Functional anatomy of a dsRNA trigger: differential requirement for the two trigger strands in RNA interference

In RNA-mediated interference (RNAi), externally provided mixtures of sense and antisense RNA trigger concerted degradation of homologous cellular RNAs. We show that RNAi requires duplex formation between the two trigger strands, that the duplex must include a region of identity between trigger and target RNAs, and that duplexes as short as 26 bp can trigger RNAi. Consistent with in vitro observations, a fraction of input dsRNA is converted in vivo to short segments of approximately 25 nt. Interference assays with modified dsRNAs indicate precise chemical requirements for both bases and backbone of the RNA trigger. Strikingly, certain modifications are well tolerated on the sense, but not the antisense, strand, indicating that the two trigger strands have distinct roles in the interference process.     

The structure of replicating adenovirus 2 DNA molecules

Adenovirus 2 (Ad2)-infected KB cells were exposed to a 2.5 min pulse of ³H-thymidine at 19 hr after infection. The labeled DNA molecules were separated from cell DNA and mature Ad2 DNA by sucrose gradient sedimentation and CsCI equilibrium centrifugation under conditions designed to minimize branch migration and hybridization of single strands. Electron microscopy-of fractions containing radioactivity revealed two basic types of putative replicating molecules: Ad2 length duplex DNA molecules with one or more single-stranded branches (type I) and Ad2 length linear DNA molecules with a single-stranded region extending a variable distance from one end (type II). Length measurements, partial denaturation studies and 3′ terminal labeling experiments were consistent with the following model for Ad2 DNA replication. Initiation of DNA synthesis occurs at or near an end of the Ad2 duplex. Following initiation, a daughter strand is synthesized in the 5′ to 3′ direction, displacing the parental strand with the same polarity. This results in the formation of a branched replicating molecule (type I). Initiations at the right and left molecular ends are approximately equal in frequency, and multiple initiations on the same replicating molecule are common. At any given displacement fork in a type I molecule, only one of the two parental strands is replicated. Two nonexclusive mechanisms are proposed to account for the replication of the other parental strand. In some cases, before completion of a round of displacement synthesis initiated at one end of the Ad2 duplex, a second initiation will occur at the opposite end. In these doubly initiated molecules, both parental strands serve as templates for displacement synthesis. Two type II molecules are generated when the oppositely moving displacement forks meet. Alternatively, displacement synthesis may proceed to the end of the Ad2 duplex, resulting in the formation of a daughter duplex and a parental single strand. Replication of the displaced parental strand is then initiated at or near its 3′ terminus, producing a type II molecule. Daughter strand synthesis proceeds in the 5′ to 3′ direction in type II molecules generated by either mechanism, and completion of synthesis results in the formation of a daughter duplex.     

Polycationic ligands of different chemical classes stimulate DNA strand displacement between short oligonucleotides in a protein‐free system

The ability of polycationic ligands to stimulate DNA strand displacement between short oligonucleotides in a protein‐free system is demonstrated. We show that two ligands, tetracationic aliphatic amine (spermine) and a dicationic intercalating drug (chloroquine), promote strand displacement in a concentration‐dependent manner. At low concentrations both ligands decelerate spontaneous strand displacement because of their impact on the stability of the DNA duplex. At elevated concentrations they accelerate strand displacement via formation of intermediate structures containing three DNA strands. The rate of the last process does not correlate with the thermal dissociation rate of the entire DNA duplex. It indicates that, possibly, the action of these agents cannot be explained by their influence on the stability of the DNA duplex. In general, our results suggest that the ability to stimulate DNA strand displacement appears to be a common feature of polycations of different chemical and structural classes. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 633–641, 2016.     

Concerted strand exchange and formation of Holliday structures by E. coli RecA protein

RecA protein makes stable joint molecules from fully duplex DNA and molecules that are partially single-stranded; the latter may be either duplex molecules with an internal gap in one strand or molecules with single-stranded ends. Stable joint molecules form only when the end of at least one strand is in a homologous region. When RecA protein pairs linear duplex molecules and tailed molecules that share the same sequence end to end, the joints, which are located away from the single-stranded tails in most instances, have the electron microscopic appearance associated with the Holliday structure resulting from the reciprocal exchange of strands. The reaction leading to reciprocal strand exchange involves the concerted displacement of a strand from the end of the duplex molecule. These observations support the view that RecA protein makes stable joint molecules only by transferring strands and not by the side-by-side pairing of duplex regions.     

Pyrimidine motif triplexes containing polypurine RNA or DNA with oligo 2'-O-methyl or DNA triplex forming oligonucleotides

Triplex forming oligonucleotides (TFOs) are potentially useful in targeting RNA for antisense therapeutic applications. To determine the feasibility of targeting polypurine RNA with nuclease-resistant oligonucleotides, TFOs containing 2'-deoxy or 2'-O-methyl (2'-OMe) backbones, designed to form pyrimidine motif triplexes with RNA, were synthesized. TFOs were made which can form trimolecular triplexes, or bimolecular, 'clamp' triplexes with polypurine RNA and DNA. It was found that the relative stabilities of the triplexes formed followed the order: M.DM(clamp)>D.DD approximately M.DD>M. RM>D.DM>M.RD approximately M.DM, where M is a 2'-OMe, D is a DNA and R is an RNA backbone. The third strand is listed first, separated by a dot from the purine strand of the Watson-Crick duplex, followed by the pyrimidine strand of the duplex. The results described here provide insight into the feasibility of using TFOs containing a 2'-OMe backbone as antisense agents.     

Mixed backbone antisense oligonucleotides: design, biochemical and biological properties of oligonucleotides containing 2'-5'-ribo- and 3'-5'-deoxyribonucleotide segments.

We have designed and synthesized mixed backbone oligonucleotides (MBOs) containing 2'-5'-ribo- and 3'-5'-deoxyribonucleotide segments. Thermal melting studies of the phosphodiester MBOs (three 2'-5'linkages at each end) with the complementary 3'-5'-DNA and -RNA target strands suggest that 2'-5'-ribonucleoside incorporation into 3'-5'-oligodeoxyribonucleotides reduces binding to the target strands compared with an all 3'-5'-oligodeoxyribonucleotide of the same sequence and length. Increasing the number of 2'-5'linkages (from six to nine) further reduces binding to the DNA target strand more than the RNA target strand [Kandimalla,E.R. and Agrawal,S. (1996)Nucleic Acids Symp. Ser., 35, 125-126]. Phosphorothioate (PS) analogs of MBOs destabilize the duplex with the DNA target strand more than the duplex with the RNA target strand. Circular dichroism studies indicate that the duplexes of MBOs with the DNA and RNA target strands have spectral characteristics of both A- and B-type conformations. Compared with the control oligonucleotide, MBOs exhibit moderately higher stability against snake venom phosphodiesterase, S1 nuclease and in fetal calf serum. Although 2'-5'modification does not evoke RNase H activity, this modification does not effect the RNase H activation property of the 3'-5'-deoxyribonucleotide segment adjacent to the modification. In vitro studies with MBOs suggest that they have lesser effects on cell proliferation, clotting prolongation and hemolytic complement lysis than do control PS oligodeoxyribonucleotides. PS analogs of MBOs show HIV-1 inhibition comparable with that of a control PS oligodeoxyribonucleotide with all 3'-5'linkages. The current results suggest that a limited number of 2'-5'linkages could be used in conjunction with PS oligonucleotides to further modulate the properties of antisense oligonucleotides as therapeutic agents.     

Homologous pairing of DNA molecules promoted by a protein from Ustilago

A protein from mitotic cells of Ustilago maydis was purified on the basis of its ability to reanneal complementary single strands of DNA. The protein catalyzed the uptake of linear single strands by super-helical DNA, but only in reactions with homologous combinations of single-strand fragments and super-helical DNA from phages phi X174 and fd. No reaction occurred with heterologous combinations. The protein also efficiently paired circular single strands and linear duplex DNA molecules. The product was a joint molecule in which the circular single strand displaced one strand of the duplex. Efficient pairing depended upon ATP, and ATPase activity was found associated with the purified protein. ATP-dependent reannealing of complementary single strands was not detectable in the rec1 mutant of Ustilago, which is deranged in meiotic recombination, as complete tetrads are rare, and is defective in radiation-induced mitotic gene conversion.     

Preparation and melting of single strand circular DNA loops.

A method for preparation of single strand DNA circles of almost arbitrary sequence is described. By ligating two sticky ended hairpins together a linear duplex is formed, closed at both ends by single stranded loops. The melting characteristics of such loops are investigated using optical absorbance and NMR. It is shown by comparison with the corresponding linear sequence (closed circle minus the end loops) that the effects of end fraying and the strand concentration dependence of the melting temperature are eliminated in the circular form. Over the concentration range examined (0.5 to 2.0 micromolar strands), the circular DNA has a monophasic melting curve, while the linear duplex is biphasic, probably due to hairpin formation. Since effects of duplex to single strands dissociation do not contribute to melting of the circular molecules (dumbells), these DNAs present a realistic experimental model for examining local thermal stability in DNA.     

The mechanics of winding and unwinding helices in recombination: torsional stress associated with strand transfer promoted by RecA protein

Homologous recombination usually involves the production of heteroduplex DNA, DNA containing strands contributed from two different duplexes. RecA protein of E. coli can promote the formation of heteroduplex DNA in vitro by the exchange of DNA strands between two helical structures, duplex DNA and a helical recA nucleoprotein filament containing a single strand of DNA. Complete unwinding of the parental duplex and the rewinding of one strand with a new complement requires rotation of the helical structures about one another, or about their respective longitudinal axes. The observations described here demonstrate an association of torsional stress with strand exchange, and suggest that exchange is accomplished principally by concomitant rotation of duplex DNA and the recA nucleoprotein filament, each about its longitudinal axis.     

RNA interference tolerates 2'-fluoro modifications at the Argonaute2 cleavage site

Short interfering RNA (siRNA) molecules with good gene-silencing properties are needed for drug development based on RNA interference (RNAi). An initial step in RNAi is the activation of the RNA-induced silencing complex RISC, which requires degradation of the sense strand of the siRNA duplex. Although various chemical modifications have been introduced to the antisense strand, modifications to the Argonaute2 (Ago2) cleavage site in the sense strand have, so far, not been described in detail. In this work, novel 2'-F-purine modifications were introduced to siRNAs, and their biological efficacies were tested in cells stably expressing human tartrate-resistant acid phosphatase (TRACP). A validated siRNA that contains both purine and pyrimidine nucleotides at the putative Ago2 cleavage site was chemically modified to contain all possible combinations of 2'-fluorinated 2'-deoxypurines and/or 2'-deoxypyrimidines in the antisense and/or sense strands. The capacity of 2'-F-modified siRNAs to knock down their target mRNA and protein was studied, together with monitoring siRNA toxicity. All 2'-F-modified siRNAs resulted in target knockdown at nanomolar concentrations, despite their high thermal stability. These experiments provide the first evidence that RISC activation not only allows 2'-F modifications at the sense-strand cleavage site, but also increase the biological efficacy of modified siRNAs in vitro.     

Effect of salt and RNA structure on annealing and strand displacement by Hfq

The Sm-like protein Hfq promotes the association of small antisense RNAs (sRNAs) with their mRNA targets, but the mechanism of Hfq''s RNA chaperone activity is unknown. To investigate RNA annealing and strand displacement by Hfq, we used oligonucleotides that mimic functional sequences within DsrA sRNA and the complementary rpoS mRNA. Hfq accelerated at least 100-fold the annealing of a fluorescently labeled molecular beacon to a 16-nt RNA. The rate of strand exchange between the oligonucleotides increased 80-fold. Therefore, Hfq is very active in both helix formation and exchange. However, high concentrations of Hfq destabilize the duplex by preferentially binding the single-stranded RNA. RNA binding and annealing were completely inhibited by 0.5 M salt. The target site in DsrA sRNA was 1000-fold less accessible to the molecular beacon than an unstructured oligonucleotide, and Hfq accelerated annealing with DsrA only 2-fold. These and other results are consistent with recycling of Hfq during the annealing reaction, and suggest that the net reaction depends on the relative interaction of Hfq with the products and substrates.     

Exclusion of RNA strands from a purine motif triple helix.

Research concerning oligonucleotide-directed triple helix formation has mainly focused on the binding of DNA oligonucleotides to duplex DNA. The participation of RNA strands in triple helices is also of interest. For the pyrimidine motif (pyrimidine.purine.pyrimidine triplets), systematic substitution of RNA for DNA in one, two, or all three triplex strands has previously been reported. For the purine motif (purine.purine.pyrimidine triplets), studies have shown only that RNA cannot bind to duplex DNA. To extend this result, we created a DNA triple helix in the purine motif and systematically replaced one, two, or all three strands with RNA. In dramatic contrast to the general accommodation of RNA strands in the pyrimidine triple helix motif, a stable triplex forms in the purine motif only when all three of the substituent strands are DNA. The lack of triplex formation among any of the other seven possible strand combinations involving RNA suggests that: (i) duplex structures containing RNA cannot be targeted by DNA oligonucleotides in the purine motif; (ii) RNA strands cannot be employed to recognize duplex DNA in the purine motif; and (iii) RNA tertiary structures are likely to contain only isolated base triplets in the purine motif.     

Triplex formation of chemically modified homopyrimidine oligonucleotides: thermodynamic and kinetic studies.

We have investigated effects of chemical modifications of a third strand on the thermodynamic and kinetic properties of the triplex formation between a 23-bp duplex and each of four kinds of 15-mer chemically modified third strands using isothermal titration calorimetry and interaction analysis system. The chemical modifications of the third strand included one base modification, with replacement of thymine by uracil; two sugar moiety modifications, RNA and 2'-O-methyl-RNA; and one phosphate backbone modification, with replacement of phosphodiester by phosphorothioate backbone. The thermodynamic and kinetic parameters obtained were similar in magnitude at room temperature for the triplex formation with the base-modified and the sugar-modified third strands. By contrast, binding constant for the triplex formation with the third strand containing phosphorothioate backbone was much smaller by a factor of 10 than that for the other triplex formations. Kinetic analyses have also demonstrated that the third strand containing phosphorothioate backbone was much slower in the association step and much faster in the dissociation step than the other third strands, which resulted in the much smaller binding constant. The reason for the instability of the triplex with the third strand containing phosphorothioate backbone will be discussed. We conclude that, at least in the triplex formation with the chemically modified third strands studied in the present work, the modification of phosphate backbone of the third strand produces more significant effect on the triplex formation than the modifications of base and sugar moiety.     

Acceleration of DNA strand exchange by polycation comb-type copolymer.

The accelerating effect of cationic substances on DNA strand exchange reaction between 20 bp DNA duplex and its complementary single strand was studied. A comb-type polycationic copolymer which is composed of poly (L-lysine) backbone and dextran graft chain (PLL-g-Dex) and known to stabilize triplex DNA expedites the strand exchange reaction under physiological relevant conditions. Electrostatically small excess of the copolymer increased DNA strand exchange rate by 300-fold while large excess of spermine or cethyltrimethylammonium bromide, cationic detergent known to promote markedly hybridization of complementary DNA strands, showed slight effect. It should be noted that the copolymer promotes the strand exchange reaction while it stabilizes double stranded DNA.