Internal motion of lysozyme studied by time-resolved fluorescence depolarization of tryptophan residues.

The internal motion of lysozyme was described by the steady-state and time-resolved fluorescence anisotropy of its tryptophan residues. The fluorescence of mutant lysozymes W62Y- and W108Y-lysozyme, in which Trp62 or Trp108 of hen egg white lysozyme was replaced with a tyrosine residue, could be respectively assigned to Trp108 or Trp62 at the longer wavelength region of the total fluorescence spectrum. The segmental motion of Trp62 as shown by its fluorescence anisotropy decay was described with two components originating from the fluctuational rotation of an indole moiety about the Calpha-Cbeta bond and rotational wobble of the peptide segment adjacent to Trp62. Although Trp62 showed a high degree of motional freedom, its motion was significantly suppressed by the interaction of the mutant protein with a trimer of N-acetyl-D-glucosamine. By contrast, the segmental motion of Trp108 is hindered by the local cage structure at temperatures below 30 degreesC, but Relief from restricted motion occurred on the formation of ligand complex or by thermal agitation. Because of overlaps of the fluorescence spectrum, it is difficult to assign the segmental motion of Trp28 or Trp111, the other two tryptophan residues in lysozyme. However, a careful analysis of the fluorescence anisotropy decay of W62Y- and W108Y-lysozyme showed that the fluctuation of the hydrophobic matrix box was greater than that expected from lysozyme's crystal structure, although it was suppressed by the binding of the ligand to the active site of lysozyme.

Preparation of enantiomerically pure L-7-azatryptophan by an enzymatic method and its application to the development of a fluorimetric activity assay for tryptophanyl-tRNA synthetase.

The reaction of D,L-7-azatryptophan (D,L-7AW) with tryptophanyl-tRNA synthetase (TrpRS), adenosine triphosphate (ATP), and Mg2+ in the presence of inorganic pyrophosphatase results in the formation of a highly fluorescent l-7AW-adenylate complex. Detection of this complex is based on its enhanced fluorescence at 315 nm excitation and 360 nm emission after the addition of ATP. This stereoselective reaction was used to develop an activity assay for TrpRS using commercially available racemic D,L-7AW. The assay can be used to determine the activity of TrpRS from samples which contain less than 1 nmol of enzyme in 250 microL of sample. Thus the enzyme activity can be assessed without resorting to a radioactive assay of tRNATrp acylation. A secondary use of the stereoselective assay was for confirming the presence of pure L-7AW, D-7AW, or mixtures of the two enantiomers. D-7AW and L-7AW were prepared by reacting D,L-7AW with chloroacetic anhydride to form N-chloroacetyl-D,L-7AW (ClAc-7AW) followed by stereospecific proteolytic digestion of ClAc-7AW using carboxypeptidase A to produce the free L-7AW. The L-7AW could be separated from unreacted N-chloroacetyl-7AW by reverse-phase HPLC. The TrpRS-based assay was able to unambiguously discriminate between the two enantiomers of 7AW. The assay was then used to identify which enantiomer of 7AW was present in resolved fractions of the tripeptide L-lysyl-D,L-7-azatryptophyl-L-lysine. Digestion of the resolved tripeptides with protease enzymes produced the free L or D enantiomer of 7AW, which was easily identified using the TrpRS assay procedure.

Identification of a chameleon-like pH-sensitive segment within the colicin E1 channel domain that may serve as the pH-activated trigger for membrane bilayer association.

In vitro, the channel-forming domain of colicin E1 requires activation by acidic pH (<4.5) or detergents. The activation of this domain to its insertion-competent state results in an increased ability of the protein to dock onto and to form channels in artificial membranes. Fluorescence methods were used to characterize the conformational changes occurring in a channel-forming peptide of colicin E1 in solution with pH. The 178-residue thermolytic fragment of colicin E1 contains three Trp residues, W-424, W-460, and W-495. In order to study the structural and dynamic requirements for activation of the C-terminal domain of colicin E1, single-Trp-containing peptides were prepared by site-directed mutagenesis. All of the mutant peptides displayed in vitro channel activity and cellular cytotoxicity similar to the those of wild-type peptide. Two Trp residues, W-413 and W-424, exhibited pH-sensitive fluorescence parameters. Upon acidification (pH 6.0 --> 3.5), the fluorescence quantum yield of W-413 and W-424 increased 50% and 80%, respectively, indicating a significant change in the local environment of the peptide segment containing these two Trp residues. The fluorescence decay of W-413 and W-424 was best fit by three fluorescence decay components, two of which were sensitive to pH. However, only small changes in spectral shape and position were observed for W-424 fluorescence, whereas there were larger changes in these fluorescence parameters for W-413. The quantum yields for the Trp residues in the seven other single-Trp mutant peptides and the wild-type peptide were distinct but only slightly affected by changes in pH. Time-resolved fluorescence measurements showed that W-460, -484, and -495 each had two fluorescence decay components with similar decay times, with one component dominating the fluorescence decay behavior. Furthermore, the individual fluorescence decay times for all the single-Trp peptides, except for W-413 and W-424, were insensitive to pH changes. At pH 3.5, the fluorescence of the wild-type peptide was fit by three decay time components, with the two longer decay times being quite different from the fluorescence decay times of the single-Trp mutant proteins (W-424, -460, and -495, the naturally occurring Trp residues). In contrast, at pH 6.0, the wild-type peptide showed double-exponential decay kinetics. Time-resolved fluorescence anisotropy decay measurements of the three single-Trp mutant proteins, containing a naturally occurring Trp residue, suggest that local segmental motion of the peptide as reported by each of the three tryptophans is highly restricted and largely insensitive to changes in pH. On the other hand, the anisotropy decay profiles of the wild-type protein were consistent with energy transfer occurring between Trp residues, likely between W-460 and W-495. These steady-state and time-resolved fluorescence results show that W-413 and W-424 report conformational changes which may be associated with the insertion-competent state and reside on the protein segment(s) which form the pH-activated trigger of the channel peptide.

Primary sequence and refined tertiary structure of Pseudomonas fluorescens holo azurin at 2.05 A.

This paper reports the primary sequence and refined crystal structure of Pseudomonas fluorescens holoazurin. The crystal structure has been determined by molecular replacement on the basis of the molecular model of azurin from Alcaligenes denitrificans, and refined by the method of molecular dynamics simulation and energy-restrained least-squares methods. P. fluorescens was crystallized in the orthorhombic space group P2(1)2(1)2(1) with unit-cell dimensions a = 31.95, b = 43.78, c = 78.81 A. The asymmetric unit is composed of only one molecule. The final R value is 16.7% for 6691 reflections to a resolution of 2.05 A. This azurin structure shows some interesting features at His35 and His83. Part of the main chain of strand 3 including His35 O are involved in the contact between two symmetrically related molecules. P. fluorescens is also compared with the other azurin structures in terms of primary sequence, crystal packing, solvent structure and Cu-site geometry. The difference in fluorescence decay behavior of two holoazurins from P. fluorescens and P. aeruginosa and the correlation between the fluorescence quenching and electron transfer are discussed.

Site-specific replacement of amino acid residues in the CD site of rat parvalbumin changes the metal specificity of this Ca2+/Mg(2+)-mixed site toward a Ca(2+)-specific site.

Rat parvalbumin (PV) and oncomodulin (OM) display considerable sequence similarity and structural similarity, but differ in the affinity and selectivity of metal binding to their CD site, a Ca2+/Mg(2+)-mixed site in PV and a Ca(2+)-specific site in OM. In an attempt to identify the structural basis for these differences, mutations were introduced in the previously generated [W102]PV mutant, which contains a unique tryptophan as a conformational-sensitive fluorescent probe inside the hydrophobic core. In the present report, we substituted selected amino acid residues in the CD site of PV by those present at identical positions in OM. One mutant protein, named [F66, W102]PV, has one new substitution in which isoleucine at position 66 was exchanged by phenylalanine. The second mutant protein, [I46, I50, L58, F66, W102]PV, has four new substitutions, namely V46-->I, L50-->I, I58-->L and I66-->F. Tryptophan fluorescence and difference spectrophotometry indicated that the mutations do not alter significantly the hydrophobic core. Both mutant proteins display two metal-binding sites of identical affinities with intrinsic affinity constants K'Ca2+ of 2.9 x 10(7) M-1 for [F66, W102]PV and 1.7 x 10(7) M-1 for [I46, I50, L58, F66, W102]PV and K'Mg2+ of 3.1 x 10(4) M-1 for [F66, W102]PV and 1.9 x 10(4) M-1 for [I46, I50, L58, F66, W102]PV. Thus, the five-residue substitution, but not the two-residue one, leads to a small decrease of affinity compared to [W102]PV (K'Ca2+ = 2.7 x 10(7) M-1, K'Mg2+ = 4.4 x 10(4) M-1). Despite these similarities, the Mg2+ effect on Ca2+ binding is different for the two mutant parvalbumins: the Ca(2+)-binding isotherms of [F66, W102]PV undergo a parallel shift upon increasing Mg2+ concentrations, which indicates that the Mg2+ effect on the two Ca(2+)-binding sites is the same and quantitatively very similar to that described for [W102]PV. In [I46, I50, L58, F66, W102]PV, Mg2+ antagonizes the binding of the second Ca2+ (likely at the EF site) much more than that of the first Ca2+ (likely the CD site). According to the competition equation, the two sites display KMg2+.compet values of 390 M-1 and 3.9 x 10(3) M-1, respectively. These data indicate that (a) the single I66-->F mutation does not modify the cation binding parameters. (b) Multiple modifications in the hydrophobic core still do not change the affinity for Ca2+ and Mg2+, but strongly affect the Mg2+ antagonism and probably the selectivity of the CD site.

A concerted tryptophanyl-adenylate-dependent conformational change in Bacillus subtilis tryptophanyl-tRNA synthetase revealed by the fluorescence of Trp92.

A semi-conserved tryptophan residue of Bacillus subtilis tryptophanyl-tRNA synthetase (TrpRS) was previously asserted to be an essential residue and directly involved in tRNATrp binding and recognition. The crystal structure of the Bacillus stearothermophilus TrpRS tryptophanyl-5'-adenylate complex (Trp-AMP) shows that the corresponding Trp91 is buried and in the dimer interface, contrary to the expectations of the earlier assertation. Here we examine the role of this semi-conserved tryptophan residue using fluorescence spectroscopy. B. subtilis TrpRS has a single tryptophan residue, Trp92. 4-Fluorotryptophan (4FW) is used as a non-fluorescent substrate analog, allowing characterization of Trp92 fluorescence in the 4-fluorotryptophanyl-5'-adenylate (4FW-AMP) TrpRS complex. Complexation causes the Trp92 fluorescence to become quenched by 70%. Titrations, forming this complex under irreversible conditions, show that this quenching is essentially complete after half of the sites are filled. This indicates that a substrate-dependent mechanism exists for the inter-subunit communication of conformational changes. Trp92 fluorescence is not efficiently quenched by small solutes in either the apo- or complexed form. From this we conclude that this tryptophan residue is not solvent exposed and that binding of the Trp92 to tRNATrp is unlikely. Time-resolved fluorescence indicates conformational heterogeneity of B. subtilis Trp92 with the fluorescence decay being best described by three discrete exponential decay times. The decay-associated spectra (DAS) of the apo- and complexed-TrpRS show large variations of the concentration of individual fluorescence decay components. Based on recent correlations of these data with changes in the local secondary structure of the backbone containing the fluorescent tryptophan residue, we conclude that changes observed in Trp92 time-resolved fluorescence originate primarily from large perturbations of its local secondary structure. The quenching of Trp92 in the 4FW-AMP complex is best explained by the crystal structure conformation, in which the tryptophan residue is found in an alpha-helix. The amino acid residue cysteine is observed clearly within the quenching radius (3.6 angstroms) of the conserved tryptophan residue. These tryptophan and cysteine residues are neighbors, one helical turn apart. If this local alpha-helix was disrupted in the apo-TrpRS, this disruption would concomitantly relieve the putative cysteine quenching by separating the two residues. Hence we propose a substrate-dependent local helix-coil transition to explain both the observed time-resolved and steady-state fluorescence of Trp92. A mechanism can be further inferred for the inter-subunit communication involving the substrate ligand Asp132 and a small alpha-helix bridging the substrate tryptophan residue and the conserved tryptophan residue of the opposite subunit. This putative mechanism is also consistent with the observed pH dependence of TrpRS crystal growth and substrate binding. We observe that the mechanism of TrpRS has a dynamic component, and contend that conformational dynamics of aminoacyl-tRNA synthetases must be considered as part of the molecular basis for the recognition of cognate tRNA.

Steady-state and time-resolved fluorescence studies on the ligand-induced conformational change in an active lysozyme derivative, Kyn62-lysozyme.

The ligand-induced conformational change of an active lysozyme derivative, Kyn62-lysozyme, in which Trp62 of hen egg-white lysozyme (EC 3.2.1.17) was selectively modified to kynurenine, was investigated by steady-state and time-resolved fluorescence spectroscopy. Kyn62 formed an intramolecular energy transfer donor-acceptor pair with a tryptophan residue as a donor. The energy transfer was related to the conformation of the active site. The spectral overlap integral (J) of the kynurenine-tryptophan pair is large as it was determined to be 4.92 x 10(-15) M-1 cm3. Time-resolved fluorescence properties of Kyn62-lysozyme and its complex with a trimer of N-acetyl-D-glucosamine [(GlcNAc)3] show that the energy donor is Trp28 or Trp111 in the hydrophobic matrix box of the free Kyn62-lysozyme. In the complex, it appears that the kynurenine residue drastically changed its orientation or approached closer to Trp108 to accept more efficiently the excitation energy from Trp108 on the binding of Kyn62-lysozyme with (GlcNAc)3.

Probing local secondary structure by fluorescence: time-resolved and circular dichroism studies of highly purified neurotoxins.

The relationship between beta-sheet secondary structure and intrinsic tryptophan fluorescence parameters of erabutoxin b, alpha-cobratoxin, and alpha-bungarotoxin were examined. Nuclear magnetic resonance and x-ray crystallography have shown that these neurotoxins have comparable beta-sheet, beta-turn, and random coil secondary structures. Each toxin contains a single tryptophan (Trp) residue within its beta-sheet. The time-resolved fluorescence properties of native erabutoxin b and alpha-cobratoxin are best described by triple exponential decay kinetics, whereas native alpha-bungarotoxin exhibits more than four lifetimes. The disulphide bonds of each toxin were reduced to facilitate carboxymethylation and amidocarboxymethylation. The two different toxin derivatives of all three neurotoxins displayed triple exponential decay kinetics and were completely denatured as evidenced by circular dichroism (random coil). The concentration (c) values of the three fluorescence decay times (time-resolved fluorescence spectroscopy (TRFS)) were dramatically different from those of the native toxins. Each neurotoxin, treated with different concentrations of guanidinium hydrochloride (GuHCl), was studied both by circular dichroism and TRFS. Disappearance of the beta-sheet secondary structural features with increasing concentrations of GuHCl was accompanied by a shift in the relative contribution (c value) of each fluorescence decay time (TRFS). It was found that certain disulphide residues confer added stability to the beta-sheet secondary structure of these neurotoxins and that the center of the beta-sheet is last to unfold. These titrations show that Trp can be used as a very localized probe of secondary structure.

Active site-directed thrombin inhibitors: alpha-hydroxyacyl-prolyl-arginals. New orally active stable analogs of D-Phe-Pro-Arg-H.

D-alpha-Hydroxyacyl-prolyl-arginals have been designed and synthesized as orally active stable analogs of D-Phe-Pro-Arg-H, the active site-directed peptidyl thrombin inhibitor prototype. Many of the new analogs possess high in vitro anticoagulant activity while having little effect on fibrinolysis. Compounds GYKI-66104 (2), -66131 (3) and -66132 (5) effectively delay the clotting time in rabbits ex vivo and prevent thrombus formation in various thrombosis models in rabbits and rats when applied in a single oral dose of 5 mg kg-1.

Bifunctional fusion proteins consisting of a single-chain antibody and an engineered lanthanide-binding protein.

The combination of an antibody fragment with a lanthanide chelating protein has desirable characteristics for fluorescence-based immunoassays and tumor radioimmunotherapy. As a model for this design, a fusion protein consisting of a single-chain antibody linked to an engineered version of oncomodulin, a protein with two Ca(2+)-binding motifs (the CD and EF loops), was produced by secretion from Escherichia coli in good yield. The single-chain antibody was specific for a Salmonella O-polysaccharide. The CD loop of oncomodulin had been redesigned to bind lanthanide ions with high affinity. The fusion protein was shown to have antigen-binding activity that was comparable to that of the unfused single-chain antibody, to bind Tb3+ with very high affinity and to give strong, sensitized Tb3+ luminescence via excitation of the tryptophan residue in the CD loop. A second fusion protein containing a 30-residue helix-loop-helix motif as the lanthanide-binding component was also prepared, but showed considerably lower solubility. Competition for Tb3+ binding by a series of metal chelators indicated that the affinities of the oncomodulin and 30 residue fusions for Tb3+ were approximately 10(11) M-1 and 10(7) M-1, respectively. Time-resolved lanthanide luminescence photography of electrophoresis gels demonstrated that the helix-loop-helix Ca(2+)-binding could be used to specifically visualize the scFv fragment.

A protease assay using time-resolved lanthanide luminescence from an engineered calcium binding protein substrate.

OBJECTIVES: The objective of this work was to demonstrate the utility of luminescence from lanthanides bound to a mutant of the Ca2+ binding protein, oncomodulin, to monitor protease activity. DESIGN AND METHODS: A mutant of oncomodulin with a cysteine residue at position 57 located in the CD binding loop was conjugated to a salicylic acid group. The luminescence of Tb3+ resulting from electronic energy transfer from the salicylic acid group was monitored using time resolved lanthanide luminescence in the presence of proteolytic enzymes. RESULTS: Low detection limits for subtilisin (150 pg), chymotrypsin (2.5 ng), cathepsin B (3.5 ng), and HIV-1 protease (25 ng) were found. CONCLUSION: The simplicity of the assay coupled with its high level of sensitivity make it useful for the detection of protease at very low concentrations.

Location of diphenyl-hexatriene and trimethylammonium-diphenyl-hexatriene in dipalmitoylphosphatidylcholine bilayers by neutron diffraction.

Neutron scattering experiments have been performed on oriented dipalmitoylphosphatidylcholine (DPPC) bilayers containing diphenylhexatriene (DPH) or its trimethylammonium analog (TMA-DPH). DPH and TMA-DPH were either protonated or deuterated in one of the phenyl rings which afforded by using proton-deuterium contrast methods the location of these fluorescent probes in the model membrane. Both probes exhibit bimodal distributions in DPPC. The position, population and orientation in the two sites vary depending upon the physical state of the bilayer (gel or fluid) and the presence or absence of the TMA group. In gel (L beta') phase lipids DPH is located close and parallel to the bilayer surface (site I) and near the bilayer center, oriented at approximately 30 degrees with respect to the normal to the surface (site II). On going to the fluid (L alpha) phase, a distribution of orientations around the parallel to the surface is only observed for site II. Orientation of DPH in site I is unchanged. In the gel phase TMA-DPH is found in a position close and parallel to the bilayer surface (site I) and in a position (site II) oriented at an angle of approximately 25 degrees with respect to the bilayer normal, with the trimethylammonium group anchored in the head group domain. On going to the fluid phase there is a change in molecular orientation of each of the sites. In site I the molecule penetrates deeper in the bilayer and adopts a approximately 20 degrees tilt with respect to the surface, with an orientational distribution of +/- 10 degrees. In site II the molecule becomes perpendicular to the membrane surface. Changes in population of sites, both with DPH and TMA-DPH, are observed on going from low to high temperatures. They are however difficult to quantitate due to experimental conditions. The H2O-2H2O exchange experiments afforded an estimate of the water layer thickness as well as the maximum penetration of water into the interior of the bilayer.

Probing alpha-helical secondary structure at a specific site in model peptides via restriction of tryptophan side-chain rotamer conformation.

The relationship between alpha-helical secondary structure and the fluorescence properties of an intrinsic tryptophan residue were investigated. A monomeric alpha-helix forming peptide and a dimeric coiled-coil forming peptide containing a central tryptophan residue were synthesized. The fluorescence parameters of the tryptophan residue were determined for these model systems at a range of fractional alpha-helical contents. The steady-state emission maximum was independent of the fractional alpha-helical content. A minimum of three exponential decay times was required to fully describe the time-resolved fluorescence data. Changes were observed in the decay times and more significantly, in their relative contributions that could be correlated with alpha-helix content. The results were also shown to be consistent with a model in which the decay times were independent of both alpha-helix content and emission wavelength. In this model the relative contributions of the decay time components were directly proportional to the alpha-helix content. Data were also analyzed according to a continuous distribution of exponential decay time model, employing global analysis techniques. The recovered distributions had "widths" that were both poorly defined and independent of peptide conformation. We propose that the three decay times are associated with the three ground-state chi 1 rotamers of the tryptophan residue and that the changes in the relative contributions of the decay times are the result of conformational constraints, imposed by the alpha-helical main-chain, on the chi 1 rotamer populations.

Myelin basic protein interaction with zinc and phosphate: fluorescence studies on the water-soluble form of the protein.

The interaction of myelin basic protein (MBP) with zinc and phosphate ions has been studied by using the emission properties of the single tryptophan residue of the protein (Trp-115). The studies have been carried out by means of both static and time-resolved fluorescence techniques. The addition of either zinc to MBP in the presence of phosphate or phosphate to MBP in the presence of zinc resulted in an increase of fluorescence intensity and a blue shift of the emission maximum wavelength. Furthermore, a concomitant increase in the scattering was also detected. Anisotropy decay experiments demonstrated that these effects are due to the formation of MBP molecules into large aggregates. A possible physiological role for such interaction is discussed.

Crystallization and preliminary crystallographic studies of the crystals of the azurin Pseudomonas fluorescens.

The Azurin Pseudomones fluorescens has been crystallized in the presence of ammonium sulfate and Tris buffer at pH 7.5. The crystals diffract to 2.05 A using a FAST system. The space group is P2(1)2(1)2(1) with a = 31.95, b = 43.78, and c = 78.81 A.

Detection of calcium binding proteins on polyacrylamide gels using time-resolved lanthanide luminescence photography.

Methods were developed for using the luminescent lanthanides Tb3+ and Eu3+ for the specific staining of calcium-binding proteins, as well as the nonspecific staining of proteins, on polyacrylamide gels. These methods involve equilibration of the gel after electrophoresis in solutions containing the appropriate lanthanide and a weak competitive chelating agent, such as N-(2-hydroxyethyl)iminodiacetic acid or nitrilotriacetic acid. This staining has the potential for complete reversibility using stronger chelating agents such as EDTA or diethylenetriaminepentaacetic acid, to allow for recovery of the protein. Specific staining produces an intense luminescent signal from those metal-binding proteins which have been modified either chemically or via site-directed mutagenesis. Gels were photographed using a time-resolved fluorescence camera system.

Effects of metal ion binding on an oncomodulin mutant containing a novel calcium-binding loop.

The Ca(2+)-binding protein oncomodulin was altered by cassette mutagenesis of the CD site (CDOM33) with a sequence that was derived by a consensus method using over 250 known Ca(2+)-binding loop sequences. This mutant was studied using time-resolved and steady-state fluorescence from the Trp residue included at position 7 of the loop (position 57 of the protein sequence). The fluorescence characteristics of this species in the absence and presence of metal ions were compared to those of a tetradecapeptide containing the loop and the single Trp mutant of oncomodulin, Y57W. The fluorescence properties of CDOM33 were quite different from the peptide, both in the apo form and in response to metal binding. The consensus CD loop in CDOM33 exhibited the characteristics of a Ca(2+)/Mg(2+) site in contrast to the Ca(2+) specificity of the wild-type CD loop. The Trp analogue, 5-hydroxytryptophan (5HW), was incorporated into both oncomodulin mutants to produce Y75(5HW) and 5HW-CDOM33. Results showed that this intrinsic probe was relatively insensitive to structural changes in the mutants upon metal binding compared to Trp itself.

Characterization of aminoacyl-adenylates in B. subtilis tryptophanyl-tRNA synthetase, by the fluorescence of tryptophan analogs 5-hydroxytryptophan and 7-azatryptophan.

The tryptophan analogs 5-hydroxytryptophan (5HW) and 7-azatryptophan (7AW) are capable of being biosynthetically incorporated into bacterial proteins and can be used as intrinsic fluorescence probes of protein structure, function and dynamics. A prerequisite for analog incorporation is their recognition by tryptophanyl-tRNA synthetase (TrpRS) and the formation of the analog aminoacyladenylate in the enzyme's active site. The binding of 5HW and 7AW to B. subtilis TrpRS and the stability of the corresponding aminoacyladenylates of 5HW and 7AW were examined using their unique spectroscopic properties. The adenylate of 7AW in the active site of TrpRS exhibited intense fluorescence with a 10.5 ns fluorescence decay time. Enzyme-bound 7AW-adenylate was a long-lived intermediate with a half-life of over 9 hours. Enzyme-bound 5HW-adenylate fluorescence was quenched compared to that of 5HW in solution. The 5HW-adenylate/TrpRS complex was much less stable than that of 7AW, with a half-life of 33 minutes. Rapid hydrolysis of the 5HW-adenylate may explain the apparent proofreading observed which prohibits 5HW incorporation into proteins in the presence of tryptophan. Hydrolysis of the adenylates of both analogs restored the fluorescence parameters towards those of the analogs in solution. Neither 1-methyltryptophan nor 5-methoxytryptophan were capable of forming long-lived aminoacyladenylate intermediates in TrpRS. This study provides perspectives on the usefulness of 5HW and 7AW as intrinsic fluorescence probes of protein structure. The enhanced fluorescence of 7AW suggests its location in a buried hydrophobic environment in the protein. Exposure to water results in significant fluorescence quenching. These studies clearly demonstrate the utility of Trp analogs for the elucidation of molecular details of protein structure and dynamics.