A novel family of RNA tetraloop structure forms the recognition site for Saccharomyces cerevisiae RNase III.

RNases III are a family of double-stranded RNA (dsRNA) endoribonucleases involved in the processing and decay of a large number of cellular RNAs as well as in RNA interference. The dsRNA substrates of Saccharomyces cerevisiae RNase III (Rnt1p) are capped by tetraloops with the consensus sequence AGNN, which act as the primary docking site for the RNase. We have solved the solution structures of two RNA hairpins capped by AGNN tetraloops, AGAA and AGUU, using NMR spectroscopy. Both tetraloops have the same overall structure, in which the backbone turn occurs on the 3' side of the syn G residue in the loop, with the first A and G in a 5' stack and the last two residues in a 3' stack. A non-bridging phosphate oxygen and the universal G which are essential for Rnt1p binding are strongly exposed. The compared biochemical and structural analysis of various tetraloop sequences defines a novel family of RNA tetraloop fold with the consensus (U/A)GNN and implicates this conserved structure as the primary determinant for specific recognition of Rnt1p substrates.

Measurement of small scalar and dipolar couplings in purine and pyrimidine bases.

A suite of spin-state-selective excitation (S3E) NMR experiments for the measurements of small one-bond (13C-13C, 15N-13C) and two-bond (1H-13C, 1H-15N) coupling constants in 13C,15N labeled purine and pyrimidine bases is presented. The incorporation of band-selective shaped pulses, elimination of the cross talk between alpha and beta sub-spectra, and accuracy and precision of the proposed approach are discussed. Merits of using S3E rather than alpha/beta-half-filter are demonstrated using results obtained on isotopically labeled DNA oligonucleotides.

A DFT study of the interresidue dependencies of scalar J-coupling and magnetic shielding in the hydrogen-bonding regions of a DNA triplex.

Scalar coupling constants and magnetic shieldings in the imino hydrogen-bonding region of Hoogsteen-Watson-Crick T.A-T and C(+).G-C triplets have been calculated as a function of the distance between proton donor and acceptor nitrogen atoms. The Fermi contact contributions to (h2)J((15)N-H...(15)N), (1)J((15)N-(1)H), and (h1)J((1)H...(15)N) were computed using density functional theory/finite perturbation theory (DFT/FPT) methods for the full base triplets at the unrestricted B3PW91/6-311G level. Chemical shifts delta((1)H) and delta((15)N) were obtained at the same level using the gauge including atomic orbital (GIAO) method for magnetic shielding. All three scalar couplings and all three chemical shifts are strongly interrelated and exhibit monotonic changes with base pair separation. These correlations are in conformity with experimental data for a 32-nucleotide DNA triplex. The results suggest that both chemical shifts and coupling constants can be used to gain information on H-bond donor-acceptor distances in nucleic acids. In addition to the DFT/FPT calculations, a simple three-orbital model of the N-H...H bond and a sum-over-states analysis is presented. This model reproduces the basic features of the H-bond coupling effect. In accordance with this model and the DFT calculations, a positive sign for the (h2)J(NN) coupling is determined from an E.COSY experiment.

Quantitative analysis of the isolated GAAA tetraloop/receptor interaction in solution: a site-directed spin labeling study.

The GNRA (N: any nucleotide; R: purine) tetraloop/receptor interaction is believed to be one of the most frequently occurring tertiary interaction motifs in RNAs, but an isolated tetraloop/receptor complex has not been identified in solution. In the present work, site-directed spin labeling is applied to detect tetraloop/receptor complex formation and estimate the free energy of interaction. For this purpose, the GAAA tetraloop/receptor interaction was chosen as a model system. A method was developed to place nitroxide labels at specific backbone locations in an RNA hairpin containing the GAAA tetraloop. Formation of the tetraloop/receptor complex was monitored through changes in the rotational correlation time of the tetraloop and the attached nitroxide. Results show that a hairpin containing the GAAA tetraloop forms a complex with an RNA containing the 11-nucleotide GAAA tetraloop receptor motif with an apparent Kd that is strongly dependent on Mg2+. At 125 mM MgCl2, Kd = 0.40 +/- 0.05 mM. The corresponding standard free energy of complex formation is -4.6 kcal/mol, representing the energetics of the tetraloop/receptor interaction in the absence of other tertiary constraints. The experimental strategy presented here should have broad utility in quantifying weak interactions that would otherwise be undetectable, for both nucleic acids and nucleic acid-protein complexes.

Recognition of pre-formed and flexible elements of an RNA stem-loop by nucleolin.

Nucleolin is an abundant nucleolar protein which is essential for ribosome biogenesis. The first two of its four tandem RNA-binding domains (RBD12) specifically recognize a stem-loop structure containing a conserved UCCCGA sequence in the loop called the nucleolin-recognition element (NRE). We have determined the structure of the consensus SELEX NRE (sNRE) by NMR spectroscopy. In both the free and bound RNA the top part of the stem forms a loop E (or S-turn) motif. In the absence of protein, the structure of the hairpin loop is not well defined due to conformational heterogeneity, and appears to be in equilibrium between two families of conformations. Titrations of RBD1, RBD2, and RBD12 with the sNRE show that specific binding requires RBD12. In complex with RBD12, the hairpin loop interacts specifically with the protein and adopts a well-defined structure which shares some of the features of the free form. The loop E motif also has specific interactions with the protein. Implications of these findings for the mechanism of recognition of RNA structures by modular proteins are discussed.

Molecular basis of sequence-specific recognition of pre-ribosomal RNA by nucleolin.

The structure of the 28 kDa complex of the first two RNA binding domains (RBDs) of nucleolin (RBD12) with an RNA stem-loop that includes the nucleolin recognition element UCCCGA in the loop was determined by NMR spectroscopy. The structure of nucleolin RBD12 with the nucleolin recognition element (NRE) reveals that the two RBDs bind on opposite sides of the RNA loop, forming a molecular clamp that brings the 5' and 3' ends of the recognition sequence close together and stabilizing the stem-loop. The specific interactions observed in the structure explain the sequence specificity for the NRE sequence. Binding studies of mutant proteins and analysis of conserved residues support the proposed interactions. The mode of interaction of the protein with the RNA and the location of the putative NRE sites suggest that nucleolin may function as an RNA chaperone to prevent improper folding of the nascent pre-rRNA.

Adenine protonation in domain B of the hairpin ribozyme.

Protein enzymes often use ionizable side chains, such as histidine, for general acid-base catalysis because the imidazole pK(a) is near neutral pH. RNA enzymes, on the other hand, are comprised of nucleotides which do not have apparent pK(a) values near neutral pH. Nevertheless, it has been recently shown that cytidine and adenine protonation can play an important role in both nucleic acid structure and catalysis. We have employed heteronuclear NMR methods to determine the pK(a) values and time scales of chemical exchanges associated with adenine protonation within the catalytically essential B domain of the hairpin ribozyme. The large, adenine-rich internal loop of the B domain allows us to determine adenine pK(a) values for a variety of non-Watson-Crick base pairs. We find that adenines within the internal loop have pK(a) values ranging from 4.8 to 5.8, significantly higher than the free mononucleotide pK(a) of 3. 5. Adenine protonation results in potential charge stabilization, hydrogen bond formation, and stacking interactions that are expected to stabilize the internal loop structure at low pH. Fast proton exchange times of 10-50 micros were determined for the well-resolved adenines. These results suggest that shifted pK(a) values may be a common feature of adenines in non-Watson-Crick base pairs, and identify two adenines which may participate in hairpin ribozyme active site chemistry.

Biochemical and structural analysis of the interaction between the UBA(2) domain of the DNA repair protein HHR23A and HIV-1 Vpr.

The DNA repair protein HHR23A is a highly conserved protein that functions in nucleotide excision repair. HHR23A contains two ubiquitin associated domains (UBA) that are conserved in a number of proteins with diverse functions involved in ubiquitination, UV excision repair, and signaling pathways via protein kinases. The cellular binding partners of UBA domains remain unclear; however, we previously found that the HHR23A UBA(2) domain interacts specifically with the HIV-1 Vpr protein. Analysis of the low resolution solution structure of HHR23A UBA(2) revealed a hydrophobic loop region of the UBA(2) domain that we predicted was the interface for protein/protein interactions. Here we present results of in vitro binding studies that demonstrate the requirement of this hydrophobic loop region for interaction with human immunodeficiency virus (HIV-1) Vpr. A single point mutation of the Pro at residue 333 to a Glu totally abolishes the binding of HIV-1 Vpr to UBA(2). High resolution NMR structures of the binding deficient UBA(2) mutant P333E as well as of the wild-type UBA(2) domain were determined to compare the effect of this mutation on the structure. Small but significant differences are observed only locally at the site of the mutation. The biochemical and structural analysis confirms the function of the HHR23A UBA(2) GFP-loop as the protein/protein interacting domain.

Solution structure of the two N-terminal RNA-binding domains of nucleolin and NMR study of the interaction with its RNA target.

Nucleolin is an abundant 70 kDa nucleolar protein involved in many aspects of ribosomal RNA biogenesis. The central region of nucleolin contains four tandem consensus RNA-binding domains (RBD). The two most N-terminal domains (RBD12) bind with nanomolar affinity to an RNA stem-loop containing the consensus sequence UCCCGA in the loop. We have determined the solution structure of nucleolin RBD12 in its free form and have studied its interaction with a 22 nt RNA stem-loop using multidimensional NMR spectroscopy. The two RBDs adopt the expected beta alpha beta beta alpha beta fold, but the position of the beta 2 strand in both domains differs from what was predicted from sequence alignments. RBD1 and RBD2 are significantly different from each others and this is likely important in their sequence specific recognition of the RNA. RBD1 has a longer alpha-helix 1 and a shorter beta 2-beta 3 loop than RBD2, and differs from most other RBDs in these respects. The two RBDs are separated by a 12 amino acid flexible linker and do not interact with one another in the free protein. This linker becomes ordered when RBD12 binds to the RNA. Analysis of the observed NOEs between the protein and the RNA indicates that both RBDs interact with the RNA loop via their beta-sheet. Each domain binds residues on one side of the loop; specifically, RBD2 contacts the 5' side and RBD1 contacts the 3'.

Characterization of the hydrogen bond network in guanosine quartets by internucleotide 3hJ(NC)' and 2hJ(NN) scalar couplings.

Scalar coupling correlations across hydrogen bonds with carbonyl groups as acceptors have been observed in a variety of proteins, but not in nucleic acids. Here we present a pulse scheme that allows such an observation and quantification of trans-hydrogen bond 3hJ(NC)' correlations in nucleic acid base pairs, between the imino nitrogen 15N1 and the carbonyl 13C6 nuclei within the guanine quartets of the Oxy-1.5 DNA-quadruplex. Intra- and internucleotide N-H...O=C connectivities can be traced around each guanine quartet, allowing the hydrogen bonding partners to be unambiguously assigned. Absolute values of the 3hJ(NC)' couplings are approximately 0.2 Hz as quantified by a selective long-range H(N)CO experiment and are thus on average smaller than the analogous 3hJ(NC)' couplings observed in proteins. In addition, an improved version of the pseudo-heteronuclear H(N)N-COSY [Majumdar et al. (1999) J. Biomol. NMR, 14, 67-70] is presented which allows simultaneous detection of the 15N-donor and 15N-acceptor resonances connected by 2hJ(NN) couplings in hydrogen bonds involving amino groups. Using this experiment, values ranging between 6 and 8 Hz are determined for the 2hJNN couplings between 15N2 and 15N7 nuclei in the guanine quartet. These values are not strongly influenced by the presence of a significant amount of chemical exchange broadening due to amino group rotations.

Determination of metal ion binding sites within the hairpin ribozyme domains by NMR.

Cations play an important role in RNA folding and stabilization. The hairpin ribozyme is a small catalytic RNA consisting of two domains, A and B, which interact in the transition state in an ion-dependent fashion. Here we describe the interaction of mono-, di-, and trivalent cations with the domains of the ribozyme, as studied by homo- and heteronuclear NMR spectroscopy. Paramagnetic line broadening, chemical shift mapping, and intermolecular NOEs indicate that the B domain contains four to five metal binding sites, which bind Mn(2+), Mg(2+), and Co(NH(3))(6)(3+). There is no significant structural change in the B domain upon the addition of Co(NH(3))(6)(3+) or Mg(2+). No specific monovalent ion binding sites exist on the B domain, as determined by (15)NH(4)(+) binding studies. In contrast to the B domain, there are no observable metal ion interactions within the internal loop of the A domain. Model structure calculations of Mn(2+) interactions at two sites within the B domain indicate that the binding sites comprise major groove pockets lined with functional groups oriented so that multiple hydrogen bonds can be formed between the RNA and Mn(H(2)O)(6)(2+) or Co(NH(3))(6)(3+). Site 1 is very similar in geometry to a site within the P4-P6 domain of the Tetrahymena group I intron, while site 2 is unique among known ion binding sites. The site 2 ion interacts with a catalytically essential nucleotide and bridges two phosphates. Due to its location and geometry, this ion may play an important role in the docking of the A and B domains.

The effect of sodium, potassium and ammonium ions on the conformation of the dimeric quadruplex formed by the Oxytricha nova telomere repeat oligonucleotide d(G(4)T(4)G(4)).

The DNA sequence d(G(4)T(4)G(4)) [Oxy-1.5] consists of 1.5 units of the repeat in telomeres of Oxytricha nova and has been shown by NMR and X-ray crystallographic analysis to form a dimeric quadruplex structure with four guanine-quartets. However, the structure reported in the X-ray study has a fundamentally different conformation and folding topology compared to the solution structure. In order to elucidate the possible role of different counterions in this discrepancy and to investigate the conformational effects and dynamics of ion binding to G-quadruplex DNA, we compare results from further experiments using a variety of counterions, namely K(+), Na(+)and NH(4)(+). A detailed structure determination of Oxy-1.5 in solution in the presence of K(+)shows the same folding topology as previously reported with the same molecule in the presence of Na(+). Both conformations are symmetric dimeric quadruplexes with T(4)loops which span the diagonal of the end quartets. The stack of quartets shows only small differences in the presence of K(+)versus Na(+)counterions, but the T(4)loops adopt notably distinguishable conformations. Dynamic NMR analysis of the spectra of Oxy-1.5 in mixed Na(+)/K(+)solution reveals that there are at least three K(+)binding sites. Additional experiments in the presence of NH(4)(+)reveal the same topology and loop conformation as in the K(+)form and allow the direct localization of three central ions in the stack of quartets and further show that there are no specific NH(4)(+)binding sites in the T(4)loop. The location of bound NH(4)(+)with respect to the expected coordination sites for Na(+)binding provides a rationale for the difference observed for the structure of the T(4)loop in the Na(+)form, with respect to that observed for the K(+)and NH(4)(+)forms.

Multistranded DNA structures.

DNA oligonucleotides can form multistranded helices through either the folding of a single strand or the association of two, three or four strands of DNA. Structures of several new DNA triplexes, G-quartet DNA quadruplexes and I-motif DNA quadruplexes have been reported recently. These structures provide new insights into helix stability and folding, loop conformations and cation interactions.

Solution structure of the HMG protein NHP6A and its interaction with DNA reveals the structural determinants for non-sequence-specific binding.

NHP6A is a chromatin-associated protein from Saccharomyces cerevisiae belonging to the HMG1/2 family of non-specific DNA binding proteins. NHP6A has only one HMG DNA binding domain and forms relatively stable complexes with DNA. We have determined the solution structure of NHP6A and constructed an NMR-based model structure of the DNA complex. The free NHP6A folds into an L-shaped three alpha-helix structure, and contains an unstructured 17 amino acid basic tail N-terminal to the HMG box. Intermolecular NOEs assigned between NHP6A and a 15 bp 13C,15N-labeled DNA duplex containing the SRY recognition sequence have positioned the NHP6A HMG domain onto the minor groove of the DNA at a site that is shifted by 1 bp and in reverse orientation from that found in the SRY-DNA complex. In the model structure of the NHP6A-DNA complex, the N-terminal basic tail is wrapped around the major groove in a manner mimicking the C-terminal tail of LEF1. The DNA in the complex is severely distorted and contains two adjacent kinks where side chains of methionine and phenylalanine that are important for bending are inserted. The NHP6A-DNA model structure provides insight into how this class of architectural DNA binding proteins may select preferential binding sites.

Solution structure of the loop B domain from the hairpin ribozyme.

The hairpin ribozyme is a small catalytic RNA with a unique two-domain structure. Here we present the solution structure of the loop B domain of the hairpin ribozyme, which contains most of the catalytically essential nucleotides. The 38-nucleotide domain contains a 16-nucleotide internal loop that forms one of the largest non-Watson-Crick segments of base pairing thus far determined by either NMR or crystallography. Since the solution structure of the smaller loop A domain has been previously solved, an NMR structure-based model of the 22,000 Mr hairpin ribozyme-substrate open complex emerges by joining the two domain structures. Strikingly, catalytically essential functional groups for the loop B domain are concentrated within an expanded minor groove, presenting a clear docking surface for the loop A domain.

HCCCH experiment for through-bond correlation of thymine resonances in 13C-labeled DNA oligonucleotides.

Application of heteronuclear magnetic resonance pulse methods to 13C, 15N-labeled nucleic acids is important for the accurate structure determination of larger RNA and DNA oligonucleotides and protein-nucleic acid complexes. These methods have been applied primarily to RNA, due to the availability of labeled samples. The two major differences between DNA and RNA are at the C2' of the ribose and deoxyribose and the additional methyl group on thymine versus uracil. We have enzymatically synthesized a 13C,15N-labeled 32 base DNA oligonucleotide that folds to form an intramolecular triplex. We present two- and three-dimensional versions of a new HCCCH-TOCSY experiment that provides intraresidue correlation between the thymine H6 and methyl resonances via the intervening carbons (H6-C6-C5-Cme-Hme).

Localization of ammonium ions in the minor groove of DNA duplexes in solution and the origin of DNA A-tract bending.

Monovalent cation binding sites on nucleic acids in solution can be localized using the isotopically labeled ammonium ion (15NH4+) as a probe in high resolution NMR spectroscopy experiments. The application of this technique to a series of DNA duplexes reveals a preference for the binding of ammonium cations in the minor groove of A-tract sequences. These results are consistent with a recent report which indicates that some solvent electron densities previously identified as water molecules in DNA X-ray crystal structures are partially occupied by sodium ions. The sequence-specific nature of monovalent cation binding sites demonstrated here for A-tract DNA provides an explanation for the origin of sequence-directed bending.

Binding sites and dynamics of ammonium ions in a telomere repeat DNA quadruplex.

Guanine quartets are readily formed by guanine nucleotides and guanine-rich oligonucleotides in the presence of certain monovalent and divalent cations. The quadruplexes composed of these quartets are of interest for their potential roles in vivo, their relatively frequent appearance in oligonucleotides derived from in vitro selection, and their inhibition of template directed RNA polymerization under proposed prebiotic conditions. The requirement of cation coordination for the stabilization of G quartets makes understanding cation-quadruplex interactions an essential step towards a complete understanding of G quadruplex formation. We have used 15NH4+ as a probe of cation coordination by the four G quartets of the DNA bimolecular quadruplex [d(G4T4G4)]2, formed from oligonucleotides with the repeat sequence found in Oxytricha nova telomeres. 1H and 15N heteronuclear NMR spectroscopy has allowed the direct localization of monovalent cation binding sites in the solution state and the analysis of cation movement between the binding sites. These experiments show that [d(G4T4G4)]2 coordinates three ammonium ions, one in each of two symmetry related sites and one on the axis of symmetry of the dimeric molecule. The NH4+ move along the central axis of the quadruplex between these sites and the solution, reminiscent of an ion channel. The residence time of the central ion is determined to be 250 ms. The 15NH4+ is shown to be a valuable probe of monovalent cation binding sites and dynamics.

Structure of a human DNA repair protein UBA domain that interacts with HIV-1 Vpr.

The HIV-1 protein Vpr is critical for a number of viral functions including a unique ability to arrest T-cells at a G2/M checkpoint and induce subsequent apoptosis. It has been shown to interact specifically with the second UBA (ubiquitin associated) domain found in the DNA repair protein HHR23A, a highly evolutionarily conserved protein. This domain is a commonly occurring sequence motif in some members of the ubiquitination pathway, UV excision repair proteins, and certain protein kinases. The three dimensional structure of the UBA domain, determined by NMR spectroscopy, is presented. The protein domain forms a compact three-helix bundle. One side of the protein has a hydrophobic surface that is the most likely Vpr target site.