Structure and thermodynamics of metal binding in the P5 helix of a group I intron ribozyme.

The solution structure of an RNA hairpin modelling the P5 helix of a group I intron, complexed with Co(NH3)63+, has been determined by nuclear magnetic resonance. Co(NH3)63+, which possesses a geometry very close to Mg(H2O)62+, was used to identify and characterize a Mg2+binding site in the RNA. Strong and positive intermolecular nuclear Overhauser effect (NOE) cross-peaks define a specific complex in which the Co(NH3)63+molecule is in the major groove of tandem G.U base-pairs. The structure of the RNA is characterized by a very low twist angle between the two G.U base-pairs, providing a flat and narrowed major groove. The Co(NH3)63+, although highly localized, is free to rotate to hydrogen bond in several ways to the O4 atoms of the uracil bases and to N7 and O6 of the guanine bases. Negative and small NOE cross-peaks to other protons in the sequence reveal a non-specific or delocalized interaction, characterized by a high mobility of the cobalt ion. Mn2+titrations of P5 show specific broadening of protons of the G.U base-pairs that form the metal ion binding site, in agreement with the NOE data from Co(NH3)63+. Binding constants for the interaction of Co(NH3)63+and of Mg2+to P5 were determined by monitoring imino proton chemical shifts during titration of the RNA with the metal ions. Dissociation constants are on the order of 0.1 mM for Co(NH3)63+and 1 mM for Mg2+. Binding studies were done on mutants with sequences corresponding to the three orientations of tandem G.U base-pairs. The affinities of Co(NH3)63+and Mg2+for the tandem G.U base-pairs depend strongly on their sequences; the differences can be understood in terms of the different structures of the corresponding metal ion-RNA complexes. Substitution of G.C or A.U for G.U pairs also affected the binding, as expected. These structural and thermodynamic results provide systematic new information about major groove metal ion binding in RNA.     

Metal ion dependence, thermodynamics, and kinetics for intramolecular docking of a GAAA tetraloop and receptor connected by a flexible linker

The GAAA tetraloop-receptor motif is a commonly occurring tertiary interaction in RNA. This motif usually occurs in combination with other tertiary interactions in complex RNA structures. Thus, it is difficult to measure directly the contribution that a single GAAA tetraloop-receptor interaction makes to the folding properties of a RNA. To investigate the kinetics and thermodynamics for the isolated interaction, a GAAA tetraloop domain and receptor domain were connected by a single-stranded A(7) linker. Fluorescence resonance energy transfer (FRET) experiments were used to probe intramolecular docking of the GAAA tetraloop and receptor. Docking was induced using a variety of metal ions, where the charge of the ion was the most important factor in determining the concentration of the ion required to promote docking {[Co(NH(3))(6)(3+)] < [Ca(2+)], [Mg(2+)], [Mn(2+)] < [Na(+)], [K(+)]}. Analysis of metal ion cooperativity yielded Hill coefficients of approximately 2 for Na(+)- or K(+)-dependent docking versus approximately 1 for the divalent ions and Co(NH(3))(6)(3+). Ensemble stopped-flow FRET kinetic measurements yielded an apparent activation energy of 12.7 kcal/mol for GAAA tetraloop-receptor docking. RNA constructs with U(7) and A(14) single-stranded linkers were investigated by single-molecule and ensemble FRET techniques to determine how linker length and composition affect docking. These studies showed that the single-stranded region functions primarily as a flexible tether. Inhibition of docking by oligonucleotides complementary to the linker was also investigated. The influence of flexible versus rigid linkers on GAAA tetraloop-receptor docking is discussed.     

Solution structure and metal-ion binding of the P4 element from bacterial RNase P RNA

We determined the solution structure of two 27-nt RNA hairpins and their complexes with cobalt(III)-hexammine (Co(NH3)3+(6)) by NMR spectroscopy. The RNA hairpins used in this study are the P4 region from Escherichia coli RNase P RNA and a C-to-U mutant that confers altered divalent metal-ion specificity (Ca2+ replaces Mg2+) for catalytic activity of this ribozyme. Co(NH3)3+(6) is a useful spectroscopic probe for Mg(H2O)2+(6)-binding sites because both complexes have octahedral symmetry and have similar radii. The thermodynamics of binding to both RNA hairpins was studied using chemical shift changes upon titration with Mg2+, Ca2+, and Co(NH3)3+(6). We found that the equilibrium binding constants for each of the metal ions was essentially unchanged when the P4 model RNA hairpin was mutated, although the NMR structures show that the RNA hairpins adopt different conformations. In the C-to-U mutant a C.G base pair is replaced by U.G, and the conserved bulged uridine in the P4 wild-type stem shifts in the 3' direction by 1 nt. Intermolecular NOE cross-peaks between Co(NH3)3+(6) and RNA protons were used to locate the site of Co(NH3)3+(6) binding to both RNA hairpins. The metal ion binds in the major groove near a bulge loop, but is shifted 5' by more than 1 bp in the mutant. The change of the metal-ion binding site provides a possible explanation for changes in catalytic activity of the mutant RNase P in the presence of Ca2+.     

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.     

Metal ion stabilization of the U-turn of the A37 N6-dimethylallyl-modified anticodon stem-loop of Escherichia coli tRNAPhe

Nucleoside base modifications can alter the structures, dynamics, and metal ion binding properties of transfer RNA molecules and are important for accurate aminoacylation and for maintaining translational fidelity and efficiency. The unmodified anticodon stem-loop from Escherichia coli tRNA(Phe) forms a trinucleotide loop in solution, but Mg(2+) and dimethylallyl modification of A(37) N6 disrupt the loop conformation and increase the mobility of the loop and loop-proximal nucleotides. We have used NMR spectroscopy to investigate the binding and structural effects of multivalent cations on the unmodified and dimethylallyl-modified anticodon stem-loops from E. coli tRNA(Phe). The divalent cation binding sites were probed using Mn(2+) and Co(NH(3))(6)(3+). These ions bind along the major groove of the stem and associate with the anticodon loop on the major groove side in a nonspecific manner. Co(NH(3))(6)(3+) stabilizes the U-turn conformation of the loop in the dimethylallyl-modified molecule, and the chemical shift changes that accompany Co(NH(3))(6)(3+) binding are similar to those observed with the addition of Mg(2+). The base-phosphate and base-2'-OH hydrogen bonds that characterize the UNR U-turn motif lead to spectral signatures in the form of unusual (15)N and (1)H chemical shifts and reduced solvent exchange of the U(33) 2'-OH and N3H protons. The unmodified molecule also displays spectral features of the U-turn fold in the presence of Co(NH(3))(6)(3+), but the loop has additional conformations and is dynamic. The results indicate that charge neutralization by a polyvalent cation is sufficient to promote formation of the U-turn fold. However, base modification is necessary to destabilize competing alternative conformers even for a purine-rich loop sequence that is predicted to have strongly favorable base stacking energy.     

Structural features and thermodynamics of the J4/5 loop from the Candida albicans and Candida dubliniensis group I introns

The J4/5 loop of group I introns has tertiary interactions with the P1 helix that position the P1 substrate for the self-splicing reaction. The J4/5 loop of Candida albicans and Candida dubliniensis, 5'GAAGG3'/3'UAAUU5', potentially contains two A.A pairs flanked by one G.U pair on one side and two G.U pairs on the other side. Results from optical melting, nuclear magnetic resonance spectroscopy, and functional group substitution experiments with a mimic of the C. albicans and C. dubliniensis J4/5 loop are consistent with the adenosines forming tandem sheared A.A pairs with a cross-strand stack and only the G.U pair not adjacent to an A.A pair forming a static wobble G.U pair. The two G.U pairs adjacent to the tandem A.A pairs are likely in a dynamic equilibrium between multiple conformations. Although Co(NH(3))(6)(3+) stabilizes the loop by several kilocalories per mole at 37 degrees C, addition of Mg(2+) or Co(NH(3))(6)(3+) has no effect on the structure of the loop. The tandem G.U pairs provide a pocket of negative charge for Co(NH(3))(6)(3+) to bind. The results contribute to understanding the structure and dynamics of purine-rich internal loops and potential G.U pairs adjacent to internal loops.     

The Role of Counterion Valence and Size in GAAA Tetraloop-Receptor Docking/Undocking Kinetics

For RNA to fold into compact, ordered structures, it must overcome electrostatic repulsion between negatively charged phosphate groups by counterion recruitment. A physical understanding of the counterion-assisted folding process requires addressing how cations kinetically and thermodynamically control the folding equilibrium for each tertiary interaction in a full-length RNA. In this work, single-molecule FRET (fluorescence resonance energy transfer) techniques are exploited to isolate and explore the cation-concentration-dependent kinetics for formation of a ubiquitous RNA tertiary interaction, that is, the docking/undocking of a GAAA tetraloop with its 11-nt receptor. Rate constants for docking (k(dock)) and undocking (k(undock)) are obtained as a function of cation concentration, size, and valence, specifically for the series Na(+), K(+), Mg(2+), Ca(2+), Co(NH(3))(6)(3+), and spermidine(3+). Increasing cation concentration acceleratesk(dock)dramatically but achieves only a slight decrease in k(undock). These results can be kinetically modeled using parallel cation-dependent and cation-independent docking pathways, which allows for isolation of the folding kinetics from the interaction energetics of the cations with the undocked and docked states, respectively. This analysis reveals a preferential interaction of the cations with the transition state and docked state as compared to the undocked RNA, with the ion-RNA interaction strength growing with cation valence. However, the corresponding number of cations that are taken up by the RNA upon folding decreases with charge density of the cation. The only exception to these behaviors is spermidine(3+), whose weaker influence on the docking equilibria with respect to Co(NH(3))(6)(3+) can be ascribed to steric effects preventing complete neutralization of the RNA phosphate groups.     

Neomycin, spermine and hexaamminecobalt (III) share common structural motifs in converting B- to A-DNA.

The (dG)n.(dC)n-containing 34mer DNA duplex [d(A2G15C15T2)]2 can be effectively converted from the B-DNA to the A-DNA conformation by neomycin, spermine and Co(NH3)6(3+). Conversion is demonstrated by a characteristic red shift in the circular dichroism spectra and dramatic NMR spectral changes in chemical shifts. Additional support comes from the substantially stronger CH6/GH8-H3'NOE intensities of the ligand-DNA complexes than those from the native DNA duplex. Such changes are consistent with a deoxyribose pucker transition from the predominate C2'-endo (S-type) to the C3'-endo (N-type). The changes for all three ligand-DNA complexes are identical, suggesting that those three complex cations share common structural motifs for the B- to A-DNA conversion. The A-DNA structure of the 4:1 complex of Co(NH3)6(3+)/d(ACCCGCGGGT) has been analyzed by NOE-restrained refinement. The structural basis of the transition may be related to the closeness of the two negatively charged sugar-phosphate backbones along the major groove in A-DNA, which can be effectively neutralized by the multivalent positively charged amine functions of these ligands. In addition, ligands like spermine or Co(NH3)6(3+) can adhere to guanine bases in the deep major groove of the double helix, as is evident from the significant direct NOE cross-peaks from the protons of Co(NH3)6(3+) to GH8, GH1 (imino) and CH4 (amino) protons. Our results point to future directions in preparing more potent derivatives of Co(NH3)6(3+) for RNA binding or the induction of A-DNA.     

Cobalt hexammine inhibition of the hammerhead ribozyme

The effects of Co(NH(3))(6)(3+) on the hammerhead ribozyme are analyzed using several techniques, including activity measurements, electron paramagnetic resonance (EPR), and circular dichroism (CD) spectroscopies and thermal denaturation studies. Co(NH(3))(6)(3+) efficiently displaces Mn(2+) bound to the ribozyme with an apparent dissociation constant of K(d app) = 22 +/- 4.2 microM in 500 microM Mn(2+) (0.1 M NaCl). Displacement of Mn(2+) coincides with Co(NH(3))(6)(3+) inhibition of hammerhead activity in 500 microM Mn(2+), reducing the activity of the WT hammerhead by approximately 15-fold with an inhibition constant of K(i) = 30.9 +/- 2.3 microM. A residual 'slow' activity is observed in the presence of Co(NH(3))(6)(3+) and low concentrations of Mn(2+). Under these conditions, a single Mn(2+) ion remains bound and has a low-temperature EPR spectrum identical to that observed previously for the highest affinity Mn(2+) site in the hammerhead ribozyme in 1 M NaCl, tentatively attributed to the A9/G10.1 site [Morrissey, S. R. , Horton, T. E., and DeRose, V. J. (2000) J. Am. Chem. Soc. 122, 3473-3481]. Circular dichroism and thermal denaturation experiments also reveal structural effects that accompany the observed inhibition of cleavage and Mn(2+) displacement induced by addition of Co(NH(3))(6)(3+). Taken together, the data indicate that a high-affinity Co(NH(3))(6)(3+) site is responsible for significant inhibition accompanied by structural changes in the hammerhead ribozyme. In addition, the results support a model in which at least two types of metal sites, one of which requires inner-sphere coordination, support hammerhead activity.     

Circular dichroism study of the irreversibility of conformational changes induced by polyamine-linked dinuclear platinum compounds

In this work, the reversibility of both the B-->Z and B-->A conformational change in polymer DNA induced by polynuclear platinum compounds was studied. The compounds examined were: [[trans-PtCl(NH(3))(2)](2)[NH(2) (CH(2))(6)NH(2)]](2+) (BBR3005); [[trans-PtCl(NH(3))(2)](2)[mu-spermine-N1,N12]](4+) (BBR3535); [[trans-PtCl(NH(3))(2)](2)[mu-spermidine-N1,N8]](3+) (BBR3571); [[trans-PtCl(NH(3))(2)](2)[mu-BOC-spermidine]](2+) (BBR3537); and [[trans-PtCl(NH(3))(2)](2)[mu-trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+) (BBR3464). The conformational changes were assessed by circular dichroism and the reversibility of the transitions was tested by subsequent titration with the DNA intercalator ethidium bromide (EtBr). Fluorescent quenching was also used to assess the ability of ethidium bromide to intercalate into A and/or Z-DNA induced by the compounds. The results were compared with those produced by the simple hexamminecobalt cation [Co(NH(3))(6)](3+). The data suggest that while conformational changes induced by electrostatic interactions are confirmed to be reversible, covalent binding induces irreversible changes in both the A and Z conformation. The relevance of these changes to the novel biological action of polynuclear platinum compounds is discussed.     

Solution structure and thermodynamics of a divalent metal ion binding site in an RNA pseudoknot.

Identification and characterization of a metal ion binding site in an RNA pseudoknot was accomplished using cobalt (III) hexammine, Co(NH3)63+, as a probe for magnesium (II) hexahydrate, Mg(H2O)62+, in nuclear magnetic resonance (NMR) structural studies. The pseudoknot causes efficient -1 ribosomal frameshifting in mouse mammary tumor virus. Divalent metal ions, such as Mg2+, are critical for RNA structure and function; Mg2+preferentially stabilizes the pseudoknot relative to its constituent hairpins. The use of Co(NH3)63+as a substitute for Mg2+was investigated by ultraviolet absorbance melting curves, NMR titrations of the imino protons, and analysis of NMR spectra in the presence of Mg2+or Co (NH3)63+. The structure of the pseudoknot-Co(NH3)63+complex reveals an ion-binding pocket formed by a short, two-nucleotide loop and the major groove of a stem. Co(NH3)63+stabilizes the sharp loop-to-stem turn and reduces the electrostatic repulsion of the phosphates in three proximal strands. Hydrogen bonds are identified between the Co(NH3)63+protons and non-bridging phosphate oxygen atoms, 2' hydroxyl groups, and nitrogen and oxygen acceptors on the bases. The binding site is significantly different from that previously characterized in the major groove surface of tandem G.U base-pairs, but is similar to those observed in crystal structures of a fragment of the 5 S rRNA and the P5c helix of the Tetrahymena thermophila group I intron. Changes in chemical shifts occurred at the same pseudoknot protons on addition of Mg2+as on addition of Co(NH3)63+, indicating that both ions bind at the same site. Ion binding dissociation constants of approximately 0.6 mM and 5 mM (in 200 mM Na+and a temperature of 15 degrees C) were obtained for Co(NH3)63+and Mg2+, respectively, from the change in chemical shift as a function of metal ion concentration. An extensive array of non-sequence-specific hydrogen bond acceptors coupled with conserved structural elements within the binding pocket suggest a general mode of divalent metal ion stabilization of this type of frameshifter pseudoknot. These results provide new thermodynamic and structural insights into the role divalent metal ions play in stabilizing RNA tertiary structural motifs such as pseudoknots.     

Metal ion requirements for structure and catalysis of an RNA ligase ribozyme

The class I ligase, a ribozyme previously isolated from random sequence, catalyzes a reaction similar to RNA polymerization, positioning its 5'-nucleotide via a Watson-Crick base pair, forming a 3',5'-phosphodiester bond between its 5'-nucleotide and the substrate, and releasing pyrophosphate. Like most ribozymes, it requires metal ions for structure and catalysis. Here, we report the ionic requirements of this self-ligating ribozyme. The ligase requires at least five Mg(2+) for activity and has a [Mg(2+)](1/2) of 70-100 mM. It has an unusual specificity for Mg(2+); there is only marginal activity in Mn(2+) and no detectable activity in Ca(2+), Sr(2+), Ba(2+), Zn(2+), Co(2+), Cd(2+), Pb(2+), Co(NH(3))(6)(3+), or spermine. All tested cations other than Mg(2+), including Mn(2+), inhibit the ribozyme. Hill analysis in the presence of inhibitory cations suggested that Ca(2+) and Co(NH(3))(6)(3+) inhibit by binding at least two sites, but they appear to productively fill a subset of the required sites. Inhibition is not the result of a significant structural change, since the ribozyme assumes a nativelike structure when folded in the presence of Ca(2+) or Co(NH(3))(6)(3+), as observed by hydroxyl-radical mapping. As further support for a nativelike fold in Ca(2+), ribozyme that has been prefolded in Ca(2+) can carry out the self-ligation very quickly upon the addition of Mg(2+). Ligation rates of the prefolded ribozyme were directly measured and proceed at 800 min(-1) at pH 9.0.     

Enthalpy of the B-to-Z conformational transition of a DNA oligonucleotide determined by isothermal titration calorimetry

The influence of high concentrations of Na(+) or [Co(NH(3))(6)](3+) on the conformation of two related DNA oligomers was investigated by circular dichroism spectropolarimetry (CD), isothermal titration calorimetry (ITC), and differential scanning calorimetry (DSC). As revealed by CD, DNA oligomers, (dC-dG)(4) and (dm(5)C-dG)(4), both form right-handed double helical structures (B-DNA) in standard phosphate buffer with 115 mM Na(+) at 25 degrees C. However, at 2.0 M Na(+) or 200 microM [Co(NH(3))(6)](3+), (dm(5)C-dG)(4) assumes a left-handed double helical structure (Z-DNA), whereas the unmethylated (dC-dG)(4) analog remains right-handed under those conditions. ITC was then used to determine the enthalpy change upon increasing the concentration of either Na(+) or [Co(NH(3))(6)](3+) for both DNA oligomers at 25 degrees C. The titration with Na(+) resulted in endothermic isotherms with (dm(5)C-dG)(4) being more endothermic than (dC-dG)(4) by 700 cal/mol basepair. In contrast, titration with [Co(NH(3))(6)](3+) resulted in exothermic isotherms with (dC-dG)(4) being more exothermic than (dm(5)C-dG)(4) by 720 cal/mol basepair. We attribute the enthalpy difference to the conformational transition from B-form DNA to Z-form DNA for (dm(5)C-dG)(4), a transition which does not occur for the unmethylated (dC-dG)(4). The value of approximately 700 cal/mol basepair for the enthalpy of the B-Z transition compares favorably with previously published results obtained by different techniques. DSC was used to monitor the duplex to single strand transitions for both oligomers under the different concentrations. These results indicated that methylation of the cytidine destabilizes (dm(5)C-dG)(4) relative to (dC-dG)(4). Coupling the DSC data with the ITC data allowed construction of a thermodynamic cycle which gives insight into the influence of both temperature and ionic strength on the heat content of the two DNA systems studied. Further, this study reveals the utility of using ITC for determinations of transition enthalpies with the appropriate choice of control.     

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.     

Solution structure of the ActD-5'-CCGTT3GTGG-3' complex: drug interaction with tandem G.T mismatches and hairpin loop backbone

Binding of actinomycin D (ActD) to the seemingly single-stranded DNA (ssDNA) oligomer 5'-CCGTT3 GTGG-3' has been studied in solution using high-resolution nuclear magnetic resonance (NMR) techniques. A strong binding constant (8 x 10(6) M(-1)) and high quality NMR spectra have allowed us to determine the initial DNA structure using distance geometry as well as the final ActD-5'-CCGTT3 GTGG-3' complex structure using constrained molecular dynamics calculations. The DNA oligomer 5'-CCGTT3GTGG-3' in the complex forms a hairpin structure with tandem G.T mismatches at the stem region next to a loop of three stacked thymine bases pointing toward the major groove. Bipartite T2O-GH1 and T2O-G2NH2 hydrogen bonds were detected for the G.T mismatches that further stabilize this unusual DNA hairpin. The phenoxazone chromophore of ActD intercalates nicely between the tandem G.T mismatches in essentially one major orientation. Additional hydrophobic interactions between the ActD quinoid amino acid residues with the loop T5-T6-T7 backbone protons were also observed. The hydrophobic G-phenoxazone-G interaction in the ActD-5'-CCGTT3GTGG-3' complex is more robust than that of the classical ActD- 5'-CCGCT3GCGG-3' complex, consistent with the roughly 2-fold stronger binding of ActD to the 5'-CCGTT3GTGG-3' sequence than to its 5'-CCG CT3GCGG-3' counterpart. Stabilization by ActD of a hairpin containing non-canonical stem base pairs further strengthens the notion that ActD or other related compounds may serve as a sequence- specific ssDNA-binding agent that inhibits human immunodeficiency virus (HIV) and other retroviruses replicating through ssDNA intermediates.     

Impact of phosphorothioate substitutions on the thermodynamic stability of an RNA GAAA tetraloop: an unexpected stabilization

This study analyzes the impact of phosphorothioate substitutions on the thermodynamic stability of a 12-nt RNA hairpin containing a (5')GAAA(3') tetraloop. The thermodynamic consequences of stereospecific phosphorothioate substitutions 5' to each adenosine in the loop region are measured using optical melting and calorimetry experiments. Surprisingly, a single stereospecific phosphorothioate substitution 5' to the second adenosine of the tetraloop, R(p)-A7, results in a stabilization corresponding to a Delta(DeltaG(37)(degrees)(C)) of approximately -2.9 kcal mol(-1) (0.1 M NaCl) when compared with that of an unmodified sample. Five other phosphorothioate-substituted samples did not show significant thermodynamic differences in comparison with the unsubstituted samples. Addition of Mg(2+) to all of the hairpins studied results in increased t(m's) that are fit with a general electrostatic model to a dissociation constant of K(d)(Mg(2+)) approximately 2-3 mM (0.1 M NaCl). The R(p)-A7 phosphorothioate-substituted hairpin showed an unusual decrease in t(m) and apparent increase in enthalpy of unfolding upon addition of Cd(2+). These results may impact the interpretation of interference mapping experiments that use phosphorothioate substitutions to characterize RNAs in solution.     

Metal interactions with a GAAA RNA tetraloop characterized by (31)P NMR and phosphorothioate substitutions

A metal site in a 5'-GAAA-3' tetraloop, a stabilizing and phylogenetically conserved RNA motif, is explored using (31)P NMR spectroscopy and phosphorothioate modifications. Similar to previous reports [Legault, P., and Pardi, A. (1994) J. Magn. Reson., Ser. B 103, 82-86], the (31)P NMR spectrum of a 12-nucleotide stem-loop sequence 5'-GGCCGAAAGGCC-3' exhibits resolved features from each of the phosphodiester linkages. Titration with Mg(2+) results in distinct shifts of a subset of these (31)P features, which are assigned to phosphodiesters 5' to A6, A7, and G5. Titration with Co(NH(3))(6)(3+) causes only a slight upfield shift in the A6 feature, suggesting that changes caused by Mg(2+) are due to inner-sphere metal-phosphate coordination. R(p)-Phosphorothioate substitutions introduced enzymatically 5' to each of the three A residues of the tetraloop provide well-resolved (31)P NMR features that are observed to shift in the presence of Cd(2+) but not Mg(2+), again consistent with a metal-phosphate site. Analysis of (31)P NMR spectra using the sequence 5'-GGGCGAAAGUCC-3' with single phosphorothioate substitutions in the loop region, separated into R(p) and S(p) diastereomers, provides evidence for an inner-sphere interaction with the phosphate 5' to A7 but outer-sphere or structural effects that cause perturbations 5' to A6. Introduction of an R(p)-phosphorothioate 5' to A7 results in a distinct (31)P NMR spectrum, consistent with thermodynamic studies reported in the accompanying paper that indicate a unique structure caused by this substitution. On the basis of these results and existing structural information, a metal site in the 5'-GAAA-3' tetraloop is modeled using restrained molecular dynamics simulations.     

Thermodynamics of RNA hairpins containing single internal mismatches.

Thermodynamic parameters and circular dichroism spectra are presented for RNA hairpins containing single internal mismatches in the stem regions. Three different sequence contexts for the G*U mismatch and two contexts for C*A, G*A, U*U, A*C and U*G mismatches were examined and compared with Watson-Crick base-pair stabilities. The RNA hairpins employed were a microhelix and tetraloop representing the Escherichia coli tRNAAlaacceptor stem and sequence variants that have been altered at the naturally occurring G*U mismatch site. UV melting studies were carried out under different conditions to evaluate the effects of sodium ion concentration and pH on the stability of mismatch-containing hairpins. Our main findings are that single internal mismatches exhibit a range of effects on hairpin stability. In these studies, the size and sequence of the loop and stem are shown to influence the overall stability of the RNA, and have a minor effect on the relative mismatch stabilities. The relationship of these results to RNA-ligand interactions involving mismatch base-pairs is discussed.     

Binding of an aminoacridine derivative to a GAAA RNA tetraloop

RNA tetraloops are common secondary structural motifs in many RNAs, especially ribosomal RNAs. There are few studies of small molecule recognition of RNA tetraloops although tetraloops are known to interact with RNA receptors and proteins, and to form nucleation sites for RNA folding. In this paper, we investigate the binding of neomycin, kanamycin, 2,4-diaminoquinazoline, quinacrine, and an aminoacridine derivative (AD1) to a GAAA tetraloop using fluorescence spectroscopy. We have found that AD1 and quinacrine bind to the GAAA tetraloop with the highest affinity of the molecules examined. The equilibrium dissociation constant of the AD1-GAAA tetraloop complex was determined to be 1.6 microM. RNase I and lead acetate footprinting experiments suggested that AD1 binds to the junction between the loop and stem of the GAAA tetraloop.     

Photoinduced cleavage by a rhodium complex at G.U mismatches and exposed guanines in large and small RNAs

Photoinduced cleavage reactions by the rhodium complex tris(4,7-diphenyl-1,10-phenanthroline)rhodium(III) [Rh(DIP)(3)(3+)] with three RNA hairpins, r(GGGGU UCGCUC CACCA) (16 nucleotide, tetraloop(Ala2)), r(GGGGCUAUAGCUCUAGCUC CACCA) (24 nucleotide, microhelix(Ala)), and r(GGCGGUUAGAUAUCGCC) (17 nucleotide, 790 loop), and full-length (1542 nucleotide) 16S rRNA from Escherichia coli were investigated. The cleavage reactions were monitored by gel electrophoresis and the sites of cleavage by Rh(DIP)(3)(3+) were determined by comparisons with chemical or enzymatic sequencing reactions. In general, RNA backbone scission by the metal complex was induced at G.U mismatches and at exposed G residues. The cleavage activity was observed on the three small RNA hairpins as well as on the isolated 1542-nucleotide ribosomal RNA.