Influence of cationic molecules on the hairpin to duplex equilibria of self-complementary DNA and RNA oligonucleotides

A self-complementary nucleotide sequence can form both a unimolecular hairpin and a bimolecular duplex. In this study, the secondary structures of the self-complementary DNA and RNA oligonucleotides with different sequences and lengths were investigated under various solution conditions by gel electrophoresis, circular dichroism (CD) and electron paramagnetic resonance (EPR) spectroscopy and a ultraviolet (UV) melting analysis. The DNA sequences tended to adopt a hairpin conformation at low cation concentrations, but a bimolecular duplex was preferentially formed at an elevated cationic strength. On the other hand, fully matched RNA sequences adopted a bimolecular duplex regardless of the cation concentration. The thermal melting experiments indicated a greater change in the melting temperature of the bimolecular duplexes (by ~20°C) than that of the hairpin (by ~10°C) by increasing the NaCl concentration from 10 mM to 1 M. Hairpin formations were also observed for the palindrome DNA sequences derived from Escherichia coli, but association of the complementary palindrome sequences was observed when spermine, one of the major cationic molecules in a cell, existed at the physiological concentration. The results indicate the role of cations for shifting the structural equilibrium toward a nucleotide assembly and implicate nucleotide structures in cells.     

Loop and stem dynamics during RNA hairpin folding and unfolding

2-Aminopurine (2AP) is a fluorescent adenine analog that probes mainly base stacking in nucleic acids. We labeled the loop or the stem of the RNA hairpin gacUACGguc with 2AP to study folding thermodynamics and kinetics at both loci. Thermal melts and fast laser temperature jumps detected by 2AP fluorescence monitored the stability and folding/unfolding kinetics. The observed thermodynamic and kinetic traces of the stem and loop mutants, though strikingly different at a first glance, can be fitted to the same free-energy landscape. The differences between the two probe locations arise because base stacking decreases upon unfolding in the stem, whereas it increases in the loop. We conclude that 2AP is a conservative adenine substitution for mapping out the contributions of different RNA structural elements to the overall folding process. Molecular dynamics (MD) totaling 0.6 μsec were performed to look at the conformations populated by the RNA at different temperatures. The combined experimental data, and MD simulations lead us to propose a minimal four-state free-energy landscape for the RNA hairpin. Analysis of this landscape shows that a sequential folding model is a good approximation for the full folding dynamics. The frayed state formed initially from the native state is a heterogeneous ensemble of structures whose stem is frayed either from the end or from the loop.     

A highly regioselective C-5 lithiation of uridine: a simple and general entry to 5-substituted uridines

A highly regioselective C-5 lithiation of uridine was accomplished by using 2',3',5'-tris-O-(tert-butyldimethylsilyl)-uridine and sec-BuLi/TMEDA. The reactions of the C-5 lithiated species with various types of electrophiles and subsequent deprotection provide a simple and general entry to 5-substituted uridines.     

Solution structure of a modified 2',5'-linked RNA hairpin involved in an equilibrium with duplex

The isomerization of phosphodiester functionality of nucleic acids from 3′,5′- to a less common 2′,5′-linkage influences the complex interplay of stereoelectronic effects that drive pseudorotational equilibrium of sugar rings and thus affect the conformational propensities for compact or more extended structures. The present study highlights the subtle balance of non-covalent forces at play in structural equilibrium of 2′,5′-linked RNA analogue, 3′-O-(2-methoxyethyl) substituted dodecamer *CG*CGAA*U*U*CG*CG, 3′-MOE-2′,5′-RNA, where all cytosines and uracils are methylated at C5. The NMR and UV spectroscopic studies have shown that 3′-MOE-2′,5′-RNA adopts both hairpin and duplex secondary structures, which are involved in a dynamic exchange that is slow on the NMR timescale and exhibits strand and salt concentration as well as pH dependence. Unusual effect of pH over a narrow physiological range is observed for imino proton resonances with exchange broadening observed at lower pH and relatively sharp lines observed at higher pH. The solution structure of 3′-MOE-2′,5′-RNA hairpin displays a unique and well-defined loop, which is stabilized by Watson–Crick A5·*U8 base pair and by n → π* stacking interactions of O4′ lone-pair electrons of A6 and *U8 with aromatic rings of A5 and *U7, respectively. In contrast, the stem region of 3′-MOE-2′,5′-RNA hairpin is more flexible. Our data highlight the important feature of backbone modifications that can have pronounced effects on interstrand association of nucleic acids.     

Global hairpin folding of tau in solution

The microtubule-associated protein tau stabilizes microtubules in its physiological role, whereas it forms insoluble aggregates (paired helical filaments) in Alzheimer's disease. Soluble tau is considered a natively unfolded protein whose residual folding and intramolecular interactions are largely undetermined. In this study, we have applied fluorescence resonance energy transfer (FRET) and electron paramagnetic resonance (EPR) to examine the proximity and flexibility of tau domains and the global folding. FRET pairs spanning the tau molecule were created by inserting tryptophans (donor) and cysteines (labeled with IAEDANS as an acceptor) by site-directed mutagenesis. The observed FRET distances were significantly different from those expected for a random coil. Notably, the C-terminal end of tau folds over into the vicinity of the microtubule-binding repeat domain, the N-terminus remains outside the FRET distance of the repeat domain, yet both ends of the molecule approach one another. The interactions between the domains were obliterated by denaturation in GdnHCl. Paramagnetic spin-labels attached in various domains of tau were analyzed by EPR and exhibited a high mobility throughout. The data indicate that tau retains some global folding even in its "natively unfolded" state, combined with the high flexibility of the chain.     

Evidence that folding of an RNA tetraloop hairpin is less cooperative than its DNA counterpart

Hairpin secondary structural elements play important roles in the folding and function of RNA and DNA molecules. Previous work from our lab on small DNA hairpin loop motifs, d(cGNAg) and d(cGNABg) (where B is C, G, or T), showed that folding is highly cooperative and obeys indirect coupling, consistent with a concerted transition. Herein, we investigate folding of the related, exceptionally stable RNA hairpin motif, r(cGNRAg) (where R is A or G). Previous NMR characterization identified a complex network of seven hydrogen bonds in this loop. We inserted three carbon (C3) spacers throughout the loop and found coupling between G1 of the loop and the CG closing base pair, similar to that found in DNA. These data support a GNRA motif being expandable at any position but before the G. Thermodynamic measurements of nucleotide-analogue-substituted oligonucleotides revealed pairwise-coupling free energies ranging from weak to strong. When coupling free energies were remeasured in the background of changes at a third site, they remained essentially unchanged even though all of the sites were coupled to each other. This type of coupling, referred to as "direct", is peculiar to the RNA loop. The data suggest that, for small stable loops, folding of RNA obeys a model with nearest-neighbor interactions, while folding of DNA follows a more concerted process in which the stabilizing interactions are linked through a conformational change. The lesser cooperativity in RNA loops may provide a more robust loop that can withstand mutations without a severe loss in stability. These differences may enhance the ability of RNA to evolve.     

Understanding the folding mechanism of an alpha-helical hairpin

The alpha-helical hairpin is the fundamental building block of the widespread helix-turn-helix DNA binding motif. With two antiparallel helices connected by a reverse turn, the alpha-helical hairpin structure may be regarded as a "supersecondary structural element" and, therefore, could exhibit rather unique folding properties. So far, the folding mechanism of alpha-helical hairpins has not been studied in detail and remains elusive. Herein, we examine the effects of the turn, the hydrophobic cluster, and a disulfide cross-linker on the folding kinetics of a designed alpha-helical hairpin, Z34C, using an infrared temperature-jump (T-jump) method in conjunction with site-specific mutagenesis. Our results show that Z34C folds with an ultrafast rate ( approximately 4.0 x 10(5) s(-1)) and support a folding mechanism in which the rate-limiting step corresponds to the formation of the reverse turn. On the other hand, the hydrophobic cluster and the disulfide cross-linker appear to largely stabilize the native state but not the folding transition state.     

Helical junctions as determinants for RNA folding: origin of tertiary structure stability of the hairpin ribozyme

Helical junctions are ubiquitous structural elements that govern the folding and tertiary structure of RNAs. The tobacco ringspot virus hairpin ribozyme consists of two helix-loop-helix elements that lie on adjacent arms of a four-way junction. In the active form of the hairpin ribozyme, the loops are in proximity. The nature of the helical junction determines the stability of the hairpin ribozyme tertiary structure [Walter, N. G., Burke, J. M., and Millar, D. P. (1999) Nat. Struct. Biol. 6, 544-549] and thus its catalytic activity. We used two-, three-, and four-way junction hairpin ribozymes as model systems to investigate the thermodynamic basis for the different tertiary structure stabilities. The equilibrium between docked and extended conformers was analyzed as a function of temperature using time-resolved fluorescence resonance energy transfer (trFRET). As the secondary and tertiary structure transitions overlap, information from UV melting curves and trFRET had to be combined to gain insight into the thermodynamics of both structural transitions. It turned out that the higher tertiary structure stability observed in the context of a four-way junction is the result of a lower entropic cost for the docking process. In the two- and three-way junction ribozymes, a high entropic cost counteracts the favorable enthalpic term, rendering the docked conformer only marginally stable. Thus, two- and three-way junction tertiary structures are more sensitive toward regulation by ligands, whereas four-way junctions provide a stable scaffold. Altogether, RNA folding and stability appear to be governed by principles similar to those for the folding of proteins.     

Two-step cleavage of hairpin RNA with 5' overhangs by human DICER

Background  

DICER is an RNase III family endoribonuclease that processes precursor microRNAs (pre-miRNAs) and long double-stranded RNAs, generating microRNA (miRNA) duplexes and short interfering RNA duplexes with 20~23 nucleotides (nts) in length. The typical form of pre-miRNA processed by the Drosha protein is a hairpin RNA with 2-nt 3' overhangs. On the other hand, production of mature miRNA from an endogenous hairpin RNA with 5' overhangs has also been reported, although the mechanism for this process is unknown.     

A NMR strategy to unambiguously distinguish nucleic acid hairpin and duplex conformations applied to a Xist RNA A-repeat

All RNA sequences that fold into hairpins possess the intrinsic potential to form intermolecular duplexes because of their high self-complementarity. The thermodynamically more stable duplex conformation is favored under high salt conditions and at high RNA concentrations, posing a challenging problem for structural studies of small RNA hairpin conformations. We developed and applied a novel approach to unambiguously distinguish RNA hairpin and duplex conformations for the structural analysis of a Xist RNA A-repeat. Using a combination of a quantitative HNN-COSY experiment and an optimized double isotope-filtered NOESY experiment we could define the conformation of the 26-mer A-repeat RNA. In contrast to a previous secondary structure prediction of a double hairpin structure, the NMR data show that only the first predicted hairpin is formed, while the second predicted hairpin mediates dimerization of the A-repeat by duplex formation with a second A-repeat. The strategy employed here will be generally applicable to identify and quantify populations of hairpin and duplex conformations and to define RNA folding topology from inter- and intra-molecular base-pairing patterns.     

Rapid one-step construction of hairpin RNA

Hairpin RNA (hpRNA) is commonly used for gene-function exploration and gene engineering. In this study, a novel method was developed to construct intron-containing hairpin RNA (ihpRNA) rapidly and efficiently based on Overlap Extension PCR (OE-PCR). This method, Mixed One-step OE-PCR (MOOE-PCR), can amplify two inverted repeats of DNA fragments and a spliceable intron in parallel, and then assemble them to generate ihpRNA constructs in the same tube without the purification of intermediate products. This method required a PCR process of 38-40 cycles and ordinary PCR reagents. A total of 10 ihpRNA constructs were amplified successfully using this method, with the stems ranging from 50 bp to 484 bp in length. Our results suggest that this novel method is a useful strategy for constructing ihpRNA.     

Selection for fitness versus selection for robustness in RNA secondary structure folding

I investigate the competition between two quasispecies residing on two disparate neutral networks. Under the assumption that the two neutral networks have different topologies and fitness levels, it is the mutation rate that determines which quasispecies will eventually be driven to extinction. For small mutation rates, I find that the quasispecies residing on the neutral network with the lower replication rate will disappear. For higher mutation rates, however, the faster replicating sequences may be outcompeted by the slower replicating ones if the connection density on the second neutral network is sufficiently high. The analytical results are in excellent agreement with flow-reactor simulations of replicating RNA sequences.     

Stable hairpin structure within the 5''-terminal 85 nucleotides of poliovirus RNA.

The primary sequence of a 5'-terminal fragment of poliovirus type 1 RNA, generated by digestion with RNase III, has been determined. This sequence reveals the presence of a stable hairpin structure beginning nine nucleotides from the terminally linked protein VPg. The sequence does not contain (i) the initiation codons AUG or GUG or (ii) the putative ribosome-binding sequence complementary to the 3' end of eucaryotic ribosomal 18S RNA. The stem-and-loop structure identified can be drawn in either plus or minus RNA strands. It is unclear to which strand functional significance (if any) can be assigned. It is possible that the hairpin structure is involved in ribosomal recognition and translation or in RNA synthesis by interacting with replicase molecules.     

Overexpression of exportin 5 enhances RNA interference mediated by short hairpin RNAs and microRNAs

Plasmids or viral vectors that express short hairpin RNAs (shRNAs) have emerged as important tools for the stable inhibition of specific genes by RNA interference. shRNAs are structural and functional homologs of pre-microRNAs, intermediates in the production of endogenously encoded microRNAs (miRNAs). Therefore, overexpressed shRNAs could inhibit miRNA function by competing for a limiting level of one or more factors involved in miRNA biogenesis or function. Here, we demonstrate that overexpressed shRNAs can saturate the activity of endogenous Exportin 5, a factor required for nuclear export of both shRNAs and pre-miRNAs. While shRNA overexpression can therefore inhibit miRNA function, simultaneous overexpression of Exportin 5 reverses this effect. Moreover, Exportin 5 overexpression can significantly enhance RNA interference mediated by shRNAs. These data have implications for the future clinical utilization of shRNAs and also provide a simple method to enhance RNA interference by shRNAs in culture.     

Metal ion binding and the folding of the hairpin ribozyme

The hairpin ribozyme comprises two formally unpaired loops carried on two arms of a four-way helical RNA junction. Addition of divalent metal ions brings about a conformational transition into an antiparallel structure in which there is an intimate association between the loops to generate the active form of the ribozyme. In this study, we have used fluorescence resonance energy transfer to analyze the global folding of the complete ribozyme, and the simple four-way junction derived from it, over a wide concentration range of divalent and monovalent metal ions. The simple junction undergoes an ion-induced rotation into an antiparallel form. In the presence of a constant background concentration of sodium ions, the magnesium-ion-induced transition is characterized by noncooperative binding with a Hill coefficient n = 1. By contrast, the magnesium-ion-induced folding of the complete ribozyme is more complex, involving two distinct binding phases. The first phase occurs in the micromolar range, and involves the cooperative binding of at least three magnesium ions. This can also be achieved by high concentrations of sodium ions, and is therefore likely to be due to diffuse binding of cations at the junction and the interface of the loop-loop interaction. The second phase occurs in the millimolar range, and can only be induced by divalent metal ions. This transition occurs in response to the noncooperative, site-specific binding of magnesium ions. We observe a good correlation between the extent of ion-induced folding and cleavage activity.     

Identification of high-stringency DNA hairpin probes by partial gene folding

Hairpin DNA sequences are widely used as probes for oligonucleotides in a broad range of assays, often as "molecular beacons". A potential disadvantage of the standard methodology for molecular beacon design is the need to add several self-complementary bases to each end of the probe, since these do not correspond to the target sequence. We describe a conceptually new method of hairpin DNA probe identification, in which a secondary structure prediction algorithm is employed to identify oligonucleotide sequences within an expressed gene having the requisite hairpin structure. Intuitively, such probes should have significantly improved performance over "traditional" hairpin probes, because they are fully complementary with the target. We present experimental evidence verifying this hypothesis for a series of hairpin probes targeting the pag gene of Bacillus anthracis.     

Characterization of RNA hairpin loop stability.

Fifteen RNA hairpins that share the same stem sequence and have homopolymer loops of A, C and U residues which vary in length from three to nine nucleotides were synthesized and their thermal stabilities determined. Tm varies as a function of loop size but is almost independent of loop composition. Loops of four or five nucleotides are found to be the most stable loop size. This is consistent with the observation that four-membered loops are the most prevalent loop size in 16S-like RNAs. The contribution of each loop to hairpin stability was calculated by subtracting the known contribution of the helical stem. These data should be useful for predicting the stability of other hairpins.