Structure and stability of X.G.C mismatches in the third strand of intramolecular triplexes.

Intramolecular DNA triplexes that contain eight base triplets formed from the folding of a single DNA strand tolerate a single X.G.C mismatch in the third strand at acidic pH. The structure and relative stability of all four triplets that are possible involving a G.C Watson-Crick base pair were determined with one- and two-dimensional proton nuclear magnetic resonance techniques. Triplexes containing A.G.C, G.G.C, or T.G.C triplets were less stable than the corresponding parent molecule containing a C.G.C triplet. However, all mismatched bases formed specific hydrogen bonds in the major groove of the double helix. The relative effect of these mismatches on the stability of the triplex differs from the effect assayed (under different conditions) by two-dimensional gel electrophoresis and DNA cleavage with oligonucleotide EDTA.Fe(II).

Z-DNA forms without an alternating purine-pyrimidine sequence in solution.

Nuclear magnetic resonance spectra (proton and phosphorus-31) and ultraviolet absorption spectra of the DNA decamer d(br5CGbr5CGATbr5CGbr5CG), in which the central two adenine-thymine base pairs are out of order with the rest of the purine-pyrimidine alternation sequence, indicate that under appropriate solvent conditions (high salt and methanol) the molecule undergoes a structural transition from a right-handed B-DNA conformation to a left-handed Z-DNA conformation. Measurements of the two-dimensional nuclear Overhauser effect on the decamer indicate that all of the guanines as well as the two equivalent thymines adopt the syn conformation.

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.

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.

Refined solution structure of the dimeric quadruplex formed from the Oxytricha telomeric oligonucleotide d(GGGGTTTTGGGG).

BACKGROUND: Telomeres, the structures at the ends of linear eukaryotic chromosomes, are essential for chromosome replication and stability. The telomeres of the unicellular ciliate Oxytricha contain a 3' single strand overhang composed of two repeats of the telomere repeat sequence d(TTTTGGGG). It has been proposed that oligonucleotides containing this repeat can form DNA quadruplexes via hydrogen bonding of the guanines into quartets. Such structures may be relevant to the biological function of the telomere, and in G-rich sequences elsewhere in the genome. RESULTS: We have previously determined from solution NMR data that the Oxy-1.5 Oxytricha repeat oligonucleotide d(GGGGTTTTGGGG) dimerizes to form an intermolecular quadruplex composed of four guanine quartets and with the thymines in loops across the diagonal at opposite ends of the quadruplex. We report here the refined solution structure of Oxy-1.5. This structure is compared with the previously published crystal structure of the same oligonucleotide. CONCLUSIONS: Oxy-1.5 forms a well-defined, symmetrical structure with ordered thymine loops. Both the solution and crystal structures of Oxy-1.5 are quadruplexes with alternating syn and anti glycosyl conformation of guanines along each strand of the helix and have thymine loops at opposite ends. However, the topology of the two structures is fundamentally different, leading to significant structural differences. A topological pathway for the formation and interconversion of the two structures is proposed.

Solution structures of unimolecular quadruplexes formed by oligonucleotides containing Oxytricha telomere repeats.

BACKGROUND: Oligonucleotides containing the guanine-rich telomeric sequence of Oxytricha chromosomes (dT4G4) have previously been shown to form DNA quadruplexes comprising guanine quartets stabilized by cations. Two different structures have been reported for both d(G4T4G4) (Oxy1.5) and d(G4T4G4T4G4T4G4) (Oxy3.5). RESULTS: Here we present the solution structure of a uracil- and inosine-containing derivative of Oxy3.5, d(G4TUTUG4T4G4UUTTG3I) (Oxy3.5-U4128), determined using two-dimensional 1H and 31P NMR techniques. This oligonucleotide forms a unimolecular quadruplex that is very similar to the dimeric Oxy1.5 solution structure, in that it contains a loop spanning the diagonal of an end quartet. The groove widths, strand polarities, and positions of the syn bases along the G4 tracts and within the quartets are all as reported for Oxy1.5. The first and third pyrimidine tracts form parallel loops spanning a wide groove and a narrow groove respectively. CONCLUSIONS: Both Oxy3.5 and Oxy3.5-U(4)128 form unimolecular quadruplexes in solution with a diagonal central T4 loop. These results conflict with those reported for d(G4TUTUG4TTUUG4UUTTG4) in solution, in which the central loop spans a wide groove.

Structural change in Rev responsive element RNA of HIV-1 on binding Rev peptide.

The HIV-1 Rev responsive element (RRE) high-affinity binding site was studied by homonuclear and heteronuclear NMR. Two Rev binding element (RBE) RNA oligonucleotides were used as model systems in this study: RBE3, which contains the wild-type Rev high-affinity binding site, and RBE3-A which is identical except for the deletion of a bulged A. The temperature dependence of the two-dimensional spectra of the free RNAs indicates that at lower temperatures more than one conformation is present. However, at higher temperatures a single conformation predominates. Model structures of RBE3 and RBE3-A as well as the RBE3-A complexed with a peptide derived from the RNA binding domain of HIV-1 Rev, were calculated using NMR-derived restraints. The Rev high-affinity binding site of the HIV-1 RRE contains a structured internal loop with two purine-purine base-pairs and an extrahelical U. Comparison of the free and bound RNA structures reveals that upon peptide binding there is a distinct change in the backbone at G24, which is involved in a G-G base-pair. In the free RNA, G24 is in the syn conformation, and the backbone is in a relatively normal configuration, antiparallel to the other strand. In the bound RNA, the backbone at G24 has flipped over so that it is parallel to the other strand. G24 in the bound RNA still forms a base-pair with G6, but is now in the anti conformation.

Three-dimensional solution structure of the thrombin-binding DNA aptamer d(GGTTGGTGTGGTTGG).

The DNA oligonucleotide d(GGTTGGTGTGGTTGG) (thrombin aptamer) binds to thrombin and inhibits its enzymatic activity in the chain of reactions that lead to blood clotting. Two-dimensional 1H NMR studies indicate that the oligonucleotide forms a folded structure in solution, composed of two guanine quartets connected by two T-T loops spanning the narrow grooves at one end and a T-G-T loop spanning a wide groove at the other end. We present the assignment strategy used, methods for the structure determination, and the refined three-dimensional structure of the thrombin aptamer. The initial structures were generated by metric matrix distance geometry using distance and dihedral bond angle constraints from NOE and coupling constants, respectively, and refined by restrained molecular dynamics and direct NOE refinement. Knowledge of the three-dimensional structure of this thrombin aptamer may be relevant for the design of improved thrombin-inhibiting anti-coagulants with similar structural motifs.

Solution structure of the conserved 16 S-like ribosomal RNA UGAA tetraloop.

The solution structure of the highly conserved UGAA tetraloop found at the 3' end of eukaryotic 16 S-like ribosomal RNA has been solved by nuclear magnetic resonance spectroscopy in the form of the 12 nucleotide hairpin 5'-GGUG[UGAA]CACC. The UGAA tetraloop displays a novel fold. The backbone turn occurs between the G and the third A in the loop, with the U and G in a 5' stack and the As in a 3' stacking arrangement. The loop is closed by a U-A mismatch in which the O2, 2'OH, and O4' groups of the U are within hydrogen bonding distance of the amino group of the A. The tetraloop does not make a uridine-turn, even though its sequence is identical to a U-turn found within the anticodon loop of tRNA(Phe). The hydrogen bonding pattern in the tetraloop provides insight into the function of base modifications found in vivo within this portion of 16 S-like rRNA.

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.

Reconciliation of the X-ray and NMR structures of the thrombin-binding aptamer d(GGTTGGTGTGGTTGG).

The thrombin-binding aptamer d(GGTTGGTGTGGTTGG) is one of a family of DNA oligonucleotides that were identified by in vitro selection to bind specifically and with high affinity to thrombin. Two groups independently determined the tertiary structure in solution by NMR and at about the same time, the X-ray crystal structure of the aptamer in complex with thrombin was reported. In all cases, the thrombin-binding aptamer was found to fold into a structure containing two planar guanine quartets as its core. The NMR and crystal structures, however, have fundamentally different folding patterns owing to differences in the way these central bases are connected. We discuss the distinctions between the refined crystal and solution structures and show that the NMR model is consistent with the X-ray diffraction data.

Proton nuclear magnetic resonance assignments and structural characterization of an intramolecular DNA triplex.

Two-dimensional 1H n.m.r. spectroscopy has been used to study the 31-base DNA oligonucleotide 5'-dAGAGAGAACCCCTTCTCTCTTTTTCTCTCTT-3', which folds to form a stable intramolecular triplex in solution at acidic pH. This structure is considerably more difficult to assign than short B-DNA duplexes and requires new assignment methods. The assignment strategy and assignments of almost all of the exchangeable and nonexchangeable resonances are presented. Seven base triplets and one Watson-Crick base-pair form the core of the structure and are connected by a four C and four T loop at either end. The second pyrimidine "strand" (bases 24 to 31) in this intramolecular pyrimidine-purine-pyrimidine triplex binds via Hoogsteen base-pairs in the major groove and is parallel to the purine "strand" (bases 1 to 8). Analysis of the sugar puckers reveals that, contrary to widely accepted belief, the triplex sugars are not predominantly in the N-type (close to C3'-endo) conformation. Except for some of the C nucleotides, all sugars are predominantly S-type (close to C2'-endo). Thus, the duplex DNA does not assume N-type sugar conformations to accommodate a third strand in the major groove. A preliminary model of the triplex structure is presented.

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'.

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.

Mutant ATP-binding RNA aptamers reveal the structural basis for ligand binding.

The solution structure of the ATP-binding RNA aptamer has recently been determined by NMR spectroscopy. The three-dimensional fold of the molecule is determined to a large extent by stacking and hydrogen bond interactions. In the course of the structure determination it was discovered that several highly conserved nucleotides in the binding pocket can be substituted while retaining binding under NMR conditions. These surprising findings allow a closer look at the interactions that determine stability and specificity of the aptamer as well as local structural features of the molecule. The binding properties of ATP binder mutants and modified ligand molecules are explored using NMR spectroscopy, column binding studies and molecular modeling. We present additional evidence and new insights regarding the network of hydrogen bonds that defines the structure and determines stability and specificity of the aptamer.

Solution structure of a pyrimidine-purine-pyrimidine triplex containing the sequence-specific intercalating non-natural base D3.

We have used NMR spectroscopy to study a pyrimidine-purine-pyrimidine DNA triplex containing a non-natural base, 1-(2-deoxy-beta-D-ribofuranosyl)-4-(3-benzamido)phenylimidazole (D3), in the third strand. The D3 base has been previously shown to specifically recognize T-A and C-G base-pairs via intercalation on the 3' side (with respect to the purine strand) of the target base pair, instead of forming sequence-specific hydrogen bonds. 1H resonance assignments have been made for the D3 base and most of the non-loop portion of the triplex. The solution structure of the triplex was calculated using restrained molecular dynamics and complete relaxation matrix refinement. The duplex portion of the triplex has an over-all helical structure that is more similar to B-DNA than to A-DNA. The three aromatic rings of the D3 base stack on the bases of all three strands and mimic a triplet. The conformation of the D3 base and its sequence specificity are discussed.

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.

Aptamer structures from A to zeta.

Solution structures of RNA aptamers for FMN, ATP, arginine, and citrulline reveal how oligonucleotides can fold to form selective binding pockets for biological cofactors and amino acids. These structures confirm old ideas and provide new insights about three-dimensional structures of nucleic acids and their possible role in chemical reactions.

Solution structure of protegrin-1, a broad-spectrum antimicrobial peptide from porcine leukocytes.

BACKGROUND: The protegrins are a family of arginine- and cysteine-rich cationic peptides found in porcine leukocytes that exhibit a broad range of antimicrobial and antiviral activities. They are composed of 16-18 amino-acid residues including four cysteines, which form two disulfide linkages. To begin to understand the mechanism of action of these peptides, we set out to determine the structure of protegrin-1 (PG-1). RESULTS: We used two-dimensional homonuclear nuclear magnetic resonance spectroscopy to study the conformation of both natural and synthetic PG-1 under several conditions. A refined three-dimensional structure of synthetic PG-1 is presented. CONCLUSIONS: Both synthetic and natural protegrin-1 form a well-defined structure in solution composed primarily of a two-stranded antiparallel beta sheet, with strands connected by a beta turn. The structure of PG-1 suggests ways in which the peptide may interact with itself or other molecules to form the membrane pores and the large membrane-associated assemblages observed in protegrin-treated, gram-negative bacteria.

Interactions of antitumor drugs with natural DNA: 1H NMR study of binding mode and kinetics.

1H NMR has been used to study the interactions of over 70 clinical and experimental antitumor drugs with DNA. Spectra of the low-field (H-bonded imino proton) resonances of DNA were studied as a function of drug per base pair ratio. From the spectral changes observed, it was possible to distinguish three modes of drug binding (intercalation, groove binding, and nonspecific outside binding), to determine the kinetics of drug binding (approximate lifetime of the bound drug), and, in favorable cases, to determine the specificity of the drugs for A X T or G X C base pairs. This method is a useful assay for general drug-binding characteristics. For the intercalating compounds there appears to be a correlation between drug-binding kinetics and useful antitumor activity.