp108 and further to the hydrophobic matrix box region. Near the binding site, the intramolecular distance between Trp108 and Glu35 was expanded or contracted depending on the pH of the buffer solution. On the other hand, the interaction of Trp28 and/or Trp111 with their surroundings was reduced by restriction of fluctuational motions at the hydrophobic matrix box region.     

Dipole–dipole interactions between tryptophan side chains and hydration water molecules dominate the observed dynamic stokes shift of lysozyme

The fluorescence intensity of tryptophan residues in hen egg-white lysozyme was measured up to 500 ps after the excitation by irradiation pulses at 290 nm. From the time-dependent variation of fluorescence intensity in a wavelength range of 320–370 nm, the energy relaxation in the dynamic Stokes shift was reconstructed as the temporal variation in wavenumber of the estimated fluorescence maximum. The relaxation was approximated by two exponential curves with decay constants of 1.2 and 26.7 ps. To interpret the relaxation, a molecular dynamics simulation of 75 ns was conducted for lysozyme immersed in a water box. From the simulation, the energy relaxation in the electrostatic interactions of each tryptophan residue was evaluated by using a scheme derived from the linear response theory. Dipole–dipole interactions between each of the Trp62 and Trp123 residues and hydration water molecules displayed an energy relaxation similar to that experimentally observed regarding time constants and magnitudes. The side chains of these residues were partly or fully exposed to the solvent. In addition, by inspecting the variation in dipole moments of the hydration water molecules around lysozyme, it was suggested that the observed relaxation could be attributed to the orientational relaxation of hydration water molecules participating in the hydrogen-bond network formed around each of the two tryptophan residues.     

Evidence for the involvement of tryptophan 38 in the active site of glutathione S-transferase P.

Glutathione S-transferase P (GST-P) exists as a homodimeric form and has two tryptophan residues, Trp28 and Trp38, in each subunit. In order to elucidate the role of the two tryptophan residues in catalytic function, we examined intrinsic fluorescence of tryptophan residues and effect of chemical modification by N-bromosuccinimide (NBS). The quenching of intrinsic fluorescence was observed by the addition of S-hexylglutathione, a substrate analogue, and the enzymatic activity was totally lost when single tryptophan residue was oxidized by NBS. To identify which tryptophan residue is involved in the catalytic function, each tryptophan was changed to histidine by site-directed mutagenesis. Trp28His GST-P mutant enzyme showed a comparable enzymatic activity with that of the wild type one. Trp38His mutant neither was bound to S-hexylglutathione-linked Sepharose nor exhibited any GST activity. These findings indicate that Trp38 is important for the catalytic function and substrate binding of GST-P.     

Raman spectroscopic characterization of tryptophan side chains in lysozyme bound to inhibitors: role of the hydrophobic box in the enzymatic function.

The state of H-bonding and the hydrophobic interaction of six tryptophan side chains in lysozyme bound to substrate-analogous inhibitors were investigated by combining H----D exchange labeling and Raman difference spectroscopy. The frequency of the W17 band due to Trp-63 shifts downward upon inhibitor binding, indicating a specific and strong H-bond formation between the N1 site of the side chain and the inhibitor molecule. On the other hand, the H-bonding state of Trp-62 in the complex is as weak as that in inhibitor-free lysozyme, suggesting no contribution of this residue to the inhibitor binding. Intensity increases of W17 and W18 bands observed upon inhibitor binding are, respectively, ascribed to an increase at Trp-28 and a decrease at Trp-111 in hydrophobic interactions with the environment. The environmental changes are explained consistently by a movement of the Met-105 side chain sandwiched by two indole rings of Trp-28 and 111 in the direction from Trp-111 to Trp-28. The sandwich structure in a core domain, hydrophobic box, and its rearrangement are considered to play an important role in the enzymatic function of lysozyme.     

Properties of the tryptophan residue in rabbit liver microsomal cytochrome P-450 isozyme 2 as determined by fluorescence

Cytochrome P-450 isozyme 2 from rabbit liver microsomes fluoresces upon excitation at 295 nm due to the single tryptophyl residue (Trp121) in the protein. The fluorescence spectrum, which is not altered by the presence of phospholipid or substrates, has a maximum at 335 nm, which suggests that the environment of the residue is hydrophobic. The fluorescence intensity decreases linearly with increase of specific content of the cytochrome preparations, and the holoenzyme was estimated to exhibit, at most, 6% as much fluorescence as the apoenzyme. This indicates that the fluorescence of the tryptophan is quenched by energy transfer to the heme. The distance between the tryptophyl residue and the heme was estimated to be less than 40 A. From enhancement of the fluorescence by methanol and ethanol, 30 to 50% of the Trp residue was found to be accessible to these solvents. On the other hand, the accessibility to iodide and cesium ions, as estimated by quenching effects, is less than 14%. From such evidence, the tryptophyl residue is believed to be partly buried. Since Trp121 is conserved at or near the same position in all mammalian P-450's so far sequenced, the results obtained may be applicable to these related cytochromes as well.     

Structural analysis of the operator binding domain of Tn10-encoded Tet repressor: a time-resolved fluorescence and anisotropy study.

An engineered Tn10-encoded Tet repressor, bearing a single Trp residue at position 43, in the putative alpha-helix-turn-alpha-helix motif of the operator binding domain, was studied by time-resolved fluorescence and anisotropy. Fluorescence intensity decay data suggested the existence of two classes of Trp-43, defined by different lifetimes. Analysis of anisotropy data were consistent with a model in which each class was defined by a different lifetime, rotational correlation time, and fluorescence emission maximum. The long-lifetime class had a red-shifted spectrum, similar to that of tryptophan zwitterion in water, and a short rotational correlation time. In contrast, the spectrum of the short-lifetime class was blue-shifted 10 nm compared to that of the long-lifetime class. Its correlation time was similar to that of the protein, which showed that Trp in this class was entirely constrained. Trp in this latter class could not be quenched by iodide, whereas most of the long-lifetime class was easily accessible. Presence of disruptive agents, such as 1 M GuCl or 3 M KCl, did not alter markedly the lifetimes but increased the weight of the short-lifetime component. In the same time, the rotational correlation time of this component was dramatically reduced. Taken together, our data suggest that the long-lifetime class could correspond to the tryptophan residues exposed to solvent whereas the short-lifetime class would correspond to the tryptophan residues embedded inside the hydrophobic core holding the helix-turn-helix motif. Destabilization of hydrophobic interactions would lead to an increase in the weight of the latter class for entropic reasons. Analysis of the fluorescence parameters of Trp-43 could provide structural information on the operator binding domain of Tet repressor.     

Hydrogen-deuterium exchange of the tryptophan residues in bovine α-lactalbumin

Effects of deuteration on the Raman spectrum of a tryptophan residue have been examined. The 1386 cm^?1 line of deuterated tryptophan residue has been found to be useful for tracing the hydrogen-deuterium exchange reaction of this residue in a protein. An examination on bovine α-lactalbumin at pH 6.4 and at 20°C indicates that two of the four tryptophan residues exchange with a rate constant much greater than 9 × 10^?4 sec^?1, while the other two exchange with a rate constant of 4 × 10^?5 sec^?1. The latter two have been assigned to Trp 28 and Trp 108 of this protein. The kinetics of hydrogen-deuterium exchange reaction of completely “free” tryptophan residue have been examined by a proton magnetic resonance study on tryptophan itself. By taking the result of this examination into account, the chance of exposure to the solvent for Trp 28 or Trp 108 has been estimated to be 3 × 10^?6 at pH 6.4 and at 20°C.     

Interaction of tyrosine 65 of RecA protein with the first and second DNA strands

We investigated the structure of the active RecA-DNA complex by analyzing the environment of tyrosine residue 65, which is on the DNA-binding surface of the protein. We prepared a modified RecA protein in which the tyrosine residue was replaced by tryptophan, a natural fluorescent reporter, and measured the change in its fluorescence upon binding of DNA and cofactor. The fluorescence of the inserted tryptophan 65 (Trp65) was centered at 345 nm, indicating a partly exposed residue. Binding cofactor, adenosine 5'-O-3-thiotriphosphate (ATPgammaS), alone at a low salt concentration did not change the fluorescence of Trp65, confirming that the residue is not close to the nucleotide. In contrast, the binding of single-stranded DNA quenched the fluorescence of Trp65 in both the presence and absence of ATPgammaS. Trp65 fluorescence was also quenched upon binding a second DNA strand. The fluorescence change depended upon the presence and absence of ATPgammaS, reflecting the difference in the DNA binding. These results indicate that residue 65 is close to both the first and second DNA strands. The degree of quenching depended upon the base composition of DNA, suggesting that the residue 65 interacts with the DNA bases. Binding of DNA with ATPgammaS as well as binding of ATPgammaS alone at high salt concentration shifted the fluorescence emission peak from 345 to 330 nm, indicating a change from a polar to a non-polar environment. Therefore, the environment change around residue 65 would also be linked to a change in conformation and thus the activation of the protein.     

Spectral properties of Trp182, Trp194, and Trp250 on the alpha subunit of bacterial luciferase.

The phosphorescence and fluorescence properties of bacterial luciferase (alphabeta) mutants from Xenorhabdus luminescens were investigated. All tryptophans in the alpha and beta subunits were replaced with tyrosines except for one or two tryptophans in the alpha subunit. Because one luciferase mutant (W250) retained only a single tryptophan in the alpha subunit while two other mutants (W182/250 and W194/250) each contained two tryptophans in the alpha subunit, it was possible to deduce the spectral properties of these specific tryptophans (Trp182, Trp194, Trp250). Analyses of the phosphorescence properties were particularly revealing as only a single phosphorescence emission peak at 411-414 nm was observed for the W250 and W194/250 mutants while peaks at 409 and 414 nm could be clearly observed for the W182/250 mutant. Coupled with intrinsic fluorescence quenching experiments, these results show that alphaTrp182 is in a distinctly polar environment while alphaTrp250 is in a hydrophobic region and illustrate the advantages of using phosphorescence to recognize different microenvironments for tryptophan residues.     

A rare protein fluorescence behavior where the emission is dominated by tyrosine: case of the 33-kDa protein from spinach photosystem II

An abnormal fluorescence emission of protein was observed in the 33-kDa protein which is one component of the three extrinsic proteins in spinach photosystem II particle (PS II). This protein contains one tryptophan and eight tyrosine residues, belonging to a "B type protein". It was found that the 33-kDa protein fluorescence is very different from most B type proteins containing both tryptophan and tyrosine residues. For most B type proteins studied so far, the fluorescence emission is dominated by the tryptophan emission, with the tyrosine emission hardly being detected when excited at 280 nm. However, for the present 33-kDa protein, both tyrosine and tryptophan fluorescence emissions were observed, the fluorescence emission being dominated by the tyrosine residue emission upon a 280 nm excitation. The maximum emission wavelength of the 33-kDa protein tryptophan fluorescence was at 317 nm, indicating that the single tryptophan residue is buried in a very strong hydrophobic region. Such a strong hydrophobic environment is rarely observed in proteins when using tryptophan fluorescence experiments. All parameters of the protein tryptophan fluorescence such as quantum yield, fluorescence decay, and absorption spectrum including the fourth derivative spectrum were explored both in the native and pressure-denatured forms.     

Intrinsic tryptophans of CRABPI as probes of structure and folding.

The native state fluorescence and CD spectra of the predominantly beta-sheet cellular retinoic acid-binding protein I (CRABPI) include contributions from its three tryptophan residues and are influenced by the positions of these residues in the three-dimensional structure. Using a combination of spectroscopic approaches and single Trp-mutants of CRABPI, we have deconvoluted these spectra and uncovered several features that have aided in our analysis of the development of structure in the folding pathway of CRABPI. The emission spectrum of native CRABPI is dominated by Trp 7. Trp 109 is fluorescence-silent due to its interaction with the guanidino group of Arg 111. Although the far-UV CD spectrum of CRABPI is largely determined by the protein's secondary structure, aromatic clustering around Trp 87 and the aromatic-charge interaction between Arg 111 and Trp 109 give rise to a characteristic feature in the CD spectrum at 228 nm. The near-UV CD bands of CRABPI arise largely from additive contributions of the three tryptophan residues. Trp 7 and Trp 87 give a negative CD band at 275 nm. The near-UV CD band from Trp 109 is positive and shifted to longer wavelengths (to 302 nm) due to the charge-aromatic interaction between Arg 111 and Trp 109. Our deconvolution of the equilibrium spectra have been used to interpret kinetic folding experiments monitored by stopped-flow fluorescence. These dynamic experiments suggest the early evolution of a well-populated, hydrophobically collapsed intermediate, which undergoes global rearrangement to form the fully folded structure. The results presented here suggest several additional strategies for dissecting the folding pathway of CRABPI.     

Use of fluorescence energy transfer to characterize the compactness of the constant fragment of an immunoglobulin light chain in the early stage of folding

The CL fragment of a type-kappa immunoglobulin light chain in which the C-terminal cysteine residue was modified with N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine (CL-AEDANS fragment) was prepared. This fragment has only one tryptophan residue at position 148. The compactness of the fragment whose intrachain disulfide bond was reduced in order for the tryptophan residue to fluoresce (reduced CL-AEDANS fragment) was studied in the early stages of refolding from 4 M guanidine hydrochloride by fluorescence energy transfer from Trp 148 to the AEDANS group. The AEDANS group attached to the SH group of a cysteine scarcely fluoresced when excited at 295 nm. For the reduced CL-AEDANS fragment, the fluorescence emission band of the Trp residue overlapped with the absorption band of the AEDANS group, and the fluorescence energy transfer was observed between Trp 148 and the AEDANS group in the absence of guanidine hydrochloride. In 4 M guanidine hydrochloride, the distance between the donor and the acceptor was larger, and the efficiency of the energy transfer became lower. The distance between Trp 148 and the AEDANS group for the intact protein estimated by using the energy-transfer data was in good agreement with that obtained by X-ray crystallographic analysis. By the use of fluorescence energy transfer, tryptophyl fluorescence, and circular dichroism at 218 nm, the kinetics of unfolding and refolding of the reduced fragment were studied. These three methods gave the same unfolding kinetic pattern. However, the refolding kinetics measured by fluorescence energy transfer were different from those measured by tryptophyl fluorescence and circular dichroism, the latter two giving the same kinetic pattern.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 uncoupling protein from brown adipose tissue mitochondria. The environment of the tryptophan residues as revealed by quenching of the intrinsic fluorescence.

The uncoupling protein from brown adipose tissue is a member of the family of metabolite carriers of the mitochondrial inner membrane. It contains two tryptophan residues which have been characterized by fluorescence spectroscopy. Application of fluorescence-quenching-resolved spectroscopy (FQRS) allowed the determination of the emission maximum for each residue, both of which occur at 332 nm, thus suggesting that they are both located in a non-polar environment. Fluorescence quenching has demonstrated that both residues are accessible to acrylamide and inaccessible to Cs+, while only one of them is accessible to I-. When FQRS is combined with guanidinium hydrochloride denaturation, the unfolding of the regions containing each tryptophan can be monitored separately as they are transferred to the polar medium where the emission maximum appears at 359 nm, revealing also that the iodide-accessible residue is more sensitive to the denaturant. Secondary structure predictions, together with the data presented here, suggest that the iodide-accessible residue could correspond to Trp173 and the denaturant-resistant iodide-inaccessible one to Trp280, located in the center of the sixth transmembrane alpha-helix. Interaction of the protein with GDP (a transport inhibitor) has been studied and has revealed that it partially shields Trp173 from the interaction with I-, as well as reducing the static component of the acrylamide quenching.     

Fluorescence quenching studies of Trp repressor using single-tryptophan mutants

Time-resolved and steady-state fluorescence have been used to resolve the heterogeneous emission of single-tryptophan-containing mutants of Trp repressors W19F and W99F into components. Using iodide as the quencher, the fluorescence-quenching-resolved spectra (FQRS) have been obtained The FQRS method shows that the fluorescence emission of Trp99 can be resolved into two component spectra characterized by maxima of fluorescence emission at 338 and 328 nm. The redder component is exposed to the solvent and participates in about 21% of the total fluorescence emission of TrpR W19F. The second component is inacessible to iodide, but is quenched by acrylamide. The tryptophan residue 19 present in TrpR W99F can be resolved into two component spectra using the FQRS method and iodide as a quencher. Both components of Trp19 exhibit similar maxima of emission at 322–324 nm and both are quenchable by iodide. The component more quenchable by iodide participates in about 38% of the total TrpR W99F emission. The fluorescence lifetime measurements as a function of iodide concentration support the existence of two classes of Trp99 and Trp19 in the Trp repressor. Our results suggest that the Trp aporepressor can exist in the ground state in two distinct conformational states which differ in the microenvironment of the Trp residues.Abbreviations TrpR tryptophan aporepressor fromE. coli - TrpR W19F TrpR mutant with phenylalanine substituted for tryptophan at position 19 - TrpR W99F TrpR mutant with phenylalanine substituted for tryptophan at position 99 - FQRS fluorescence-quenching-resolved spectra - FPLC fast protein liquid chromatography     

慈菇蛋白酶抑制剂A和B中Trp残基周围构象与酶抑制专一性的关系

通过定点诱变结合荧光光谱学方法研究了慈菇蛋白酶抑制剂A和B(APIA和APIB)Trp残基周围构象与酶抑制专一性之间的关系。研究表明APIB中的两个Trp残基 (93和 12 2位 )所处环境的疏水性要比APIA中的强。Trp定点诱变研究表明 ,在APIB中 ,Trp12 2 周围环境的疏水性要比Trp93 强。用Ser和Leu分别替代 82位Leu和 87位Arg ,使APIB中色氨酸荧光特性变得与APIA的基本相同 ,同时还发现其酶的抑制专一性也变得趋近APIA的 ,暗示Trp周围的构象与酶抑制剂的抑制专一性有关。     

Chemical modification of tryptophan residues and stability changes in proteins

The role of tryptophan residues in the stability of proteins was studied by ozone oxidation, which causes a small change in the tryptophan side chain. Trp 187 of the constant fragment of a type lambda immunoglobulin light chain, Trp 59 of ribonuclease T1, and Trp 62 of hen egg white lysozyme were oxidized specifically by ozone to N'-formylkynurenine or kynurenine. Judging from their circular dichroic and fluorescence spectra, these modified proteins were found to be the same as those of the respective intact proteins. However, even the slight modification of a single tryptophan residue produced a large decrease in the stability of these proteins to guanidine hydrochloride and heat. The smaller the extent of exposure of the tryptophan residue, the greater the effect of the modification on the stability. The formal kinetic mechanism of unfolding and refolding by guanidine hydrochloride of the CL fragment was not altered by tryptophan oxidation, but the rate constants for unfolding and refolding changed. The thermal unfolding transitions were analyzed to obtain the thermodynamic parameters. The enthalpy and entropy changes for the modified proteins were larger than the respective values for the intact proteins.     

Intrinsic fluorescence of a truncated Bordetella pertussis adenylate cyclase expressed in Escherichia coli

A truncated, 432 residue long, Bordetella pertussis adenylate cyclase expressed in Escherichia coli was analyzed for intrinsic fluorescence properties. The two tryptophans (Trp69 and Trp242) of adenylate cyclase, each situated in close proximity to residues important for catalysis or binding of calmodulin (CaM), produced overlapping fluorescence emission bands upon excitation at 295 nm. CaM, alone or in association with low concentrations of urea, induced important modifications in the spectra of adenylate cyclase such as shifts of the maxima and change in the shape of the bands. From these changes and from the fluorescence spectrum of a modified form of adenylate cyclase, in which a valine residue was substituted for Trp242, it was deduced that, upon binding of CaM to the wild-type adenylate cyclase, only the environment of Trp242 was affected. The fluorescence maximum of this residue, which is more exposed to the solvent than Trp69 in the absence of CaM, is shifted by 13 nm to shorter wavelength upon interaction of protein with its activator. Trypsin cleaved adenylate cyclase into two fragments, one carrying the catalytic domain, and the second carrying the CaM-binding domain (Ladant et al., 1989). The isolated peptides conserved most of the environment around their single tryptophan residues, as in the intact adenylate cyclase, which suggests that the two domains of truncated B. pertussis adenylate cyclase also conserved most of their three-dimensional structure in the isolated forms.     

Effect of chemical modifications of tryptophan residues on the folding of reduced hen egg-white lysozyme

The effects of chemical modifications of Trp62 and Trp108 on the folding of hen egg-white lysozyme from the reduced form were investigated by means of the sulfhydryl-disulfide interchange reaction at pH 8 and 40 degrees C. The folding of reduced lysozyme was monitored by following the recovery of the original activity. Under the conditions employed, the apparent first-order rate constant for the folding of reduced lysozyme was not changed by the modifications of both Trp62 and Trp108 and the folding was completed within 30 min. However, the extent of the correct folding was changed by the modification of Trp62 but not by that of Trp108. Native and oxindolealanine108 lysozymes recovered 80 and 81% of their original activities after 30-min refolding, respectively, but Trp62-modified lysozymes recovered their activities to a lesser extent than native and oxindolealanine108 lysozymes. The recovered activities of Trp62-modified lysozymes after 30-min refolding were 63% for oxindolealanine62 lysozyme, 65% for delta 1-carboxamidomethylthiotryptophan62 lysozyme, and 52% for delta 1-carboxymethylthiotryptophan62 lysozyme. These results suggest that Trp62 is important for preventing the misfolding of reduced lysozyme, but that neither Trp62 nor Trp108 is involved in the rate-determining step (the slowest step) in the folding pathway. A decrease in the hydrophobic nature of Trp62 seems to increase the misfolding and thus to decrease the extent of the correct folding of reduced lysozyme. A mechanism for the involvement of Trp62 in the folding pathway of reduced lysozyme is proposed.     

Structural organization of the N-terminal domain of apolipoprotein A-I: studies of tryptophan mutants

Site-directed mutagenesis and detailed fluorescence studies were used to study the structure and dynamics of recombinant human proapolipoprotein (proapo) A-I in the lipid free state and in reconstituted high-density lipoprotein (rHDL) particles. Five different mutants of proapoA-I, each containing a single tryptophan residue, were produced in bacteria corresponding to each of the naturally occurring Trp residues (position -3 in the pro-segment, 8, 50, 72, and 108) in the N-terminal half of the protein. Structural analyses indicated that the conservative Phe-Trp substitutions did not perturb the conformation of the mutants with respect to the wild-type protein. Steady-state fluorescence studies indicated that all of the Trp residues exist in nonpolar environments that are highly protected from solvent in both the lipid-free and lipid-bound forms. Time-resolved lifetime and anisotropy studies indicated that the shape of the monomeric form of proapoA-I is a prolate ellipsoid with an axial ratio of about 6:1. In addition, the region surrounding Trp 108 appears to be more mobile than the rest of the protein in the lipid-free state. However, in rHDL particles, no significant domain motion was detected for any of the Trp residues. The results presented in this work are consistent with a model for monomeric lipid-free proapoA-I in which the N-terminal half of the molecule is organized into a bundle of helices.