Adaptive recognition by nucleic acid aptamers.

Nucleic acid molecules play crucial roles in diverse biological processes including the storage, transport, processing, and expression of the genetic information. Nucleic acid aptamers are selected in vitro from libraries containing random sequences of up to a few hundred nucleotides. Selection is based on the ability to bind ligand molecules with high affinity and specificity. Three-dimensional structures have been determined at high resolution for a number of aptamers in complex with their cognate ligands. Structures of aptamer complexes reveal the key molecular interactions conferring specificity to the aptamer-ligand association, including the precise stacking of flat moieties, specific hydrogen bonding, and molecular shape complementarity. These basic principles of discriminatory molecular interactions in aptamer complexes parallel recognition events central to many cellular processes involving nucleic acids.

DNA conformation, dynamics, and interactions in solution.

The conformation and dynamics of the d(CGCGAATTCGCG) duplex, its analogs containing mismatched base pairs and helix interruptions, and its complexes with actinomycin and Netropsin, bound separately and simultaneously, have been investigated by nuclear magnetic resonance spectroscopy in aqueous solution. Structural information has been deduced from chemical shift and nuclear Overhauser effect parameters, while the kinetics have been probed from line width and saturation recovery experiments on proton and phosphorus markers at the individual base pair level. These studies lead to an improved understanding of the role of nucleic acid sequence on the structure, flexibility, and conformational interconversions in the duplex state. The nuclear magnetic resonance measurements readily identify helix modification and antibiotic binding sites on the nucleic acid and estimate the extent to which the observed conformational and dynamic perturbations are transmitted to adjacent base pair regions.

Adaptive recognition in RNA complexes with peptides and protein modules.

Recently, progress has been made towards the structural characterization of the novel folds of RNA-bound arginine-rich peptides and the architecture of their peptide-binding RNA pockets in viral and phage systems. These studies are based on an approach whereby the peptide and RNA components are minimalist modular domains that undergo adaptive structural transitions upon complex formation. Such complexes are characterized by recognition alignments in which the tertiary fold of the RNA generates binding pockets with the potential to envelop minimal elements of protein secondary structure. Strikingly, the peptides fold as isolated alpha-helical or beta-hairpin folds within their RNA major-groove targets, without the necessity of additional appendages for anchorage within the binding pocket. The RNA peptide-binding pocket architectures are sculptured through precisely positioned mismatches, triples and looped-out bases, which accommodate amino acid sidechains through hydrophobic, hydrogen bonding and ionic intermolecular contacts. By contrast, protein modules associated with the HIV-1 nucleocapsid and MS2 phage coat target their RNA binding sites through the insertion of specificity-determining RNA base residues within conserved hydrophobic pockets and crevices on the protein surface, with the bases anchored through hydrogen bonding interactions. These alternative strategies of RNA recognition at the peptide and protein module level provide novel insights into the principles, patterns and diversity of the adaptive transitions associated with the recognition process.

Solution structure of the human telomeric repeat d[AG3(T2AG3)3] G-tetraplex.

BACKGROUND: Repeats of Gn sequences are detected as single strand overhangs at the ends of eukaryotic chromosomes together with associated binding proteins. Such telomere sequences have been implicated in the replication and maintenance of chromosomal termini. They may also mediate chromosomal organization and association during meiosis and mitosis. RESULTS: We have determined the three-dimensional solution structure of the human telomere sequence, d[AG3(T2AG3)3] in Na(+)-containing solution using a combined NMR, distance geometry and molecular dynamics approach (including relaxation matrix refinement). The sequence, which contains four AG3 repeats, folds intramolecularly into a G-tetraplex stabilized by three stacked G-tetrads which are connected by two lateral loops and a central diagonal loop. Of the four grooves that are formed, one is wide, two are of medium width and one is narrow. The alignment of adjacent G-G-G segments in parallel generates the two grooves of medium width whilst the antiparallel arrangement results in one wide and one narrow groove. Three of the four adenines stack on top of adjacent G-tetrads while the majority of the thymines sample multiple conformations. CONCLUSIONS: The availability of the d[AG3(T2AG3)3] solution structure containing four AG3 human telomeric repeats should permit the rational design of ligands that recognize and bind with specificity and affinity to the individual grooves of the G-tetraplex, as well as to either end containing the diagonal and lateral loops. Such ligands could modulate the equilibrium between folded G-tetraplex structures and their unfolded extended counterparts.

Solution structure of a purine.purine.pyrimidine DNA triplex containing G.GC and T.AT triples.

BACKGROUND: Oligonucleotide-directed triple helix formation allows sequence specific recognition of double helical DNA. This powerful approach has been used to inhibit gene transcription in vitro and to mediate single site specific cleavage of a human chromosome. RESULTS: Using a combined NMR and molecular dynamics approach (including relaxation matrix refinement), we have determined the solution structure of an intramolecular purine.purine.pyrimidine (R.RY) DNA triplex containing guanines and thymines in the third strand to high resolution. Our studies define the G.GC and T.AT base triple pairing alignments in the R.RY triplex and identify the structural discontinuities in the third strand associated with the non-isomorphism of the base triples. The 5'-d(TpG)-3' base steps exhibit a pronounced increase in axial rise and reduction in helical twist, while the reverse is observed, to a lesser extent at 5'-d(GpT)-3' steps. A third groove is formed between the purine-rich third strand and the pyrimidine strand. It is wider and deeper than the other two grooves. CONCLUSIONS: Our structure of the R.RY DNA triplex will be important in the design of oligonucleotide probes with enhanced specificity and affinity for targeting in the genome. The third groove presents a potential target for binding additional ligands.

Solution structure of a pyrimidine.purine.pyrimidine DNA triplex containing T.AT, C+.GC and G.TA triples.

BACKGROUND: Under certain conditions, homopyrimidine oligonucleotides can bind to complementary homopurine sequences in homopurine-homopyrimidine segments of duplex DNA to form triple helical structures. Besides having biological implications in vivo, this property has been exploited in molecular biology applications. This approach is limited by a lack of knowledge about the recognition by the third strand of pyrimidine residues in Watson-Crick base pairs. RESULTS: We have therefore determined the solution structure of a pyrimidine.purine.pyrimidine (Y.RY) DNA triple helix containing a guanine residue in the third strand which was postulated to specifically recognize a thymine residue in a Watson-Crick TA base pair. The structure was solved by combining NMR-derived restraints with molecular dynamics simulations conducted in the presence of explicit solvent and counter ions. The guanine of the G-TA triple is tilted out of the plane of its target TA base pair towards the 3'-direction, to avoid a steric clash with the thymine methyl group. This allows the guanine amino protons to participate in hydrogen bonds with separate carbonyls, forming one strong bond within the G-TA triple and a weak bond to an adjacent T.AT triple. Dramatic variations in helical twist around the guanine residue lead to a novel stacking interaction. At the global level, the Y.RY DNA triplex shares several structural features with the recently solved solution structure of the R.RY DNA triplex. CONCLUSIONS: The formation of a G.TA triple within an otherwise pyrimidine.purine.pyrimidine DNA triplex causes conformational realignments in and around the G.TA triple. These highlight new aspects of molecular recognition that could be useful in triplex-based approaches to inhibition of gene expression and site-specific cleavage of genomic DNA.

Hydration sites in purine.purine.pyrimidine and pyrimidine.purine.pyrimidine DNA triplexes in aqueous solution.

BACKGROUND: DNA triplexes are higher-order nucleic acid structures with potential roles in gene regulation and hence biochemical and therapeutic applications. The stabilizing influence exerted by water molecules on the conformation of the DNA duplex is well known. However, the role of water molecules in the DNA triple helix has not been investigated. We have previously determined the solution structures of the purine.purine.pyrimidine (R.RY) and pyrimidine.purine.pyrimidine (Y.RY) structural motifs in DNA triplexes and identified both the global helical parameters, as well as local helical distortions associated with non-standard base triple pairing alignments. RESULTS: Here we have used homonuclear two-dimensional NMR spectroscopy to define the hydration sites in R.RY and Y.RY DNA triplexes in aqueous solution. Long-lived hydration sites with residence times exceeding 1 nanosecond have been identified in the new groove formed by the Hoogsteen paired strands in both triplexes. Distinctive patterns of hydration are displayed by each triplex in the remaining two grooves. CONCLUSION: The role played by water molecules in DNA triplexes appears to be similar to that played in duplexes. By binding to specific sites, particularly in the narrow groove formed by the Hoogsteen paired strands whose phosphate groups are in close proximity, water molecules may stabilize the triplex by shielding it against unfavorable electrostatic interactions.

Solution structure of the Tetrahymena telomeric repeat d(T2G4)4 G-tetraplex.

BACKGROUND: Telomeres in eukaryotic organisms are protein-DNA complexes which are essential for the protection and replication of chromosomal termini. The telomeric DNA of Tetrahymena consists of T2G4 repeats, and models have been previously proposed for the intramolecular folded structure of the d(T2G4)4 sequence based on chemical footprinting and cross-linking data. A high-resolution solution structure of this sequence would allow comparison with the structures of related G-tetraplexes. RESULTS: The solution structure of the Na(+)-stabilized d(T2G4)4 sequence has been determined using a combined NMR-molecular dynamics approach. The sequence folds intramolecularly into a right-handed G-tetraplex containing three stacked G-tetrads connected by linker segments consisting of a G-T-T-G lateral loop, a central T-T-G lateral loop and a T-T segment that spans the groove through a double chain reversal. The latter T-T connectivity aligns adjacent G-G-G segments in parallel and introduces a new G-tetraplex folding topology with unprecedented combinations of strand directionalities and groove widths, as well as guanine syn/anti distributions along individual strands and around individual G-tetrads. CONCLUSIONS: The four repeat Tetrahymena and human G-tetraplexes, which differ by a single guanine for adenine substitution, exhibit strikingly different folding topologies. The observed structural polymorphism establishes that G-tetraplexes can adopt topologies which project distinctly different groove dimensions, G-tetrad base edges and linker segments for recognition by, and interactions with, other nucleic acids and proteins.

RNA bulges as architectural and recognition motifs.

RNA bulges constitute versatile structural motifs in the assembly of RNA architectures. Three-dimensional structures of RNA molecules and their complexes reveal the role of bulges in RNA architectures and illustrate the molecular mechanisms by which they confer intramolecular interactions and intermolecular recognition.

Solution structure of the donor site of a trans-splicing RNA.

BACKGROUND: RNA splicing is both ubiquitous and essential for the maturation of precursor mRNA molecules in eukaryotes. The process of trans-splicing involves the transfer of a short spliced leader (SL) RNA sequence to a consensus acceptor site on a separate pre-mRNA transcript. In Caenorhabditis elegans, a majority of pre-mRNA transcripts receive the 22-nucleotide SL from the SL1 RNA. Very little is known about the various roles that RNA structures play in the complex conformational rearrangements and reactions involved in premRNA splicing. RESULTS: We have determined the solution structure of a domain of the first stem loop of the SL1 RNA of C. elegans, using homonuclear and heteronuclear NMR techniques; this domain contains the splice-donor site and a nine-nucleotide hairpin loop. In solution, the SL1 RNA fragment adopts a stem-loop structure: nucleotides in the stem region form a classical A-type helix while nucleotides in the hairpin loop specify a novel conformation that includes a helix, that extends for the first three residues; a syn guanosine nucleotide at the turn region; and an extrahelical adenine that defines a pocket with nucleotides at the base of the loop. CONCLUSION: The proximity of this pocket to the splice donor site, combined with the observation that the nucleotides in this motif are conserved among all nematode SL RNAs, suggests that this pocket may provide a recognition site for a protein or RNA molecule in the trans-splicing process.

Anchoring an extended HTLV-1 Rex peptide within an RNA major groove containing junctional base triples.

BACKGROUND: The Rex protein of the human T cell leukemia virus type 1 (HTLV-1) belongs to a family of proteins that use arginine-rich motifs (ARMs) to recognize their RNA targets. Previously, an in vitro selected RNA aptamer sequence was identified that mediates mRNA transport in vivo when placed in the primary binding site on stem-loop IID of the Rex response element. We present the solution structure of the HTLV-1 arginine-rich Rex peptide bound to its RNA aptamer target determined by multidimensional heteronuclear NMR spectroscopy. RESULTS: The Rex peptide in a predominantly extended conformation threads through a channel formed by the shallow and widened RNA major groove and a looped out guanine. The RNA aptamer contains three stems separated by a pair of two-base bulges, and adopts an unanticipated fold in which both junctional sites are anchored through base triple formation. Binding specificity is associated with intermolecular hydrogen bonding between guanidinium groups of three non-adjacent arginines and the guanine base edges of three adjacent G.C pairs. CONCLUSIONS: The extended S-shaped conformation of the Rex peptide, together with previous demonstrations of a beta-hairpin conformation for the bovine immunodeficiency virus (BIV) Tat peptide and an alpha-helical conformation for the human immunodeficiency virus (HIV) Rev peptide in complex with their respective RNA targets, expands our understanding of the strategies employed by ARMs for adaptive recognition and highlights the importance of RNA tertiary structure in accommodating minimalist elements of protein secondary structure.

Interlocked mismatch-aligned arrowhead DNA motifs.

BACKGROUND: Triplet repeat sequences are of considerable biological importance as the expansion of such tandem arrays can lead to the onset of a range of human diseases. Such sequences can self-pair via mismatch alignments to form higher order structures that have the potential to cause replication blocks, followed by strand slippage and sequence expansion. The all-purine d(GGA)n triplet repeat sequence is of particular interest because purines can align via G.G, A.A and G.A mismatch formation. RESULTS: We have solved the structure of the uniformly 13C,15N-labeled d(G1-G2-A3-G4-G5-A6-T7) sequence in 10 mM Na+ solution. This sequence adopts a novel twofold-symmetric duplex fold where interlocked V-shaped arrowhead motifs are aligned solely via interstrand G1.G4, G2.G5 and A3.A6 mismatch formation. The tip of the arrowhead motif is centered about the p-A3-p step, and symmetry-related local parallel-stranded duplex domains are formed by the G1-G2-A3 and G4-G5-A6 segments of partner strands. CONCLUSIONS: The purine-rich (GGA)n triplet repeat sequence is dispersed throughout the eukaryotic genome. Several features of the arrowhead duplex motif for the (GGA)2 triplet repeat provide a unique scaffold for molecular recognition. These include the large localized bend in the sugar-phosphate backbones, the segmental parallel-stranded alignment of strands and the exposure of the Watson-Crick edges of several mismatched bases.

Saccharide-RNA recognition in a complex formed between neomycin B and an RNA aptamer.

BACKGROUND: Aminoglycoside antibiotics can target RNA folds with micromolar affinity and inhibit biological processes ranging from protein biosynthesis to ribozyme action and viral replication. Specific features of aminoglycoside antibiotic-RNA recognition have been probed using chemical, biochemical, spectroscopic and computational approaches on both natural RNA targets and RNA aptamers identified through in vitro selection. Our previous studies on tobramycin-RNA aptamer complexes are extended to neomycin B bound to its selected RNA aptamer with 100 nM affinity. RESULTS: The neamine moiety (rings I and II) of neomycin B is sandwiched between the major groove floor of a 'zippered-up' G.U mismatch aligned segment and a looped-out purine base that flaps over the bound antibiotic. Specific intermolecular hydrogen bonds are observed between the charged amines of neomycin B and base mismatch edges and backbone phosphates. These interactions anchor 2-deoxystreptamine ring I and pyranose ring II within the RNA-binding pocket. CONCLUSIONS: The RNA aptamer complexes with tobramycin and neomycin B utilize common architectural principles to generate RNA-binding pockets for the bound aminoglycoside antibiotics. In each case, the 2-deoxystreptamine ring I and an attached pyranose ring are encapsulated within the major groove binding pocket, which is lined with mismatch pairs. The bound antibiotic within the pocket is capped over by a looped-out base and anchored in place through intermolecular hydrogen bonds involving charged amine groups of the antibiotic.

NMR studies of the structure and stability of the 1 : 2 actinomycin D-d-pG-C complex in aqueous solution.

We describe NMR studies at superconducting fields which characterize aspects of the structure and stability of the 1 : 2 actinomycin-d-pG-C complex in solution as monitored at the Watson-Crick base pairs and backbone phosphate groups. Two guanine N1H resonances (12.17 and 11.66 ppm) are observed in the 360 MHz proton NMR spectra of the complex in water at -4 degrees C. These slowly exchangeable resonances, which demonstrate the presence of two Watson-Crick G + C base pairs in the complex, broaden in a sequential manner with increasing temperature. The terminal and internucleotide phosphates of both d-pG-C molecules are observable in the 145.7 MHz 31P spectra of the 1 : 2 actinomycin-d-pG-C complex at 0 degrees C. The internucleotide phosphate resonance at 1.905 ppm broadens prior to that at 2.385 ppm with increasing temperature, consistent with a sequential breakage of the G + C base pairs in the complex. The lifetime of the complex (4.5 +/- 0.5 X 10(-4) s, 33 degrees C) was deduced from the variation of the d-pG-D internucleotide 31P resonance line width on gradual addition of the antibiotic in solution.

Assignment of the imidazole ring nitrogen protons of histidine 48 in the proton NMR spectrum of ribonuclease A in water solution.

Several exchangeable resonances, designated a, b, c and d are observed in the 11-14 ppm (from 2,2-dimethyl-2-silapentane-5-sulfonate) region of the proton spectrum of ribonuclease A in water solution. We describe a number of lines of evidence suggesting the assignment of peaks b and c to the N1 and N3 protons of His 48, which occupies an interior position in the protein remote from the active site. This evidence includes the observation that the binding of Cu(II) and 3'-CMP (cytidine 3'-monophosphate) has no effect on these resonances. Further evidence includes pH titration data showing a pKa of approx. 2 for these protons, solvent exchange rates in the native state and with disulfide bridges IV-V and III-VIII cleaved, the observation of the carboxymethylated enzymes CM-His12-RNAase A and CM-His119-RNAase A, and of the modified enzymes Des(1-21)-RNAase A (S-protein) and Des(119-124)-RNAase A.

Structural analysis of nucleic acid aptamers.

Solution structures and hydrogen exchange characteristics of ligand-RNA aptamer and ligand-DNA aptamer complexes have been solved within the past year. The ligands range from cofactors to amino acids, nucleotides, aminoglycoside antibiotics and peptides that are targeted by the nucleic acid aptamers with high specificity and affinity. The structural and dynamics studies provide insights into the principles, patterns and diversity associated with nucleic acid architecture, molecular recognition and the adaptive binding that takes place upon complex formation. These new results provide opportunities for structure-based drug design strategies relevant to therapeutic intervention.

Solution structure of a parallel-stranded G-quadruplex DNA.

This paper reports on the solution structure of a parallel-stranded G-quadruplex formed by the Tetrahymena telomeric sequence d(T-T-G-G-G-G-T) whose NMR parameters in potassium cation containing solution were previously published from our laboratory. The structure was determined by combining a quantitative analysis of the NMR data with molecular dynamics calculations including relaxation matrix refinement. The combined NMR-computational approach yielded a set of seven distance-refined structures with pairwise RMSDs ranging from 0.66 to 1.30 A for the central G-G-G-G tetranucleotide segment. Four of the seven structures were refined further using complete relaxation-matrix calculations to yield solution structures with pairwise RMSDs ranging from 0.64 to 1.04 A for the same tetranucleotide segment. The R-factors also decreased on proceeding from the distance-refined to relaxation matrix-refined structures. The four strands of the G-quadruplex are aligned in parallel and are related by a 4-fold symmetry axis coincident with the helix axis. Individual guanines from each strand form planar G.G.G.G tetrad arrangements with each tetrad stabilized by eight hydrogen bonds involving the Watson-Crick and Hoogsteen edges of the guanine bases. All guanines adopt anti glycosidic torsion angles and S type sugar puckers in this right-handed parallel-stranded G-quadruplex structure. The four G.G.G.G tetrad planes stack on each other with minimal overlap of adjacent guanine base planes within individual strands. The thymine residues are under-defined in the solution structure of the d(T-T-G-G-G-G-T) G-quadruplex and sample amongst multiple conformations in solution.

Solution structure and hydration patterns of a pyrimidine.purine.pyrimidine DNA triplex containing a novel T.CG base-triple.

The solution structure of a pyrimidine.purine.pyrimidine DNA triplex containing a novel T.CG base-triple has been determined via two and three-dimensional NMR spectroscopy and restrained molecular dynamics simulations incorporating explicit solvent and counter-ions. The T.CG triple, which expands the triplex code, is stabilized by a single hydrogen bond between the O-2 atom of thymine and the free amino proton of cytosine in the Watson-Crick C.G base-pair. This hydrogen bonding alignment produces large variations in helical twist at the dinucleotide steps involving the thymine residue. Localized structural perturbations in the purine-rich strand of the molecule are observed around the cytosine residue in the T.CG triple. Globally, the triplex resembles the solution structure of a previously solved pyrimidine.purine.pyrimidine DNA triplex containing an unusual G.TA triple. Also conserved are the sites and patterns of hydration in the two triplexes.

Solution structure of the d(T-C-G-A) duplex at acidic pH. A parallel-stranded helix containing C+ .C, G.G and A.A pairs.

The solution structure of the d(T-C-G-A) sequence at acidic pH has been determined by a combination of NMR and molecular dynamics calculations including NOE intensity based refinements. This sequence forms a right-handed parallel-stranded duplex with C+ .C (three hydrogen bonds along Watson-Crick edge), G.G (two symmetry related N2-H.. N3 hydrogen bonds) and A.A (two symmetry related N6-H..N7 hydrogen bonds) homo base-pair formation at acidic pH. The duplex is stabilized by intra-strand base stacking at the C2-G3 step and cross-strand base stacking at the G3-A4 step. The thymine residues on partner strands are directed towards each other and are positioned over the C+ .C base-pair. All four residues adopt anti glycosidic torsion angles and C2'-endo type sugar conformations in the parallel-stranded d(T-C-G-A) duplex which exhibits large changes in twist angles between adjacent steps along the duplex. This study rules out previously proposed models for the structure of the d(T-C-G-A) duplex at acidic pH and supports earlier structural contributions, which established that d(C-G) and d(C-G-A) containing sequences at acidic pH pair through parallel-stranded alignment. We have also monitored hydration patterns in the symmetry related grooves of the parallel-stranded d(T-C-G-A) duplex.

Solution structure of the covalent duocarmycin A-DNA duplex complex.

Duocarmycin A is an antitumour antibiotic that binds covalently to the minor groove N-3 position of adenine with sequence specificity for the 3'-adenine in a d(A-A-A-A) tract in duplex DNA. The adenine ring becomes protonated on duocarmycin adduct formation resulting in charge delocalization over the purine ring system. We report on the solution structure of duocarmycin A bound site specifically to A12 (designated *A12+) in the sequence context d(T3-T4-T5-T6).d(A9-A10-A11-*A12+) within a hairpin duplex. The solution structure was solved based on a combined NMR-molecular dynamics study including NOE based intensity refinement. The A and B-rings of duocarmycin are positioned deep within the walls of the minor groove with the B-ring (which is furthest from the covalent linkage site) directed towards the 5'-end of the modified strand. Duocarmycin adopts an extended conformation and is aligned at approximately 45 degrees to the helix axis with its non-polar concave edges interacting with the floor of the minor groove while its polar edges are sandwiched within the walls of the minor groove. The T3.*A12+ modification site pair forms a weak central Watson-Crick hydrogen bond in contrast to all A.T and G.C pairs, which align through standard Watson-Crick pairing in the complex. The helical parameters are consistent with a minimally perturbed right-handed duplex in the complex with minor groove width and x-displacement parameters indicative of a B-form helix. A striking feature of the complex is the positioning of duocarmycin A within the walls of the minor groove resulting in upfield shifts of the minor groove sugar protons, as well as backbone proton and phosphorus resonances in the DNA segment spanning the binding site.