Selective isotopic enrichment of synthetic RNA: application to the HIV-1 TAR element

Isotope-Labeled RNA Building Blocks for NMR Structure and Dynamics Studies

RNA structural research lags behind that of proteins, preventing a robust understanding of RNA functions. NMR spectroscopy is an apt technique for probing the structures and dynamics of RNA molecules in solution at atomic resolution. Still, RNA analysis by NMR suffers from spectral overlap and line broadening, both of which worsen for larger RNAs. Incorporation of stable isotope labels into RNA has provided several solutions to these challenges. In this review, we summarize the benefits and limitations of various methods used to obtain isotope-labeled RNA building blocks and how they are used to prepare isotope-labeled RNA for NMR structure and dynamics studies.

Structure of HIV TAR in complex with a Lab-Evolved RRM provides insight into duplex RNA recognition and synthesis of a constrained peptide that impairs transcription

Natural and lab-evolved proteins often recognize their RNA partners with exquisite affinity. Structural analysis of such complexes can offer valuable insight into sequence-selective recognition that can be exploited to alter biological function. Here, we describe the structure of a lab-evolved RNA recognition motif (RRM) bound to the HIV-1 trans-activation response (TAR) RNA element at 1.80 Å-resolution. The complex reveals a trio of arginines in an evolved β2-β3 loop penetrating deeply into the major groove to read conserved guanines while simultaneously forming cation-π and salt-bridge contacts. The observation that the evolved RRM engages TAR within a double-stranded stem is atypical compared to most RRMs. Mutagenesis, thermodynamic analysis and molecular dynamics validate the atypical binding mode and quantify molecular contributions that support the exceptionally tight binding of the TAR-protein complex (KD,App of 2.5 ± 0.1 nM). These findings led to the hypothesis that the β2-β3 loop can function as a standalone TAR-recognition module. Indeed, short constrained peptides comprising the β2-β3 loop still bind TAR (KD,App of 1.8 ± 0.5 μM) and significantly weaken TAR-dependent transcription. Our results provide a detailed understanding of TAR molecular recognition and reveal that a lab-evolved protein can be reduced to a minimal RNA-binding peptide.

Stable isotope labeling methods for DNA

NMR is a powerful method for studying proteins and nucleic acids in solution. The study of nucleic acids by NMR is far more challenging than for proteins, which is mainly due to the limited number of building blocks and unfavorable spectral properties. For NMR studies of DNA molecules, (site specific) isotope enrichment is required to facilitate specific NMR experiments and applications. Here, we provide a comprehensive review of isotope-labeling strategies for obtaining stable isotope labeled DNA as well as specifically stable isotope labeled building blocks required for enzymatic DNA synthesis.

Chemo-enzymatic labeling for rapid assignment of RNA molecules

Even though Nuclear Magnetic Resonance (NMR) spectroscopy is one of the few techniques capable of determining atomic resolution structures of RNA, it is constrained by two major problems of chemical shift overlap of resonances and rapid signal loss due to line broadening. Emerging tools to tackle these problems include synthesis of atom specifically labeled or chemically modified nucleotides. Herein we review the synthesis of these nucleotides, the design and production of appropriate RNA samples, and the application and analysis of the NMR experiments that take advantage of these labels.

Preparative separation of ribonucleoside monophosphates by ion-pair reverse-phase HPLC

Structural and dynamic investigations of RNA by nuclear magnetic resonance (NMR) spectroscopy strongly benefit from isotopic-labeling strategies. Among these, nucleotide-specific and site-specific labeling methods can help tremendously in simplifying complex NMR data, while providing unique opportunities for structural investigation of larger RNAs. Such methods generally require separation of individual isotopically labeled ribonucleoside monophosphates prior to their conversion into nucleoside triphosphates and selective incorporation of these nucleoside triphosphates into the RNA. This chapter provides the experimental details for preparative separation of ribonucleoside monophosphates by ion-pair reverse-phase HPLC. It also describes a quick procedure for clean-up and quality control of the individual ribonucleoside monophosphates.

Database proton NMR chemical shifts for RNA signal assignment and validation

The Biological Magnetic Resonance Data Bank contains NMR chemical shift depositions for 132 RNAs and RNA-containing complexes. We have analyzed the (1)H NMR chemical shifts reported for non-exchangeable protons of residues that reside within A-form helical regions of these RNAs. The analysis focused on the central base pair within a stretch of three adjacent base pairs (BP triplets), and included both Watson-Crick (WC; G:C, A:U) and G:U wobble pairs. Chemical shift values were included for all 4(3) possible WC-BP triplets, as well as 137 additional triplets that contain one or more G:U wobbles. Sequence-dependent chemical shift correlations were identified, including correlations involving terminating base pairs within the triplets and canonical and non-canonical structures adjacent to the BP triplets (i.e. bulges, loops, WC and non-WC BPs), despite the fact that the NMR data were obtained under different conditions of pH, buffer, ionic strength, and temperature. A computer program (RNAShifts) was developed that enables convenient comparison of RNA (1)H NMR assignments with database predictions, which should facilitate future signal assignment/validation efforts and enable rapid identification of non-canonical RNA structures and RNA-ligand/protein interaction sites.

Biosynthetic preparation of 13C/15N-labeled rNTPs for high-resolution NMR studies of RNAs

High-resolution investigations of the structure and dynamics of RNA molecules by nuclear magnetic resonance (NMR) methodologies require the production of (13)C/(15)N-isotopically labeled samples. A common strategy entails the preparation of (13)C/(15)N-enriched ribonucleoside 5'-triphosphates (rNTPs) to be incorporated into RNA oligomers by in vitro transcription. Here, we describe the methods to obtain isotopically labeled rNTP in a uniform or selective fashion from bacterial cultures, using common and versatile E. coli strains. This chapter also covers procedures for extraction and digestion of the total RNA from bacterial cells, purification of the ribonucleoside 5'-monophosphates and their enzymatic phosphorylation to rNTPs.

Biomass production of site selective 13C/15N nucleotides using wild type and a transketolase E. coli mutant for labeling RNA for high resolution NMR

Characterization of the structure and dynamics of nucleic acids by NMR benefits significantly from position specifically labeled nucleotides. Here an E. coli strain deficient in the transketolase gene (tktA) and grown on glucose that is labeled at different carbon sites is shown to facilitate cost-effective and large scale production of useful nucleotides. These nucleotides are site specifically labeled in C1' and C5' with minimal scrambling within the ribose ring. To demonstrate the utility of this labeling approach, the new site-specific labeled and the uniformly labeled nucleotides were used to synthesize a 36-nt RNA containing the catalytically essential domain 5 (D5) of the brown algae group II intron self-splicing ribozyme. The D5 RNA was used in binding and relaxation studies probed by NMR spectroscopy. Key nucleotides in the D5 RNA that are implicated in binding Mg(2+) ions are well resolved. As a result, spectra obtained using selectively labeled nucleotides have higher signal-to-noise ratio compared to those obtained using uniformly labeled nucleotides. Thus, compared to the uniformly (13)C/(15)N-labeled nucleotides, these specifically labeled nucleotides eliminate the extensive (13)C-(13)C coupling within the nitrogenous base and ribose ring, give rise to less crowded and more resolved NMR spectra, and accurate relaxation rates without the need for constant-time or band-selective decoupled NMR experiments. These position selective labeled nucleotides should, therefore, find wide use in NMR analysis of biologically interesting RNA molecules.

Site-specific isotope labeling of long RNA for structural and mechanistic studies

A site-specific isotope labeling technique of long RNA molecules was established. This technique is comprised of two simple enzymatic reactions, namely a guanosine transfer reaction of group I self-splicing introns and a ligation with T4 DNA ligase. The trans-acting group I self-splicing intron with its external cofactor, ‘isotopically labeled guanosine 5′-monophosphate’ (5′-GMP), steadily gave a 5′-residue-labeled RNA fragment. This key reaction, in combination with a ligation of 5′-remainder non-labeled sequence, allowed us to prepare a site-specifically labeled RNA molecule in a high yield, and its production was confirmed with ¹⁵N NMR spectroscopy. Such a site-specifically labeled RNA molecule can be used to detect a molecular interaction and to probe chemical features of catalytically/structurally important residues with NMR spectroscopy and possibly Raman spectroscopy and mass spectrometry.

Site-specific labeling of nucleotides for making RNA for high resolution NMR studies using an E. coli strain disabled in the oxidative pentose phosphate pathway

Escherichia coli (E. coli) is a versatile organism for making nucleotides labeled with stable isotopes ((13)C, (15)N, and/or (2)H) for structural and molecular dynamics characterizations. Growth of a mutant E. coli strain deficient in the pentose phosphate pathway enzyme glucose-6-phosphate dehydrogenase (K10-1516) on 2-(13)C-glycerol and (15)N-ammonium sulfate in Studier minimal medium enables labeling at sites useful for NMR spectroscopy. However, (13)C-sodium formate combined with (13)C-2-glycerol in the growth media adds labels to new positions. In the absence of labeled formate, both C5 and C6 positions of the pyrimidine rings are labeled with minimal multiplet splitting due to (1)J(C5C6) scalar coupling. However, the C2/C8 sites within purine rings and the C1'/C3'/C5' positions within the ribose rings have reduced labeling. Addition of (13)C-labeled formate leads to increased labeling at the base C2/C8 and the ribose C1'/C3'/C5' positions; these new specific labels result in two- to three-fold increase in the number of resolved resonances. This use of formate and (15)N-ammonium sulfate promises to extend further the utility of these alternate site specific labels to make labeled RNA for downstream biophysical applications such as structural, dynamics and functional studies of interesting biologically relevant RNAs.

Isotope labeling strategies for NMR studies of RNA

The known biological functions of RNA have expanded in recent years and now include gene regulation, maintenance of sub-cellular structure, and catalysis, in addition to propagation of genetic information. As for proteins, RNA function is tightly correlated with structure. Unlike proteins, structural information for larger, biologically functional RNAs is relatively limited. NMR signal degeneracy, relaxation problems, and a paucity of long-range (1)H-(1)H dipolar contacts have limited the utility of traditional NMR approaches. Selective isotope labeling, including nucleotide-specific and segmental labeling strategies, may provide the best opportunities for obtaining structural information by NMR. Here we review methods that have been developed for preparing and purifying isotopically labeled RNAs, as well as NMR strategies that have been employed for signal assignment and structure determination.

Key labeling technologies to tackle sizeable problems in RNA structural biology

The ability to adopt complex three-dimensional (3D) structures that can rapidly interconvert between multiple functional states (folding and dynamics) is vital for the proper functioning of RNAs. Consequently, RNA structure and dynamics necessarily determine their biological function. In the post-genomic era, it is clear that RNAs comprise a larger proportion (>50%) of the transcribed genome compared to proteins (< or =2%). Yet the determination of the 3D structures of RNAs lags considerably behind those of proteins and to date there are even fewer investigations of dynamics in RNAs compared to proteins. Site specific incorporation of various structural and dynamic probes into nucleic acids would likely transform RNA structural biology. Therefore, various methods for introducing probes for structural, functional, and biotechnological applications are critically assessed here. These probes include stable isotopes such as (2)H, (13)C, (15)N, and (19)F. Incorporation of these probes using improved RNA ligation strategies promises to change the landscape of structural biology of supramacromolecules probed by biophysical tools such as nuclear magnetic resonance (NMR) spectroscopy, X-ray crystallography and Raman spectroscopy. Finally, some of the structural and dynamic problems that can be addressed using these technological advances are outlined.

General method of preparation of uniformly 13C, 15N-labeled DNA fragments for NMR analysis of DNA structures

(13)C, (15)N labeling of biomolecules allows easier assignments of NMR resonances and provides a larger number of NMR parameters, which greatly improves the quality of DNA structures. However, there is no general DNA-labeling procedure, like those employed for proteins and RNAs. Here, we describe a general and widely applicable approach designed for preparation of isotopically labeled DNA fragments that can be used for NMR studies. The procedure is based on the PCR amplification of oligonucleotides in the presence of labeled deoxynucleotides triphosphates. It allows great flexibility thanks to insertion of a short DNA sequence (linker) between two repeats of DNA sequence to study. Size and sequence of the linker are designed as to create restriction sites at the junctions with DNA of interest. DNA duplex with desired sequence and size is released upon enzymatic digestion of the PCR product. The suitability of the procedure is validated through the preparation of two biological relevant DNA fragments.

The structure of a mixed LNA/DNA:RNA duplex is driven by conformational coupling between LNA and deoxyribose residues as determined from 13C relaxation measurements

A study of the internal dynamics of an LNA/DNA:RNA duplex has been performed to further characterize the conformational changes associated with the incorporation of locked nucleic acid (LNA) nucleotides in a DNA:RNA duplex. In general, it was demonstrated that the LNA/DNA:RNA duplex has a very high degree of order compared to dsDNA and dsRNA duplexes. The order parameters of the aromatic carbon atoms in the LNA/DNA strand are uniformly high, whereas a sharp drop in the degree of order was seen in the RNA strand in the beginning of the AUAU stretch in the middle of the strand. This can be related to a return to normal dsRNA dynamics for the central A:U base pair. The high order of the heteroduplex is consistent with preorganization of the chimera strand for an A-form duplex conformation. These results partly explain the dramatic increase in T(m) of the chimeric heteroduplex over dsDNA and DNA:RNA hybrids of the same sequence.

The apical loop of the HIV-1 TAR RNA hairpin is stabilized by a cross-loop base pair

The TAR hairpin of the HIV-1 RNA genome is indispensable for trans-activation of the viral promoter and virus replication. The TAR structure has been studied extensively, but most attention has been directed at the three-nucleotide bulge that constitutes the binding site of the viral Tat protein. In contrast, the conformational properties of the apical loop have remained elusive. We performed biochemical studies and molecular dynamics simulations, which indicate that the TAR loop is structured and stabilized by a cross-loop base pair between residues C30 and G34. Mutational disruption of the cross-loop base pair results in reduced Tat response of the LTR promoter, which can be rescued by compensatory mutations that restore the base pair. Thus, Tat-mediated transcriptional activation depends on the structure of the TAR apical loop. The C30-G34 cross-loop base pair classes TAR in a growing family of hairpins with a structured loop that was recently identified in ribosomal RNA, tRNA, and several viral and cellular mRNAs.

NMR structure of a ribosomal RNA hairpin containing a conserved CUCAA pentaloop

The structure of a 23 nt RNA sequence, rGGACCCGGGCUCAACCUGGGUCC, was elucidated using homonuclear NMR, distance geometry and restrained molecular dynamics. This RNA is analogous to residues 612-628 of the Escherichia coli 16S rRNA. The structure of the RNA reveals the presence of a pentaloop closed by a duplex stem in typical A-form conformation. The loop does not form a U-turn motif, as previously predicted. A non-planar A.C.A triple base interaction (hydrogen bonds A13 NH6-C10 O2 and C10 N3-A14 NH6) stabilizing the loop structure is inferred from structure calculations. The CUCAA loop structure is asymmetrical, characterized by a reversal of the phosphodiester backbone at the UC step (hydrogen bond C12 NH4-C10 O2') and 3'-stacking within the CAA segment. Loop base U11 is oriented towards the major groove and the consecutive adenosines on the 3'-end of the loop are well stacked, exposing their reactive functional groups in the minor groove defined by the duplex stem. The solution structure of the loop resembles that seen in the 3.3 A X-ray structure of the entire 30S subunit, where the analogous loop interacts with a ribosomal protein and a receptor RNA helix.

An optimized PCR-based procedure for production of 13C/15N-labeled DNA

We have substantially improved a procedure that we previously described for producing 13C/15N-labeled DNA (Chen et al., FEBS Lett. 436, 372-376, 1998) to provide an economical and straightforward approach to the preparation of labeled DNA. The conditions for the PCR reactions have been optimized to permit the use of low concentrations of the costly labeled dNTPs (50 microM for each). In addition, a rapid and high-yield purification procedure has been developed that allows us to obtain a high yield of very pure labeled DNA. These modifications to our original procedure permit us to obtain 1.9 mg of an 18 bp DNA oligomer from 20 mg of dNTPs (ca. 10% yield from the starting dNTPs). This is sufficient material for the preparation of 0.4 mM sample in a volume of 400 microl. In summary, this procedure is a cost-effective, time-efficient procedure for the production of labeled DNA for NMR studies.

[(13)C,(13)C]- and [(13)C,(1)H]-TROSY in a triple resonance experiment for ribose-base and intrabase correlations in nucleic acids

A novel TROSY (transverse relaxation-optimized spectroscopy) element is introduced that exploits cross-correlation effects between (13)C-(13)C dipole-dipole (DD) coupling and (13)C chemical shift anisotropy (CSA) of aromatic ring carbons. Although these (13)C-(13)C effects are smaller than the previously described [(13)C,(1)H]-TROSY effects for aromatic (13)C-(1)H moieties, their constructive use resulted in further transverse relaxation-optimization by up to 15% for the resonances in a 17 kDa protein-DNA complex. As a practical application, two- and three-dimensional versions of the HCN triple resonance experiment for obtaining ribose-base and intrabase correlations in the nucleotides of DNA and RNA (Sklenar, V.; Peterson, R. D.; Rejante, M. R.; Feigon, J. J. Biomol. NMR 1993, 3, 721-727) have been implemented with [(13)C,(1)H]- and [(13)C,(13)C]-TROSY elements to reduce the rate of transverse relaxation during the polarization transfers between ribose (13)C1' and base (15)N1/9 spins, and between (13)C6/8 and N1/9 within the bases. The resulting TROSY-HCN experiment is user-friendly, with a straightforward, robust experimental setup. Compared to the best previous implementations of the HCN experiment, 2-fold and 5-fold sensitivity enhancements have been achieved for ribose-base and intrabase connectivities, respectively, for (13)C,(15)N-labeled nucleotides in structures with molecular weights of 10 and 17 kDa. TROSY-HCN experiments should be applicable also with significantly larger molecular weights. By using modified TROSY-HCN schemes, the origins of the sensitivity gains have been analyzed.

The synthesis of deuterionucleosides

The synthesis of deuterionucleosides for site-specific incorporation into oligo-DNA or -RAA is herein reviewed for NMR or biological studies. The review covers the following aspects: (i) deuteration of the aglycone; (ii) single-site chemical deuteration of the sugar residues; (iii) multiple-site chemical deuteration of the sugar residues; (iv) enzymatic synthesis of deuterated nucleosides or nucleotides; and (v) synthesis of labelled nucleosides with multiple isotopes

Detection of N-H...N hydrogen bonding in RNA via scalar couplings in the absence of observable imino proton resonances

Hydrogen bond networks stabilize RNA secondary and tertiary structure and are thus essentially important for protein recognition. During structure refinements using either NMR or X-ray techniques, hydrogen bonds were usually inferred indirectly from the proximity of donor and acceptor functional groups. Recently, quantitative heteronuclear J(N,N)-HNN COSY NMR experiments were introduced that allowed the direct identification of donor and acceptor nitrogen atoms involved in hydrogen bonds. However, protons involved in base pairing interactions in nucleic acids are often not observable due to exchange processes. The application of a modified quantitative J(N,N)-HNN COSY pulse scheme permits observation of(2h)J(N,N) couplings via non-exchangeable protons. This approach allowed the unambiguous identification of the A27.U23 reverse Hoogsteen base pair involved in a U-A.U base triple in the HIV-2 transactivation response element-argininamide complex. Despite a wealth of NOE information, direct evidence for this interaction was lacking due to the rapid exchange of the U23 imino proton. The ability to directly observe hydrogen bonds, even in D(2)O and in the presence of rapid exchange, should facilitate structural studies of RNA.

Direct identification of NH...N hydrogen bonds in non-canonical base pairs of RNA by NMR spectroscopy

It is shown that the recently developed quantitative J(NN)HNN-COSY experiment can be used for the direct identification of hydrogen bonds in non-canonical base pairs in RNA. Scalar(2h)J(NN)couplings across NH.N hydrogen bonds are observed in imino hydrogen bonded GA base pairs of the hpGA RNA molecule, which contains a tandem GA mismatch, and in the reverse Hoogsteen AU base pairs of the E-loop of Escherichia coli 5S rRNA. These scalar couplings correlate the imino donor(15)N nucleus of guanine or uridine with the acceptor N1 or N7 nucleus of adenine. The values of the corresponding(2h)J(NN)coupling constants are similar in size to those observed in Watson-Crick base pairs. The reverse Hoogsteen base pairs could be directly detected for the E-loop of E.coli 5S rRNA both in the free form and in a complex with the ribosomal protein L25. This supports the notion that the E-loop is a pre-folded RNA recognition site that is not subject to significant induced conformational changes. Since Watson-Crick GC and AU base pairs are also readily detected the HNN-COSY experiment provides a useful and sensitive tool for the rapid identification of RNA secondary structure elements.

DNA duplex dynamics: NMR relaxation studies of a decamer with uniformly 13C-labeled purine nucleotides

Dynamics in a DNA decamer duplex, d(CATTTGCATC). d(GATGCAAATG), were investigated via a detailed 13C NMR relaxation study. Every 2'-deoxyadenosine and 2'-deoxyguanidine was chemically enriched with 15% 13C and 98% 15N isotopes. Six nuclear relaxation parameters [R(13Cz), R(1Hz), R(2(1)Hz13Cz), R(13Cx), R(2(1)Hz13Cx) and steady-state 13C¿1H¿ NOE] were measured at 600 MHz and three were measured at 500 MHz (1H frequency) for the CH spin systems of sugar 1', 3', and 4' as well as base 8 and 2 positions. A dependence of relaxation parameter values on chemical position was clearly observed; however, no sequence-specific variation was readily evident within our experimental error of approximately 5-10%, except for 3' and 5' termini. It was demonstrated that the random 15% 13C enrichment effectively suppressed both scalar and dipolar contributions of the neighboring carbons and protons on the relaxation parameters. To analyze dynamics via all observed relaxation parameters, full spectral density mapping (1992, J. W. Peng and G. Wagner, J. Magn. Reson. 98, 308) and the "model-free" approach (1982, Lipari and Szabo, J. Am. Chem. Soc. 104, 4546) were applied complementarily. A linear correlation between three spectral density values, J(omegaC), J(omegaH - omegaC), and J(omegaH + omegaC) was observed in plots containing all measured values, but not for the other spectral density terms including J(0). These linear correlations reflect the effect of overall motion and similar internal motions for each CH vector in the decamer. The correlations yielded two correlation times, 3-4 ns and 10-200 ps. One value, 3-4 ns, corresponds to the value of 3.3 ns obtained for the overall isotropic tumbling correlation time determined from analysis of 13C T1/T2 ratios. The possibility of overall anisotropic tumbling was examined, but statistical analysis showed no advantage over the assumption of simple isotropic tumbling. Lack of correlations entailing J(0) implies that a relatively slow chemical exchange contributes to yielding of effective Jeff(0) values. Based on spectral density mapping and the T1/T2 ratio analysis, three basic assumptions were initially employed (and subsequently justified) for the model-free calculation: isotropic overall tumbling, one internal motion, and the presence of chemical exchange terms. Except for terminal residues, the order parameter S2 and the corresponding fast internal motion correlation time were determined to be about 0.8 +/- 0.1 and 20 +/- 20 ps, respectively, for the various CH vectors. Only a few differences were observed between or within sugars and bases. The internal motion is very fast (ps-ns time scale) and its amplitude restricted; e.g., assuming a simple wobble-in-a-cone model, the internal motion is restricted to an angular amplitude of +/-22. 5 degrees for each of the 1', 3', 4', 2, and 8 positions in the purine nucleotides in the entire duplex.

Simple, efficient protocol for enzymatic synthesis of uniformly 13C, 15N-labeled DNA for heteronuclear NMR studies

The use of uniformly 13C,15N-labeled RNA has greatly facilitated structural studies of RNA oligonucleotides by NMR. Application of similar methodologies for the study of DNA has been limited, primarily due to the lack of adequate methods for sample preparation. Methods for both chemical and enzymatic synthesis of DNA oligonucleotides uniformly labeled with 13C and/or 15N have been published, but have not yet been widely used. We have developed a modified procedure for preparing uniformly 13C,15N-labeled DNA based on enzymatic synthesis using Taq DNA polymerase. The highly efficient protocol results in quantitative polymerization of the template and approximately 80% incorporation of the labeled dNTPs. Procedures for avoiding non-templated addition of nucleotides or for their removal are given. The method has been used to synthesize several DNA oligonucleotides, including two complementary 15 base strands, a 32 base DNA oligonucleotide that folds to form an intramolecular triplex and a 12 base oligonucleotide that dimerizes and folds to form a quadruplex. Heteronuclear NMR spectra of the samples illustrate the quality of the labeled DNA obtained by these procedures.

Preparation of uniformly isotope-labeled DNA oligonucleotides for NMR spectroscopy

Two methods for the large scale preparation of uniformly isotope-labeled DNA for NMR studies have been developed. The first method comprises the growth of a suitable plasmid harboring multiple copies of the desired oligonucleotide in a medium based on 15N and 13C nutrients. The second method uses a polymerase chain reaction (PCR)-based approach with 15N- and/or 13C-labeled deoxynucleoside triphosphates. The novelty of our PCR strategy over existing ones is that the primer and template are the identical molecule, resulting in an exponential growth in the length of the double strand that contains tandem repeats of the target DNA sequence. This novel PCR approach, which we have termed ESRA for endonuclease-sensitive repeat amplification, is easy to use, results in high yields, and can be accomplished at low costs. The utility of both methods is demonstrated for the preparation of a double-stranded 21-mer uniformly labeled with 15N and a double-stranded 17-mer DNA uniformly labeled with 15N and 13C.

3D C(CC)H TOCSY experiment for assigning protons and carbons in uniformly 13C- and selectively 2H-labeled RNA

We have prepared RNAs uniformly 13C-labeled in the ribose ring and with the H3',H4',H5'/H5" protons specifically replaced with deuterons (3',4',5'/5"-2H-13C, termed d4-13C ribose), which offers the advantage of spectral simplification without sacrifice of sensitivity for the remaining protons. A 3D C(CC)H TOCSY experiment that uses a combination of cross-polarization transfer and deuterium decoupling improves the transfer of magnetization around the ribose ring and facilitates assignment of all ribose carbons and H1' and H2' protons in a 30-nucleotide RNA from HIV-2. These and other combinations of labeling and pulse sequence methodology should prove invaluable for the study of large RNAs, RNA-ligand, and RNA-protein complexes.

Comparison of H5 and H8 relaxation rates of a 2H/13C/15N labeled RNA oligonucleotide with selective protonation at C5 and C8

Uniformly 13C/15N enriched ribonucleotide monophosphates have been prepared with extensive deuterium enrichment of the non-exchangeable positions. The purine C8 and pyrimidine C5 base positions were selectively protonated prior to incorporation of the individual nucleotide triphosphates into an RNA oligonucleotide. The longitudinal and transverse relaxation rates of the H8 and H5 resonances of this deuterated molecule were compared with the relaxation rates of the corresponding protonated, 13C/15N enriched RNA molecule. Deuteration disrupts the efficiency of 1H-1H dipolar relaxation and reduces the longitudinal and transverse magnetization relaxation rates on average to 25% and 68%, respectively, of the values measured for the non-deuterated RNA molecule. Importantly, the longitudinal relaxation rates remain sufficiently rapid (> 1s[-1]) to permit the use of short recovery delays in multidimensional NMR experiments without significant loss of sensitivity.

A model of the iron responsive element RNA hairpin loop structure determined from NMR and thermodynamic data

The iron responsive element (IRE) is a conserved RNA structure that is found in the 5' UTR of ferritin mRNA and in the 3' UTR of transferrin receptor mRNA. It is the binding site of the iron responsive protein (IRP), and the interaction is part of the regulation of cellular iron metabolism. The IRE six-nucleotide hairpin loop, 5'C1A2G3U4G5N6, is conserved in sequence, and mutations have shown that it is required for IRP binding. On the basis of the thermodynamic and NMR experiments utilized here, the IRE loop structure 5'C1A2G3U4G5C6, is described in detail. Measurements of loop stability show that it has 2.9 kcal/mol more free energy than predicted. NMR data suggest that there is hydrogen bonding between C1 and G5 in a tertiary interaction across the loop. A model structure, produced by MC-SYM/energy minimization, illustrates the conformational flexibility of U4 and C6, which appear to exhibit considerable local motion in solution. NMR data indicate that the position of G3 is not well defined, leading to two families of loop structures.

Structural features of a six-nucleotide RNA hairpin loop found in ribosomal RNA

The hairpin loop GUAAUA occurs frequently in ribosomal RNA. Optical melting studies show that r(GGCGUAAUAGCC) folds into a hairpin containing this loop. The structural features of the r(GGCGUAAUAGCC) hairpin have been determined by NMR and molecular modeling. NOEs from G4-H1' to A9-H2 and from A9-H2 to G10-H1' show that G4 and A9 form a sheared base pair with two hydrogen bonds: A-N7 to G-NH2 and A-NH6 to G-N3. One-dimensional NOE data show no NOEs between the imino protons of U5 and U8, but NOEs are observed between the U5-H1' and the U8-H6 and U8-H5, thus orienting the U8 imino proton away from U5. Thus U5 and U8 do not form an imino hydrogen-bonded U.U pair. The U5-H2' exhibits NOEs to both the A6-H8 and A7-H8, and the 3' phosphorus resonances of U5 and A6 are shifted downfield. This suggests that the helix turn is between the U5 and A6 nucleotides. The JH1'-H2 and JH3'-H4' coupling constants indicate that the loop is dynamic, particularly at 35 degrees C, well below the melting temperature of 63 degrees C. Structures were generated using 75 distance and 46 dihedral angle restraints. In these structures, the U5 base is stacked on the sheared base pair formed by G4 and A9 and can initiate a uridine turn similar to that observed in the anticodon loop of tRNA. The A6, A7, and U8 bases can stack on one another with their hydrogen-bonding surfaces exposed to the solvent, suggesting that they are available for tertiary interactions or protein recognition in rRNA. A range of loop structures are consistent with the data, however. The lack of formation of a U.U mismatch is consistent with a recent model that predicts the stability of hairpin loops of six nucleotides on the basis of the closing base pair and first mismatch in the loop [Serra, M. J., Axenson, T. J., & Turner, D. H. (1994) Biochemistry 33, 14289-14296].

Initial analysis of 750 MHz NMR spectra of selective 15N-G,U labelled E. coli 5S rRNA

The overall folding of an RNA molecule is reflected in its base pairing pattern. The identification of that pattern provides a first step towards the determination of the structure of an RNA molecule. We show that the application of heteronuclear NMR methods at 750 MHz to E. coli 5S rRNA (120 nucleotides) selectively labelled with 15N in guanine and uridine allows observation of base pairing patterns for a larger RNA molecule. We also present evidence that the fold of the E-domain of the 5S rRNA (nt 79-97) as a contiguous part of the 5S rRNA and as an isolated molecule is virtually the same.

NMR of enzymatically synthesized uniformly 13C15N-labeled DNA oligonucleotides

A procedure for the enzymatic synthesis of uniformly 13C15N-labeled DNA oligonucleotides in milligram quantities for NMR studies is described. Deoxynucleotides obtained from microorganisms grown on 13C and 15N nutrient sources are enzymatically phosphorylated to dNTPs, and the dNTPs are incorporated into oligonucleotides using a 3'-5' exonuclease-deficient mutant of Klenow fragment of DNA polymerase I and an oligonucleotide template primer designed for efficient separation of labeled product DNA from unlabeled template. The labeling strategy has been used to uniformly label one or the other oligonucleotide strand in the DNA duplex dGGCAAAACGG.dCCGTTTTGCC in order to facilitate assignment and structure determination by NMR. Application of 15N and 13C heteronuclear NMR experiments to isotopically labeled DNA is presented.

A method for production of 13C/15N double labelled RNA in E. coli, and subsequent in vitro synthesis of ribonucleotide 5' triphosphates

In this paper we describe an enhanced method for the large scale production of high quality 13C/15N labelled NTPs. High amounts of labelled RNA was obtained from E. coli cells grown in 13C/15N enriched medium and treated with chloramphenicol. Total RNA was extracted from spheroplasted cells in the presence of SDS and proteinase K and subsequently degraded to NMPs by nuclease P1 and high concentrations of nuclease S1 in a low salt buffer. To avoid non-specific degradation of the RNA, nuclease digestion was performed in a short term reaction on native, not heat-denatured RNA. CMP, AMP, GMP and UMP were chromatographically separated and converted to the corresponding NTPs by a mixture of kinases in the presence of a coupled redox system based on thioredoxin and dithiothreitol. The quality of the 13C/15N labelled NTPs was tested by in vitro transcription.

Solution structure of a selectively 13C-labeled intramolecular DNA triplex

The three-dimensional structure of an intramolecular triple helix whose three strands have been linked by a hexaethylene glycol chain, and selectively 13C-enriched in position C1' on the third strand was investigated by NMR spectroscopy and constrained molecular mechanics calculations. Starting from different initial conformations, we show that the NOE constraints determined by the complete relaxation matrix calculation and iterative back-calculations allowed us to reach the same final restrained triple helix, taking into account implicitly the solvent effect. We conclude that this triplex adopted a B-type conformation rather than a A-type. The sugar pucker was found predominantly in the S-type conformation, in the range of C2'-endo geometry.

Novel techniques in nuclear magnetic resonance for nucleic acids

Recent techniques for the efficient preparation of isotopically labelled RNA of desired sequence represent a dramatic step forward for NMR of nucleic acids. Three- and four-dimensional NMR experiments greatly facilitate spectral analysis and quantification of structural constraints. Backbone-driven assignment procedures have been introduced to parallel the powerful assignment methods introduced for work with proteins. Additional structural information to complement interproton distances, namely scalar coupling constants defining the backbone conformation, can be obtained using isotopically labelled oligonucleotides. The additional interproton distance and dihedral angle constraints resolved in higher-dimensional spectra will enable the determination of larger DNA and RNA structures and also increase accuracy and precision.

The importance of a single G in the hairpin loop of the iron responsive element (IRE) in ferritin mRNA for structure: an NMR spectroscopy study

Noncoding sequences regulate the function of mRNA and DNA. In animal mRNAs, iron responsive elements (IREs) regulate the synthesis of proteins for iron storage, uptake and red cell heme formation. Folding of the IRE was indicated previously by reactivity with chemical and enzymatic probes. 1H- and 31P-NMR spectra now confirm the IRE folding; an atypical 31P-spectrum, differential accessibility of imino protons to solvents, multiple long-range NOEs and heat stable subdomains were observed. Biphasic hyperchromic transitions occurred (52 and 73 degrees C). A G-C base pair occurs in the hairpin loop (HL) (based on dimethylsulfate, RNAse T1 previously used, and changes in NMR imino proton resonances typical of G-C base pairs after G/A substitution). Mutation of the hairpin loop also decreased temperature stability and changed the 31P-NMR spectrum; regulation and protein (IRP) binding were previously shown to change. Alteration of IRE structure shown by NMR spectroscopy, occurred at temperatures used in studies of IRE function, explaining loss of IRP binding. The effect of the HL mutation on the IRE emphasizes the importance of HL structure in other mRNAs, viral RNAs (e.g. HIV-TAR), and ribozymes.

Sequential backbone assignment of uniformly 13C-labeled RNAs by a two-dimensional P(CC)H-TOCSY triple resonance NMR experiment

A new 1H-13C-31P triple resonance experiment is described which allows unambiguous sequential backbone assignment in 13C-labeled oligonucleotides via through-bond coherence transfer from 31P via 13C to 1H. The approach employs INEPT to transfer coherence from 31P to 13C and homonuclear TOCSY to transfer the 13C coherence through the ribose ring, followed by 13C to 1H J-cross-polarisation. The efficiencies of the various possible transfer pathways are discussed. The most efficient route involves transfer of 31Pi coherence via C4'i and C4'i-1, because of the relatively large JPC4' couplings involved. Via the homonuclear and heteronuclear mixing periods, the C4'i and C4'i-1 coherences are subsequently transferred to, amongst others, H1'i and H1'i-1, respectively, leading to a 2D 1H-31P spectrum which allows a sequential assignment in the 31P-1H1' region of the spectrum, i.e. in the region where the proton resonances overlap least. The experiment is demonstrated on a 13C-labeled RNA hairpin with the sequence 5'(GGGC-CAAA-GCCU)3'.

Uses of 13C- and 15N-labeled RNA in NMR of RNA-protein complexes

The interactions between RNA and protein will not be simple ones in the sense that they cannot be predicted by the structure of the free RNA. The assumption in describing these interactions must be that the RNA nucleotide is free to use any or all of its chemical moieties to anchor it to the protein, and the spectroscopist must be ready for these possibilities. The incorporation of both 15N and 13C into the RNA is absolutely necessary to obtain a picture of how the RNA is associated to the protein, and the implementation of pulsed field gradients allows observation of the critical hydrogen bonding sites. We must note here that since some of the hydrogen bonds between RNA and protein are certain to be mediated by water molecules, gradients should also provide a means to look for these specific associations.