Accurate nucleic acid concentrations by nuclear magnetic resonance

Determination of the concentration of biochemical samples often yields values with uncertainties of 10-20% or more. This paper details a protocol for use with 500- to 600-MHz NMR spectrometers to measure approximately 1mM concentrations within +/-1-3% accuracy. With suitable precautions, all compounds have equal NMR "absorption coefficients" for protons. About 2mg of sample are needed for proteins and nucleic acids with MW=5000, although less accurate determinations could be made with smaller amounts. The technique utilizes standardized internal reference reagent compounds, cacodylic acid or 3-(trimethylsilyl)propionic-2,2,3,3-d(4) acid sodium salt. Spectra were signal-averaged using long interpulse delays so that integrals of nonexchangeable protons could be quantified relative to the reference standard. Accurate determinations require careful optimization of the homogeneity of the magnetic field and meticulous attention to sample preparation and spectral processing. The main source of error is usually the accuracy of micropipets. If sample preparation errors could be eliminated, the lower limit of accuracy with the current generation of NMR spectrometers is probably near 0.4%. However, this would require >99.5% sample purity. Methods are described to establish the concentration of the standards, and applications are illustrated with DNA mono- and oligonucleotides. Similar procedures should apply to proteins, polysaccharides, and other biomolecules, with about the same accuracy and precision.

Structure of SL4 RNA from the HIV-1 packaging signal

The NMR-based structure is described for an RNA model of stem-loop 4 (SL4) from the HIV-1 major packaging domain. The GAGA tetraloop adopts a conformation similar to the classic GNRA form, although there are differences in the details. The type II tandem G.U pairs have a combination of wobble and bifurcated hydrogen bonds where the uracil 2-carbonyl oxygen is hydrogen-bonded to both G,H1 and G,H2. There is the likelihood of a Na(+) ion coordinated to the four carbonyl oxygens in the major groove for these G.U pairs and perhaps to the N7 lone pairs of the G bases as well. A continuous stack of five bases extends over nearly the whole length of the stem to the base of the loop in the RNA 16mer: C15/U14/G13/G5/C6. There is no evidence for a terminal G.A pair; instead, G1 appears quite unrestrained, and A16 stacks on both C15 and G2. Residues G2 through G5 exhibit broadened resonances, especially G3 and U4, suggesting enhanced mobility for the 5'-side of the stem. The structure shows G2/G3/U4 stacking along the same strand, nearly isolated from interaction with the other bases. This is probably an important factor in the signal broadening and apparent mobility of these residues and the low stability of the 16mer hairpin against thermal denaturation.

Regioselective synthesis of 1,3,5-13C3 and 2,4-13C2-labeled 2-deoxyribonolactones

The synthesis of 1,3,5-13C3- and 2,4-13C2-labeled 5-O-bromobenzyl-2-deoxyribonolactones 2, precursors to 13C-enriched nucleoside phosphoramidites for solid-phase synthesis of DNA oligonucletides, is described. An equimolar combination of these two multiply labeled lactones affords a "population-labeled" mixture of isotopomers which exhibits an approximately 50-fold increase in the sensitivity of 13C-NMR compared to natural abundance measurements. The 13C-13C 2-bond and 4-bond coupling constants are reported for the lactones; all are <2Hz, confirming that this labeling scheme should be especially useful for NMR-relaxation measurements.

Changes in 13C NMR chemical shifts of DNA as a tool for monitoring drug interactions

The antibiotic drug, netropsin, was complexed with the DNA oligonucleotide duplex [d(GGTATACC)]2 to explore the effects of ligand binding on the 13C NMR chemical shifts of the DNA base and sugar carbons. The binding mode of netrospin to TA-rich tracts of DNA has been well documented and served as an attractive model system. For the base carbons, four large changes in resonance chemical shifts were observed upon complex formation: -0.64 ppm for carbon 4 of either Ado4 or Ado6, 1.36 ppm for carbon 2 of Thd5, 1.33 ppm for carbon 5 of Thd5 and 0.94 for carbon 6 of Thd5. AdoC4 is covalently bonded to a heteroatom that is hydrogen bonded to netropsin; this relatively large deshielding is consistent with the known hydrogen bond formed at AdoN3. The three large shielding increases are consistent with hydrogen bonds to water in the minor groove being disrupted upon netropsin binding. For the DNA sugar resonances, large changes in chemical shifts were observed upon netropsin complexation. The 2', 3' and 5' 13C resonances of Thd3 and Thd5 were shielded whereas those of Ado4 and Ado6 were deshielded; the 13C resonances of 1' and 4' could not be assigned. These changes are consistent with alteration of the dynamic pseudorotational states occupied by the DNA sugars. A significant alteration in the pseudorotational states of Ado4 or Ado6 must occur as suggested by the large change in chemical shift of -1.65 ppm of the C3' carbon. In conclusion, 13C NMR may serve as a practical tool for analyzing structural changes in DNA-ligand complexes.

Three-dimensional folding of an RNA hairpin required for packaging HIV-1

An NMR-based structure is presented for a 20 mer hairpin model of the SL3 stem-loop from the HIV-1 packaging signal. The stem has an A-family structure. However, the GGAG tetraloop appears to be flexible with the second (G10) and fourth (G12) bases extruded from the normal stacking arrangement. The A-base (A11) occupies a cavity large enough for it to jump rapidly between stacking upon G9 (in the loop) and G13 (from the base-pair adjacent to the loop). The H-bonding loci of G10, A11, and G12 are unoccupied in the free RNA structure. The loop should be easily adaptable to binding by the HIV-1 nucleocapsid protein or loop receptors.

Full 1H NMR assignment of a 24-nucleotide RNA hairpin: application of the 1H 3D-NOE/2QC experiment

The subject RNA models the binding site for the coat protein of the R17 virus, as well as the ribosome recognition sequence for the R17 replicase gene. With an RNA of this size, overlaps among the sugar protons complicate assignments of the 1H NMR spectrum. The cross peaks that overlap significantly in 2D-NOE spectra can frequently be resolved by introducing a third, in our approach the double-quantum, frequency axis. In particular the planes in a 3D-NOE/2QC spectrum perpendicular to the 2Q axis are extremely useful, showing a highly informative repeating NOE-2Q pattern. In this experiment substantial J-coupling confers special advantages. This always occurs for geminal pairs (H5'/H5" for RNA plus H2'/H2" for DNA), as well as for H5/H6, for H3'/H4' in sugars with substantial populations of the N-pucker, for H1'/H2' for S-puckered sugars, and usually for H2'/H3'. For the 24-mer RNA hairpin the additional information from the 3D-NOE/2QC spectrum allowed assignment of all of the non-exchangeable protons, eliminating the need for stable-isotope labeling.

Structure of the HIV-1 nucleocapsid protein bound to the SL3 psi-RNA recognition element

The three-dimensional structure of the human immunodeficiency virus-type 1 (HIV-1) nucleocapsid protein (NC) bound to the SL3 stem-loop recognition element of the genomic Psi RNA packaging signal has been determined by heteronuclear magnetic resonance spectroscopy. Tight binding (dissociation constant, approximately 100 nM) is mediated by specific interactions between the amino- and carboxyl-terminal CCHC-type zinc knuckles of the NC protein and the G7 and G9 nucleotide bases, respectively, of the G6-G7-A8-G9 RNA tetraloop. A8 packs against the amino-terminal knuckle and forms a hydrogen bond with conserved Arg32, and residues Lys3 to Arg10 of NC form a 310 helix that binds to the major groove of the RNA stem and also packs against the amino-terminal zinc knuckle. The structure provides insights into the mechanism of viral genome recognition, explains extensive amino acid conservation within NC, and serves as a basis for the development of inhibitors designed to interfere with genome encapsidation.

Improved proton assignment for DNA by application of aliasing and dispersive-absorptive phasing to two-quantum COSY spectra

A unique combination of aliasing and dispersive-absorptive (DA) phasing of two-quantum correlated spectroscopy (2 Q-COSY) NMR data is shown to enhance proton chemical-shift assignments in DNA oligonucleotides by (i) reducing the time necessary for acquiring NMR data or, alternatively, improving the spectral resolution in a given time, (ii) reducing the number of spectra necessary for NMR data processing and analysis, and (iii) increasing the complexity of oligonucleotide sequences and structures which are accessible to 2D NMR analysis. Aliasing allows a reduction in the size of the acquired data without significant risk of losing information. Phasing the 2Q-COSY dispersive in the F2 dimension reduces the primary antiphase doublet into a pseudo-singlet and increases the apparent signal-to-noise. A single 2Q-COSY spectrum can provide an amount of chemical-shift information comparable to that from a series of COSY, relayed-COSY, and/or spin-lock COSY spectra optimized for various coupling constants. The low signal-to-noise inherent in the most popular two-quantum-filtered correlated spectroscopy (2QF-COSY) of samples with naturally broad lines is largely avoided due to less cancellation. There is no diagonal in a 2Q-COSY which can obscure correlations between protons which are nearly isochronous. As an example of this efficient application, the assignment of 139 of the 143 proton resonances from a single 2Q-COSY and a 2D-NOE spectrum of the DNA hexadecamer [d(AAATATAGCTATATTT)]2 is demonstrated.

Monte Carlo estimation of errors in 13C-NMR relaxation studies of a DNA oligomer duplex

An analysis of errors has been done with the Monte Carlo method for natural abundance 13C-NMR relaxation studies of a DNA duplex. Repeated measurements of the longitudinal relaxation time, T1, and the heteronuclear NOE were made at 90.6 MHz on the duplexed DNA pentanucleotide, [d(TCGCG)]2. The deviations averaged over all carbons were 13% for T1 and 9% for NOE. These relative deviations were applied to generate 100 values of T1 and NOE with normal distributions about the measured mean values for each carbon. A new version of MOLDYN, called McMOLDYN, has been written, which was used to generate 100 values of T1 and NOE with normal distributions corresponding to the measured errors; the same error distributions were also applied to measurements at 125.8 MHz. The order parameter, S2, and the effective internal correlation time, tau e, in the Model-Free Approach have been optimized from the distributions simulated by McMOLDYN. McMOLDYN also permits the automated entry of multiple sets of initial guesses for the output parameters S2, tau e, and tau m. In addition, McMOLDYN adds cross-relaxation terms from chemical shift anisotropy, increasingly important as spectrometer magnetic fields get higher. Between the two parameters optimized, S2 has the smallest relative error, estimated at 15% on average, which means that S2 is a well-defined parameter. However, tau e is very poorly defined with the average relative error estimated 85%; it is typically found in the range of 30-300 ps.

Proton NMR and structural features of a 24-nucleotide RNA hairpin

The three-dimensional conformation of a 24-nucleotide variant of the RNA binding sequence for the coat protein of bacteriophage R17 has been analyzed using NMR, molecular dynamics, and energy minimization. The imino proton spectrum is consistent with base pairing requirements for coat protein binding known from biochemical studies. All 185 of the nonexchangeable protons were assigned using a variety of homonuclear 2D and 3D NMR methods. Measurements of nuclear Overhauser enhancements and two-quantum correlations were made at 500 MHz. New procedures were developed to characterize as many resonances as possible, including deconvolution and path analysis methods. An average of 21 distance constraints per residue were used in molecular dynamics calculations to obtain preliminary folded structures for residues 3-21. The unpaired A8 residue is stacked in the stem, and the entire region from G7 to C15 in the upper stem and loop appears to be flexible. Several of these residues have a large fraction of S-puckered ribose rings, rather than the N-forms characteristic of RNA duplexes. There is considerable variation in the low-energy loop conformations that satisfy the distance constraints at this preliminary level of refinement. The Shine-Dalgarno ribosome binding site is exposed, and only two apparently weak base pairs would have to break for the 16S ribosomal RNA to bind and the ribosome to initiate translation of the replicase gene. Although the loop form must be regarded as tentative, the known interaction sites with the coat protein are easily accessible from the major groove side of the loop.

Computer-assisted assignment of peptides with non-standard amino acids

A comprehensive peptide assignment program and its application to a cyclic peptide, cyclosporin A, are presented in this paper. A group of graph theoretical algorithms using fuzzy logic are discussed with the aid of examples from cyclosporin A. The algorithms deal with heavily overlapped peaks, recover disjointed and distorted spin coupling networks, and include strategies for sequence-specific assignment. A procedure to extend the Protein Knowledge Base for automatically assigning non-standard amino acid residues is also presented. The program is capable of completely automated assignment for small peptides (approximately 20 residues). For such molecules, it is insensitive to whether the peptide chain is cyclic or acyclic, and to whether amide protons are present or absent. For larger peptides/proteins, more user interaction is required and the sequence-specific assignment step usually must proceed through fragments smaller than the full length to avoid problems due to occurrence of a combinatorial explosion. The program can be applied as a rigorous tool to check manual assignments. The fuzzy graph theoretical concepts built in the program are illustrated with 2D proton spectra of a peptide, but may be extended to higher-dimensional spectra, other biopolymers, natural products and other organic structures.

13C-NMR of the deoxyribose sugars in four DNA oligonucleotide duplexes: assignment and structural features

Natural-abundance 13C-NMR spectra have been obtained for four self-complementary DNA oligonucleotides: [d(TAGCGCTA)]2, [d(GGTATACC)]2, [d(CG)3]2, and [d(TCGCG)]2; this paper focuses on the deoxyribose resonances. Assignments were made by a combination of the two-dimensional proton-detected heteronuclear correlation experiment and comparison of 1D spectra, accounting for 31P coupling, base composition, and similarities in chemical shift versus temperature profiles (delta vs T). Large shielding and deshielding of the sugar resonances (between 2.0 and -1.9 ppm) are observed upon thermal dissociation of the duplex. The shapes of the delta vs T profiles correlate strongly with the purine/pyrimidine nature of the base attached at C1' in these duplexes that have a substantial fraction of residues within alternating purine-pyrimidine sequences. The correlation is primarily associated with changes in the equilibrium distribution of furanose pseudorotational states that may arise in part from the relief of interstrand purine-purine steric clashes.

13C-NMR relaxation in three DNA oligonucleotide duplexes: model-free analysis of internal and overall motion

Natural-abundance 13C-NMR spectra of [d(TCGCG)] (1), [d(CGCGCG)]2 (2), and [d(GGTATACC)]2 (3) were measured at 90.6 MHz to obtain 13C-1H NOEs and T1 relaxation times; relaxation data were also measured at 125.7 MHz for 1 and 2 and at 62.9 MHz for 1. Analysis of the relaxation data was performed in the context of the "model-free" approach of Lipari and Szabo [Lipari, G., & Szabo, A. (1982) J. Am. Chem. Soc. 104, 4546-4559], leading to the following conclusions: (i) Optimized values for the overall correlation times of 0.9 ns for 1 and 1.4 ns for 2 are close to those predicted by light-scattering results on similar molecules [Eimer et al. (1990) Biochemistry 29, 799-811]. (ii) For the nonterminal residues, the "order parameter", S2, is around 0.8 for the protonated base carbons and 0.6 for the sugar carbons, indicating less spatial restriction on the sugar carbons (in the model-free approach, the order parameter is 1 for a rigid body and 0 for a system with completely unrestricted internal motion). (iii) The order parameters for the terminal residues vary over a wide range with the smallest values around 0.2-0.3 for the HO-13C5' and the 13C3'-OH; rational trends are seen in the variation of S2 with chain position in the terminal residues. (iv) The analysis shows that the order parameters are accurate within 15%. (v) The "effective internal correlation time", tau e, is very short for the sugar carbons (30-300 ps) and less well-defined, but probably also short, for the bases. (vi) The analysis indicates that most of the relaxation in DNA is accounted for by S2 and the tau e is so short that a good approximation to any relaxation property, P (e.g., T1, T2, 13C-1H NOE, 1H-1H cross-relaxation rate), is P = S2Prigid, where Prigid is the value for the property in a system without internal motion (the analysis assumes the same isotropic overall motion for both the rigid and flexible bodies).

Actinomycin D induced DNase I hypersensitivity and asymmetric structure transmission in a DNA hexadecamer

DNase I cleavage rates and nmr chemical shifts are shown to change for DNA sequences distal to an intercalated actinomycin D molecule in a duplex hexadecamer upon drug binding. Both sets of observations suggest that the source of these changes is a DNA-mediated structural response. The nmr results imply the response is transmitted preferentially in a 5'-to-3' direction from the drug binding site. An inequivalent response of the two strands to a ligand-induced conformational change immediately suggests a mechanism for distinguishing the sense and antisense strands of DNA.

Enzymatic and NMR analysis of oligoribonucleotides synthesized with 2'-tert-butyldimethylsilyl protected cyanoethylphosphoramidite monomers

The regioisomeric integrity of the internucleotide phosphate linkage in synthetic RNA using 2'-tert-butyldimethylsilyl protection was examined using enzymatic and NMR techniques. Two sets of DNA-RNA hybrid nonamers, T3XT5 and T5XT3 (where X = rA, rC, rG and U) and the tetramer AGCU were analyzed. Enzyme catalyzed hydrolysis of the nonamers with ribonuclease T2 showed that the linkage at the ribonucleotide was the desired 3'-5'. A control nonamer with a 2'-5' linkage was subjected to the enzyme, and showed no cleavage. High-resolution proton NMR of the tetramer also gave a favorable comparison with the same molecule obtained by non-chemical means.

Toward a computer assisted analysis of NOESY spectra: a multivariate data analysis of an RNA NOESY spectrum

A multivariate data-representation of a portion of the H-NOESY spectrum of an RNA octamer duplex was used to explore the possibility of using Principal Component Analysis and Partial Least Squares Discrimination for pattern recognition. In this case, it is found that the methods can: (i) distinguish slices containing signal from those containing only noise, (ii) locate slices containing overlapping signals, and (iii) in some cases to segregate slices with unique aspects such as those from terminal nucleotides, overlapping signals, purine-H8, pyrimidine-H6 and adenine-H2 containing slices. These properties can easily be included in a scheme to automate spectral analysis. The formulation described here does not distinguish patterns needed to automate sequential assignment of resonances in NOESY spectra of RNA.

Actinomycin D induced DNase I cleavage enhancement caused by sequence specific propagation of an altered DNA structure

Two DNA hexadecamers containing one central 5'-GC-3' base step have been examined by footprinting methodology in the presence and absence of actinomycin D. The results of these studies, coupled with imino proton NMR measurements indicate that the antitumor drug causes a change in DNA conformation at a distance from the actinomycin intercalation site in a molecule of sequence d[ATATATAGCTATATAT] that does not occur in d[AAAAAAAGCTTTTTTT]. The experiments demonstrate that DNase I rate enhancements associated with actinomycin D binding are caused by ligand alteration of equilibrium DNA structure.

13C NMR assignments of the bases in oligodeoxynucleotides: an automated procedure using Bayesian statistics

A statistical method, Bayes Maximum Likelihood, has been applied to the classification of base 13C NMR resonances in DNA oligomers. An accuracy of 100% for carbon class discrimination was achieved for a preliminary training set of four oligomers using the following four parameters: (1) the chemical shift; (2) the temperature at which the spectrum was obtained; (3) the difference in chemical shift from the C5 resonances; and (4) a sequence factor representing the neighboring nucleotides. Classification of a fifth oligomer, previously assigned and not contained in the original training set, gave reasonable carbon class assignments.

13C NMR of the bases of three DNA oligonucleotide duplexes: assignment methods and structural features

Natural abundance 13C NMR spectra of three DNA oligomers have been obtained. Most of the base resonances are well resolved from one another. A combination of two independent methods was used in making assignments: a one-dimensional spectral comparison method and a two-dimensional proton-detected 1H-13C correlated experiment for the protonated carbons. There are large shielding changes (between 1.62 and -1.40 ppm) upon thermal dissociation of the duplex. The shapes of the chemical shift vs temperature curves are largely independent of sequence. The base carbon resonance frequencies are sensitive to hydrogen bonding, base stacking, sugar conformation, and changes in the glycosyl torsion angle.

13C NMR assignments of the protonated carbons of [d(TAGCGCTA)]2 by two-dimensional proton-detected heteronuclear correlation

The resonances of the protonated carbons of [d(TAGCGCTA)]2 have been assigned by the two-dimensional proton-detected double-quantum heteronuclear correlation experiment [( 1H-13C]-DQCOSY). 13C-coupled and 13C-decoupled versions of the experiment were used. The assignment method is discussed in detail. The deoxyribose cross peaks segregate into five well-resolved regions, and the base cross peaks have distinct features that are helpful for assignments. The cross peaks from the 1H-13C pairs at the Cyd5, Ado2 and ThdCH3 base positions fall in separate regions of the spectrum from each other; they also are resolved from the closely spaced Ado8, Guo8, Cyd6 and Thd6. Additional parameters for distinction of the base signals are their differing J-coupling values and long-range coupling patterns.

Hydrogen-bonding effects and 13C-NMR of the DNA double helix

13C-nmr chemical shifts of the nucleotides in DNA are sensitive to hydrogen bonding, especially for three of the carbons immediately bonded to exocyclic oxygen or nitrogen atoms acting as H-bond acceptors or donors. GuoC2, GuoC6 and ThdC4 are strongly deshielded (about 1 ppm) upon Watson-Crick pairing in oligodeoxynucleotide duplexes, regardless of the base sequence. Deshielding at these sites may be useful to distinguish bases involved in Watson-Crick pairs from unpaired bases.

Effects of ethanol on gastric epithelial cell phospholipid dynamics and cellular function

The lipid profile of isolated gastric superficial epithelial cells (SEC) was evaluated by proton nuclear magnetic resonance spectroscopy (1H-NMR). The most conspicuous resonance band in SEC spectra was due to the protons of +N(CH3)3 groups of phosphatidylcholine and, to a lesser degree, other phospholipid derivatives, on the basis of their chemical shift and addition of purified phospholipids. NMR of cell lysates and phospholipid extracts of SEC in deutero-chloroform provided further spectral resolution of these components. Phospholipase or ethanol treatments of SEC produced membrane disorganization reflected as increased peak intensity of the phospholipid signals. In addition, ethanol, in a dose-dependent manner, attenuated paranitrophenyl phosphatase activity, which correlated with inhibition of total and ouabain-sensitive 86Rubidium chloride uptake by SEC. This study suggests that NMR used in conjunction with other biochemical techniques can monitor SEC membrane structure-function relationships. NMR is a potentially powerful noninvasive probe to show changes in lipid membrane organization induced by low concentrations of ethanol (1%) and may indicate an early sign of "cytotoxicity" in intact SEC.

Actinomycin D facilitates transition of AT domains in molecules of sequence (AT)nAGCT(AT)n to a DNAse I detectable alternating structure

The interaction of actinomycin D with (AT)nAGCT(AT)n (where n = 2, 3, or 4) was investigated using a combination of imino proton NMR and DNAse I digestion. The stoichiometry of the interaction appears to be one:one with the actinomycin chromophore intercalated between the two GC base pairs. This binding event facilitates the conversion of the flanking repetitive AT regions to an alternating conformation characterized by induced sensitivity of the ApT sequences to attack by DNAse I. The neighboring TpA sequences do not exhibit rate changes as a function of binding of the drug. The potential relevance of such ligand induced DNA structural alterations is discussed.

NMR studies of flexible opiate conformations at monoclonal antibody binding sites. I. Transferred nuclear Overhauser effects show bound conformations

500 MHz H, homonuclear, intra-molecular, transferred Nuclear Overhauser Effect measurements have been performed on the bound forms of a classical opiate antagonist, nalorphine and an agonist, levorphanol at their respective binding sites in two different specific anti-opiate monoclonal antibody fragments. Based upon previous studies of opiate conformations in solution the results clearly show without extensive interpretation that one of these flexible haptens has the opposite (from solution) isomeric conformation in its bound form. For nalorphine the axial isomer of the N-allyl substituent is the bound form whereas in solution the equatorial isomer dominates at a ratio of 5:1. For levorphanol the bound form is that of equatorial N-methyl in accord with the low energy conformation in solution. In this preliminary report we discuss the initial measurements and results and their implications with respect to the conformations of flexible ligands at macromolecular binding sites including opiate receptors.

NMR studies of pig gastric microsomal H+,K+-ATPase and phospholipid dynamics. Effects of ethanol perturbation

The effects of ethanol on the gastric H+,K+-ATPase activity and the degree of mobility of various microsomal phospholipids were assessed using 31P and 1H NMR. This illuminated the role of lipid-protein association in the function of pig gastric microsomes. Treatment of gastric microsomes with 15% ethanol for 1 min at 37 degrees C inactivated the H+,K+-ATPase activity, which could largely be reconstituted by supplementation with phosphatidylcholine isolated from the gastric microsomes. Under similar conditions, the 1H NMR profile of the microsomal +N(CH3)3 choline moiety showed dramatic enhancement of peak intensity as well as a break point at 25 degrees C which was restored to the untreated control value after reconstitution. This break, together with the dramatic enhancement in the overall lipid profile, compared to the control and reconstituted microsomes, suggested a greater degree of freedom of movement of the microsomal lipids following ethanol perturbation. The data demonstrate the unique ability that a combined approach using 31P and 1H NMR holds as a noninvasive probe to study the structure-function relationship of biomembranes.

13C-NMR of ribosyl ApApA, ApApG and ApUpG

The chemical shifts as well as the 13C-31P coupling constants of the carbon-13 nuclei in single-stranded ApApA, ApApG, and ApUpG are sensitive to sequence and temperature. ApApA and ApApG have similar properties with large shielding (up to 1.7 ppm) of many of the base carbons upon decreasing the temperature from 70 degrees C to 11 degrees C; the base carbons have smaller shielding changes in ApUpG. Large shielding and deshielding effects are observed for the 1', 3', 4' and 5'-carbons over this temperature range. Analysis of the 13C-31P couplings measured at the 4' ribose carbons show that the population of the anti rotamer about O5'-C5' varies from 98 to 75%, and is higher in ApApA and ApApG than in ApUpG. The CCOP coupling data at 2' and 4' is consistent with a blend of the -antiperiplanar/-synclinal nonclassical rotamers about the C3'-O3' bond, varying from 89/11% in ApApG to 55/45% in ApUpG. The coupling and chemical shift data support the thesis that ApUpG is stacked much less than the other two molecules. The stacked forms of all three trinucleotides is most easily interpreted by a standard A-RNA model. It is not necessary to invoke the "bulged base" hypothesis [Lee, C.-H. and Tinoco, Jr., I. (1981) Biophysical Chemistry 1, 283-294; Lankhorst, P.P., Wille, G., van Boom., J.H., Altona, C., and Haasnoot, C.A.G. (1983) Nucleic Acids Research 11, 2839-2856] to explain the contrast in 13C spectroscopic properties of ApUpG in comparison to ApApG and ApApA.

13C-NMR of ribosyl A-A-A, A-A-G, and A-U-G. Synthesis and assignment

The three RNA trinucleotides; ApApA, ApApG, and ApUpG, have been synthesized in sufficient quantity to obtain natural abundance 13C(1H)-NMR spectra at strand concentrations between 4 and 100 mM. Comparisons between 70 degrees C spectra of the three trimers and their consistuent dimers ApA, ApG, ApU, and UpG allow secure assignments to be made for most of the resonances. This paper describes the syntheses and 13C assignments of the oligomers.

31P-NMR analysis of the B to Z transition in double-stranded (dC-dG)3 and (dC-dG)4 in high salt solution

In 4M NaCl solutions (dC-dG)n (n = 3,4; approximately 9 mM) exist as a mixture o +/- B and Z forms. The low and high field components of two 31P NMR resonances originating from internal phosphodiester groups are assigned to the GpC and CpG linkages, respectively. Low temperatures stabilize the Z-forms, which completely disappear above 50 degrees C (n = 3) and 65 degrees C (n = 4). delta H = -44 and -17 kJ/mol for B to Z transition in the hexamer and octamer duplexes, respectively. Temperature dependent changes (0-50 degrees C range) in the spin-lattice relaxation times at 145.7 MHz are distinctly different for the 31P nuclei o +/- GpC and CpG groups. The relaxation data can be explained by assuming that the GpC phosphodiester groups undergo more local internal motion than do the CpG groups.

Conformation and dynamics of short DNA duplexes: (dC-dG)3 and (dC-dG)4

Natural abundance 13C NMR spectra of duplexed (dC-dG)3 and (dC-dG)4 exhibit resolved resonances for most of the carbons at 0.1M NaCl in aqueous solution. Large transitions in chemical shift for many of the hexamer carbons (up to 1.8 ppm) are observed in variable temperature measurements. Determination of spin-lattice relaxation times and nuclear Overhauser enhancements in 0.1M NaCl indicate that the duplexes tumble almost isotropically, with overall correlation times near 5 nsec; the sugar carbons experience more rapid local motions than do the base carbons. The relaxation data are also consistent with the most rapid local motions occurring at the chain-terminal residues, especially in the Cyd(1) sugar. 4M NaCl causes changes in the 13C chemical shifts of most of the guanine base carbons, and rearrangements in the deoxyribose carbon shifts; this is consistent with changes predicted by a salt-induced B to Z transition, viz. conversion of the guanylates from the anti to syn range about the glycosyl bond, and from the S to N pseudorotational state of the deoxyribose ring.

Sequence and structure in double-stranded ribonucleic acid: (A-G-C-U)2 and (A-C-G-U)2

Comparative studies of the thermally induced helix--coil transition in ribosyl (A-G-C-U)2 and (A-C-G-U)2 are described. Ordered structures form at low temperatures where the ribofuranose rings adopt the 3'-endo conformation and both oligomer helices have base-paired stacking arrangements qualitatively similar to the A-RNA family configuration. Especially for (A-C-G-U)2, there is a lack of quantitative agreement between the A-family base overlap and the 1H NMR data; ring-current and atomic diamagnetic anisotropies using A-form structures fail to predict five of the seven aromatic C--H resonances within 0.2 ppm. The NMR results are in better agreement with the A form for (A-G-C-U)2. For both oligomers, the changes in chemical shift for the anomeric (H1') resonances indicate substantial (greater than or equal to 20 degrees) changes in the average glycosidic torsion angle upon base pairing and stacking for the adenosine and cytidine residues; this angle in uridine and guanosine residues must change only slightly.

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.

Separation of oligo-RNA by reverse-phase HPLC

A rapid and highly reproducible chromatographic technique has been developed for analysis and purification of complex mixtures of oligoribonucleotides. The method utilizes a column of microparticulate porous silica beads fully derivatized with octadecylsilyl groups. The column is eluted with gradients in acetonitrile/water/ammonium acetate pumped at pressures of 1500-300 psi. Most separations are completed in 5-15 min. with usually better than 1% reproducibility of absolute retention times and about 0.1% reproducibility of relative retention times. A single column accomplishes separations of mononucleosides, mononucleotides, and larger oligomers through at least 20-mers. The absolute detection limit is approximately 1 pmole of base though most of the analytical separations described use approximately 1 nmole. In favorable circumstances it is possible to use the analytical colums to purify approximately 1 mg of an oligonucleotide in a single 10-30 min. elution.

Conformation and interaction of short nucleic acid double-stranded helices. II. Proton magnetic resonance studies on the hydrogen-bonded NH-N protons of ribosyl ApApGpCpUpU helix

A self-complementary ribohexanucleotide, ApApGpCpUpU, was synthesized and its NH-N hydrogen-bonded protons were studied by proton magnetic resonance. At 1 degree C, 0.17 M Na+, pH 7.6 with 10 mM phosphate-0.1 mM EDTA in H2O, three proton resonances are found in the low-field region with the following chemical shifts and line widths at half-height: 13.2 ppm (80 Hz), 13.5 ppm (30 Hz), and 14.2 ppm (44 Hz). The existence of these resonances indicates the formation of a self-complementary, hydrogen-bonded duplex under these conditions. Upon elevation of temperature, these three resonances sequentially broaden and finally all disappear near 35 degrees C. Unambiguous assignments of these three resonances can be made to the terminal A(1)-U(6) pairs, interior A(2)-U(5) pairs, and to the middle G(3)-C(4) pairs. The assignments were based on (i) the differential sensitivities of the line widths of these resonances to thermal variation, as well as on (ii) a comparison of the computed chemical shifts with the observed chemical shifts. The quantitative aspects of the NH proton transfer between helix, coil, and water are discussed in relationship to the line widths of these resonances and the lifetime of the helix state. The computed chemical shifts of the NH-N resonances based on the A-RNA (or A'-RNA) model agree more closely with the observed chemical shifts than the computed values based on the B-DNA model. These results suggest that the helical duplex of A2GCU2 assumes a conformation similar to A-RNA (or A'-RNA) in aqueous solution. The results on both the NH-N resonances and the C-H resonances are summarized and discussed in terms of the helical conformation of (A2GCU2)2.

Conformation and interaction of short nucleic acid double-stranded helices. I. Proton magnetic resonance studies on the nonexchangeable protons of ribosyl ApApGpCpUpU

1H nuclear magnetic resonance (NMR) spectra of a self-complementary ribosyl hexanucleotide, A2GCU2, are investigated as a function of temperature and ionic strength in D2O. Seventeen nonexchangeable base and ribose-H1' resonances are resolved, and unequivocally assigned by a systematic comparison with the spectra of a series of oligonucleotide fragments of the A2GCU2 sequence varying in chain length from 2 to 5. Changes in the chemical shifts of the 17 protons from the hexamer as well as the six H1'-H2' coupling constants are followed throughout a thermally induced helix-coil transition. These sigma vs. T and J vs. T (degrees C) profiles indicate that the transition is not totally cooperative and that substantial populations of partially bonded structures must exist at intermediate temperatures, with the central G-C region being most stable. Transitions in chemical shift for protons in the same base pair exhibit considerable differences in their Tm values as the data reflect both thermodynamic and local magnetic field effects in the structural transition, which are not readily separable. However, an average of the Tm values agrees well with the value predicted from studies of the thermally induced transition made by optical methods. The values of J1'-2' for all six residues become very small (less than 1.5 Hz) at low temperatures indicating that C3'-endo is the most heavily populated furanose conformation in the helix. The sigma values of protons in the duplex were compared with those calculated from the ring current magnetic anisotropies of nearest and next-nearest neighboring bases using the geometrical parameters of the A'-RNA and B-DNA models. The sigma values of the base protons in the duplex calculated assuming the A'-RNA geometry agree (+/- approximately 0.1 ppm) with the observed values much more accurately than those calculated on the basis of B-DNA geometry. The measured sigma values of the H1' are not accurately predicted from either model. The synthesis of 35 mg of A2GCU2 using primer-dependent polynucleotide phosphorylase is described in detail with extensive discussion in the microfilm edition.