Identification of tertiary base pair resonances in the nuclear magnetic resonance spectra of transfer ribonucleic acid.

The low-field hydrogen-bond ring NH proton nuclear magnetic resonance (NMR) spectra of several transfer ribonucleic acids (tRNAs) related to yeast tRNAPhe have been examined in detail. Several resonances are sensitive to magnesium ion and temperature, suggesting that they are derived from tertiary base pairs. These same resonances cannot be attributed to cloverleaf base pairs as shown by experimental assignment and ring current shift calculation of the secondary base pair resonances. The crystal structure of yeast tRNAPhe reveals at least six tertiary base pairs involving ring NH hydrogen bonds, which we conclude are responsible for the extra resonances observed in the low-field NMR spectrum. In several tRNAs with the same tertiary folding potential and dihydrouridine helix sequence as yeast tRNAPhe, the extra resonances from tertiary base pairs are observed at the same position in the spectrum.     

Assignment of imino proton spectra of yeast phenylalanine transfer ribonucleic acid

Yeast tRNAPhe has been studied by using proton NMR and nuclear Overhauser effect (NOE) with deuterium substitution. Direct NOE evidence is presented for assignment of imino resonances of 23 of 27 base pairs in this tRNA. Other indirect evidence is presented for tentative assignment of four other base pairs. Almost total assignment also has been made of the important noninternally bonded imino protons and tertiary interactions (however, G18-psi 55 remains unassigned). The most surprising result has been identification of GC11 at -13.68 ppm; this is the first time a GC base pair has been identified so far downfield. This peak (GC11) is also identified as the resonance of the unique imino proton that exchanges in a time of more than 1 day, as previously described. These identifications of imino proton resonances made it possible to reinterpret the proton solvent exchange rate data previously published on this tRNA and understand them better. The assignments of resonances should pave the way for more detailed solution study of this tRNA and its interaction with biologically relevant molecules.     

Nuclear magnetic resonance studies on transfer ribonucleic acid: assignment of AU tertiary resonances.

The hydrogen-bonded ring NH nuclear magnetic resonance (NMR) spectra of several transfer ribonucleic acid (RNA) species have been examined with particular emphasis on the extreme low-field portion. Betwen --13.8 and --15 ppm there are two extra resonances which are not derived from cloverleaf base pairs. A combined approach involving undermodified tRNAs, chemical modification, and hairpin fragment studies has assigned the T54--A58 resonance at --14.3 ppm in yeast tRNAPhe and Escherichia coli tRNA1 Val., the U8--A14 resonance has been assigned at --14.3 ppm, and the s4U8--A14 resonance in bacterial tRNAs has been assigned at --14.9 ppm. The T54--A58 resonance shifts between --14.3. and --13.8 ppm depending on the surrounding nucleotide sequence in the ribothymidine loop.     

Study of transfer ribonucleic acid unfolding by dynamic nuclear magnetic resonance

Nuclear magnetic resonance (NMR) measurements of proton exchange were performed on yeast tRNAPhe, and in much less detail on Escherichia coli tRNAfMet, over a range of Mg2+ concentrations and temperatures, at neutral pH and 0.1 M NaCl. The resonances studied were those of ring nitrogen protons, resonating between 10 and 15 ppm downfield from sodium 3-(trimethylsilyl)-1-propanesulfonate, which partake in hydrogen bonding between bases of secondary and tertiary pairs. Methods include saturation--recovery, line width, and real-time observation after a change to deuterated solvent. The relevant theory is briefly reviewed. We believe that most of the higher temperature rates reflect major unfolding of the molecule. For E. coli tRNAfMet, the temperature dependence of the rate for the U8--A14 resonance maps well onto previous optical T-jump studies for a transition assigned to tertiary melting. For yeast tRNAPhe, exchange rates of several resolved protons could be studied from 30 to 45 degrees C in zero Mg2+ concentration and had activation energies on the order of 40 kcal/mol. Initially, the tertiary structure melts, followed shortly by the acceptor stem. At high Mg2+ concentration, relatively few exchange rates are measurable below the general cooperative melt at about 60 degrees C; these are attributed to tertiary changes. Real-time observations suggest a change in the exchange mechanism at room temperature with a lower activation energy. The results are compared with those obtained by other methods directed toward assaying ribonucleic acid dynamics.     

Paramagnetic ion effects on the nuclear magnetic resonance spectrum of transfer ribonucleic acid: assignment of the 15--48 tertiary resonance.

We have studied the effects of Co2+ and Mn2+ ions on the low-field nuclear magnetic resonance (NMR) spectra of pure class 1 transfer ribonucleic acid (tRNA) species. With 1.2 mM tRNA in the presence of 15 mM MgCl2 discrete paramagnetic effects were observed for Co2+ at concentrations in the range 0.02--0.1 mM and for Mn2+ in the range 0.002--0.01 mM, indicating fast exchange of these cations with tRNA. Both of these cations paramagnetically relax the s4U8--A14 resonance as well as other resonances from proximal base pairs. The Co2+ site appears to be the same site on G15 which was observed crystallographically [Jack, A., Ladner, J. E., Rhodes, D., Brown, R. S., & Klug, A. (1977) J. Mol. Biol. 111, 315-328]; the initially occupied tight Mn2+ site is the cation site involving the phosphate of U8. There are three base pairs within 10 A of both sites, namely, G15--C48, A14--s4U8, and C13--G22; this has led to the assignment of the G15--C48 and C13--G22 resonances in the NMR spectrum [Jack, A., Ladner, J. E., Rhodes, D., Brown, R. S., & Klug, A. (1977) J. Mol. Biol. 111, 315--328; Holbrook, S. R., Sussman, J. L., Warrant, R. W., Church, G. M., & Kim, Sung-Hou (1977) Nucleic Acids Res. 4, 2811--2820; Quigley, G. J., Teeter, M. M., & Rich, A. (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 64--68].     

Phosphorus-31 nuclear magnetic resonance of ethidium complexes with ribonucleic acid model systems and phenylalanine-accepting transfer ribonucleic acid

The temperature dependence of the 31P NMR spectra of the ethidium complexes with poly(A) X oligo(U) and the 31P spectra of phenylalanine tRNA (yeast) in various molar ratios of ethidium ion (Et) are presented. In the poly(A) X oligo(U) X Et complex, a new peak about 2.0 ppm downfield from the double-helix peak appears. We have assigned this peak to phosphates perturbed by ethidium. The chemical shift of this peak is consistent with the intercalation mode of binding and provides additional support for our hypothesis that 31P shifts are sensitive probes of phosphate ester conformations. The main effect of ethidium on the 31P spectra of tRNAPhe is the broadening of several of the scattered signals. These scattered signals are associated with phosphates involved in tertiary interactions. We propose that these broadened signals arise from phosphates near the Et binding site.     

High-resolution phosphorus nuclear magnetic resonance spectra of yeast phenylalanine transfer ribonucleic acid. Melting curves and relaxation effects.

In a continuation of our studies on structural effects on the 31P chemical shifts of nucleic acids, we present 31P NMR spectra of yeast phenylalanine tRNA in the presence and absence of Mg2+. Superconducting field (146 MHz) and 32-MHz 31P NMR spectra reveal approximately 15 nonhelical diester signals spread over approximately 7 ppm besides the downfield terminal 3'-phosphate monoester. In the presence of 10 mM Mg2+, most scattered and main cluster signals do not shift between 22--66 degrees C, thus supporting our earlier hypothesis that 31P chemical shifts are sensitive to phosphate ester torsional and bond angles. At 70 degrees C, all of the signals merge into a single random coil conformation signal. Similar effects are observed in the absence of Mg2+ except that the transition melting temperature is approximately 20 degrees C lower. Measured spin-lattice and spin-spin relaxation times reveal another lower temperature transition besides the thermal denaturation process. A number of the scattered peaks are shifted (0.2--1.7 ppm) and broadened between 22 and 66 degrees C in the presence of Mg2+ as a result of this conformational transition between two intact tertiary structures. The loss of the scattered peaks in the absence of Mg2+ occurs in the temperature range expected for melting of a tertiary structure. An attempt to simulate the 31P spectra of tRNA Phe based upon the X-ray crystallographically determined phosphate ester torsional agles supports the suggestion that the large shifts in the scattered peaks are due to bond angle distortions in the tertiary structure.     

Unusual structures in single-stranded ribonucleic acid: proton nuclear magnetic resonance of AUCCA in deuterium oxide

Conformational features of the oligoribonucleic acid (oligo-RNA) A1-U2-C3-C4-A5 are explored by proton nuclear magnetic resonance (NMR). The sequence is a molecular cognate of a portion of the T psi C loop and stem regions of yeast tRNAPhe. The molecule forms at least two classes of flexible yet ordered structures. Class I states are similar in spectral properties to the component oligomers, AU, AUC, and AUCC, and are likely to be standard right-helical structures. Class II states are characterized by a 2'-endo pucker at A1 and unusually large shielding of several C3 and U2 protons. Most of these features are consistent with identifying the class II solution structures with the "arch" conformation for the T psi C region determined by X-ray crystallography of yeast tRNAPhe.     

Nuclear magnetic resonance studies on the tertiary folding of transfer ribonucleic acid: assignment of the 7-methylguanosine resonance.

Analysis of the low-field nuclear magnetic resonance (NMR) spectra of several class 1 D4V5 transfer ribonucleic acid (tRNA) species containing 7-methylguanosine in their variable loops reveals a set of six to seven tertiary base pair resonances, one of which is always located at ca. --13.4 ppm. Other tRNA species which do not contain 7-methyl-guanosine do not contain the tertiary resonance at --13.4 ppm. Chemical removal of 7-methylguanosine from several tRNAs containing the same dihydrouridine (DHU) helix sequence as yeast tRNAPhe results in the loss of the --13.4-ppm tertiary resonance. In the initiator methionine tRNA, which contains a different DHU helix sequence, the 7-methylguanosine hydrogen bond has been assigned at --14.55 ppm by chemical removal of this residue. In these experiments the aromatic C8H proton of 7-methylguanosine was also assigned (--9.1 ppm). The unexpectedly low-field position of the 7-methylguanosine resonance is explained by the deshielding effect of the delocalized positive charge in this nucleoside.     

Nuclear Overhauser effect study and assignment of D stem and reverse-Hoogsteen base pair proton resonances in yeast tRNAAsp

Nuclear Overhauser effects (NOEs) in yeast tRNAAsp were found for all four GU and G psi base pairs. NOEs of both reverse-Hoogsteen pairs were identified by comparison with a purine C8 deuterated sample. Several NOEs involving these resonances were also found which are clearly between single protons on adjacent base pairs. These interbase NOEs, combined with the assumption of reasonable similarity between the structure of yeast tRNAAsp and that of yeast tRNAPhe, lead to unambiguous assignment of many resonances including all the ring NH and C2 protons in the D stem. The stability of the stem at 28 degrees C, as recently deduced by Moras et al (Nature 288 669-674), from x-ray diffraction is confirmed. Assignments of the ring NH resonances of T54-A58 and of a G psi pair are made for the first time.     

Nuclear magnetic resonance studies on yeast tRNAPhe. III. Assignments of the iminoproton resonances of the tertiary structure by means of nuclear Overhauser effect experiments at 500 MHz.

Resonances of the water exchangeable iminoprotons of the tertiary structure of yeast tRNAPhe were studied by experiments involving Nuclear Overhauser Effects (NOE's). Direct NOE evidence is presented for the assignment of all resonances of iminoprotons participating in tertiary basepairing (except that of G19C56 which was assigned by an elimination procedure). The present results in conjunction with our previous assignment of secondary iminoprotons constitute for the first time a complete spectral assignment of all iminoprotons participating in basepairing in yeast tRNAPhe. In addition we have been able to assign the non(internally) hydrogen bonded N1 proton of psi 55 as well as the N3 proton of this residue, which is one of the two iminoprotons hydrogen bonded to a phosphate group according to X-ray results. No evidence could be obtained for the existence in solution of the other iminoproton-phosphate interaction: that between U33 N3H and P36 located in the anticodon loop. Remarkable is the assignment of a resonance at 12.4 - 12.5 ppm to the iminoproton of the tertiary basepair T54m1A58. The resonance positions obtained for the iminoprotons of G18 (9.8 ppm) and m2(2)G26 (10.4 ppm) are surprisingly far upfield considering that these protons are involved in hydrogen bonds according to X-ray diffraction results. As far as reported by changes in chemical shifts of iminoproton resonances the main structural event induced by Mg++ ions takes place near the tertiary interactions U8A14 and G22m7G46.     

Internal dynamics of transfer ribonucleic acid determined by nuclear magnetic resonance of carbon-13-enriched ribose carbon 1

Carbon-13 enrichment of the C1' position of the ribose moiety in Escherichia coli tRNA has made possible the detailed study of motion in this molecule. Enrichment was accomplished in vivo with a strain, M1R, selected for growth and degree of incorporation of ribose in a stringently defined minimal medium. Purine biosynthesis de novo was blocked with 6-mercaptopurine. Exogenously provided [1-13C]ribose and nucleobases were utilized via the salvage pathway and were required for growth of culture. Carbon-13-enriched transfer RNA in solution at 30 degrees C exhibited a prominent, broad, asymmetric NMR signal at 91.5 ppm for the C1' carbon. Upon heat denaturation of the tRNA, three C1' signals were resolved and could be attributed to the base-specific nucleotides in tRNA: uridine and guanosine at 88.7 ppm; adenosine at 89.5 ppm; and cytidine at 90.6 ppm. Ribose C3' and C5' were partially enriched due to scrambling of ribose carbons in vivo. The minimum net isotopic enrichment of C1' was 33%. Values for the relaxation time T1 and the nuclear Overhauser enhancement (NOE) at 75.5, 67.8, and 25.2 MHz (13C), the NOE at 50.3 MHz, T2 at 75.5 MHz, and line widths over the range of 20-75.5 MHz were analyzed in light of several models for internal motion in macromolecules. The data were inconsistent with physically unreasonable constructs involving free internal diffusion of the C1'-H vector about the glycosidic bond. Internal diffusion (wobble) within a cone or jumps between states were models that did fit the data. For diffusion within a cone, the cone half-angle was 15-20 degrees, with a correlation time of about 2 X 10(-9) s for internal reorientation. With the two-state jump model, the half-angle for jumps about the glycosidic bond was 14 +/- 2 degrees with a lifetime of 2 X 10(-9) s.     

Characterization of trotter horses urine metabolome by means of proton nuclear magnetic resonance spectroscopy

Background

Metabolomics has been recognized as a powerful approach for disease screening. In order to highlight potential health issues in subjects, a key factor is the possibility to compare quantitatively the metabolome of their biofluids with reference values from healthy individuals. Such efforts towards the systematic characterization of the metabolome of biofluids in perfect health conditions, far from concluded for humans, have barely begun on horses.

Objectives

The present work attempts, for the first time, to give reference quantitative values for the molecules mostly represented in the urine metabolome of horses at rest and under light training, as observable by ¹H-NMR.

Methods

The metabolome of ten trotter horses, four male and six female, ranging from 3 to 8 years of age, has been observed by ¹H-NMR spectroscopy before and after three training sessions.

Results

We could characterize and quantify 54 molecules in trotter horse urine, originated from diet, protein digestion, energy generation or gut-microbial co-metabolism.

Conclusion

We were able to describe how gender, age and exercise affected their concentration, by means of a two steps protocol based on univariate and robust principal component analysis.

     

Studies of yeast phenylalanine-accepting transfer ribonucleic acid backbone structure in solution by phosphorus-31 nuclear magnetic resonance spectroscopy.

Approximately 17 diester phosphates from the backbone structure of yeast tRNAPhe give rise to phosphorus resonances, which are resolved in its 31P NMR spectrum. To localize these diester phosphates within the tRNA structure, 31P NMR spectra of several chemically or enzymatically modified yeast tRNAPhe species were recorded. To this end selective modifications were performed in the anticodon, the DHU, and the T psi C loop. Modifications, performed in different loop regions, give rise to perturbation of different characteristic 31P resonances. The 31P spectra were correlated with the corresponding 1H NMR spectra of the ring N hydrogen-bonded protons and interpreted in view of the X-ray results obtained on yeast tRNAPhe. It is concluded that the diester phosphate groups, which experience an unusual shift, can be accounted for in the X-ray structure in terms of hydrogen-bonded phosphates groups and diester phosphates with a diester geometry, deviating from the normal double-helical conformation.     

Proton nuclear magnetic resonance spectra of excised rat brain. Assignment of resonances

We have recorded 1H NMR spectra of excised rat brain at 361 MHz using two different water suppression pulse sequences. The assignment of the resonances has been carried out in perchloric acid extracts and subcellular fractions. Our results show that cytosolic proteins, membrane phospholipids and 16 different metabolites contribute to the observed spectra. The new resonances assigned allow the direct observation of myo-inositol and urea. Moreover, changes in the spectral pattern upon anesthesia, ischemic exposure of the brain and age of the rat have been recorded and correlated with the compounds producing the spectra.     

Amino acid analysis of angiotensin I by proton nuclear magnetic resonance spectroscopy

The chemical shifts of the isoleucine and histidine protons of angiotensin I were assigned and the chemical shifts of the protons of the other amino acids in the peptide were confirmed at a field strength of 400 MHz. These chemical shift assignments were used to determine the amino acid composition of angiotensin I. These data were then compared to the amino acid composition which was determined by chromatographic analysis of the peptide hydrolysate. The results obtained by the chromatographic method were similar to those obtained by the NMR method. The standard deviations of the results were similar, indicating that these methods are equally precise. The major advantages of the NMR method are that it permits the recovery of the peptide after completion of the analysis and improves the quantitation of amino acids which are either partially destroyed by the hydrolysis procedure or require special derivatization methods for detection and quantitation.     

Nuclear magnetic resonance studies on yeast tRNAPhe. II. Assignment of the iminoproton resonances of the anticodon and T stem by means of nuclear Overhauser effect experiments at 500 MHz.

Resonances of the water exchangeable iminoprotons of the T and anticodon stem of yeast tRNAPhe were assigned by means of Nuclear Overhauser Effects (NOE's). Together with our previous assignments of iminoproton resonances from the acceptor and D stem (A. Heerschap, C.A.G. Haasnoot and C.W. Hilbers (1982) Nucleic Acids Res. 10, 6981-7000) the present results constitute a complete assignment of all resonances of iminoprotons involved in the secondary structure of yeast tRNAPhe with a reliability and spectral resolution not reached heretofore. Separate identification of the methylprotons in m5C40 and m5C49 was also possible due to specific NOE patterns in the lowfield part of the spectrum. Our experiments indicate that in solution the psi 39 residue in the anticodon stem is orientated in a syn conformation in contrast to the normally observed anti orientation of the uracil base in AU basepairs. Evidence is presented that in solution the acceptor stem is stacked upon the T stem. Furthermore, it turns out that in a similar way the anticodon stem forms a continuous stack with the D stem, but here the m2(2)G26 residue is located between the latter two stems (as is found in the X-ray crystal structure). The stacking of these stems is not strictly dependent on the presence of magnesium ions. NOE experiments show that these structural features are preserved when proceeding from a buffer with magnesium ions to a buffer without magnesium ions although differences in chemical shifts and NOE intensities indicate changes in the conformation of the tRNA.     

Sequence-specific recognition of deoxyribonucleic acid. Chemical synthesis and nuclear magnetic resonance assignment of the imino protons of lambda OR3 operator deoxyribonucleic acid

Using solid-phase phosphite triester methods, we have synthesized both strands of the phage lambda OR3 DNA sequence, reannealed them, and studied the native operator duplex by high-resolution NMR at 500 MHz. At 7 degrees C the imino protons of the two terminal base pairs at each end have disappeared from the spectrum by exchange broadening. The 13 detectable imino resonances have been assigned to their respective base pairs in the duplex by using sequential nearest-neighbor NOE connectivity methods described previously. In cases where two imino protons overlap in the spectrum, spin diffusion was used to drive the cross-saturation further afield in order to produce second-order next-nearest-neighbor effects. The results show that the imino connectivity method can be used to unambiguously assign the imino proton spectrum of operator DNAs containing one to two full turns of the helix.