Tet repressor-tetracycline interaction

Previous studies [Wasylewskiet al. (1996),J. Protein Chem. 15, 45–58] have shown that the W43 residue localized within the helix-turn-helix structure domain of Tet repressor can exist in the ground state in two conformational states. In this paper we investigate the fluorescence properties of W43 of TetR upon binding of tetracycline inducer and its chemical analogs such as anhydro- and epitetracycline. Binding of the drug inducer to the protein indicates that the W43 residue still exists in two conformational states; however, its environment changes drastically, as can be judged by the changes in fluorescence parameters. The FQRS (fluorescence-quenching-resolved spectra) method was used to decompose the total emission spectrum. The resolved spectra exhibit maxima of fluorescence at 346 and 332 nm and the component quenchable by KI (346 nm) is shifted 9 nm toward the blue side of the spectrum upon inducer binding. The observed shift does not result from the changes in the exposure of W43, since the bimolecular quenching rate constant remains the same and is equal to about 2.7×10⁹M^–1sec^–1. The binding of tetracycline leads to drastic decrease of the W43 fluorescence intensity and increase of the tetracycline intensity as well as the decrease of fluorescence lifetime, especially of the W43 component characterized by the emission at 332 nm. The observed energy transfer from W43 to tetracycline is more efficient for the state characterized by the fluorescence emission at 332 nm (88%) than for the component quenchable by iodide (53%) Tetracycline and several of its derivatives were also used to observe how chemical modifications of the hydrophilic groups in tetracycline influence the mechanism of binding of the antibiotic to Tet repressor. By use of pulsed-laser photoacoustic spectroscopy it is shown that the binding of tetracyclines to Tet repressor leads to significant increase of tetracycline fluorescence quantum yields. Steady-state fluorescence quenching of tetracycline analogs in complexes with Tet repressor using potassium iodide as a quencher allowed us to determine the dependence of the exposure of bound antibiotic on the modifications of hydrophilic substituents of tetracycline. Circular dichroism studies of the TetR-[Mg · tc]⁺ complex do not indicate dramatic changes in the secondary structure of the protein; however, the observed small decrease in the TetR helicity may occur due to partial unfolding of the DNA recognition helix of the protein. The observed changes may play an important role in the process of induction in which tetracycline binding results in the loss of specific DNA binding.Abbreviations FQRS fluorescence-quenching-resolved spectra - HTH helix-turn-helix motif - tc tetracycline - TetR tetracycline repressor from Escherichia coli - TetR WT wild-type TetR - TetR W43 single point mutant with phenylalanine substituted for tryptophan at position 75 in both subunits     

Resolution of the fluorescence equilibrium unfolding profile of trp aporepressor using single tryptophan mutants.

Single tryptophan mutants of the trp aporepressor, tryptophan 19-->phenylalanine (W19F) and tryptophan 99-->phenylalanine (W99F), were used in this study to resolve the individual steady-state and time-resolved fluorescence urea unfolding profiles of the two tryptophan residues in this highly intertwined, dimeric protein. The wild-type protein exhibits a large increase in fluorescence intensity and lifetime, as well as a large red shift in the steady-state fluorescence emission spectrum, upon unfolding by urea (Lane, A.N. & Jardetsky, O., 1987, Eur. J. Biochem. 164, 389-396; Gittelman, M.S. & Matthews, C.R., 1990, Biochemistry 29, 7011-7020; Fernando, T. & Royer, C.A., 1992, Biochemistry 31, 6683-6691). Unfolding of the W19F mutant demonstrated that Trp 99 undergoes a large increase in intensity and a red shift upon exposure to solvent. Lifetime studies revealed that the contribution of the dominant 0.5-ns component of this tryptophan tends toward zero with increasing urea, whereas the longer lifetime components increase in importance. This lifting of the quenching of Trp 99 may be due to disruption of the interaction between the two subunits upon denaturation, which abolishes the interaction of Trp 99 on one subunit with the amide quenching group of Asn 32 on the other subunit (Royer, C.A., 1992, Biophys. J. 63, 741-750). On the other hand, Trp 19 is quenched in response to unfolding in the W99F mutant. Exposure to solvent of Trp 19, which is buried at the hydrophobic dimer interface in the native protein, results in a large red shift of the average steady-state emission.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fluorescence study ofEscherichia coli cyclic AMP receptor protein

Time-resolved, steady-state fluorescence and fluorescence-detected circular dichroism (FDCD) have been used to resolve the fluorescence contributions of the two tryptophan residues, Trp-13 and Trp-85, in the cyclic AMP receptor protein (CRP). The iodide and acrylamide quenching data show that in CRP one tryptophan residue, Trp-85, is buried within the protein matrix and the other, Trp-13, is moderately exposed on the surface of the protein. Fluorescence-quenching-resolved spectra show that Trp-13 has emission at about 350 nm and contributes 76–83% to the total fluorescence emission. The Trp-85, unquenchable by iodide and acrylamide, has the fluorescence emission at about 337 nm. The time-resolved fluorescence measurements show that Trp-13 has a longer fluorescence decay time. The Trp-85 exhibits a shorter fluorescence decay time. In the CRP-cAMP complex the Trp-85, previously buried in the apoprotein becomes totally exposed to the iodide and acrylamide quenchers. The FDCD spectra indicate that in the CRP-cAMP complex Trp-85 remains in the same environment as in the protein alone. It has been proposed that the binding of cAMP to CRP is accompanied by a hinge reorientation of two protein domains. This allows for penetration of the quencher molecules into the Trp-85 residue previously buried in the protein matrix.Abbreviations CRP cyclic AMP receptor protein - NATA N-acetyltryptophanamide - FQRS fluorescence-quenching-resolved spectra - FDCD fluorescence-detected circular dichroism - EDTA ethylenediaminetetraacetic acid - SDS sodium dodecyl sulfate - FPLC fast protein liquid chromatography     

A fluorescence study of Tn10-encoded Tet repressor

Steady-state fluorescence quenching and time-resolved measurements have been performed to resolve the fluorescence contributions of the two tryptophan residues, W43 and W75, in the subunit of the homodimer of the Tet repressor fromEscherichia coli. The W43 residue is localized within the helix-turn-helix structural domain, which is responsible for sequence-specific binding of the Tet repressor to thetet operator. The W75 residue is in the protein matrix near the tetracycline-binding site. The assignment of the two residues has been confirmed by use of single-tryptophan mutants carrying either W43 or W75. The FQRS (fluorescence-quenching-resolved-spectra) method has been used to decompose the total emission spectrum of the wild-type protein into spectral components. The resolved spectra have maxima of fluorescence at 349 and 324 nm for the W43 and W75 residues, respectively. The maxima of the resolved spectra are in excellent agreement with those found using single-tryptophan-containing mutants. The fluorescence decay properties of the wild type as well as of both mutants of Tet repressor have been characterized by carrying out a multitemperature study. The decays of the wild-type Tet repressor and W43-containing mutant can be described as being of double-exponential type. The W75 mutant decay can be described by a Gaussian continuous distribution centered at 5.0 nsec with a bandwidth equal to 1.34 nsec. The quenching experiments have shown the presence of two classes of W43 emission. One of the components, exposed to solvent, has a maximum of fluorescence emission at 355 nm, with the second one at about 334 nm. The red-emitting component can be characterized by bimolecular-quenching rate constant,k _q equal to 2.6×10⁹, 2.8×10⁹, and 2.0×10⁹ M^–1 sec^–1 for acrylamide, iodide, and succinimide, respectively. The bluer component is unquenchable by any of the quenchers used. The W75 residue of the Tet repressor has quenching rate constant equal to 0.85×10⁹ and 0.28 × 10⁹ M^–1 sec^–1 for acrylamide and succinimide, respectively. These values indicate that the W75 is not deeply buried within the protein matrix. Our results indicate that the Tet repressor can exist in its ground state in two distinct conformational states which differ in the microenvironment of the W43 residue.Abbreviations FQRS fluorescence-quenching-resolved spectra - HTH helix-turn-helix motif - TetR tetracycline repressor fromE. coli - WT wild-type TetR - W43 single point mutant with phenyloalanine substituted for tryptophan at position 75 in both subunits - W75 single point mutant with phenyloalanine substituted for tryptophan at position 43 in both subunits     

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-resolved spectra of melittin in lipid bilayers

The interaction of bee venom melittin with dimyristoylphosphatidylcholine (DMPC) unilamellar vesicles has been studied by means of fluorescence quenching of the single tryptophan residue of the protein, at lipid-to-peptide ratio, Ri = 50 and at high ionic strength (2 M NaCl). The method of fluorescence-quenching-resolved spectra (FQRS), applied in this study with potassium iodide as a quencher, enabled us to decompose the tryptophan emission spectrum of liposome-bound melittin into components, at temperatures above as well as below the main phase transition temperature (Tt) of DMPC. One of the two resolved spectra exhibits maximum at 342 and 338 nm for experiments above and below Tt, respectively, and is similar to the maximum of tryptophan emission found for tetrameric melittin in solution (340 nm). This spectrum is characterized by the Stern-Volmer quenching constant, Ksv, of about 4 M-1 and it represents the fraction of melittin molecules whose tryptophan residues are exposed to the solvent to a degree comparable with tetrameric species in solution. The other spectrum component, corresponding to the quencher-inaccessible fraction of tryptophan molecules (Ksv = 0 M-1) has its maximum blue-shifted up to 15 nm, indicating a decrease in polarity of the environment. For experiments above Tt, the blue spectrum component revealed the excitation-wavelength dependence, originating probably from the relaxation processes between the excited tryptophan molecules and lipid polar head groups. We conclude that melittin bound to DMPC liposomes exists in two lipid-associated forms; one, with tryptophan residues exposed to the solvent and the other, penetrating the membrane interior, with tryptophan residues located in close proximity to the phospholipid polar head groups of the outer vesicle lipid layer. We also discuss our data with current models of melittin-bilayer interactions.     

Fluorescence Quenching Studies of Trp Repressor–Operator Interaction

Steady-state quenching and time-resolved fluorescence measurements of L-tryptophan binding to the tryptophan-free mutant W19/99F of the tryptophan repressor of Escherichia coli have been used to observe the coreperessor microenvirnment changes upon ligand binding. Using iodide and acrylamide as quenchers, we have resolved the emission spectra of the corepressor into two components. The bluer component of L-tryptophan buried in the holorepressor exhibits a maximum of the fluorescence emission at 336 nm and can be characterized by a Stern–Volmer quenching constant equal to about 2.0–2.3 M^?1. The second, redder component is exposed to the solvent and possesses the fluorescence emission and Stern–Volmer quenching constant characteristic of L-tryptophan in the solvent. When the Trp holorepressor is bound to the DNA operator, further alterations in the corepressor fluorescence are observed. Acrylamide quenching experiments indicate that the Stern–Volmer quenching constant of the buried component of the corepressor decreases drastically to a value of 0.56 M^?1. The fluorescence lifetimes of L-tryptophan in a complex with Trp repressor decrease substantially upon binding to DNA, which indicates a dynamic mechanism of the quenching process.     

Investigation of the structural determinants of the intrinsic fluorescence emission of the trp repressor using single tryptophan mutants.

The fluorescence decay properties of wild-type trp repressor (TR) have been characterized by carrying out a multi-emission wavelength study of the frequency response profiles. The decay is best analyzed in terms of a single exponential decay near 0.5 ns and a distribution of lifetimes centered near 3-4 ns. By comparing the recovered decay associated spectra and lifetime values with the structure of the repressor, tentative assignments of the two decay components recovered from the analysis to the two tryptophan residues, W19 and W99, of the protein have been made. These assignments consist of linking the short, red emitting component to emission from W99 and most of the longer bluer emitting lifetime distribution to emission from W19. Next, single tryptophan mutants of the repressor in which one of each of the tryptophan residues was substituted by phenylalanine were used to confirm the preliminary assignments, inasmuch as the 0.5-ns component is clearly due to emission from tryptophan 99, and much of the decay responsible for the recovered distribution emanates from tryptophan 19. The data demonstrate, however, that the decay of the wild-type protein is not completely resolvable due both to the large number of components in the wild-type emission (at least five) as well as to the fact that three of the five lifetime components are very close in value. The fluorescence decay of the wild-type decay is well described as a combination of the components found in each of the mutants. However, whereas the linear combination analysis of the 15 data sets (5 from the wild-type and each mutant) yields a good fit for the components recovered previously for the two mutants, the amplitudes of these components in the wild-type are not recovered in the expected ratios. Because of the dominance of the blue shifted emission in the wild-type protein, it is most likely that subtle structural differences in the wild-type as compared with the mutants, rather than energy transfer from tryptophan 19 to 99, are responsible for this failure of the linear combination hypothesis.     

Fluorescence quenching studies of Trp repressor-operator interaction

Steady-state quenching and time-resolved fluorescence measurements of L-tryptophan binding to the tryptophan-free mutant W19/99F of the tryptophan repressor of Escherichia coli have been used to observe the coreperessor microenvirnment changes upon ligand binding. Using iodide and acrylamide as quenchers, we have resolved the emission spectra of the corepressor into two components. The bluer component of L-tryptophan buried in the holorepressor exhibits a maximum of the fluorescence emission at 336 nm and can be characterized by a Stern–Volmer quenching constant equal to about 2.0–2.3 M^–1. The second, redder component is exposed to the solvent and possesses the fluorescence emission and Stern–Volmer quenching constant characteristic of L-tryptophan in the solvent. When the Trp holorepressor is bound to the DNA operator, further alterations in the corepressor fluorescence are observed. Acrylamide quenching experiments indicate that the Stern–Volmer quenching constant of the buried component of the corepressor decreases drastically to a value of 0.56 M^–1. The fluorescence lifetimes of L-tryptophan in a complex with Trp repressor decrease substantially upon binding to DNA, which indicates a dynamic mechanism of the quenching process.     

Tryptophan replacements in the trp aporepressor from Escherichia coli: probing the equilibrium and kinetic folding models.

Mutants of the dimeric Escherichia coli trp aporepressor are constructed by replacement of the two tryptophan residues in each subunit in order to assess the effects on equilibrium and kinetic fluorescence properties of the folding reaction. The three kinetic phases detected by intrinsic tryptophan fluorescence in refolding of the wild-type aporepressor are also observed in folding of both Trp 19 to Phe and Trp 99 to Phe single mutants, demonstrating that these phases correspond to global rather than local conformational changes. Comparison of equilibrium fluorescence (Royer, C.A., Mann, C.J., & Matthews, C.R., 1993, Protein Sci. 2, 1844-1852) and circular dichroism transition curves induced by urea shows that replacement of either Trp 19 or Trp 99 results in noncoincident behavior. Unlike the wild-type protein (Gittelman, M.S. & Matthews, C.R., 1990, Biochemistry 29, 7011-7020), tertiary and/or quaternary structures are disrupted at lower denaturant concentration than is secondary structure. The equilibrium results can be interpreted in terms of enhancement in the population of a monomeric folding intermediate in which the lone tryptophan residue is highly exposed to solvent, but in which substantial secondary structure is retained. The location of both mutations at the interface between the two subunits (Zhang, R.G., et al., 1987, Nature 327, 591-597) provides a simple explanation for this phenomenon.     

Effects of five-tryptophan mutations on structure, stability and function of Escherichia coli dihydrofolate reductase

To elucidate the roles of tryptophan residues in the structure, stability, and function of Escherichia coli dihydrofolate reductase (DHFR), its five tryptophan residues were replaced by site-directed mutagenesis with leucine, phenylalanine or valine (W22F, W22L, W30L, W47L, W74F, W74L, W133F, and W133V). Far-ultraviolet circular dichroism (CD) spectra of these mutants reveal that exciton coupling between Trp47 and Trp74 strongly affects the peptide CD of wild-type DHFR, and that Trp133 also contributes appreciably. No additivity was observed in the contributions of individual tryptophan residues to the fluorescence spectrum of wild-type DHFR, Trp74 having a dominant effect. These single-tryptophan mutations induce large changes in the free energy of urea unfolding, which showed values of 1.79-7.14 kcal/mol, compared with the value for wild-type DHFR of 6.08 kcal/mol. Analysis of CD and fluorescence spectra suggests that thermal unfolding involves an intermediate with the native-like secondary structure, the disrupted Trp47-Trp74 exciton coupling, and the solvent-exposed Trp30 and Trp47 side chains. All the mutants except W22L (13%) retain more than 50% of the enzyme activity of wild-type DHFR. These results demonstrate that the five tryptophan residues of DHFR play important roles in its structure and stability but do not crucially affect its enzymatic function.     

Spectral contribution of the individual tryptophan of alphaB-crystallin: a study by site-directed mutagenesis

There are two tryptophan residues in the lens alphaB-crystallin, Trp9 and Trp60. We prepared two Trp --> Phe substituted mutants, W9F and W60F, for use in a spectroscopic study. The two tryptophan residues contribute to Trp fluorescence and near-ultraviolet circular dichroism (UV CD) differently. The major difference in the near-UV CD is the contribution of 1La of Trp: it is positive in W60F but becomes negative in W9F. Further analysis of the near-UV CD shows an increased intensity in the region of 270-280 nm for W60F, suggesting that the Tyr48 is affected by the W60F mutation. It appears that Trp60 is located in a more rigid environment than Trp9, which agrees with a recent structural model in which Trp60 is in a beta-strand.     

Tryptophan fluorescence of terminal deoxynucleotidyl transferase: effects of quenchers on time-resolved emission spectra

Terminal deoxynucleotidyl transferase (EC 2.7.7.31) is a eucaryotic DNA polymerase that does not require a template. The tryptophan environments in calf thymus terminal transferase were investigated by fluorescence. The heterogeneous emission from this multitryptophan enzyme was separated by time-resolved emission spectroscopy. Nanosecond fluorescence decays at 296-nm excitation and various emission wavelengths were deconvolved by global analysis, assuming that the lifetimes but not the relative weighting factors were independent of emission wavelength. The data were fit to three exponentials of lifetimes tau 1 = 1.4 ns, tau 2 = 4.5 ns, and tau 3 = 7.7 ns. The corresponding decay-associated emission spectra of the three components had maxima at about 328, 335, and 345 nm. The accessibility of individual tryptophan environments to polar and nonpolar fluorescence quenchers was examined in steady-state and time-resolved experiments. In the presence of iodide and acrylamide, the steady-state emission spectra shift to the blue. However, at low quencher concentrations, the emission from the 7.7-ns component (maximum 345 nm) is hardly affected, suggesting that this hydrophilic tryptophan environment is buried within the protein. On the other hand, the red shift in the steady-state emission spectrum in the presence of trichloroethanol indicates that the 1.4-ns component (maximum 328 nm) is an exposed hydrophobic tryptophan environment. The results are consistent with an inside-out model for terminal transferase protein, with the more hydrophobic tryptophan(s) near the surface and the most hydrophilic tryptophan(s) in the core.     

Fluorescence contributions of the individual Trp residues in goat alpha-lactalbumin

Goat alpha-lactalbumin (GLA) contains four tryptophan (Trp) residues. In order to obtain information on the fluorescence contribution of the individual Trp residues in native GLA, we recorded the fluorescence spectra of four GLA mutants, W26F, W60F, W104F, and W118F, in each of which a single Trp residue was replaced with phenylalanine (Phe). Comparison of the fluorescence spectra of the four mutants with that of wild-type GLA indicated that, in native GLA, three Trp residues (Trp60, Trp104, and Trp118) are strongly quenched and account for the partial indirect quenching of Trp26. As a consequence, the fluorescence of wild-type GLA and of the mutants W60F, W104F, and W118F mainly results from Trp26. An inspection of the crystal structure indicated that, in addition to the disulfide bonds that are in direct contact with the indole groups of Trp60 and Trp118, backbone peptide bonds that are in direct contact with the indole groups of Trp60, Trp104, and Trp118, contribute to the direct quenching effects. Interestingly, the lack of direct quenching of Trp26 explains why the cleavage of disulfide bonds by UV light is mediated more by the highly fluorescent Trp26 than by the less fluorescent Trp104 and Trp118.     

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.     

Sugar binding to recombinant wild-type and mutant glucokinase monitored by kinetic measurement and tryptophan fluorescence

Tryptophan fluorescence was used to study GK (glucokinase), an enzyme that plays a prominent role in glucose homoeostasis which, when inactivated or activated by mutations, causes diabetes mellitus or hypoglycaemia in humans. GK has three tryptophan residues, and binding of D-glucose increases their fluorescence. To assess the contribution of individual tryptophan residues to this effect, we generated GST-GK [GK conjugated to GST (glutathione transferase)] and also pure GK with one, two or three of the tryptophan residues of GK replaced with other amino acids (i.e. W99C, W99R, W167A, W167F, W257F, W99R/W167F, W99R/W257F, W167F/W257F and W99R/W167F/W257F). Enzyme kinetics, binding constants for glucose and several other sugars and fluorescence quantum yields (varphi) were determined and compared with those of wild-type GK retaining its three tryptophan residues. Replacement of all three tryptophan residues resulted in an enzyme that retained all characteristic features of GK, thereby demonstrating the unique usefulness of tryptophan fluorescence as an indicator of GK conformation. Curves of glucose binding to wild-type and mutant GK or GST-GK were hyperbolic, whereas catalysis of wild-type and most mutants exhibited co-operativity with D-glucose. Binding studies showed the following order of affinities for the enzyme variants: N-acetyl-D-glucosamine>D-glucose>D-mannose>D-mannoheptulose>2-deoxy-D-glucose>L-glucose. GK activators increased sugar binding of most enzymes, but not of the mutants Y214A/V452A and C252Y. Contributions to the fluorescence increase from Trp(99) and Trp(167) were large compared with that from Trp(257) and are probably based on distinct mechanisms. The average quantum efficiency of tryptophan fluorescence in the basal and glucose-bound state was modified by activating (Y214A/V452A) or inactivating (C213R and C252Y) mutations and was interpreted as a manifestation of distinct conformational states.     

Characterization of the tryptophan environments of interleukins 1 alpha and 1 beta by fluorescence quenching and lifetime measurements

The tryptophan environments of interleukins 1 alpha and 1 beta, immunomodulatory proteins with similar biological activities but only 25% sequence homology, were characterized by steady-state and dynamic fluorescence measurements. Both proteins exhibited similar emission maxima, but the emission intensity of IL-1 beta was greatly enhanced by increasing the ionic strength of the medium, whereas that of IL-1 alpha was unaffected. The two cytokines were also similarly quenched by the polar quencher acrylamide, but differences were observed for the ionic quenchers iodide and cesium. The fluorescence intensity decays of both cytokines were characterized by two (long and short) component lifetimes. However, the average lifetime of IL-1 beta (4.4 ns) was much longer than that of IL-1 alpha (1.93 ns). Taken together with the results of steady-state measurements, we suggest that the single tryptophan of IL-1 beta is statically quenched by neighboring charged residues, whereas the tryptophan fluorescence of IL-1 alpha is unaffected by ionic strength, and that the tryptophans of the two proteins have different accessibilities to ionic quenchers. The results are discussed in terms of similarities and differences in the tryptophan environments of the two proteins.     

The binding of 14-3-3γ to membranes studied by intrinsic fluorescence spectroscopy

Human 14-3-3 proteins contain two conserved tryptophan residues in each monomer, Trp60 and Trp233 in isoform γ. 14-3-3γ binds to negatively charged membranes and here we show that membrane binding can be monitored by steady-state intrinsic fluorescence spectroscopy. Measurements with W60F and W233F 14-3-3γ mutants revealed that Trp60 is the major contributor to the emission fluorescence, whereas the fluorescence of Trp233, which π-stacks with Tyr184, is quenched. The fluorescence is reduced and red-shifted upon specific binding of a phosphate ligand, and further red-shifted upon binding of 14-3-3γ to the membrane, compatible with solvent exposure of Trp60. Moreover, our results support that membrane binding involves the non-conserved, convex area of 14-3-3γ, and that Trp residues do not intercalate in the bilayer.     

A fluorescence study of Tn10-encoded Tet repressor

Steady-state fluorescence quenching and time-resolved measurements have been performed to resolve the fluorescence contributions of the two tryptophan residues, W43 and W75, in the subunit of the homodimer of the Tet repressor fromEscherichia coli. The W43 residue is localized within the helix-turn-helix structural domain, which is responsible for sequence-specific binding of the Tet repressor to thetet operator. The W75 residue is in the protein matrix near the tetracycline-binding site. The assignment of the two residues has been confirmed by use of single-tryptophan mutants carrying either W43 or W75. The FQRS (fluorescence-quenching-resolved-spectra) method has been used to decompose the total emission spectrum of the wild-type protein into spectral components. The resolved spectra have maxima of fluorescence at 349 and 324 nm for the W43 and W75 residues, respectively. The maxima of the resolved spectra are in excellent agreement with those found using single-tryptophan-containing mutants. The fluorescence decay properties of the wild type as well as of both mutants of Tet repressor have been characterized by carrying out a multitemperature study. The decays of the wild-type Tet repressor and W43-containing mutant can be described as being of double-exponential type. The W75 mutant decay can be described by a Gaussian continuous distribution centered at 5.0 nsec with a bandwidth equal to 1.34 nsec. The quenching experiments have shown the presence of two classes of W43 emission. One of the components, exposed to solvent, has a maximum of fluorescence emission at 355 nm, with the second one at about 334 nm. The red-emitting component can be characterized by bimolecular-quenching rate constant,k _q equal to 2.6×10⁹, 2.8×10⁹, and 2.0×10⁹ M^?1 sec^?1 for acrylamide, iodide, and succinimide, respectively. The bluer component is unquenchable by any of the quenchers used. The W75 residue of the Tet repressor has quenching rate constant equal to 0.85×10⁹ and 0.28 × 10⁹ M^?1 sec^?1 for acrylamide and succinimide, respectively. These values indicate that the W75 is not deeply buried within the protein matrix. Our results indicate that the Tet repressor can exist in its ground state in two distinct conformational states which differ in the microenvironment of the W43 residue.     

Possible role of two phenylalanine residues in the active site of human cytidine deaminase

Site-directed mutagenesis on human cytidine deaminase (CDA) was employed to mutate specifically two highly conserved phenylalanine residues, F36 and F137, to tryptophan; at the same time, the unique tryptophan residue present in the sequence at position 113 was mutated to phenylalanine. These double mutations were performed in order to have for each protein a single tryptophan signal for fluorescence studies relative to position 36 or 137. The mutant enzymes thus obtained, W113F, F36W/W113F and F137W/W113F, showed by circular dicroism and thermal stability an overall structure not greatly affected by the mutations. The titration of Trp residues by N-bromosuccinimide (NBS) suggested that residue W113 of the wild-type CDA and W36 of mutant F36W/W113F are buried in the tertiary structure of the enzyme, whereas the residue W137 of mutant F137W/W113F is located near the surface of the molecule. Kinetic experiments and equilibrium experiments with FZEB showed that the residue W113 seems not to be part of the active site of the enzyme whereas the Phe/Trp substitution in F36W/W113F and F137W/W113F mutant enzymes had a negative effect on substrate binding and catalysis, suggesting that F137 and F36 of the wild-type CDA are involved in a stabilizing interaction between ligand and enzyme.