Probing local environments of tryptophan residues in proteins: comparison of 19F nuclear magnetic resonance results with the intrinsic fluorescence of soluble human tissue factor

19F nuclear magnetic resonance (19F NMR) of 5-fluorotryptophan (5F-Trp) and tryptophan (Trp) fluorescence both provide information about local environment and solvent exposure of Trp residues. To compare the information provided by these spectroscopies, the four Trp residues in recombinant soluble human tissue factor (sTF) were replaced with 5F-Trp. 19F NMR assignments for the 5F-Trp residues (14, 25, 45, and 158) were based on comparison of the wild-type protein spectrum with the spectra of three single Trp-to-Phe replacement mutants. Previously we showed from fluorescence and absorption difference spectra of mutant versus wild-type sTF that the side chains of Trpl4 and Trp25 are buried, whereas those of Trp45 and Trp158 are partially exposed to bulk solvent (Hasselbacher et al., Biophys J 1995;69:20-29). 19F NMR paramagnetic broadening and solvent-induced isotope-shift experiments show that position 5 of the indole ring of 5F-Trp158 is exposed, whereas that of 5F-Trp45 is essentially inaccessible. Although 5F-Trp incorporation had no discernable effect on the procoagulant cofactor activity of either the wild-type or mutant proteins, 19F NMR chemical shifts showed that the single-Trp mutations are accompanied by subtle changes in the local environments of 5F-Trp residues residing in the same structural domain.     

19F NMR studies of the D-galactose chemosensory receptor. 2. Ca(II) binding yields a local structural change.

The Escherichia coli D-galactose and D-glucose receptor possesses a Ca(II)-binding site closely related in structure and metal-binding characteristics to the eukaryotic EF-hand sites. Only the structure of the Ca(II)-occupied site is known. To investigate the structural change triggered by Ca(II) and Sr(II) binding, we have used 19F NMR to probe five 5-fluorotryptophan (5F-Trp) and seven 3-fluorophenylalanine (3F-Phe) positions in the structure, extending the approach described in the preceding article. Of particular interest were two 5F-Trp residues near the N terminus of the Ca(II) site at positions 127 and 133. Substitution of the larger Sr(II) for Ca(II) triggered 19F NMR frequency shifts of the 5F-Trp127 and -133 resonances, indicating a detectable structural change in the Ca(II) site. In contrast, the three 5F-Trp resonances from distant regions of the structure exhibited no detectable frequency shifts. When the metal was removed from the Ca(II) site, the 5F-Trp127 and -133 frequencies shifted to a new value similar to that observed for free 5F-Trp in aqueous solvent, and this new frequency was a function of the H2O to D2O ratio, indicating that the residues had become solvent exposed. Metal removal yielded small or undetectable frequency shifts for the three distant 5F-Trp resonances and for four of the five resolved 3F-Phe resonances. The allosteric coupling of the metal and sugar binding sites was observed to be slight: depletion of metal ions was observed to reduce the D-galactose affinity of the receptor by 2-fold. Together the results indicate that the structural changes in the Ca(II) site are primarily localized in the region of the site. Removal of the metal ion from the site exposes the nearby 5F-Trp127 and -133 residues to the solvent, suggesting that the empty site has a more open structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relation of enzyme activity to local/global stability of murine adenosine deaminase: 19F NMR studies

Adenosine deaminase (ADA, EC 3.5.4.4) is a ubiquitous (beta/alpha)8-barrel enzyme crucial for purine metabolism and normal immune competence. In this study, it was observed that loss of enzyme activity of murine ADA (mADA) precedes the global secondary and tertiary structure transition when the protein is exposed to denaturant. The structural mechanism for this phenomenon was probed using site-specific 19F NMR spectroscopy in combination with [6-19F]tryptophan labeling and inhibitor binding. There are four tryptophan residues in mADA and all are located more than 12 A from the catalytic site. The 19F NMR spectra of [6-19F]Trp-labelled mADA show that the urea-induced chemical shift change of 19F resonance of W161, one of the four tryptophan 19F nuclei, correlates with the loss of enzyme activity. The urea-induced chemical shift change of another 19F resonance of W117 correlates with the change of the apparent rate constant for the binding of transition-state analogue inhibitor deoxycoformycin to the enzyme. On the other hand, the chemical environment of the local region around W264 does not change significantly, as a consequence of perturbation by low concentrations of urea or substrate analog. The results indicate that different regions of mADA have different local stability, which controls the activity and stability of the enzyme. The results provide new insights into the relationship between the function of a protein and its conformational flexibility as well as its global stability. This study illustrates the advantage of 19F NMR spectroscopy in probing site-related conformational change information in ligand binding, enzymatic activity and protein folding.     

19F NMR studies of plasminogen activator inhibitor-1

Plasminogen activator inhibitor-1 (PAI-1) is a 43 kDa protein involved in the regulation of fibrinolysis. PAI-1 is the principal inhibitor of tissue-type plasminogen activator (t-PA), trapping the proteinase as an acyl-enzyme covalent complex (approximately 105 kDa). Four single tryptophan mutants of PAI-1 have been constructed in which three of the four tryptophan residues (Trp86, Trp139, Trp175, and Trp262) were replaced with phenylalanine. Biosynthetic incorporation of 5-fluorotryptophan (5F-Trp) into wild-type PAI-1 (5FW wtPAI-1) and the single tryptophan mutants (5FW86, 5FW139, 5FW175, and 5FW262) was achieved, allowing a (19)F NMR spectroscopic study of PAI-1 in its active and cleaved forms and in complex with t-PA. The (19)F NMR spectrum of active 5FW wtPAI-1 shows four clearly resolved peaks at -39.20, -49.26, -50.74, and -52.57 ppm relative to trifluoroacetic acid at 0 ppm. Unequivocal assignments of these four resonances in the spectrum of 5FW wtPAI-1 to specific tryptophan residues were accomplished by measuring the chemical shifts of the (19)F resonances of the single tryptophan mutants. There was close agreement between the resonances observed in 5FW wtPAI-1 and of those in the mutants for all three protein forms. This would imply little structural perturbation in the local structures of the tryptophan residues resulting from substitution by phenylalanine. The 5FW wtPAI-1 was observed to have lower second-order rate constant (k(app)) for the inhibition of t-PA than the natural tryptophan wtPAI-1, suggesting that the decreased activity may result from a small structural effect of the fluorine substituent of the indole ring. Further alterations in the k(app) and the stoichiometry of inhibition (SI) were observed in each of the mutants indicating an effect of the three tryptophan to phenylalanine mutations. Detailed interpretation of the (19)F NMR spectra of the PAI-1 mutants provides insights into the local segmental structure of the active form of the proteins and the structural changes that occur in the cleaved and t-PA complexed forms.     

(19)F NMR studies of the leucine-isoleucine-valine binding protein: evidence that a closed conformation exists in solution

The leucine-isoleucine-valine binding protein (LIV) found in the periplasmic space of E. coli has been used as a structural model for a number of neuronal receptors. This "venus fly trap" type protein has been characterized by crystallography in only the open form. Herein we have labeled LIV with 5-fluorotryptophan (5F-Trp) and difluoromethionine (DFM) in order to explore the structural dynamics of this protein and the application of DFM as a potential (19)F NMR structural probe for this family of proteins. Based on mass spectrometric analysis of the protein overproduced in the presence of DFM, approximately 30% of the five LIV methionine residues were randomly substituted with the fluorinated analog. Urea denaturation experiments imply a slight decrease in protein stability when DFM is incorporated into LIV. However, the fluorinated methionine did not alter leucine-binding activity upon its incorporation into the protein. Binding of L-leucine stabilizes both the unlabeled and DFM-labeled LIV, and induces the protein to adopt a three-state unfolding model in place of the two-state process observed for the free protein. The (19)F NMR spectrum of DFM-labeled LIV gave distinct resonances for the five Met residues found in LIV. 5F-Trp labeled LIV gave a well resolved spectrum for the three Trp residues. Trp to Phe mutants defined the resonances in the spectrum. The distinct narrowing in line width of the resonances when ligand was added identified the closed form of the protein.     

Thermal unfolding in a GCN4-like leucine zipper: 13C alpha NMR chemical shifts and local unfolding curves.

13C alpha chemical shifts and site-specific unfolding curves are reported for 12 sites on a 33-residue, GCN4-like leucine zipper peptide (GCN4-lzK), ranging over most of the chain and sampling most heptad positions. Data were derived from NMR spectra of nine synthetic, isosequential peptides bearing 99% 13C alpha at sites selected to avoid spectral overlap in each peptide. At each site, separate resonances appear for unfolded and folded forms, and most sites show resonances for two folded forms near room temperature. The observed chemical shifts suggest that 1) urea-unfolded GCN4-lzK chains are randomly coiled; 2) thermally unfolded chains include significant transient structure, except at the ends; 3) the coiled-coli structure in the folded chains is atypical near the C-terminus; 4) only those interior sites surrounded by canonical interchain salt bridges fail to show two folded forms. Local unfolding curves, obtained from integrated resonance intensities, show that 1) sites differ in structure content and in melting temperature, so the equilibrium population must comprise more than two molecular conformations; 2) there is significant end-fraying, even at the lowest temperatures, but thermal unfolding is not a progressive unwinding from the ends; 3) residues 9-16 are in the lowest melting region; 4) heptad position does not dictate stability; 5) significant unfolding occurs below room temperature, so the shallow, linear decline in backbone CD seen there has conformational significance. It seems that only a relatively complex array of conformational states could underlie these findings.     

Comparison of C40/82A and P27A C40/82A barstar mutants using 19F NMR

Barstar, an inhibitor of the enzyme barnase, contains two phenylalanine residues, three tryptophan residues, and two proline residues. After incorporating either 2-19F-Phe, 4-19F-Phe, or 6-19F-Trp, the structural, dynamic, and folding properties of two mutants (C40/82A, a double mutant, and P27A C40/82A, a triple mutant) were studied by 19F NMR. Experiments were performed as a function of temperature and urea with the two mutants. We show that the consequences of the P27A mutation are extensive. The effect of the mutation is transmitted to distant residues (Phe56 and Trp53) as well as to a residue deeply buried in the hydrophobic core (Phe74). By incorporating 2-19F-Phe, it is shown that Phe56 undergoes a slow ring flipping on the NMR time scale in the triple mutant that is not observed in the double mutant. On the other hand, incorporating 4-19F-Phe shows that the P27A mutation has little effect along the Cbeta-Cgamma axis of Phe56. Labeling with 4-19F-Phe shows, from line broadening, that Phe74 experiences more dynamic motion than does Phe56 in both the double and triple mutant. After incorporating 6-19F-Trp, it is found that, in the triple mutant, Trp53 shows conformational heterogeneity at low temperature while Trp44, which is close to the P27A mutation, does not. At 20 degrees C, residual native-like structure was detected around Trp53 at high concentrations of denaturant. Barstar is cold denatured in the presence of urea. For the double mutant at temperatures below 15 degrees C, and in the presence of 2.5-3.5 M urea, the resonance for Phe74 broadens, and two peaks are observed at 5 degrees C indicative of an exchange process. From line-shape analysis, assuming a two-site conformational exchange, the rate constants as a function of temperature can be extracted. An Eyring plot is linear at 0 M urea but deviates from linearity below 20 degrees C in the presence of 2.5 or 3.5 M urea. The data as a function of urea suggest sequential events in the unfolding process.     

Insights into signal transduction revealed by the low resolution structure of the FixJ response regulator

P19(INK4d) is a tumor suppressing protein and belongs to a family of cyclin D-dependent kinase inhibitors of CDK4 and CDK6, which play a key role in human cell cycle control. P19 comprises ten alpha-helices arranged sequentially in five ankyrin repeats forming an elongated structure. This rather simple topology, combined with its physiological function, makes p19 an interesting model protein for folding studies. Urea-induced unfolding transitions monitored by far-UV CD and phenylalanine fluorescence coincide and suggest a two-state mechanism for equilibrium unfolding. Unfolding of p19 followed by 2D (1)H-(15)N HSQC spectra revealed a third species at moderate urea concentrations with a maximum population of about 30 % near 3.2 M urea. It shows poor chemical shift dispersion, but cross-peaks emerge for some residues that are distinct from the native or unfolded state. This equilibrium intermediate either arises only at high protein concentrations (as in the NMR experiment) or has similar optical properties to the unfolded state. Stopped-flow far-UV CD experiments at various urea concentrations revealed that alpha-helical structure is formed in three phases, of which only the fastest phase (10 s(-1)) depends upon the urea concentration. The kinetic of the slowest phase (0.017 s(-1)) can be resolved by 1D real-time NMR and accelerated by cyclophilin. It is limited in rate by prolyl isomerization, and native-like ordered structure cannot form prior to this isomerization. The two fast phases lead to 83 % native protein within the dead time of the NMR experiment. In contrast to p16(INK4a), which exhibits only a marginal stability and high unfolding rates, p19 shows the expected stability for a protein of this size with a clear kinetic barrier between the unfolded and folded state. Therefore, p19 might complement the function of less stable INK4 inhibitors in cell cycle control under unfavorable conditions.     

Nuclear magnetic resonance titration curves of histidine ring protons. Ribonuclease S-peptide and S-proteins.

The histidine C-2 proton NMR titration curves of ribonuclease S-peptide (residues 1 to 20) and S-protein (residues 21 to 124) are reported. Although S-protein contains 3 histidine residues, four discrete resonances are observed to titrate. One of these arises from the equivalent histidine residues of unfolded S-protein. The variation in area of the four resonances indicate that there is a reversible pH-dependent equilibrium between the folded and unfolded forms of S-protein, with some unfolded material being present at most pH values. Two of the resonances of the folded S-protein can be assigned to 2 of the histidine residues, 48 and 105, from the close similarity of their titration curves to those in ribonuclease. These similarities indicate a homology of portions of the folded conformation of S-protein to that of ribonuclease in solution. These results indicate that the complete amino acid sequence is not required to produce a folded conformation similar to the native globular protein, and they appear to eliminate the possibility that proteins fold from their NH2 terminus during protein synthesis. The low pH inflection present in the titration curve assigned to histidine residue 48 in ribonuclease is absent from this curve in S-protein. This is consistent with our previous conclusion that this inflection arises from the interaction of histidine 48 with aspartic acid residue 14, which is also absent in S-protein. The third titrating resonance of native S-protein is assigned to the remaining histidine residue at position 119. The properties of this resonance are not identical with either of the titration curves of the active site histidine residues 12 and 119 of ribonuclease. The resonance assigned to histidine 119 is the only one significantly affected on the addition of sodium phosphate to S-protein, indicating that some degree of phosphate binding occurs. In both the absence and presence of phosphate this curve also lacks the low pH inflection observed in the histidine 119 NMR titration curve in ribonuclease. This difference presumably arise from a conformational between ribonuclease and the folded S-protein involving a carboxyl group.     

Urea Impedes the Hydrophobic Collapse of Partially Unfolded Proteins

Proteins are denatured in aqueous urea solution. The nature of the molecular driving forces has received substantial attention in the past, whereas the question how urea acts at different phases of unfolding is not yet well understood at the atomic level. In particular, it is unclear whether urea actively attacks folded proteins or instead stabilizes unfolded conformations. Here we investigated the effect of urea at different phases of unfolding by molecular dynamics simulations, and the behavior of partially unfolded states in both aqueous urea solution and in pure water was compared. Whereas the partially unfolded protein in water exhibited hydrophobic collapses as primary refolding events, it remained stable or even underwent further unfolding steps in aqueous urea solution. Further, initial unfolding steps of the folded protein were found not to be triggered by urea, but instead, stabilized. The underlying mechanism of this stabilization is a favorable interaction of urea with transiently exposed, less-polar residues and the protein backbone, thereby impeding back-reactions. Taken together, these results suggest that, quite generally, urea-induced protein unfolding proceeds primarily not by active attack. Rather, thermal fluctuations toward the unfolded state are stabilized and the hydrophobic collapse of partially unfolded proteins toward the native state is impeded. As a result, the equilibrium is shifted toward the unfolded state.     

An NMR view of the folding process of a CheY mutant at the residue level

The folding of CheY mutant F14N/V83T was studied at 75 residues by NMR. Fluorescence, NMR, and sedimentation equilibrium studies at different urea and protein concentrations reveal that the urea-induced unfolding of this CheY mutant includes an on-pathway molten globule-like intermediate that can associate off-pathway. The populations of native and denatured forms have been quantified from a series of 15N-1H HSQC spectra recorded under increasing concentrations of urea. A thermodynamic analysis of these data provides a detailed picture of the mutant's unfolding at the residue level: (1) the transition from the native state to the molten globule-like intermediate is highly cooperative, and (2) the unfolding of this state is sequential and yields another intermediate showing a collapsed N-terminal domain and an unfolded C-terminal tail. This state presents a striking similarity to the kinetic transition state of the CheY folding pathway.     

Equilibrium unfolding of dimeric and engineered monomeric forms of lambda Cro (F58W) repressor and the effect of added salts: evidence for the formation of folded monomer induced by sodium perchlorate

The equilibrium unfolding transitions of Cro repressor variants, dimeric variant Cro F58W and monomer Cro K56[DGEVK]F58W, have been studied by urea and guanidine hydrochloride to probe the folding mechanism. The unfolding transitions of a dimeric variant are well described by a two state process involving native dimer and unfolded monomer with a free energy of unfolding, DeltaG(0,un)(0), of approximately 10-11 kcal/mol. The midpoint of transition curves is dependent on total protein concentration and DeltaG(0,un)(0) is independent of protein concentration, as expected for this model. Unfolding of Cro monomer is well described by the standard two state model. The stability of both forms of protein increases in the presence of salt but decreases with the decrease in pH. Because of the suggested importance of a N2<-->2F dimerization process in DNA binding, we have also studied the effect of sodium perchlorate, containing the chaotropic perchlorate anion, on the conformational transition of Cro dimer by CD, fluorescence and NMR (in addition to urea and guanidine hydrochloride) in an attempt both to characterize the thermodynamics of the process and to identify conditions that lead to an increase in the population of the folded monomers. Data suggest that sodium perchlorate stabilizes the protein at low concentration (<1.5 M) and destabilizes the protein at higher perchlorate concentration with the formation of a "significantly folded" monomer. The tryptophan residue in the "significantly folded" monomer induced by perchlorate is more exposed to the solvent than in native dimer.     

Correlation between mutational destabilization of phage T4 lysozyme and increased unfolding rates

The thermodynamics and kinetics of unfolding of 28 bacteriophage T4 lysozyme variants were compared by using urea gradient gel electrophoresis. The mutations studied cause a variety of sequence changes at different residues throughout the polypeptide chain and result in a wide range of thermodynamic stabilities. A striking relationship was observed between the thermodynamic and kinetic effects of the amino acid replacements: All the substitutions that destabilized the native protein by 2 kcal/mol or more also increased the rate of unfolding. The observed increases in unfolding rate corresponded to a decrease in the activation energy of unfolding (delta Gu) at least 35% as large as the decrease in thermodynamic stability (delta Gu). Thus, the destabilizing lesions bring the free energy of the native state closer to that of both the unfolded state and the transition state for folding and unfolding. Since a large fraction of the mutational destabilization is expressed between the transition state and the native conformation, the changes in folding energetics cannot be accounted for by effects on the unfolded state alone. The results also suggest that interactions throughout much of the folded structure are altered in the formation of the transition state during unfolding.     

Nuclear magnetic resonance studies of 6-fluorotryptophan-substituted rat cellular retinol-binding protein II produced in Escherichia coli. Analysis of the apoprotein and the holoprotein containing bound all-trans-retinol and all-trans-retinal

Rat cellular retinol-binding protein II (CRBP II) is a 15.6-kDa intestinal protein which binds all-trans-retinol and all-trans-retinal but not all-trans-retinoic acid. We have previously analyzed the interaction of Escherichia coli-derived rat apoCRBP II with several retinoids using fluorescence spectroscopic techniques. Interpretation of these experiments is complicated, because the protein has 4 tryptophan residues. To further investigate ligand-protein interactions, we have utilized 19F nuclear magnetic resonance (NMR) spectroscopy of CRBP II labeled at its 4 tryptophan residues with 6-fluorotryptophan. Efficient incorporation of 6-fluorotryptophan (93%) was achieved by growing a tryptophan auxotroph of E. coli harboring a prokaryotic expression vector with a full-length rat CRBP II cDNA on defined medium supplemented with the analog. Comparison of the 19F NMR spectra of 6-fluorotryptophan-substituted CRBP II with and without bound all-trans-retinol revealed that resonances corresponding to 2 tryptophan residues (designated WA and WB) undergo large downfield changes in chemical shifts (2.0 and 0.5 ppm, respectively) associated with ligand binding. In contrast, 19F resonances corresponding to two other tryptophan residues (WC and WD) undergo only minor perturbations in chemical shifts. The 19F NMR spectra of 6-fluorotryptophan-substituted CRBP II complexed with all-trans-retinal and all-trans-retinol were very similar, suggesting that the interactions of these two ligands with the protein are similar. Molecular model building, based on the crystalline structures of two homologous proteins was used to predict the positions of the 4 tryptophan residues of CRBP II and to make tentative resonance assignments. The fact that ligand binding produced residue-specific changes in the chemical shifts of resonances in CRBP II suggests that NMR analysis of isotopically labeled retinoid-binding proteins expressed in E. coli will provide an alternate, albeit it complementary, approach to fluorescence spectroscopy for examining the structural consequences of their association with ligand.     

The use of p-fluorobenzenesulfonyl chloride as a reagent for studies of proteins by fluorine nuclear magnetic resonance

The reagent p-fluorobenzenesulfonyl chloride modifies the protein side chains of tyrosine, lysine, and histidine and the alpha-NH2 group. The p-fluorobenzenesulfonyl (Fbs-) group, identified by the 19F nuclear magnetic resonance signal, exhibits a different 19F chemical shift for each functional group modified. The Fourier-transformed spectra of the Fbs- group displayed the expected nine-line multiplet in Fbs- amino acids and simple Fbs- peptides but not in the Fbs- proteins, where the resolution was less. Lysozyme, RNase, DNase, and chymotrypsin react with this reagent and each Fbs- protein exhibits a distinctive pattern of 19F NMR signals due to the label, suggesting that the reaction of the reagent varies with the reactivity of the side chains in a protein. The three major 19F signals of the unfolded Fbs-RNase in 8 M urea are due to the Fbs- label on the imidazolium, alpha-NH2, and epsilon-NH2 groups. Based upon results from amino acid and 19F NMR analyses of the tryptic-chymotryptic peptides of Fbs-RNase, portions of the imidazolium and epsilon-NH2 resonances were assigned to the Fbs- label on His-105 and Lys-41, respectively, while the alpha-NH2 resonance was entirely due to the Fbs- label on the alpha-NH2 of Lys-1. Because Fbs-RNase has an unchanged, near-ultraviolet circular dichroism spectrum and because it retains approximately 80% of the RNase activity, the conformation of Fbs-RNase is probably not altered from the folded conformation of the native enzyme. Upon unfolding in 8 M urea or heating at 70 degrees C, Fbs-RNase gave a 19F NMR spectrum differing from that of the folded Fbs-RNase. In the presence of uridylic acid, Lys-41 was the only residue protected from modification by the reagent with a concomitant reduction of the epsilon-NH2 resonance, and the RNase thus modified was fully active. Hence, 19F NMR analysis of protein, via the reaction with p-fluorobenzenesulfonyl chloride, provided not only information about the protein conformation but also direct measurements of the modification status.     

Apparent pKa shifts of titratable residues at high denaturant concentration and the impact on protein stability

Urea and guanidine-hydrochloride (GdnHCl) are frequently used for protein denaturation in order to determine the Gibbs free energy of folding and kinetic folding/unfolding parameters. Constant pH value is applied in the folding/unfolding experiments at different denaturant concentrations and steady protonation state of titratable groups is assumed in the folded and unfolded protein, respectively. The apparent side-chain pKa values of Asp, Glu, His and Lys in the absence and presence of 6 M urea and GdnHCl, respectively, have been determined by 1H-NMR. pKa values of all four residues are up-shifted by 0.3-0.5 pH units in presence of 6 M urea by comparison with pKa values of the residues dissolved in water. In the presence of 6 M GdnHCl, pKa values are down-shifted by 0.2-0.3 pH units in the case of acidic and up-shifted by 0.3-0.5 pH units in the case of basic residues. Shifted pKa values in the presence of denaturant may have a pronounced effect on the outcome of the protein stability obtained from denaturant unfolding experiments.     

A 19F-NMR study of the membrane-binding region of D-lactate dehydrogenase of Escherichia coli.

D-Lactate dehydrogenase (D-LDH) is a membrane-associated respiratory enzyme of Escherichia coli. The protein is composed of 571 amino acid residues with a flavin adenine dinucleotide (FAD) cofactor, has a molecular weight of approximately 65,000, and requires lipids or detergents for full activity. We used NMR spectroscopy to investigate the structure of D-LDH and its interaction with phospholipids. We incorporated 5-fluorotryptophan (5F-Trp) into the native enzyme, which contains five tryptophan residues, and into mutant enzymes, where a sixth tryptophan is substituted into a specific site by oligonucleotide-directed mutagenesis, and studied the 5F-Trp-labeled enzymes using 19F-NMR spectroscopy. In this way, information was obtained about the local environment at each native and substituted tryptophan site. Using a nitroxide spin-labeled fatty acid, which broadens the resonance from any residue within 15 A, we have established that the membrane-binding area of the protein includes the region between Tyr 228 and Phe 369, but is not continuous within this region. This conclusion is strengthened by the results of 19F-NMR spectroscopy of wild-type enzyme labeled with fluorotyrosine or fluorophenylalanine in the presence and absence of a nitroxide spin-labeled fatty acid. These experiments indicate that 9-10 Phe and 3-4 Tyr residues are located near the lipid phase.     

19F nuclear magnetic resonance studies of 6-fluorotryptophan-substituted rat cellular retinol binding protein II produced in Escherichia coli. An analysis of four tryptophan substitution mutants and their interactions with all-trans-retinol

Rat cellular retinol binding protein (CRBP II) is a 134-amino acid intracellular protein synthesized in the polarized absorptive cells of the intestine. We have previously used 19F nuclear magnetic resonance (NMR) spectroscopy to survey the structural effects of ligand binding on the apoprotein. For these studies, all 4 Trp residues of rat CRBP II were efficiently labeled with 6-fluorotryptophan (6-F-Trp) by inducing its expression in a tryptophan auxotroph of Escherichia coli. Resonances corresponding to 2 of its Trp residues underwent large downfield shifts upon binding of all-trans-retinol and retinal, while resonances corresponding to the other 2 Trp residues underwent only minor perturbations in chemical shifts. To identify which Trp residues undergo changes in their environment upon ligand binding, we have constructed four CRBP II mutants where Trp9, Trp89, Trp107, or Trp110 have been replaced by another hydrophobic amino acid. By comparing the 19F NMR spectrum of each 6-F-Trp-labeled mutant with that of wild type 6-F-Trp CRBP II, we demonstrate that the 19F resonance corresponding to Trp107 undergoes the largest change in chemical shift upon ligand binding (2.0 ppm downfield). This is consistent with the position of this residue predicted from molecular modeling studies. The 19F resonance corresponding to Trp9 also undergoes a downfield change in chemical shift of 0.5 ppm associated with retinol binding even though it is predicted to be removed from the ligand binding site. By contrast, the resonances assigned to Trp89 and Trp110 undergo only minor perturbations in chemical shifts. These results have allowed us to identify residue-specific probes for evaluating the interactions of all-trans-retinol (and other retinoids) with this intracellular binding protein.     

Phenylalanine side chain behavior of the intestinal fatty acid-binding protein: the effect of urea on backbone and side chain stability

The equilibrium unfolding behavior of the intestinal fatty acid-binding protein has been investigated by (19)F-NMR after incorporation of 4-fluorophenylalanine and by pulsed field gradient diffusion (1)H-NMR. At low urea concentrations (0-3 m) but prior to the global unfolding that begins at 4 m urea, the protein exhibits dynamic motion in the backbone and an expanded hydrodynamic radius with no major change in the side chain orientation. As monitored by two-dimensional (19)F-(19)F nuclear Overhauser effect, the distance between two phenylalanine residues (Phe(68) and Phe(93)) located in the two different beta-sheets that enclose the internal cavity did not change up to 4 m urea. Additionally, the chemical shifts of these two residues changed almost identically as a function of denaturant. At all urea concentrations, as well as in the native protein, multiple conformations exist. These conformers interconvert at different rates under different conditions, ranging from slow exchange by showing separate peaks in the native state to intermediate exchange at intermediate urea concentrations. Residual structure persisted around Phe(62) even at very high concentrations of denaturant, suggesting that region as a nucleation site during folding. The results were compared with previous studies examining the backbone behavior (Hodsdon, M. E., and Frieden, C. (2001) Biochemistry 40, 732-742) and suggest that the side chains show more stability than the backbone prior to global unfolding of the protein.     

NMR-detected order in core residues of denatured bovine pancreatic trypsin inhibitor

The NMR characteristics of [14-38]Abu, a synthetic variant of BPTI that is partially folded in aqueous buffer near neutral pH, support a model of early folding events which begin with stabilization of the nativelike, slow exchange core [Barbar, E., Hare, M., Daragan, V., Barany, G., and Woodward, C. (1998) Biochemistry 37, 7822-7833 (1)]. In partially folded [14-38]Abu, urea denaturation profiles for representative amide protons show that global unfolding is non-two-state and that core residues require a higher concentration of urea to unfold. Dynamic properties of pH-denatured [14-38]Abu and fully reduced and unfolded BPTI analogue were determined from heteronuclear NMR relaxation measurements at similar solution conditions. Differences at various sites in the polypeptide chain were evaluated from spectral density functions determined from T1, T2, and steady-state heteronuclear NOE data. Although denatured [14-38]Abu contains no persistent secondary structure, its most ordered residues are those that, in native BPTI, fold into the slow exchange core. The fully reduced analogue is significantly more mobile and shows less heterogeneous dynamics, but at 1 degree C, restricted motion is observed for residues in the central segments of the polypeptide chain. These observations indicate that there is a developing core or cores even in highly unfolded species. Apparently the effect of 14-38 disulfide on unfolded