A base-triple structural domain in RNA

Crystal Structure of an RNA Duplex [r(gugcaca)dC](2) with 3'-Dinucleoside Overhangs Forming a Superhelix

Abstract Crystal structure of the RNA octamer duplex, [r(gugcaca)dC] (2), with space group I2(1)2(1)2(1) and the cell constants a=24.29, b=45.25 and c=73.68Å, has been determined and refined. The structural and packing architecture of the molecule consist of a highly bent six base paired duplex forming a right-handed superhelix stacked in tandem compared to an infinite pseudo- continuous column as is usually present in RNA crystal structures. The super helix could be formed by the head-to-head stacking (g1 over g1 and g9 over g9), the large bend and the twists at the junctions may also be responsible. The sugar-phosphate backbones of the 3'-end dinucleoside overhangs snuggly fit into the minor grooves of adjacent double helical stacks. The 3'-terminal deoxycytidines form antiparallel hemiprotonated trans (C·C)(+) pairs with symmetry related deoxycytidines, while the penultimate adenines form base triples (a*g·c) with the capping g·c base pairs of the hexamer duplex with the adenine (a7) at one end being syn and at the other anti. These triple interactions are the same as those found in the tetrahymena ribozyme and group I intron.

The emerging role of triple helices in RNA biology

The ability of RNA to form sophisticated secondary and tertiary structures enables it to perform a wide variety of cellular functions. One tertiary structure, the RNA triple helix, was first observed in vitro over 50 years ago, but biological activities for triple helices are only beginning to be appreciated. The recent determination of several RNA structures has implicated triple helices in distinct biological functions. For example, the SAM-II riboswitch forms a triple helix that creates a highly specific binding pocket for S-adenosylmethionine. In addition, a triple helix in the conserved pseudoknot domain of the telomerase-associated RNA TER is essential for telomerase activity. A viral RNA cis-acting RNA element called the ENE contributes to the nuclear stability of a viral noncoding RNA by forming a triple helix with the poly(A) tail. Finally, a cellular noncoding RNA, MALAT1, includes a triple helix at its 3'-end that contributes to RNA stability, but surprisingly also supports translation. These examples highlight the diverse roles that RNA triple helices play in biology. Moreover, the dissection of triple helix mechanisms has the potential to uncover fundamental pathways in cell biology.

Propensities for loop structures of RNA & DNA backbones

RNA oligonucleotides exhibit a large tendency to bend and form a loop conformation which is a major motif contributing to their complex three-dimensional structure. This is in contrast to DNA molecules that predominantly form the double-helix structure. In this paper we investigate by molecular dynamics simulation, as well as, by its combination with the replica-exchange method, the propensity of RNA chains containing the GCUAA pentaloop to form spontaneously a hairpin conformation. The results were then compared with those of analogous hybrid oligonucleotides in which the ribose groups in the loop-region were substituted by deoxyriboses. We find that the RNA oligomers exhibit a marginal excess stability to form loop structures. The equilibrium constant for opening the loop to an extended conformation is twice as large in the hybrid than it is in the RNA chain. Analyses of the hydrogen bonds indicate that the excess stability for forming a hairpin is a result of hydrogen bonds the 2'-hydroxyls in the loop region form with other groups in the loop. Of these hydrogen bonds, the most important is the hydrogen bond donated from the 2'-OH at the first position of the loop to N7 of adenine at the forth position. RNA and DNA backbones are characterized by different backbone dihedral angles and sugar puckering that can potentially facilitate or hamper the hydrogen bonds involving the 2'-OH. Nevertheless, the sugar puckerings of all the pentaloop nucleotides were not significantly different between the two chains displaying the C3'-endo conformation characteristic to the A-form double helix. All of the other backbone dihedrals also did not show any considerable difference in the loop-region except of the δ-dihedral. In this case, the RNA loop exhibited bimodal distributions corresponding to, both, the RNA and DNA backbones, whereas the loop of the hybrid chain behaved mostly as that of a DNA backbone. Thus, it is possible that the behavior of the δ-dihedrals in the loop-region of the RNA adopts conformations that facilitate the intra-nucleotide hydrogen bondings of the 2'-hydroxyls, and consequently renders loop structures in RNA more stable.

The GA-minor submotif as a case study of RNA modularity, prediction, and design

Complex natural RNAs such as the ribosome, group I and group II introns, and RNase P exemplify the fact that three-dimensional (3D) RNA structures are highly modular and hierarchical in nature. Tertiary RNA folding typically takes advantage of a rather limited set of recurrent structural motifs that are responsible for controlling bends or stacks between adjacent helices. Herein, the GA minor and related structural motifs are presented as a case study to highlight several structural and folding principles, to gain further insight into the structural evolution of naturally occurring RNAs, as well as to assist the rational design of artificial RNAs.

Ribose 2'-Hydroxyl Groups Stabilize RNA Hairpin Structures Containing GCUAA Pentaloop

The chemical structure of RNA and DNA is very similar; however, the three-dimensional conformation of these two nucleic acids is very different. Whereas the DNA adopts a repetitive structure of a double-stranded helix, RNA is primarily single stranded with a complex three-dimensional structure in which the hairpin is the most common secondary structure. Apart from the difference between uracil and thymine, the difference in the chemical structure between RNA and DNA is the presence of a hydroxyl group at position 2' of the sugar (ribose) instead of a hydrogen (deoxyribose). In this paper, we present molecular dynamics simulations addressing the contribution of 2'-hydroxyls to the stability of a GCUAA pentaloop motif. The results indicate that the 2'-hydroxyls stabilize the hairpin conformation of the GCUAA pentaloop relative to an analogous oligonucleotide in which the ribose sugars in the loop region were substituted with deoxyriboses. The magnitude of the stabilization was found to be 23.8 ± 4.1 kJ/mol using an alchemical mutations free energy method and 4.2 ± 6.5 kJ/mol using potential of mean force calculations. The latter indicates that in addition to its larger thermodynamic stability the RNA hairpin is also kinetically more stable. We find that the excess stability is a result of intrahairpin hydrogen bonds in the loop region between the 2'-hydroxyls and sugars, bases, and phosphates. The hydrogen bonds with the sugars and phosphates involve predominantly interactions with adjacent nucleotides. However, the hydrogen bonds with the bases involve also interactions between groups on opposite sides of the loop or with the middle base of the loop and are therefore likely to contribute significantly to the stability of the loop. Of these hydrogen bonds, the most frequent is observed between the 2'-hydroxyl at the first position of the pentaloop with N6/N7 of adenine at the forth position, as well as between the 2'-hydroxyl at position -1 with N6 of adenine at the fifth position. Our results contribute to the notion that one of the important roles of the ribose sugars in RNA is to facilitate hairpin formation.

Biophysical characterization of the strong stabilization of the RNA triplex poly(U)•poly(A)*poly(U) by 9-O-(ω-amino) alkyl ether berberine analogs

BACKGROUND

Binding of two 9-O-(ω-amino) alkyl ether berberine analogs BC1 and BC2 to the RNA triplex poly(U)(•)poly(A)(*)poly(U) was studied by various biophysical techniques.

METHODOLOGY/PRINCIPAL FINDINGS

Berberine analogs bind to the RNA triplex non-cooperatively. The affinity of binding was remarkably high by about 5 and 15 times, respectively, for BC1 and BC2 compared to berberine. The site size for the binding was around 4.3 for all. Based on ferrocyanide quenching, fluorescence polarization, quantum yield values and viscosity results a strong intercalative binding of BC1 and BC2 to the RNA triplex has been demonstrated. BC1 and BC2 stabilized the Hoogsteen base paired third strand by about 18.1 and 20.5 °C compared to a 17.5 °C stabilization by berberine. The binding was entropy driven compared to the enthalpy driven binding of berbeine, most likely due to additional contacts within the grooves of the triplex and disruption of the water structure by the alkyl side chain.

CONCLUSIONS/SIGNIFICANCE

Remarkably higher binding affinity and stabilization effect of the RNA triplex by the amino alkyl berberine analogs was achieved compared to berberine. The length of the alkyl side chain influence in the triplex stabilization phenomena.

A deteriorated triple-helical scaffold accelerates formation of the Tetrahymena ribozyme active structure

The Tetrahymena group I ribozyme requires a hierarchical folding process to form its correct three-dimensional structure. Ribozyme activity depends on the catalytic core consisting of two domains, P4-P6 and P3-P7, connected by a triple-helical scaffold. The folding proceeds in the following order: (i) fast folding of the P4-P6 domain, (ii) slow folding of the P3-P7 domain, and (iii) structure rearrangement to form the active ribozyme structure. The third step is believed to directly determine the conformation of the active catalytic domain, but as yet the precise mechanisms remain to be elucidated. To investigate the folding kinetics of this step, we analyzed mutant ribozymes having base substitution(s) in the triple-helical scaffold and found that disruption of the scaffold at A105G results in modest slowing of the P3-P7 folding (1.9-fold) and acceleration of step (iii) by 5.9-fold. These results suggest that disruption or destabilization of the scaffold is a normal component in the formation process of the active structure of the wild type ribozyme.

Interactions of the antiviral quinoxaline derivative 9-OH-B220 [2, 3-dimethyl-6-(dimethylaminoethyl)- 9-hydroxy-6H-indolo-[2, 3-b]quinoxaline] with duplex and triplex forms of synthetic DNA and RNA

The binding of an antiviral quinoxaline derivative, 2,3-dimethyl- 6 - (dimethylaminoethyl) - 9 - hydroxy - 6H - indolo - [2,3 - b]quinoxaline (9-OH-B220), to synthetic double and triple helical DNA (poly(dA).poly(dT) and poly(dA).2poly(dT)) and RNA (poly(rA). poly(rU) and poly (rA).2poly(rU)) has been characterized using flow linear dichroism (LD), circular dichroism (CD), fluorescence spectroscopy, and thermal denaturation. When either of the DNA structures or the RNA duplex serve as host polymers a strongly negative LD is displayed, consistent with intercalation of the chromophoric ring system between the base-pairs/triplets of the nucleic acid structures. Evidence for this geometry also includes weak induced CD signals and strong increments of the fluorescence emission intensities upon binding of the drug to each of these polymer structures. In agreement with intercalative binding, 9-OH-B220 is found to effectively enhance the thermal stability of both the double and triple helical states of DNA as well as the RNA duplex. In the case of poly(dA).2poly(dT), the drug provides an unusually large stabilization of its triple helical state; upon binding of 9-OH-B220 the triplex-to-duplex equilibrium is shifted towards higher temperature by 52.5 deg. C in a 10 mM sodium cacodylate buffer (pH 7.0) containing 100 mM NaCl and 1 mM EDTA. When triplex RNA serves as host structure, LD indicates that the average orientation angle between the drug chromophore plane and the helix axis of the triple helical RNA is only about 60 to 65 degrees. Moreover, the thermal stabilizing capability, as well as the fluorescence increment, CD inducing power and perturbations of the absorption envelope, of 9-OH-B220 in complex with the RNA triplex are all less pronounced than those observed for the complexes with DNA and duplex RNA. These features indicate binding of 9-OH-B220 in the wide and shallow minor groove of poly(rA).2poly(rU). Based on the present results, some implications for the applications of this low-toxic, antiviral and easily administered drug in an antigene strategy, as well as its potential use as an antiretroviral agent, are discussed.

Inhibition of Rev·RRE complexation by triplex tethered oligonucleotide probes

We have described a class of molecules, called tethered oligonucleotide probes (TOPs), that bind RNA on the basis of both sequence and structure. TOPs consist of two short oligonucleotides joined by a tether whose length and composition may be varied using chemical synthesis. In a triplex TOP, one oligonucleotide recognizes a short single-stranded region in a target RNA through the formation of Watson-Crick base pairs; the other oligonucleotide recognizes a short double-stranded region through the formation of Hoogsteen base pairs. Binding of triplex TOPs to an HIV-1 Rev Response Element RNA variant (RREAU) was measured by competition electrophoretic mobility shift analysis. Triplex TOP.RREAU stabilities ranged between -9.6 and -6.1 kcal mol-1 under physiological conditions of pH, salt, and temperature. Although the most stable triplex TOP.RREAU complex contained 12 contiguous U.AU triple helical base pairs, complexes containing only six or nine triple helical base pairs also formed. Triplex TOPs inhibited formation of the RRE.Rev complex with IC50 values that paralleled the dissociation constants of the analogous triplex TOP.RREAU complexes. In contrast to results obtained with TOPs that target two single-stranded RRE regions, inhibition of Rev.RREAU complexation by triplex TOPs did not require pre-incubation of RREAU and a TOP: triplex TOPs competed efficiently with Rev for RREAU and inhibited RREAU.Rev complexation at equilibrium.

Using guanidinium groups for the recognition of RNA and as catalysts for the hydrolysis of RNA

The guanidinium functional group is commonly used in nature to recognize and bind anions through ion pairing and hydrogen bonding. Specific hydrogen-bonding patterns can be found in crystal structures of simple guanidinium salts. Analysis of these simple salts reveals a variety of features which are found in natural systems. These features have been applied to a series of artificial phosphodiesterases for RNA. These receptors incorporate guanidinium groups positioned to mimic the hydrogen-bonding patterns found in simple guanidinium salts and natural enzymes. This paper outlines general guanidinium hydrogen-bonding patterns. Next, the complexation of phosphodiesters with a series of artificial receptors are analyzed in terms of counterions, solvent mixtures, and cavity flexibility. In addition, strategies to enhance catalysis through a pKa analysis of phosphoranes are addressed. Next, we describe how our findings were incorporated into second generation receptors/catalysts. Finally, our future work is discussed.

RNA structure and the regulation of gene expression

RNA secondary and tertiary structure is involved in post-transcriptional regulation of gene expression either by exposing specific sequences or through the formation of specific structural motifs. An overview of RNA secondary and tertiary structures known from biophysical studies is followed by a review of examples of the elements of RNA processing, mRNA stability and translation of the messenger. These structural elements comprise sense-antisense double-stranded RNA, hairpin and stem-loop structures, and more complex structures such as bifurcations, pseudoknots and triple-helical elements. Metastable structures formed during RNA folding pathway are also discussed. The examples presented are mostly chosen from plant systems, plant viruses, and viroids. Examples from bacteria or fungi are discussed only when unique regulatory properties of RNA structures have been elucidated in these systems.

Structural features and stability of an RNA triple helix in solution

A 30 nt RNA with a sequence designed to form an intramolecular triple helix was analyzed by one-and two-dimensional NMR spectroscopy and UV absorption measurements. NMR data show that the RNA contains seven pyrimidine-purine-pyrimidine base triples stabilized by Watson-Crick and Hoogsteen interactions. The temperature dependence of the imino proton resonances, as well as UV absorption data, indicate that the triple helix is highly stable at acidic pH, melting in a single sharp transition centered at 62 degrees C at pH 4.3. The Watson-Crick and Hoogsteen pairings are disrupted simultaneously upon melting. The NMR data are consistent with a structural model where the Watson-Crick paired strands form an A-helix. Results of model building, guided by NMR data, suggest a possible hydrogen bond between the 2' hydroxyl proton of the Hoogsteen strand and a phosphate oxygen of the purine strand. The structural model is discussed in terms of its ability to account for some of the differences in stability reported for RNA and DNA triple helices and provides insight into features that are likely to be important in the design of RNA binding compounds.

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.

An RNA fragment consisting of the P7 and P9.0 stems and the 3'-terminal guanosine of the Tetrahymena group I intron

On the basis of the nucleotide sequence of Tetrahymena group I intron, we constructed a 31 residue RNA that has the P7 stem and the 3'-terminal guanosine residue (3'-G) with a putative stem-loop structure (P9.0) intervening between them. For this model RNA (P7/P9.0/G), four residues around the guanosine binding site (GBS) in the P7 stem were found to exhibit much lower sensitivities to ribonuclease V1 than those of a variant RNA having adenosine in place of the 3'-G, suggesting that the 3'-G contacts around the GBS. NMR analyses of the imino proton resonances of the P7/P9.0/G RNA indicated that the base pairing in the GBS is retained on the interaction with the 3'-G, and that the two base pairs of the putative P9.0 stem-loop are definitely formed. Comparison of the RNA with its variants with either A (3'-A) or a deletion in place of the 3'-G suggested that the stability of the P9.0 stem-loop is affected by the GBS-3'-G interaction. The melting temperatures of the P9.0 stem-loop were determined from the UV absorbances of these RNAs, which quantitatively indicated that the P9.0 stem-loop is significantly stabilized by the interaction of the GBS with the 3'-G, rather than the 3'-A, and also by direct interaction with divalent cations (Mg2+, Ca2+ or Mn2+). Upon replacement of the G-C base pair by C-G in the GBS of the P7/P9.0/G RNA, the specificity was switched from 3'-G to 3'-A, as in the case of the intact intron.

In vitro trans-splicing in Saccharomyces cerevisiae

The interactions established at the 5'-splice site during spliceosome assembly are likely to be important for both precise recognition of the upstream intron boundary and for positioning this site in the active center of the spliceosome. Definition of the RNA-RNA and the RNA-protein interactions at the 5' splice site would be facilitated by the use of a small substrate amenable to modification during chemical synthesis. We describe a trans-splicing reaction performed in Saccharomyces cerevisiae extracts in which the 5' splice site and the 3' splice site are on separate molecules. The RNA contributing the 5' splice site is only 20 nucleotides long and was synthesized chemically. The trans-splicing reaction is accurate and has the same sequence, ATP, and Mg2+ requirements as cis-splicing. We also report how deoxy substitutions around the 5'-splice site affect trans-splicing efficiency.

Structural characterization of an intramolecular RNA triple helix by NMR spectroscopy

A chemically synthesized 29-base RNA oligomer, designed to fold to form an intramolecular triple helix at acid pH, has been studied by NMR spectroscopy. The molecule consisted of seven U.A.U or C+.G.C base triples joined by two pyrimidine tetra-loops. The fold was such that the third strand was Hoogsteen base-paired in the major groove of a Watson-Crick paired double helix. The nature and size of the molecule required the use of an assignment strategy using two- and three-dimensional homonuclear methods, complemented by a natural abundance 13C correlation experiment. The assignment of the majority of the exchangeable and non-exchangeable resonances is presented. The data suggest a C3'-endo sugar puckering for all the nucleotides involved in base triples. A preliminary structural model consistent with the NMR data is presented.

Spectroscopic evidence for an intramolecular RNA triple helix

A 29-base RNA oligomer has been chemically synthesized and shown to form an intramolecular triple helix in solution at acidic pH. Assignment of the majority of the exchangeable proton NMR resonances demonstrated the Watson-Crick and Hoogsteen base pairings consistent with folding to form pyrimidine-purine-pyrimidine base triplets. FTIR spectroscopy provided independent evidence of base triplet formation, and indicated a predominately C3'-endo sugar pucker. UV absorption as a function of temperature suggested monophasic melting behaviour, which was confirmed by NMR of the imino protons.

Coaxially stacked RNA helices in the catalytic center of the Tetrahymena ribozyme

Coaxial stacking of helical elements is a determinant of three-dimensional structure in RNA. In the catalytic center of the Tetrahymena group I intron, helices P4 and P6 are part of a tertiary structural domain that folds independently of the remainder of the intron. When P4 and P6 were fused with a phosphodiester linkage, the resulting RNA retained the detailed tertiary interactions characteristic of the native P4-P6 domain and even required lower magnesium ion concentrations for folding. These results indicate that P4 and P6 are coaxial in the P4-P6 domain and, therefore, in the native ribozyme. Helix fusion could provide a general method for identifying pairs of coaxially stacked helices in biological RNA molecules.

Representation of the secondary and tertiary structure of group I introns

Group I introns, which are widespread in nature, carry out RNA self-splicing. The secondary structure common to these introns was for the most part established a decade ago. Information about their higher order structure has been derived from a range of experimental approaches, comparative sequence analysis, and molecular modelling. This information now provides the basis for a new two-dimensional structural diagram that more accurately represents the domain organization and orientation of helices within the intron, the coaxial stacking of certain helices, and the proximity of key nucleotides in three-dimensional space. It is hoped that this format will facilitate the detailed comparison of group I intron structures.

In vitro genetic analysis of the hinge region between helical elements P5-P4-P6 and P7-P3-P8 in the sunY group I self-splicing intron

Modeling of the group I intron RNA suggests that its catalytic core is primarily composed of two extended structural elements (stacked helices P5-P4-P6 and P7-P3-P8) whose relative orientation is partially determined by base-triple interactions between paired regions P4 and P6, and single-stranded joining regions J6/7 and J3/4, respectively. In vitro genetic selection was used to isolate functional sequence variants of the proposed triple helical domain of the sunY intron. Comparative sequence analysis of the selected variants provided supporting evidence for the two previously established base-triples between P4 and J6/7 and provided the first experimental evidence for an interaction between P6(1) and J3/4(3). Sequence covariations also indicated that a simple relationship exists between the length of a single-stranded joining region, J3/4, and the identity of a particular base-pair, P4(1). Selected variants based on a core structure with an extra nucleotide inserted in J3/4 revealed two different responses to this structural perturbation: a base-triple interaction and an intrahelical bulged pyrimidine. Chemical modification analysis supported the existence of these alternative structures. The function of this region of the ribozyme can therefore be fulfilled by at least three different structures.

An NMR study of the HIV-1 TAR element hairpin

The TAR hairpin is an important part of the 5' long terminal repeat of HIV-1 and appears to be recognized by a cellular protein. A 14-base model of the native TAR hairpin 5'-GAGC[CUGGGA]-GCUC-3' (loop bases in square brackets) has been studied by proton, phosphorus, and natural abundance carbon NMR; these results are compared to other published NMR studies of the TAR hairpin. Assignments of all nonexchangeable protons and of all the stem-exchangeable protons have been made, as well as all phosphorus and many carbon resonances. Large J1'2' and J3'4' proton-proton coupling in the C5, G8, and G9 sugars indicate an equilibrium between C2'- and C3'-endo forms; these data show a dynamic loop structure. We see three broad imino resonances that have not been reported before; these resonances are in the right region for unbonded loop imino protons. These peaks suggest the protons are protected from fast exchange with the solvent by the structure of the hairpin loop. Simulated annealing and molecular dynamics with 148 distance constraints, 11 hydrogen bonds, and 84 torsion angle constraints showed a wide variety of structures. Certain trends are evident, such as continuation of the A-form helix on the 3' side of the hairpin loop. The ensemble of calculated structures agree with most chemical modification data.

Role of RNA structure in arginine recognition of TAR RNA

The human immunodeficiency virus Tat protein binds specifically to an RNA stem-loop structure (TAR) that contains two helical stem regions separated by a three-nucleotide bulge. A single arginine within the basic region of Tat mediates specific binding to TAR, and arginine as the free amino acid also binds specifically to TAR. We have previously proposed a model in which interaction of the arginine guanidinium group with guanosine-26 (G26) and with a pair of phosphates is stabilized by formation of a base triple between U23 in the bulge and A27.U38 in the upper helix. Here we show by NMR spectroscopy that formation of the base triple is critical for arginine binding to TAR. Mutants of TAR that cannot form the base triple or that remove the guanine contact do not bind arginine specifically. These mutants also showed reduced transactivation by Tat. A triple mutant designed to form an isomorphous base triple between C23 and G27.C38 binds arginine and adopts the same conformation as wild-type TAR. These results demonstrate the importance of RNA structure for arginine binding and further demonstrate the direct correspondence between arginine and Tat binding.