Terminus-free siRNA prepared by photo-crosslinking activated via slicing by Ago2

We report the development of photo-crosslinked siRNA strands modified at each terminus with p-cyanostilbene. The siRNA was nuclease resistant and retained RNAi activity. We further studied the activation mechanism of the covalently-crosslinked siRNA. Interestingly Dicer, which is known to generate siRNA with overhanging 3' ends from the precursor siRNA, did not cleave the crosslinked siRNA at all. Our results suggest that the activation of the crosslinked siRNAs required cleavage by Argonaute2.

The role of duplex stability for wavelength-shifting fluorescent DNA probes: energy transfer vs. exciton interactions in DNA "traffic lights"

Exciton interactions between thiazole orange and thiazole red as nucleotide substitutes in DNA hairpins interfere with efficient energy transfer and fluorescence color change as readout. This interference can be tuned by two structural parameters that control the hairpin duplex stability.

Enhancement of stability and activity of siRNA by terminal substitution with serinol nucleic acid (SNA)

RNA interference (RNAi ), sequence-specific gene silencing triggered by double-stranded, small interfering RNA (siRNA), has become a facile and effective tool for biological research and holds potential for therapeutic applications. However, the application of siRNA is hindered by susceptibility to nucleases and off-target effects. In this study, we introduced artificial nucleotides, serinol nucleic acid (SNA), with an acyclic scaffold, at the termini of siRNA strands. Our aim was appropriately to accommodate the antisense strand in an RNA-induced silencing complex (RISC) by inhibiting sense-strand incorporation and thus improve resistance to nuclease-mediated degradation. Substitution of SNA into siRNA at both termini of the sense strand and at the 3' terminus of the antisense strand improved antisense strand selectivity remarkably in the formation of RISC, RNAi activity, and nuclease resistance.

De novo design of functional oligonucleotides with acyclic scaffolds

In this account, we demonstrate a new methodology for the de novo design of functional oligonucleotides with the acyclic scaffolds threoninol and serinol. Four functional motifs-wedge, interstrand-wedge, dimer, and cluster-have been prepared from natural DNA or RNA and functional base surrogates prepared from d-threoninol. The following applications of these motifs are described: (1) photoregulation of formation and dissociation of a DNA duplex modified with azobenzene, (2) sequence-specific detection of DNA using a fluorescent probe, (3) formation of fluorophore assemblies that mimic quantum dots, (4) improved strand selectivity of siRNA modified with a base surrogate, and (5) in vivo tracing of the RNAi pathway. Finally, we introduce artificial nucleic acids (XNAs) prepared from d-threoninol and serinol functionalized with each of the four nucleobases, which have unique properties compared with other acyclic XNAs. Functional oligonucleotides designed from acyclic scaffolds will be powerful tools for both DNA nanotechnology and biotechnology.

Reversed assembly of dyes in an RNA duplex compared with those in DNA

We prepared reversed dye clusters by hybridizing two RNA oligomers, each of which tethered dyes (Methyl Red, 4'-methylthioazobenzene, and thiazole orange) on D-threoninols (threoninol nucleotides) at the center of their strands. NMR spectroscopic analyses revealed that two dyes from each strand were axially stacked in an antiparallel manner to each other in the duplex, and were located adjacent to the 3'-side of a natural nucleobase. Interestingly, this positional relationship of the dyes was completely the opposite of that assembled in DNA that we reported previously: dyes in DNA were located adjacent to the 5'-side of a natural nucleobase. This observation was also consistent with the circular dichroism of dimerized dyes in which the Cotton effect of the dyes (i.e., the winding properties of two dyes) was inverted in RNA relative to that in DNA. Further spectroscopic analyses revealed that clustering of the dyes on RNA duplexes induced distinct hypsochromicity and narrowing of the band, thus demonstrating that the dyes were axially stacked (i.e., H-aggregates) even on an A-type helix. On the basis of these results, we also prepared heterodimers of a fluorophore (thiazole orange) and quencher (Methyl Red) in an RNA duplex. Fluorescence from thiazole orange was found to be strongly quenched by Methyl Red due to the excitonic interaction, so that the ratio of fluorescent intensities of the RNA-thiazole orange conjugate with and without its complementary strand carrying a quencher became as high as 27. We believe that these RNA-dye conjugates are potentially useful probes for real-time monitoring of RNA interference (RNAi) mechanisms.

Modification of the siRNA passenger strand by 5-nitroindole dramatically reduces its off-target effects

During the formation of RNA-induced silencing complex (RISC), the passenger and guide strand of an siRNA duplex separate from each other to generate an active RISC complex. Accumulating evidence shows that an siRNA passenger strand can also assemble into a RISC complex and mediate RNA interference, thereby causing undesired off-target effects. To reduce this effect, the so-called "universal base" 5-nitroindole nucleotides were incorporated into an siRNA passenger strand. Melting temperature and circular dichroism spectrum measurements showed no significant changes compared to the unmodified duplex, thus indicating the formation of normal A-form conformation. Using a dual luciferase reporter assay, we have further shown that 5-nitroindole modification at position 15 of the siRNA passenger strand drastically decreased the RNAi (RNA interfering) potency of this strand, whereas the potency of the RNA guide strand was not much affected. These results could provide a practical approach for reducing off-target effects mediated by the siRNA passenger strand.