Fluorine Magnetic Resonance in Biochemistry

Probing DNA mismatched and bulged structures by using 19F NMR spectroscopy and oligodeoxynucleotides with an 19F-labeled nucleobase

In this study, DNA local structures with bulged bases and mismatched base pairs as well as ordinary full-matched base pairs by using (19)F NMR spectroscopy with (19)F-labeled oligodeoxynucleotides (ODNs) were monitored. The chemical shift change in the (19) F NMR spectra allowed discrimination of the DNA structures. Two types of ODNs possessing the bis(trifluoromethyl)benzene unit (F-unit) at specified uridines were prepared and hybridized with their complementary or noncomplementary strands to form matched, mismatched, or bulged duplexes. By using ODN F1, in which an F-unit was connected directly to a propargyl amine-substituted uridine, three local structures, that is, full-matched, G-U mismatch, and A-bulge could be analyzed, whereas other structures could not be discriminated. A molecular modeling study revealed that the F-unit in ODN F1 interacted little with the nucleobases and sugar backbone of the opposite strand because the linker length between the F-unit and the uridine base was too short. Therefore, the capacity of ODN F1 to discriminate the DNA local structures was limited. Thus, ODN F2 was designed to improve this system; aminobenzoic acid was inserted between the F-unit and uridine base so the F-unit could interact more closely with the opposite strand. Eventually, the G-bulge and T-U mismatch and the three aforementioned local structures could be discriminated by using ODN F2. In addition, the dissociation processes of these duplexes could be monitored concurrently by (19)F NMR spectroscopy.

Monitoring of duplex and triplex formation by 19F NMR using oligodeoxynucleotides possessing 5-fluorodeoxyuridine unit as 19F signal transmitter

We prepared oligodeoxynucleotides (ODNs) possessing a 5-fluorodeoxyuridine (5-FU) unit as a 19F-signal transmitter, and characterized their structures including single strand, duplex, and triplex using 19F NMR. The change in chemical shift induced by incorporation of 5-FU into the ODNs and the formation of higher order structures allowed monitoring of structural changes. Data from UV melting experiments and CD spectra were consistent with the spectral changes in the NMR studies. These 19F-labeled ODNs may be promising molecular probes for the identification of DNA structures in complicated biological conditions.

The molecular basis for the high photosensitivity of rhodopsin

Based on structural information derived from the F NMR data of labeled rhodopsins, rhodopsin crystal structure, and excited-state properties of model polyenes, we propose a molecular mechanism that accounts specifically for the causes of the well-known enhanced photoreactivity of rhodopsin (increased rates and quantum yield of isomerization). It involves the key features of close proximity of C-187 to H-12 and chromophore bond lengthening upon light absorption. The resultant "sudden punch" to H-12 triggers dual processes of decay of the Franck-Condon-excited rhodopsin, a productive directed photoisomerization and a nonproductive decay returning to the ground state as two separate molecular pathways [based on real-time fluorescence results of Chosrowjan, H., Mataga, N., Shibata, Y., Tachibanaki, S., Kandori, H., Shichida, Y., Okada, T. & Kouyama, T. (1998) J. Am. Chem. Soc. 120, 9706-9707]. The two processes are controlled by the local protein structure: an empty space provided by the intradiscal loop connecting transmembrane helices 4 and 5 and a protein wall composed of amino acid units in transmembrane 3. Suggestions, involving retinal analogs and rhodopsin mutants, to improve the unusually high photosensitivity of rhodopsin are proposed.

19F NMR studies with 2'-F-2'-deoxyarabinoflavoproteins

Apoproteins of several flavoproteins were reconstituted with 2'-F-2'-deoxyarabinoflavins and studied by 19F NMR and absorption spectroscopy. Extensive protein-fluorine interactions were observed by large chemical shift changes on binding to the apoprotein of Old Yellow Enzyme (apoOYE) and apoflavodoxin, whereas binding to apoglucose oxidase and apo -amino acid oxidase (apoDAAO) resulted in minimal interactions. Modification at the flavin 2'-position in OYE resulted in a substantial decrease in the binding affinity of the flavin, possibly from the disruption of two important hydrogen bonds to Pro-35 and Arg-243. 19F NMR studies of complexes of OYE with testosterone, cyclohexenone, and beta-estradiol suggest that phenols and alpha,beta-unsaturated ketones orient differently at the active site on binding. The two separate one-electron potentials for the EFlox/EFlsq and EFlsq/EFlred couples were different for the reconstituted OYE. With native enzyme, there is 15-20% thermodynamic stabilization of the anionic flavin semiquinone, while no detectable amount of semiquinone was observed with modified OYE. This change in potential was further substantiated by blue shifts for the maxima of the modified protein-phenol charge transfer complexes. In accordance with the crystal structure of the OYE-p-OH-benzaldehyde complex (Fox, K.M. & Karplus, P.A. (1994) Structure 2, 1089-1105), 19F NMR studies with the modified OYE-2,4-F2-phenol suggest strong interaction between the para-fluorine of the phenol and Tyr-375.

Contribution of the tyrosines to the structure and function of the human U1A N-terminal RNA binding domain

RNA binding domains (RBDs) are members of a large family of proteins that share minimal sequence conservation but adopt an alpha beta sandwich global fold. Defining the contributions of specific amino acids to RBD structure and RNA binding is critical to understanding the functions of these proteins. In these experiments with the human U1A N-terminal RNA binding domain (RBD1), the contributions from each of its four tyrosines to protein structure, stability, and RNA binding were measured. Each tyrosine was substituted with phenylalanine and one other selected residue, and the resulting proteins were characterized by chemical denaturation to measure their unfolding free energy, by binding free energies to the wild-type RNA hairpin, and by 19F NMR to probe for structural changes. Features of the protein identified in these experiments include a possible tyrosine/lysine contact in an alpha-helix, which may be an example of an energetically favorable aromatic/amino side chain interaction. One long loop of the protein, which shows unusual 15N backbone and tyrosine side-chain dynamics, is implicated in protein:protein association. The diverse interactions of the four tyrosine residues in the organization of RBD1 illustrate how each member of this family of proteins will have unique molecular details that contribute to function.

Evaluation of Solvent Accessibility to the [Fe(4)S(4)] Binding Pocket in Native and Tyr19 Mutant High Potential Iron Proteins by (1)H-(15)N HMQC and (19)F NMR Experiments

The solvent accessibility of Chromatium vinosumhigh potential iron protein (HiPIP) has been investigated by use of (1)H-(15)N HMQC, and (19)F NMR spectroscopy. These NMR experiments indicate that solvent accessibility to the cluster core is similar, and minimal, for the reduced and oxidized states of native HiPIP, but increases significantly for mutant proteins (Tyr19Leu and Tyr19His). These results support a proposed role [Agarwal, A.; Li, D.; Cowan, J. A. Proc. Natl. Acad. Sci. U.S.A. 1995, 92, 9440-9444] for Tyr19 in maintaining hydrolytic stability of the [Fe(4)S(4)] cluster, and demonstrate a general strategy for mapping out the solvent accessibility of protein-bound metalloredox prosthetic centers.

Detection of site-specific binding and co-binding of ligands to macromolecules using 19F NMR

Study of ligand-macromolecular interactions by 19F nuclear magnetic resonance (NMR) spectroscopy affords many opportunities for obtaining molecular biochemical and pharmaceutical information. This is due to the absence of a background fluorine signal, as well as the relatively high sensitivity of 19F NMR. Use of fluorine-labeled ligands enables one to probe not only binding and co-binding phenomena to macromolecules, but also can provide data on binding constants, stoichiometries, kinetics, and conformational properties of these complexes. Under conditions of slow exchange and macromolecule-induced chemical shifts, multiple 19F NMR resonances can be observed for free and bound ligands. These shifted resonances are a direct correlate of the concentration of ligand bound in a specific state rather than the global concentrations of bound or free ligand which are usually determined using other techniques such as absorption spectroscopy or equilibrium dialysis. Examples of these interactions are demonstrated both from the literature and from interactions of 5-fluorotryptophan, 5-fluorosalicylic acid, flurbiprofen, and sulindac sulfide with human serum albumin. Other applications of 19F NMR to study of these interactions in vivo, as well for receptor binding and metabolic tracing of fluorinated drugs and proteins are discussed.

19F NMR studies on 8-fluoroflavins and 8-fluoro flavoproteins

The 19F NMR spectra of the oxidized and reduced forms of 8-fluororiboflavin, 8-fluoro-FAD, and the 8-fluoroflavin-reconstituted flavoproteins flavodoxin, riboflavin binding protein, D-amino acid oxidase, p-hydroxybenzoate hydroxylase, Old Yellow Enzyme, anthranilate hydroxylase, general acyl-CoA dehydrogenase, glucose oxidase, and L-lactate oxidase were measured. For the proteins studied the oxidized resonances appeared over a 10.1-ppm range, while the reduced resonances were spread over 10.3 ppm. Reduction caused an upfield shift of about 27 ppm for the free 8-fluoroflavins and most of the 8-fluoro flavoproteins. The notable exception was 8-fluoro-FMN flavodoxin, which was shifted 37.6 ppm, indicating an unusually high electron density in the benzene ring. Ligand binding to the oxidized 8-fluoro flavoproteins caused either upfield or downfield shifts of 1.5-5 ppm, depending on the protein/ligand combination. The 8-fluoro-FAD anthranilate hydroxylase resonance was shifted downfield and split into two peaks in the presence of anthranilate. The 8-fluoro-FMN Old Yellow Enzyme resonance was shifted upfield upon complexation with charge-transfer-forming, para-substituted phenolates. The upfield shift increased from less than 1 to 5 ppm as the electron-donating capacity of the phenolate increased. Complexation of native Old Yellow Enzyme with 2,4-difluorophenol caused the fluorine resonances of the ligand to shift and split into two pairs of signals. Each pair of signals was associated with a different isozyme of Old Yellow Enzyme.

Fluorinated carbohydrates as potential plasma membrane modifiers and inhibitors. Synthesis of 2-acetamido-2,6-dideoxy-6-fluoro-D-galactose

Reaction of benzyl 2-acetamido-3,4-di-O-benzyl-2-deoxy-6-O-mesyl-alpha-D-galactopyran oside with cesium floride gave benzyl 2-acetamido-3,6-anhydro-4-O-benzyl-2-deoxy-alpha-D-galactopyranoside instead of the desired 6-fluoro derivative. Acetonation of benzyl 2-acetamido-2-deoxy-6-O-mesyl-alpha-D-galactopyranoside gave the corresponding 3,4-O-isopropylidene derivative. The 6-O-mesyl group was displaced by fluorine with cesium fluoride in boiling 1,2-ethanediol, and hydrolysis and subsequent N-acetylation gave the target compound. In another procedure, treatment of 2-acetamido-1,3,4-tri-O-acetyl-2-deoxy-alpha-D-galactose with N-(diethylamino)sulfur trifluoride gave 2-acetamido-1,3,4-tri-O-acetyl-2,6-dideoxy-6-fluoro-D-galactose which, on acid hydrolysis followed by N-acetylation, gave 2-acetamido-2,6-dideoxy-6-fluoro-D-galactose.

Fluorine-NMR studies of chimpanzee hemoglobin

It has been demonstrated that 4-fluorophenylalanine, a known inhibitor of protein synthesis, becomes incorporated into hemoglobin when present in the diet of a chimpanzee. 19F-NMR spectra of various forms of this protein show well-resolved lines, each line presumably corresponding to a unique phenylalanine/fluorophenylalanine position of the primary sequence. Fluorine chemical shifts and, by implication, tertiary structures vary with the oxidation state and ligand.

Photosensitivity of 10-substituted visual pigment analogues: detection of a specific secondary opsin-retinal interaction

The photosensitivities of the bovine rhodopsin and gecko pigment 521 analogues regenerated from C-10-substituted analogues of 11-cis- and 9-cis-retinals were determined by two different methods. A similar reactivity trend was noted for both pigment systems as revealed in the photosensitivity of the gecko pigments and relative quantum yields of the bovine analogues. The 10-fluoro-11-cis photopigments had a photosensitivity less than, but approaching, that of the native (11-cis) visual pigment while the 10-fluoro-9-cis photopigments had a much lower photosensitivity than the parent 9-cis regenerated pigment. The results are interpreted in terms of recently described models of rhodopsin architecture and of the primary molecular reaction of visual pigments to light. The unusually low photoreactivity of the 10-fluoro-9-cis pigment molecule is viewed as the result of a regiospecific hydrogen-bonding interaction of the electronegative fluorine atom to the opsin.

Motion at the active site of [(4-fluorophenyl)sulfonyl]chymotrypsin

Fluorine and deuterium NMR relaxation studies have been used to examine the motion of the 4-fluorophenyl ring attached to the active site of [(4-fluorophenyl)sulfonyl]-alpha-chymotrypsin at pH 4. Analysis of the results indicates that rotation about the 2-fold axis of this ring is reasonably rapid, though not as fast as in tosylchymotrypsin. Two-dimensional (2D) nuclear Overhauser effects (NOEs) were used to suggest the shifts of those protons of the enzyme close enough to the fluorine nucleus to lead to relaxation; important proton-fluorine dipolar relaxation contributions arise from protons with shifts of 7.4 +/- 0.3 ppm and between 4.0 and 5.4 ppm. Specific deuteration permits the assignment of the first of these to the protons ortho to the fluorine while serine-189, cysteines-191 and -220, and methionine-192 are suggested as possible bearers of the other protons. The fluorine chemical shift effect observed for the native conformation of this protein is 9 ppm downfield of the shift observed with the denatured protein; this large shift may be the result of van der Waals interactions between the fluorine and one or more of the protons whose signals appear in the 2D NOE experiments.

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.

Noninvasive observations of fluorinated anesthetics in rabbit brain by fluorine-19 nuclear magnetic resonance

Fluorinated anesthetics were observed noninvasively in the brain of intact rabbits with fluorine-19 nuclear magnetic resonance spectroscopy. High-resolution fluorine-19 spectra of halothane, methoxyflurane, and isoflurane were obtained with a surface coil centered over the calvarium. Elimination of halothane from the brain was also monitored by this technique. Residual fluorine-19 signals from halothane (or a metabolite) could be detected as long as 98 hours after termination of anesthesia. These observations demonstrate the feasibility of using this technique to study the fate of fluorinated anesthetics in live mammals.

Multiple environments of fluorinated anesthetics in intact tissues observed with 19F NMR spectroscopy

The incorporation of two fluorine-containing general anesthetic agents, halothane and methoxyflurane, into erythrocytes (from three different species), rabbit muscle and rabbit nerve, was followed with 19F NMR spectroscopy. Two major findings emerged from these studies: (1) multiple environments indicative of domain structure in the membrane can be observed depending on the anesthetic and the tissue type; and (2) the 19F chemical shifts of a given anesthetic were characteristic for the tissue examined. Halothane showed a single resonance in erythrocytes and multiple resonances in muscle and nerve, while methoxyflurane showed multiple resonances in both muscle and erythrocytes. The range of the 19F chemical shifts for the multiple peaks was as great as 6 ppm.

Synthesis and 19F spectra of tetra-L-alanine analogs containing selectively incorporated 3-fluoro-L-alanine residues

The synthesis of analogs of tetra-L-alanine containing 3-fluoro-L-alanine selectively incorporated at each position is described. The standard procedures in the literature used to couple L-alanine peptides together were often found to lead to undesired products, or elimination reactions when corresponding 3-fluoro-L-alanine peptide analogs were used. Several modified procedures have thus been developed for the synthesis of fluorine-substituted analogs. In addition, the pH-dependence of 19F n.m.r. spectra of 3-fluoro-L-alanine and the tetrapeptide analogs is presented.

A biochemical study of the reconstitution of D-lactate dehydrogenase-deficient membrane vesicles using fluorine-labeled components

Fluorine-19 labeled compounds have been incorporated into lipids and proteins of Escherichia coli. 19F-Labeled membrane vesicles, prepared by growing a fatty acid auxotroph of a D-lactate dehydrogenase-deficient strain on 8,8-difluoromyristic acid, can be reconstituted for oxidase and transport activities by binding exogenous D-lactate dehydrogenase. 19F-Labeled D-lactate dehydrogenases prepared by addition of fluorotryptophans to a tryptophan-requiring strain are able to reconstitute D-lactate dehydrogenase-deficient membrane vesicles. Thus, lipid and protein can be labeled independently and used to investigate protein-lipid interactions in membranes.