Resolution of ligand positions by site-directed tryptophan fluorescence in tear lipocalin

The lipocalin superfamily of proteins functions in the binding and transport of a variety of important hydrophobic molecules. Tear lipocalin is a promiscuous lipid binding member of the family and serves as a paradigm to study the molecular determinants of ligand binding. Conserved regions in the lipocalins, such as the G strand and the F-G loop, may play an important role in ligand binding and delivery. We studied structural changes in the G strand of holo- and apo-tear lipocalin using spectroscopic methods including circular dichroism analysis and site-directed tryptophan fluorescence. Apo-tear lipocalin shows the same general structural characteristics as holo-tear lipocalin including alternating periodicity of a beta-strand, orientation of amino acid residues 105, 103, 101, and 99 facing the cavity, and progressive depth in the cavity from residues 105 to 99. For amino acid residues facing the internal aspect of cavity, the presence of a ligand is associated with blue shifted spectra. The collisional rate constants indicate that these residues are not less exposed to solvent in holo-tear lipocalin than in apo-tear lipocalin. Rather the spectral blue shifts may be accounted for by a ligand induced rigidity in holo-TL. Amino acid residues 94 and 95 are consistent with positions in the F-G loop and show greater exposure to solvent in the holo- than the apo-proteins. These findings are consistent with the general hypothesis that the F-G loop in the holo-proteins of the lipocalin family is available for receptor interactions and delivery of ligands to specific targets. Site-directed tryptophan fluorescence was used in combination with a nitroxide spin labeled fatty acid analog to elucidate dynamic ligand interactions with specific amino acid residues. Collisional quenching constants of the nitroxide spin label provide evidence that at least three amino acids of the G strand residues interact with the ligand. Stern-Volmer plots are inconsistent with a ligand that is held in a static position in the calyx, but rather suggest that the ligand is in motion. The combination of site-directed tryptophan fluorescence with quenching by nitroxide labeled species has broad applicability in probing specific interactions in the solution structure of proteins and provides dynamic information that is not attainable by X-ray crystallography.     

Binding studies of tear lipocalin: the role of the conserved tryptophan in maintaining structure, stability and ligand affinity.

The principal lipid binding protein in tears, tear lipocalin (TL), binds acid and the fluorescent fatty acid analogs, DAUDA and 16-AP at one site TL compete for this binding site. A fluorescent competitive binding assay revealed that apo-TL has a high affinity for phospholipids and stearic acid (Ki) of 1.2 microM and 1.3 microM, respectively, and much less affinity for cholesterol (Ki) of 15.9 of the hydrocarbon chain. TL binds most strongly the least soluble lipids permitting these lipids to exceed their maximum solubility in aqueous solution. These data implicate TL in solubilizing and transporting lipids in the tear film. Phenylalanine, tyrosine and cysteine+ were substituted for TRP 17, the only invariant residue throughout the lipocalin superfamily. Cysteine substitution resulted in some loss os secondary structure, relaxation of aromatic side chain rigidity, decreased binding affinity for DAUDA and destabilization of structure. Mutants of TL, W17Y, and W17F showed a higher binding affinity for DAUDA than wild-type TL. Comparison of the results of the tryptophan 17 substitution in lipocalin with those of tryptophan 19 substitution in beta-lactoglobulin revealed important differences in binding characteristics that reflect the functional heterogeneity within the lipocalin family.     

Phage display reveals a novel interaction of human tear lipocalin and thioredoxin which is relevant for ligand binding

Human tear lipocalin (TL) is an unusual member of the lipocalin protein family, since it is known to bind a large variety of lipophilic ligands in vivo and acts as a cysteine proteinase inhibitor in vitro. It is suggested to function as a physiological protection factor by scavenging lipophilic potentially harmful compounds. Since protein-protein interaction or macromolecular complexation is a common feature of many lipocalins, we applied phage display technology to identify TL interacting proteins. By panning of a human prostate cDNA phagemid library against purified TL we isolated a thioredoxin (Trx) encoding phage clone. Biochemical analysis revealed that TL indeed interacts with Trx and is reduced by this redox protein. Reduction of the TL-specific disulfide bond is of functional relevance, since the reduced protein shows a nine-fold increase in ligand affinity when tested with retinoic acid as ligand.     

Site-directed circular dichroism of proteins: 1Lb bands of Trp resolve position-specific features in tear lipocalin

The absorption spectra of N-acetyl-l-tryptophanamide in various solvents were resolved into the sums of the ¹L_a and ¹L_b components. The relative intensities of the 0-0 transitions of the ¹L_b bands correlate linearly with the solvent polarity values (). A novel strategy that uses a set of the experimental ¹L_b bands was employed to resolve the near-UV circular dichroism (CD) spectra of tryptophanyl residues. Resolved spectral parameters from the single-tryptophan mutants of tear lipocalin (TL), F99W and Y87W, corroborate the fluorescence and structural data of TL. Analysis of the ¹L_b bands of the Trp CD spectra in proteins is a valuable tool to obtain the local features. The dimethyl sulfoxide (DMSO)-like ¹L_b band of Trp CD spectra may be used as a “fingerprint” to identify the tryptophanyl side chains in situations where the benzene rings of Trp have van der Waals interactions with the side chains of its nearest neighbor. In addition, the signs and intensities of the components hold information about the side chain conformations and dynamics in proteins. Combined with Trp mutagenesis, this method, which we call site-directed circular dichroism, is broadly applicable to various proteins to obtain the position-specific data.     

Restoration of structural stability and ligand binding after removal of the conserved disulfide bond in tear lipocalin

Disulfide bonds play diverse structural and functional roles in proteins. In tear lipocalin (TL), the conserved sole disulfide bond regulates stability and ligand binding. Probing protein structure often involves thiol selective labeling for which removal of the disulfide bonds may be necessary. Loss of the disulfide bond may destabilize the protein so strategies to retain the native state are needed. Several approaches were tested to regain the native conformational state in the disulfide-less protein. These included the addition of trimethylamine N-oxide (TMAO) and the substitution of the Cys residues of disulfide bond with residues that can either form a potential salt bridge or others that can create a hydrophobic interaction. TMAO stabilized the protein relaxed by removal of the disulfide bond. In the disulfide-less mutants of TL, 1.0 M TMAO increased the free energy change (ΔG⁰) significantly from 2.1 to 3.8 kcal/mol. Moderate recovery was observed for the ligand binding tested with NBD-cholesterol. Because the disulfide bond of TL is solvent exposed, the substitution of the disulfide bond with a potential salt bridge or hydrophobic interaction did not stabilize the protein. This approach should work for buried disulfide bonds. However, for proteins with solvent exposed disulfide bonds, the use of TMAO may be an excellent strategy to restore the native conformational states in disulfide-less analogs of the proteins.     

The conserved disulfide bond of human tear lipocalin modulates conformation and lipid binding in a ligand selective manner

The primary aim of this study is the elucidation of the mechanism of disulfide induced alteration of ligand binding in human tear lipocalin (TL). Disulfide bonds may act as dynamic scaffolds to regulate conformational changes that alter protein function including receptor-ligand interactions. A single disulfide bond, (Cys61-Cys153), exists in TL that is highly conserved in the lipocalin superfamily. Circular dichroism and fluorescence spectroscopies were applied to investigate the mechanism by which disulfide bond removal effects protein stability, dynamics and ligand binding properties. Although the secondary structure is not altered by disulfide elimination, TL shows decreased stability against urea denaturation. Free energy change (ΔG(0)) decreases from 4.9±0.2 to 2.1±0.3kcal/mol with removal of the disulfide bond. Furthermore, ligand binding properties of TL without the disulfide vary according to the type of ligand. The binding of a bulky ligand, NBD-cholesterol, has a decreased time constant (from 11.8±0.2 to 3.3s). In contrast, the NBD-labeled phospholipid shows a moderate decrease in the time constant for binding, from 33.2±0.2 to 22.2±0.4s. FRET experiments indicate that the hairpin CD is directly involved in modulation of both ligand binding and flexibility of TL. In TL complexed with palmitic acid (PA-TL), the distance between the residues 62 of strand D and 81 of loop EF is decreased by disulfide bond reduction. Consequently, removal of the disulfide bond boosts flexibility of the protein to reach a CD-EF loop distance (24.3?, between residues 62 and 81), which is not accessible for the protein with an intact disulfide bond (26.2?). The results suggest that enhanced flexibility of the protein promotes a faster accommodation of the ligand inside the cavity and an energetically favorable ligand-protein complex.     

The 1.8-A crystal structure of human tear lipocalin reveals an extended branched cavity with capacity for multiple ligands

In contrast with earlier assumptions, which classified human tear lipocalin (Tlc) as an outlier member of the lipocalin protein family, the 1.8-A resolution crystal structure of the recombinant apoprotein confirms the typical eight-stranded antiparallel beta-barrel architecture with an alpha-helix attached to it. The fold of Tlc most closely resembles the bovine dander allergen Bos d 2, a well characterized prototypic lipocalin, but also reveals similarity with beta-lactoglobulin. However, compared with other lipocalin structures Tlc exhibits an extremely wide ligand pocket, whose entrance is formed by four partially disordered loops. The cavity deeply extends into the beta-barrel structure, where it ends in two distinct lobes. This unusual structural feature explains the known promiscuity of Tlc for various ligands, with chemical structures ranging from lipids and retinoids to the macrocyclic antibiotic rifampin and even to microbial siderophores. Notably, earlier findings of biological activity as a thiol protease inhibitor have no correspondence in the three-dimensional structure of Tlc, rather it appears that its proteolytic fragments could be responsible for this phenomenon. Hence, the present structural analysis sheds new light on the ligand binding activity of this functionally obscure but abundant human lipocalin.     

Identification of determinants that confer ligand specificity on the insulin receptor.

We have previously shown, using truncated soluble recombinant receptors, that substituting the 62 N-terminal amino acids of the alpha subunit from the insulin-like growth factor I receptor (IGFIR) with the corresponding 68 amino acids from the insulin receptor (IR) results in a chimeric receptor with an approximately 200-fold increase in affinity for insulin and only a 5-fold decrease in insulin-like growth factor I (IGFI) affinity (Kjeldsen, T., Andersen, A. S., Wiberg, F. C., Rasmussen, J. S., Sch?ffer, L., Balschmidt, P., M?ller, K. B., and M?ller, N. P. H. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 4404-4408). We demonstrate that these 68 N-terminal amino acids of the IR also confer insulin affinity on the intact IGFI holoreceptor both in the membrane-bound state and when solubilized by Triton X-100. Furthermore, this domain can be subdivided into two regions (amino acids 1-27 and 28-68 of the IR alpha subunit) that, when replacing the corresponding IGFIR sequences, increases the insulin affinity of truncated soluble receptor chimeras 8- and 20-fold, respectively, with only minor effects on the IGFI affinity. Within the latter of these two regions, we found that amino acids 38-68 of the IR, representing 13 amino acid differences from IGFIR, confer the same 20-fold increase in insulin affinity on the IGFIR. Finally, the amino acids from position 42 to 50 are not responsible for this increase in insulin affinity. We thus propose that at least two determinants within the 68 N-terminal amino acids of the insulin receptor are involved in defining the ligand specificity of the insulin receptor, and that one or a combination of the remaining seven amino acid differences between position 38 and 68 are involved in conferring insulin affinity on the insulin receptor.     

Crystal structure of human complement protein C8gamma at 1.2 A resolution reveals a lipocalin fold and a distinct ligand binding site

C8gamma is a 22-kDa subunit of human C8, which is one of five components of the cytolytic membrane attack complex of complement (MAC). C8gamma is disulfide-linked to a C8alpha subunit that is noncovalently associated with a C8beta chain. In the present study, the three-dimensional structure of recombinant C8gamma was determined by X-ray diffraction to 1.2 A resolution. The structure displays a typical lipocalin fold forming a calyx with a distinct binding pocket that is indicative of a ligand-binding function for C8gamma. When compared to other lipocalins, the overall structure is most similar to neutrophil gelatinase associated lipocalin (NGAL), a protein released from granules of activated neutrophils. Notable differences include a much deeper binding pocket in C8gamma as well as variation in the identity and position of residues lining the pocket. In C8gamma, these residues allow ligand access to a large hydrophobic cavity at the base of the calyx, whereas corresponding residues in NGAL restrict access. This suggests the natural ligands for C8gamma and NGAL are significantly different in size. Cys40 in C8gamma, which forms the disulfide bond to C8alpha, is located in a partially disordered loop (loop 1, residues 38-52) near the opening of the calyx. Access to the calyx may be regulated by movement of this loop in response to conformational changes in C8alpha during MAC formation.     

Zebrafish reveals different and conserved features of vertebrate neuroglobin gene structure, expression pattern, and ligand binding

Neuroglobin has been identified as a respiratory protein that is primarily expressed in the mammalian nervous system. Here we present the first detailed analysis of neuroglobin from a non-mammalian vertebrate, the zebrafish Danio rerio. The zebrafish neuroglobin gene reveals a mammalian-type exon-intron pattern in the coding region (B12.2, E11.0, and G7.0), plus an additional 5'-non-coding exon. Similar to the mammalian neuroglobin, the zebrafish protein displays a hexacoordinate deoxy-binding scheme. Flash photolysis kinetics show the competitive binding on the millisecond timescale of external ligands and the distal histidine, resulting in an oxygen affinity of 1 torr. Western blotting, immune staining, and mRNA in situ hybridization demonstrate neuroglobin expression in the fish central nervous system and the retina but also in the gills. Neurons containing neuroglobin have a widespread distribution in the brain but are also present in the olfactory system. In the fish retina, neuroglobin is mainly present in the inner segments of the photoreceptor cells. In the gills, the chloride cells were identified to express neuroglobin. Neuroglobin appears to be associated with mitochondria-rich cell types and thus oxygen consumption rates, suggesting a myoglobin-like function of this protein in facilitated oxygen diffusion.     

Structural features of the ligand binding site on human complement protein C8gamma: a member of the lipocalin family

Human C8 is one of five components of the cytolytic membrane attack complex of complement. It contains three subunits (C8alpha, C8beta, C8gamma) arranged as a disulfide-linked C8alpha-gamma heterodimer that is noncovalently associated with C8beta. C8gamma has the distinction of being the only lipocalin in the complement system. Lipocalins have a core beta-barrel structure forming a calyx with a binding site for a small hydrophobic ligand. A natural ligand for C8gamma has not been identified; however previous structural studies indicate C8gamma has a typical lipocalin fold that is suggestive of a ligand-binding capability. A distinctive feature of C8gamma is the division of its putative ligand binding pocket into a hydrophilic upper portion and a large hydrophobic lower cavity. Access to the latter is restricted by the close proximity of two tyrosine side chains (Y83 and Y131). In the present study, binding experiments were performed using lauric acid as a pseudoligand to investigate the potential accessibility of the lower cavity. The crystal structure of a C8gamma.laurate complex revealed that Y83 and Y131 can move to allow penetration of the hydrocarbon chain of laurate into the lower cavity. Introducing a Y83W mutation blocked access but had no effect on the ability of C8gamma to enhance C8 cytolytic activity. Together, these results indicate that the lower cavity in C8gamma could accommodate a ligand if such a ligand has a narrow hydrophobic moiety at one end. Entry of that moiety into the lower cavity would require movement of Y83 and Y131, which act as a gate at the cavity entrance.     

Mutagenesis study of rice nonspecific lipid transfer protein 2 reveals residues that contribute to structure and ligand binding

Plant nonspecific lipid transfer protein 2 (nsLTP2) is a small (7 kDa) protein that binds lipid-like ligands. An inner hydrophobic cavity surrounded by alpha-helices is the defining structural feature of nsLTP2. Although nsLTP2 structures have been reported earlier, the detailed mechanisms of ligand binding and lipid transfer remain unclear. In this study, we used site-directed mutagenesis to determine the role of various hydrophobic residues (L8, I15, F36, F39, Y45, Y48, and V49) in the structure, stability, ligand binding, and lipid transfer activity of rice nsLTP2. Three single mutations (L8A, F36A, and V49A) drastically alter the native tertiary structure and perturb ligand binding and lipid transfer activity. Therefore, these three residues are structurally important. The Y45A mutant, however, retains a native-like structure but has decreased lipid binding affinity and lipid transfer activity, implying that this aromatic residue is critical for these biological functions. The mutants, I15A and Y48A, exhibit quite different ligand binding affinities. Y48 is involved in planar sterol binding but not linear lysophospholipid association. As for I15A, it had the highest dehydroergosterol binding affinity in spite of the lower lipid binding and transfer abilities. Our results suggest that the long alkyl side chain of I15 would restrict the flexibility of loop I (G13-A19) for sterol entry. Finally, F39A can markedly increase the exposed hydrophobic surface to maintain its transfer efficiency despite reduced ligand binding affinity. These findings suggest that the residues forming the hydrophobic cavity play various important roles in the structure and function of rice nsLTP2.     

Site-directed mutagenesis of beta-adrenergic receptors. Identification of conserved cysteine residues that independently affect ligand binding and receptor activation

Using site-directed mutagenesis of the human beta 2-adrenergic receptor and continuous expression in B-82 cells, the role of 3 conserved cysteines in transmembrane domains and 2 conserved cysteines in the third extracellular domain in receptor function was examined. Cysteine was replaced with serine in each mutant receptor as this amino acid is similar to cysteine in size but it cannot form disulfide linkages. Replacement of cysteine residues 77 and 327, in the second and seventh transmembrane-spanning domains, respectively, had no effect on ligand binding or the ability of the receptor to mediate isoproterenol stimulation of adenylate cyclase. Substitution of cysteine 285, in the sixth transmembrane domain of the receptor, produced a mutant receptor with normal ligand-binding properties but a significantly attenuated ability to mediate stimulation of adenylate cyclase. Mutation of cysteine residues 190 and 191, in the third extracellular loop of the beta 2 receptor, had qualitatively similar effects on ligand binding and isoproterenol-mediated stimulation of adenylate cyclase. Replacement of either of these residues with serine produced mutant receptors that displayed a marked loss in affinity for both beta-adrenergic agonists and antagonists. Replacement of both cysteine 190 and 191 with serine had an even greater effect on the ability of the receptor to bind ligands. Consistent with the loss of Ser190 and/or Ser191 mutant receptor affinity for agonists was a corresponding shift to the right in the dose-response curve for isoproterenol-induced increases in intracellular cyclic AMP concentrations in cells expressing the mutant receptors. These data implicate one of the conserved transmembrane cysteine residues in the human beta 2-adrenergic receptor in receptor activation by agonists and also suggest that conserved cysteine residues in an extracellular domain of the receptor may be involved in ligand binding.     

Structural features required for ligand binding to the beta-adrenergic receptor.

On the basis of the homology between the amino acid sequences of the beta-adrenergic receptor (beta AR) and the opsin proteins we have proposed that the ligand binding domain lies within the seven transmembrane hydrophobic regions of the protein, which are connected by hydrophilic regions alternatively exposed extracellularly and intracellularly. We have systematically examined the importance of each of these regions by making a sequential series of deletions in the gene for the hamster beta AR which encompass most of the protein coding region. The ability of the corresponding mutant receptors to be expressed, localized to the cell membrane, and bind beta-adrenergic ligands has been analyzed, using transient expression in COS-7 cells. The hydrophobic regions and the hydrophilic segments immediately adjacent to the membrane cannot be removed without affecting the processing and membrane localization of the beta AR. However, most of the hydrophilic regions appear to be dispensable for ligand binding. In addition, we observed that substitution of the conserved cysteine residues at positions 106 and 184 dramatically altered the ligand binding characteristics of the beta AR, suggesting the occurrence of a disulfide bond between these two residues in the native protein. These data are discussed in terms of the tertiary structure of the beta AR.     

Picosecond tryptophan fluorescence of thioredoxin: evidence for discrete species in slow exchange

The steady-state tryptophan fluorescence and time-resolved tryptophan fluorescence of Escherichia coli thioredoxin, calf thymus thioredoxin, and yeast thioredoxin have been studied. In all proteins, the tryptophan residues undergo strong static and dynamic quenching, probably due to charge-transfer interactions with the nearby sulfur atoms of the active cysteines. The use of a high-resolution photon counting instrument, with a time response of 60 ps full width at half-maximum, allowed the detection of fluorescence lifetimes ranging from a few tens of picoseconds to 10 ns. The data were analyzed both by classical nonlinear least squares and by a new method of entropy maximization (MEM) for the recovery of lifetime distributions. Simulations representative of the experimental data were used to test the MEM analysis. Strong support was obtained in this way for a small number of averaged discrete species in the fluorescence decays. Wavelength studies show that each of these components spreads over closely spaced excited states, while the temperature studies indicate that they do not exchange significantly on the nanosecond time scale. The oxidized form of thioredoxin is characterized by a high content of a very short lifetime below 70 ps, the amplitude of which is sharply decreased upon reduction. On the other hand, the fluorescence anisotropy decays indicate that reduction causes an increase of the very fast tryptophan rotations in an otherwise relatively rigid structure. While the calf thymus and E. coli proteins have mostly similar dynamical fluorescence properties, the yeast thioredoxin differs in many respects.     

On the nature of antibody combining sites: unusual structural features that may confer on these sites an enhanced capacity for binding ligands.

A detailed analysis of the structural aspects of antibody-antigen interactions has been made possible by the availability of X-ray structures for three complexes of antilysozyme Fabs to lysozyme (reviewed by Davies et al.: J. Biol. Chem. 263:10541-10544, 1988.) Examination of the antigen-contacting residues in the three antilysozyme Fabs reveals the occurrence of a large number of aromatics, particularly tyrosines, and the absence of apolar, aliphatic residues. Calculation of the frequency of occurrence of the various amino acid types reveals that tyrosines are three times, and histidines and asparagines eight times, more likely to be found in the complementarity-determining regions than in the framework of the variable domains. Analysis of the solvent accessibility of the residues in Fvs (the modules containing variable domains of the light and heavy chains) of known three-dimensional structure indicates that tyrosines and tryptophans are more exposed when they occur in the complementarity-determining regions than when in the framework. Furthermore, many more of the asparagines in the complementarity-determining regions than in the framework are buried. These asparagines appear to have a structural role in that they hydrogen-bond through their side chains to other side chains and, even more so, to the protein backbone. The stabilizing effect of the asparagines, plus the rigidity of the framework, may serve to allow the greater exposure of the aromatic residues to solvent. In view of the greater potential contribution of aromatic side chains to the total binding energy, these results suggest that antibody combining sites have structural features that make them especially suited for interacting with ligands.     

Effect of ligand binding and conformational changes in proteins on oxygen quenching and fluorescence depolarization of tryptophan residues

The rotational freedom of tryptophan residues in protein-ligand complexes was studied by measuring steady-state fluorescence anisotropies under conditions of oxygen quenching. There was a decrease in the oxygen bimolecular quenching constant upon complexation of trypsin and alpha-chymotrypsin with proteinaceous trypsin inhibitors, of lysozyme with N-acetylglucosamine (NAG) and di(N-acetyl-D-glucosamine) ((NAG)2) and of hexokinase with glucose. Binding of the bisubstrate analogue N-phosphonacetyl-L-aspartate (PALA) to aspartate transcarbamylase (ATCase) and binding of biotin to avidin resulted in increased oxygen quenching constants. The tryptophan of human serum albumin (HSA) in the F state was more accessible to oxygen quenching than that in the N state. With the exception of ATCase, the presence of subnanosecond motions of the tryptophan residues in all the proteins is suggested by the short apparent correlation times for fluorescence depolarization and by the low apparent anisotropies obtained by extrapolation to a lifetime of zero. Complex formation evidently resulted in more rigid structures in the case of trypsin, alpha-chymotrypsin and lysozyme. The effects of glucose binding on hexokinase were not significant. Binding of biotin to avidin resulted in a shorter correlation time for the tryptophan residues. The N --> F transition in HSA resulted in a more rigid environment for the tryptophan residue. Overall, these changes in the dynamics of the protein matrix and motional freedom of tryptophan residues due to complex formation and subsequent conformational changes are in the same direction as those observed by other techniques, especially hydrogen exchange. Significantly, the effects of complex formation on protein dynamics are variable. Among the limited number of cases we examined, the effects of complex formation were to increase, decrease or leave unchanged the apparent dynamics of the protein matrix.     

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.