Correlations between fluorine-19 nuclear magnetic resonance chemical shift and the secondary and tertiary structure of 5-fluorouracil-substituted tRNA.

To complete assignment of the 19F nuclear magnetic resonance (NMR) spectrum of 5-fluorouracil-substituted Escherichia coli tRNA(Val), resonances from 5-fluorouracil residues involved in tertiary interactions have been identified. Because these assignments could not be made directly by the base-replacement method used to assign 5-fluorouracil residues in loop and stem regions of the tRNA, alternative assignment strategies were employed. FU54 and FU55 were identified by 19F homonuclear Overhauser experiments and were then assigned by comparison of their 19F NMR spectra with those of 5-fluorouracil-labeled yeast tRNA(Phe) mutants having FU54 replaced by adenine and FU55 replaced by cytosine. FU8 and FU12, were assigned from the 19F NMR spectrum of the tRNA(Val) mutant in which the base triple G9-C23-G12 substituted for the wild-type A9-A23-FU12. Although replacement of the conserved U8 (FU8) with A or C disrupts the tertiary structure of tRNA(Val), it has only a small effect on the catalytic turnover number of valyl-tRNA synthetase, while reducing the affinity of the tRNA for enzyme. Analysis of the 19F chemical shift assignments of all 14 resonances in the spectrum of 5-fluorouracil-substituted tRNAVal indicated a strong correlation to tRNA secondary and tertiary structure. 5-Fluorouracil residues in loop regions gave rise to peaks in the central region of the spectrum, 4.4 to 4.9 parts per million (p.p.m.) downfield from free 5-fluorouracil. However, the signal from FU59, in the T-loop of tRNA(Val), was shifted more than 1 p.p.m. downfield, to 5.9 p.p.m., presumably because of the involvement of this fluorouracil in the tertiary interactions between the T and D-loops. The 19F chemical shift moved upfield, to the 2.0 to 2.8 p.p.m. range, when fluorouracil was base-paired with adenine in helical stems. This upfield shift was less pronounced for the fluorine of the FU7.A66 base-pair, located at the base of the acceptor stem, an indication that FU7 is only partially stacked on the adjacent G49 in the continuous acceptor stem/T-stem helix. An unanticipated finding was that the 19F resonances of 5-fluorouracil residues wobble base-paired with guanine were shifted 4 to 5 p.p.m. downfield of those from fluorouracil residues paired with A. In the 19F NMR spectra of all fluorinated tRNAs studied, the farthest downfield peak corresponded to FU55, which replaced the conserved pseudouridine normally found at this position.     

19F NMR of 5-fluorouracil-substituted transfer RNA transcribed in vitro: resonance assignment of fluorouracil-guanine base pairs.

5-Fluorouracil is readily incorporated into active tRNA(Val) transcribed in vitro from a recombinant phagemid containing a synthetic E. coli tRNA(Val) gene. This tRNA has the expected sequence and a secondary and tertiary structure resembling that of native 5-fluorouracil-substituted tRNA(Val), as judged by 19F NMR spectroscopy. To assign resonances in the 19F spectrum, mutant phagemids were constructed having base changes in the tRNA gene. Replacement of fluorouracil in the T-stem with cytosine, converting a FU-G to a C-G base pair, results in the loss of one downfield peak in the 19F NMR spectrum of the mutant tRNA(Val). The spectra of other mutant tRNAs having guanine for adenine substitutions that convert FU-A to FU-G base pairs all have one resonance shifted 4.5 to 5 ppm downfield. These results allow assignment of several 19F resonances and demonstrate that the chemical shift of the 19F signal from base-paired 5-fluorouracil differs considerably between Watson-Crick and wobble geometry.     

Characterization of the fluorodihydrouracil substituent in 5-fluorouracil-containing Escherichia coli transfer RNA

The fluorodihydrouridine derivative previously detected in one of two isoaccepting forms of FUra-substituted Escherichia coli tRNAMetf has been further characterized. This substituent is responsible for the 19F resonance observed 15 ppm upfield from free FUra (= 0 ppm) in the high resolution 19F-NMR spectra of FUra-substituted tRNA purified by chromatography on DEAE-cellulose, at pH 8.9, to remove normal tRNA. Similar highfield 19F signals have now been observed in the spectra of two other purified fluorinated E. coli tRNAs, tRNAMetm and tRNAVal1, as well as in unfractionated tRNA, indicating the widespread occurrence of the constituent. Comparison with 19F spectrum of the model compound 5'-deoxy-5-fluoro-5,6-dihydrouridine (dH56FUrd) (delta FUra = -31.4 ppm; JHF = 48 Hz) indicates that the substituent does not contain an intact fluorodihydrouridine ring. dH56FUrd is considerably more alkali labile than 5,6-dihydrouridine (H56Urd). At pH 8.9, where H56Urd is stable, dH56FUrd is degraded to a derivative, presumably a fluoroureidopropionic acid, with a 19F resonance at - 15.7 ppm that nearly coincides with the upfield peak in the spectrum of pH 8.9-treated tRNA. The 19F-NMR spectrum of fluorinated tRNA, not exposed to pH 8.9, exhibits two peaks 31 and 32 ppm upfield of FUra, in place of the 19F signal at - 15 ppm. Hydrolysis of this tRNA with RNAase T2 produces a sharp doublet 33 ppm upfield (JHF = 45 Hz). Similarities of the 19F chemical shift and coupling constant to those of dH56FUrd, allows assignment of the peak at -33 ppm to an intact fluorodihydrouridine residue in the tRNA. Our results demonstrate that FUra residues incorporated into E. coli tRNA at sites normally occupied by dihydrouridine can be recognized by tRNA-modifying enzymes and reduced to fluorodihydrouridine. This substituent is labile at moderately alkaline pH values and undergoes ring-opening during purification of the tRNA.     

19F nuclear magnetic resonance as a probe of anticodon structure in 5-fluorouracil-substituted Escherichia coli transfer RNA

The use of 19F nuclear magnetic resonance (n.m.r.) spectroscopy as a probe of anticodon structure has been extended by investigating the effects of tetranucleotide binding to 5-fluorouracil-substituted Escherichia coli tRNA(Val)1 (anticodon FAC). 19F n.m.r. spectra were obtained in the absence and presence of different concentrations of oligonucleotides having the sequence GpUpApX (X = A,G,C,U), which contain the valine codon GpUpA. Structural changes in the tRNA were monitored via the 5-fluorouracil residues located at positions 33 and 34 in the anticodon loop, as well as in all other loops and stems of the molecule. Binding of GpUpApA, which is complementary to the anticodon and the 5'-adjacent FUra 33, shifts two resonances in the 19F spectrum. One, peak H (3.90 p.p.m.), is also shifted by GpUpA and was previously assigned to FUra 34 at the wobble position of the anticodon. The effects of GpUpApA differ from those of GpUpA in that the tetranucleotide induces the downfield shift of a second resonance, peak F (4.5 p.p.m.), in the 19F spectrum of 19F-labeled tRNA(Val)1. Evidence that the codon-containing oligonucleotides bind to the anticodon was obtained from shifts in the methyl proton spectrum of the 6-methyladenosine residue adjacent to the anticodon and from cleavage of the tRNA at the anticodon by RNase H after binding dGpTpApA, a deoxy analog of the ribonucleotide codon. The association constant for the binding of GpUpApA to fluorinated tRNA(Val)1, obtained by Scatchard analysis of the n.m.r. results, is in good agreement with values obtained by other methods. On the basis of these results, we assign peak F in the 19F n.m.r. spectrum of 19F-labeled tRNA(Val)1 to FUra 33. This assignment and the previous assignment of peak H to FUra 34 are supported by the observation that the intensities of peaks F and H in the 19F spectrum of fluorinated tRNA(Val)1 are specifically decreased after partial hydrolysis with nucleass S1 under conditions leading to cleavage in the anticodon loop. The downfield shift of peak F occurs only with adenosine in the 3'-position of the tetranucleotide; binding of GpUpApG, GpUpApC, or GpUpApU results only in the upfield shift of peak H. The possibility is discussed that this base-specific interaction between the 3'-terminal adenosine and the 5-fluorouracil residue at position 33 involves a 5'-stacked conformation of the anticodon loop. Evidence also is presented for a temperature-dependent conformational change in the anticodon loop below the melting temperature of the tRNA.     

19F nuclear magnetic resonance of 5-fluorouridine-substituted tRNA1Val from Escherichia coli.

The 19F NMR spectrum of Escherichia coli tRNA1Val in which [5-19F]uridine replaces 93% of all uridine and uridine-derived residues has been examined at 93.6 and 235 MHz. The resolution of 11 peaks and visibility of two additional shoulders at either frequency for the 14 FUra residues in the molecule attests to the excellence of 19F as a probe for the structure of tRNA1Val in solution. No significant gain in resolution was attained at the higher frequency. A comparison of the relative areas in the different regions of the 19F spectrum of mixed [FUra]tRNAs with that of [FUra]tRNA1Val suggests that the three single resonances at lowest field in the region 86.5 to 88.5 ppm upfield from trifluoroacetate correspond to the three invariant bases which form tertiary hydrogen bonds in all tRNAs, namely, 8 (U or s4U), 54 (T), and 55 (phi) in unsubstituted tRNAs.     

Characterization of the fluorodihydrouracil substituent in 5-fluorouracil-containing Escherichia coli transfer RNA

The fluorodihydrouridine derivative previously detected in one of two isoaccepting forms of FUra-substituted Escherichia coli tRNA^Met_f has been further characterized. This substituent is responsible for the ¹⁹F resonance observed 15 ppm upfield from free FUra (= 0 ppm) in the high resolution ¹⁹F-NMR spectra of FUra-substituted tRNA purified by chromatography on DEAE-cellulose, at pH 8.9, to remove normal tRNA. Similar highfield ¹⁹F signals have now been observed in the spectra of two other purified fluorinated E. coli tRNAs, tRNA^Met_m and tRNA^Val_l, as well as in unfractionated tRNA, indicating the widespread occurrence of the constituent. Comparison with ¹⁹F spectrum of the model compound 5′-deoxy-5-fluoro-5,6-dihydrouridine (dH⁵₆FUrd) (δ_FUra = ? 31.4 ppm; J_HF = 48 Hz) indicates that the substituent does not contain an intact fluorodihydrouridine ring. dH⁵₆FUrd is considerably more alkali labile than 5,6-dihydrouridine (H⁵₆Urd). At pH 8.9, where H⁵₆Urd is stable, dH⁵₆FUrd is degraded to a derivative, presumably a fluoroureidopropionic acid, with a ¹⁹F resonance at ? 15.7 ppm that nearly coincides with the upfield peak in the spectrum of pH 8.9-treated tRNA. The ¹⁹F-NMR spectrum of fluorinated tRNA, not exposed to pH 8.9, exhibits two peaks 31 and 32 ppm upfield of FUra, in place of the ¹⁹F signal at ? 15 ppm. Hydrolysis of this tRNA with RNAase T₂ produces a sharp doublet 33 ppm upfield (J_HF = 45 Hz). Similarities of the ¹⁹F chemical shift and coupling constant to those of dH⁵₆FUrd, allows assignment of the peak at ? 33 ppm to an intact fluorodihydrouridine residue in the tRNA. Our results demonstrate that FUra residues incorporated into E. coli tRNA at sites normally occupied by dihydrouridine can be recognized by tRNA-modifying enzymes and reduced to fluorodihydrouridine. This substituent is labile at moderately alkaline pH values and undergoes ring-opening during purification of the tRNA.     

Fluorine-19 nuclear magnetic resonance study of codon-anticodon interaction in 5-fluorouracil-substituted E. coli transfer RNAs.

Codon-anticodon interaction was investigated in fully active 5-fluorouracil-substituted E. coli tRNAVal1 (anticodon FAC) by 19F NMR spectroscopy. Binding of the codon GpUpA results in the upfield shift of a 19F resonance at 3.9 ppm in the central region of the 19F NMR spectrum, whereas trinucleotides not complementary to the anticodon have no effect. The same 19F resonance shifts upfield upon formation of an anticodon-anticodon dimer between the 19F-labeled tRNA and E. coli tRNATyr2 (anticodon QUA). These results permit assignment of the peak at 3.9 ppm to the 5-fluorouracil at position 34 in the anticodon of fluorouracil-substituted tRNAVal1. The methionine codon ApUpG also causes a sequence-specific upfield shift of a peak in the central part of the 19F NMR spectrum of fluorinated E. coli tRNAMetm. However, ApUpG has no effect on the 19F spectrum of 19F-labeled E. coli tRNAMetf, indicating possible conformational differences between the anticodon loop of initiator and chain-elongating methionine tRNAs. 19F NMR experiments detect no binding of CpGpApA to the complementary FpFpCpG (replaces Tp psi pCpG) in the T-loop of 5-fluorouracil-substituted tRNAVal1, in the presence or absence of codon, suggesting that the tertiary interactions between the T- and D-loops are not disrupted by codon-anticodon interactions.     

Fluoroquinacrine binding to nucleic acids: Investigation of the 19F-nmr,optical, and fluorescence properties in the presence of DNA,poly(A), and tRNA

The interaction of fluoroquinacrine, 3-fluoro-7-chloro-9-(diethylamino-1-methylbutyl-amino)acridine, with poly(A), DNA, and tRNA has been investigated by monitoring changes in the ¹⁹F-nmr properties, the fluorescence, and the optical absorbance of the drug. The changes in the properties of fluoroquinacrine in the presence of nucleic acids are similar to those observed for quinacrine and suggest that the drugs bind in a similar fashion. The molecular dynamics of fluoroquinacrine bound to nucleic acids were determined by interpreting the data from a number of different nmr relaxation experiments with a two-correlation-time model. The two motions are the long-range bending motion of the drug-nucleic acid complex and the sliding of the drug between the base pairs. Both dipolar and chemical shift anisotropy contributions to the nmr relaxation parameters were taken into consideration. The binding of fluoroquinacrine to tRNA appears to be different from that observed for binding to DNA. Optical absorbance and ¹⁹F-nmr were also used to examine the helix-to-coil transitions of the drug–nucleic acid complexes. In the DNA complex, the ¹⁹F chemical shift changes parallel the absorption changes that occur during the transition. ¹⁹F-nmr and absorption show that the drug–tRNA complexes undergo a cooperative helix-to-coil transition, with the drug binding sites melting when the tRNA is 70% denatured.     

Rotational dynamics of transfer ribonucleic acid: effect of ionic strength and concentration

We have investigated the influence of ionic strength and nucleic acid concentration on the rotational Brownian motion of Escherichia coli tRNA1Val by studying the decay of the fluorescence polarization anisotropy (FPA) of intercalated ethidium on a nanosecond time scale. The rotational relaxation time tau R remains essentially constant as the ionic strength is varied from 2 to 100 mM at a tRNA concentration of 54 mg/mL. tau R also remains practically unchanged as the tRNA concentration is varied from 0.3 to 54 mg/mL at an ionic strength of 130 mM. Present hydrodynamic theories generally predict a more pronounced concentration dependence for rotational diffusion than we observe. This disagreement may result from a nonrandom distribution of the tRNA molecules in solution due to electrostatic interactions. By combining independent data from time-resolved nuclear Overhauser effect (NOE) cross-relaxation experiments and FPA experiments on the same tRNA, we are able to estimate the interproton spacing for the guanine N1-H and the uracil N3-H of the GU-50 base pair in E. coli tRNA1Val. This distance is 0.272 nm.     

Fluorine-19 nuclear magnetic resonance studies of the structure of 5-fluorouracil-substituted Escherichia coli transfer RNA

19F nuclear magnetic resonance has been used to study fully active Escherichia coli tRNA1Val in which 5-fluorouracil has replaced more than 90% of all uracil and uracil-derived modified bases. The 19F spectrum of the native tRNA contains resolved resonances for all 14 incorporated 5-fluorouracils. These are spread over a 6 ppm range, from 1.8 to 7.7 ppm downfield of the standard free 5-fluorouracil. The 19F resonances serve as sensitive monitors of tRNA conformation. Removal of magnesium or addition of NaCl produces major, reversible changes in the 19F spectrum. Most affected is the lowest field resonance (peak A) in the spectrum of the native tRNA. This shifts 2-3 ppm upfield as the Mg2+ concentration is lowered or the NaCl concentration is raised. Thermal denaturation of the tRNA results in a collapse of the spectrum to a single broad peak centered at 4.7 ppm. Study of the pH dependence of the 19F spectrum shows that five incorporated fluorouracils with 19F signals in the central, 4-5.5 ppm, region of the spectrum, peaks C, D, E, F, and H, are accessible to titration in the pH 4.5-9 range. All have pKa's close to that of free 5-fluorouridine (ca. 7.5). Evidence for a conformation change in the tRNA at mildly acidic pHs, ca. 5.5, is also presented. Four of the titratable 5-fluorouracil residues, those corresponding to peaks D, E/F, and H in the 19F spectrum of fluorine-labeled tRNAVal1, are essentially completely exposed to solvent as determined by the solvent isotope shift (SIS) on transfer of the tRNA from H2O to 2H2O. These are also the 5-fluorouracils that readily form adducts with bisulfite, a reagent that reacts preferentially with pyrimidines in single-stranded regions. On the basis of these results, resonances D, E, F, and H in the middle of the 19F spectrum are attributed to 5-fluorouracils in non-base-paired (loop) regions of the tRNA. Evidence from the ionic strength dependence of the 19F spectrum and arguments based on other recent studies with fluorinated tRNAs support earlier suggestions [Horowitz, J., Ofengand, J., Daniel, W. E., & Cohn, M. (1977) J. Biol. Chem. 252, 4418-4420] that the resonances at lowest field correspond to tertiary hydrogen-bonded 5-fluorouracils. Consideration of ring-current effects and the preferential perturbation of upfield 19F resonances by the cyclophotoaddition of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, which is known to react most readily with pyrimidines in double-stranded regions, permits initial assignment of upfield resonances to 5-fluorouracils in helical stems.(ABSTRACT TRUNCATED AT 400 WORDS)     

Carbon-13 NMR relaxation studies of pre-melt structural dynamics in [4-13C-uracil] labeled E. coli transfer RNAIVal.

We report 67.8 MHz carbon-13 spin-lattice relaxation studies on [4-13C-uracil] labeled tRNAIVal purified from E. coli SO-187. Following 13C-enriched C4 carbonyl resonances from modified and unsubstituted uridines scattered throughout the polymer backbone enables us to determine dynamical features in both loop and helical stem regions. The experimental results have been analyzed in terms of a model of isotropic overall molecular reorientation. "Anomalous" residues for which the experimental data cannot be accounted for in terms of the model provide an assessment of local and regional properties. Thus, "native" tRNAIVal under physiological conditions of magnesium (10 mM) and temperature (20 degrees - 40 degrees C), exhibits the following characteristics: 1) uridines held rigidly in helical stems and tertiary interactions display correlation times for rotational reorientation of 15-20 nsecs, typical for overall tRNA motion; 2) uridines in loops such as the wobble residue uridine-5-oxyacetic acid (V34) are quite accessible to solvent; moreover V34 and another loop residue, D17, exhibit local mobility; 3) the tertiary interactions involving 4-thio uridine (s4U8) and A14 and ribothymidine (rT54) and A58 are weakened as temperature increases.     

Carbon-13 NMR studies on [4-13C] uracil labelled E. coli transfer RNA1(Val1).

In this paper we describe carbon-13 nuclear magnetic resonance results on 13C-enriched purified transfer RNAI(VAL) from from E. coli SO-187, a uracil requiring auxotroph. The organism was grown on uracil 90% 13C-enriched at the carbonyl C4 position. Transfer RNAI(Val) was purified from bulk tRNA by sequential chromatography on columns of BD cellulose, DEAE-Sephadex A-50 and reverse gradient sepharose 4B. Dihydrouridine, 4-thiouridine, and uridine 5-oxyacetic acid located at discrete positions in the polymer backbone were tentatively assigned in the highly resolved 25 MHz 13C-spectra. Chemical shift versus temperature plots reveal differential thermal perturbation of the ordered solution structure, evident in the large dispersion (ca 3-4 ppm) of the uridine C4 resonances. Over the range 26-68 degrees C, V in the anticodon displays the largest downfield shift. Whereas several uridine residues rapidly shift downfield between 50-68 degrees, one moves upfield beginning at 37 degrees. The results are qualitatively compared with proton NMR analysis of the three dimensional structure.     

19F NMR investigation of molecular motion and packing in sonicated phospholipid vesicles

Dimyristoylphosphatidylcholine (DMPC) labeled with a C19F2 group in the 4-, 8-, or 12-position of the 2-acyl chain has been investigated in sonicated unilamellar vesicles (SUV) by fluorine-19 nuclear magnetic resonance (NMR) at 282.4 MHz from 26 to 42 degrees C. The 19F NMR spectra exhibit two overlapping resonances with different line widths. Spin-lattice relaxation time measurements have been performed in both the laboratory frame (T1) and the rotating frame (T1 rho) in order to investigate the packing and dynamics of phospholipids in lipid bilayers. Quantitative line-shape and relaxation analyses are possible by using the experimental chemical shift anisotropy (delta nu CSA) and the internuclear F-F vector order parameter (SFF) values obtained from the 19F powder spectra of multilamellar liposomes. The following conclusions can be made: The 19F chemical shift difference between the inside and outside leaflets of SUV can be used to monitor the lateral packing of the phospholipid in the two SUV monolayers. The hydrocarbon chains in the outer layer are found to be more tightly packed than those of the inner one, and the differences between them become smaller near the chain terminals. The effective correlation time [(1-4) x 10(-7) s] obtained from either the motional narrowing of the line widths or off-resonance T1 rho measurements is shorter than that estimated from the Stokes-Einstein diffusion model (10(-6) s), on the basis of a hydrodynamic radius of 110 A for SUV.(ABSTRACT TRUNCATED AT 250 WORDS)     

13C NMR and fluorescence analysis of tryptophan dynamics in wild-type and two single-Trp variants of Escherichia coli thioredoxin.

The rotational motion of tryptophan side chains in oxidized and reduced wild-type (WT) Escherichia coli thioredoxin and in two single-tryptophan variants of E. coli thioredoxin was studied in solution in the temperature range 20-50 degrees C from 13C-NMR relaxation rate measurements at 75.4 and 125.7 MHz and at 20 degrees C from steady-state and time-resolved trp fluorescence anisotropy measurements. Tryptophan enriched with 13C at the delta 1 and epsilon 3 sites of the indole ring was incorporated into WT thioredoxin and into two single-trp mutants, W31F and W28F, in which trp-28 or trp-31 of WT thioredoxin was replaced, respectively, with phenylalanine. The NMR relaxation data were interpreted using the Lipari and Szabo "model-free" approach (G. Lipari and A. Szabo. 1982. J. Amer. Chem. Soc. 104:4546-4559) with trp steady-state anisotropy data included for the variants at 20 degrees C. Values for the correlation time for the overall rotational motion (tau m) from NMR of oxidized and reduced WT thioredoxin at 35 degrees C agree well with those given by Stone et al. (Stone, M. J., K. Chandrasekhar, A. Holmgren, P. E. Wright, and H. J. Dyson. 1993. Biochemistry. 32:426-435) from 15N NMR relaxation rates, and the dependence of tau m on viscosity and temperature was in accord with the Stokes-Einstein relationship. Order parameters (S2) near 1 were obtained for the trp side chains in the WT proteins even at 50 degrees C. A slight increase in the amplitude of motion (decrease in S2) of trp-31, which is near the protein surface, but not of trp-28, which is partially buried in the protein matrix, was observed in reduced relative to oxidized WT thioredoxin. For trp-28 in W31F, order parameters near 1 (S2 > or = 0.8) at 20 degrees C were found, whereas trp-31 in W28F yielded the smallest order parameters (S2 approximately 0.6) of any of the cases. Analysis of time-resolved anisotropy decays in W28F and W31F yielded S2 values in good agreement with NMR, but gave tau m values about 60% smaller. Generally, values of tau e, the effective correlation time for the internal motion, were < or = 60 ps from NMR, whereas somewhat longer times were obtained from fluorescence. The ability of NMR and fluorescence techniques to detect subnanosecond motions in proteins reliably is examined.     

Tryptophan sidechain dynamics in hydrophobic oligopeptides determined by use of 13C nuclear magnetic resonance spectroscopy.

Two oligopeptides, t-boc-LAWAL-OMe and t-boc-LALALW-OMe, were synthesized for the purpose of examining the sidechain dynamics of the tryptophan residue in hydrophobic environments by 13C nuclear magnetic resonance and fluorescence spectroscopy. In both peptides, the tryptophan sidechain was greater than 95% enriched with 13C at the C delta 1 position. Spin-lattice relaxation time (T1) and steady-state nuclear Overhauser effect (NOE) data were obtained at 50.3 and 75.4 MHz for both peptides in CD3OD, and at 75.4 MHz for t-boc-LALALW-OMe in lysolecithin-D2O micelles. We have adapted the model-free approach of G. Lipari and A. Szabo (1982, J. Am. Chem. Soc. 104:4546) to interpret the 13C-NMR data. Computer-generated curves based on experimental data obtained at a single frequency demonstrate relationships between an effective correlation time for tryptophan sidechain motion (tau e), a generalized order parameter (sigma) describing the extent of motional restriction, and an overall correlation time for the peptide (tau m). Assuming predominantly dipolar relaxation, least-squares fits of the dual frequency relaxation data provide values for these parameters for both peptides. The contribution of chemical shift anisotropy (CSA), however, is also explicitly assessed in the data analysis, and is shown to perturb the predicted sigma, tau e, and tau m values and to decrease chi(2) values observed in nonlinear least-squares analysis of the data. Because of uncertainty in the contribution of CSA to the relaxation of the indole ring 13C delta 1 atom, nonlinear least-squares analysis of the relaxation data were performed with and without inclusion of a CSA term in the appropriate relaxation equations. Neglecting CSA, an overall peptide correlation time of 0.69 ns is predicted for t-boc-LAWAL-OMe in CD3OD at 20 degrees C compared with 1.28 ns for t-boc-LALALW-OMe. Given these tau m values and taking into account the effect of measurement error in the T1 and NOE data, the internal dynamics of the tryptophan residue of t-boc-LAWAL-OMe in this isotropic environment are described by a range of tau e values from 70 to 112 ps and sigma values between 0.22 and 0.36. Similarly, for t-boc-LALALW-OMe, 68 less than or equal to tau e less than or equal to 93 ps and 0.09 less than or equal to sigma less than or equal to 0.17. The Ch-terminal position of the tryptophan residue in the hexapeptide may account for its lower order parameter.(ABSTRACT TRUNCATED AT 400 WORDS)     

19F nuclear magnetic resonance as a probe of the spatial relationship between the heme iron of cytochrome P-450 and its substrate

The distance between the heme iron of ferrous cytochrome P-450-CAM and a fluorine label attached to the 9-methyl carbon of its substrate, (1R)-(+)-camphor, has been determined using 19F NMR. This investigation uses the Solomon-Bloembergen equation to measure the distance from a paramagnetic heme iron to a fluorine probe incorporated into a substrate that is not in fast exchange. The structural identity of the substrate analogue, 9-fluorocamphor, has been established using one- and two-dimensional NMR methods and mass spectrometry. The relaxation rate of 9-fluorocamphor bound to high-spin paramagnetic ferrous P-450-CAM has been studied at 188, 282, and 376 MHz, and the correlation time has been directly determined from the frequency dependence of the relaxation rate. When the substrate analogue was bound to the low-spin diamagnetic ferrous-CO derivative of the enzyme, the relaxation rate was found to be 100 times slower and was therefore neglected in the distance calculation. The relaxation data for the paramagnetic system and the correlation time have been used to calculate a distance of 3.8 A between the heme iron and the C-9 fluoride. A fit of the distance and the chemical shift data to the pseudocontact shift equation predicts an angle of approximately 52 degrees between the heme normal and the Fe-F vector. The solution state Fe-F distance is somewhat shorter and the angle between the heme normal and the Fe-F vector slightly larger for the substrate-bound ferrous enzyme reported herein than the analogous values for the substrate-bound ferric enzyme determined in the solid state by x-ray crystallography. These differences may reflect a structural change at the substrate-binding site upon reduction of the iron.     

Transfer RNA structure by carbon NMR: C2 of adenine, uracil and cytosine.

Fourier transform 13C NMR spectra of E. coli tRNA enriched on 13C in either position 2 of adenine (60 atom % 13C) or in position 2 of uracil (82%) and cytosine (63%) were taken at 25.16 MHz over the temperature range 10 degrees - 76 degrees. For C2 of adenine the peak as initially 5 ppm wide, but narrowed to 0.5 ppm as the molecule unfolded. C2 of uracil displayed behavior similar to that of adenine while the cytosine peak, initially relatively narrow at low temperature, sharpened less dramatically. Comparison of spectra at 26.16 MHz and 67.9 MHz showed that the peak widths for folded tRNA were determined largely by chemical shift non-equivalence. T2 T2 measurements suggested that intrinsic line widths of most cytosine C2 peaks were 4 Hz and 2-3 Hz for uracil. Adenine C2 with a directly bonded proton had resonances of about 40 Hz line width. T1 values were measured for C2 of adenine and the ribose carbons of tRNA. Consideration of dipolar relaxation and chemical shift anisotrophy led to a calculated rotational correlation time of 1.6 +/- 0.4 x 10(-8) sec for the adenines and 1.3 +/- 0.3 x 10(-8) sec for the ribose carbons.     

Sites of methylation of purified transfer ribonucleic acid preparations by enzymes from normal tissues and from tumours induced by dimethylnitrosamine and 1,2-dimethylhydrazine

1. The sites within the tRNA sequence of nucleosides methylated by the action of enzymes from mouse colon, rat kidney and tumours of these tissues acting on tRNA(Asp) from yeast and on tRNA(Glu) (2), tRNA(fMet) and tRNA(Val) (1) from Escherichia coli were determined. 2. The same sites in a particular tRNA were methylated by all of these extracts. Thus tRNA(Glu) (2) was methylated at the cytidine residue at position 48 and the adenosine residue at position 58 from the 5'-end of the molecule; tRNA(Asp) was methylated at the guanosine residue at position 26 from the 5'-end of the molecule; tRNA(fMet) was methylated at the guanosine residues 9 and 27, the cytidine residue 49 and the adenosine residue 59 from the 5'-end; tRNA(Val) (1) was methylated at the guanosine residue 10, the cytidine residue 48 and the adenosine residue 58 from the 5'-end. 3. All of these sites within the clover leaf structure of the tRNA sequence are occupied by a methylated nucleoside in some tRNA species of known sequence. It is concluded that methylation of tRNA from micro-organisms by enzymes from mammalian tissues in vitro probably does accurately represent the specificity of these enzymes in vivo. However, there was no evidence that the tumour extracts, which had considerably greater tRNA methylase activity than the normal tissues, had methylases with altered specificity capable of methylating sites not methylated in the normal tissues.     

19F NMR relaxation studies on 5-fluorotryptophan- and tetradeutero-5-fluorotryptophan-labeled E. coli glucose/galactose receptor

Summary ¹⁹F NMR relaxation studies have been carried out on a fluorotryptophan-labeled E. coli periplasmic glucose/galactose receptor (GGR). The protein was derived from E. coli grown on a medium containing a 50:50 mixture of 5-fluorotryptophan and [2,4,6,7-²H₄]-5-fluorotryptophan. As a result of the large -isotope shift, the two labels give rise to separate resonances, allowing relaxation contributions of the substituted indole protons to be selectively monitored. Spin-lattice relaxation rates were determined at field strengths of 11.75 T and 8.5 T, and the results were analyzed using a model-free formalism. In order to evaluate the contributions of chemical shift anisotropy to the observed relaxation parameters, solid-state NMR studies were performed on [2,4,6,7-²H₄]-5-fluorotryptophan. Analysis of the observed ¹⁹F powder pattern lineshape resulted in anisotropy and asymmetry parameters of =–93.5 ppm and =0.24. Theoretical analyses of the relaxation parameters are consistent with internal motion of the fluorotryptophan residues characterized by order parameters S² of 1, and by correlation times for internal motion 10^-11 s. Simultaneous least squares fitting of the spin-lattice relaxation and line-width data with ⁱ set at 10 ps yielded a molecular correlation time of 20 ns for the glucose-complexed GGR, and a mean order parameter S²=0.89 for fluorotryptophan residues 183, 127, 133, and 195. By contrast, the calculated order parameter for FTrp²⁸⁴, located on the surface of the protein, was 0.77. Significant differences among the spin-lattice relaxation rates of the five fluorotryptophan residues of glucose-complexed GGR were also observed, with the order of relaxation rates given by: R _inf1F ^sup183 >R _inf1F ^sup127 R _inf1F ^sup133 R _inf1F ^sup195 >R _inf1F ^sup284 . Although such differences may reflect motional variations among these residues, the effects are largely predicted by differences in the distribution of nearby hydrogen nuclei, derived from crystal structure data. In the absence of glucose, spin-lattice relaxation rates for fluorotryptophan residues 183, 127, 133, and 195 were found to decrease by a mean of 13%, while the value for residue 284 exhibits an increase of similar magnitude relative to the liganded molecule. These changes are interpreted in terms of a slower overall correlation time for molecular motion, as well as a change in the internal mobility of FTrp²⁸⁴, located in the hinge region of the receptor.Abbreviations FTrp D,L-5-fluorotryptophan - GGR glucose/galactose receptor protein - R_1F spin-lattice relaxation rate of fluorine - R_1F(H) spinlattice relaxation rate of the fluorine nuclei in normal (nondeuterated) fluorotryptophan residues - R_1F(D) spin-lattice relaxation rate of the fluorine in [2,4,6,7-²H₄]-5-fluorotryptophan To whom correspondence should be addressed.     

High-resolution NMR studies of fibrinogen-like peptides in solution: interaction of thrombin with residues 1-23 of the A alpha chain of human fibrinogen

The interaction of the following human fibrinogen-like peptides with bovine thrombin was studied by use of one- and two-dimensional NMR techniques in aqueous solution: Ala(1)-Asp-Ser-Gly-Glu-Gly-Asp-Phe(8)-Leu-Ala-Glu-Gly-Gly-Gly-Val-Arg(16 )- Gly(17)-Pro-Arg(19)-Val(20)-Val-Glu-Arg (F10), residues 1-16 of F10 (fibrinopeptide A), residues 17-23 of F10 (F12), residues 1-20 of F10 (F13), residues 6-20 of F10 with Arg(16) replaced by a Gly residue (F14), and residues 6-19 of F10 with Arg(16) replaced by a Leu residue (F15). At pH 5.3 and 25 degrees C, the Arg(16)-Gly(17) peptide bonds of both peptides F10 and F13 were cleaved instantaneously in the presence of 0.6 mM thrombin, whereas the cleavage of the Arg(19)-Val(20) peptide bonds in peptides F12, F13, and F14 took over 1 h for completion. On the basis of observations of line broadening, fibrinopeptide A was found to bind to thrombin. While resonances from residues Ala(1)-Glu(5) were little affected, binding of fibrinopeptide A to thrombin caused significant line broadening of NH and side-chain proton resonances within residues Asp(7)-Arg(16). There is a chain reversal within residues Asp(7)-Arg(16) such that Phe(8) is brought close to the Arg(16)-Gly(17) peptide bond in the thrombin-peptide complex, as indicated by transferred NOEs between the aromatic ring protons of Phe(8) and the C alpha H protons of Gly(14) and the C gamma H protons of Val(15). A similar chain reversal was obtained in the isolated peptide F10 at a subzero temperature of -8 degrees C. The titration behavior of Asp(7) in peptide F13 does not deviate from that of the reference peptide, N-acetyl-Asp-NHMe at both 25 and -8 degrees C, indicating that no strong interaction exists between Asp(7) and Arg(16) or Arg(19). Peptides with Arg(16) replaced by Gly and Leu, respectively, i.e., F14 and F15, were also found to bind to thrombin but with a different conformation, as indicated by the absence of the long-range NOEs observed with fibrinopeptide A. Residues Asp(7)-Arg(16) constitute an essential structural element in the interaction of thrombin with fibrinogen.