Control of RNA with quinone methide reversible acylating reagents.

Caging RNA by polyacylation (cloaking) has been developed recently as a simple and rapid method to control the function of RNAs. Previous approaches for chemical reversal of acylation (uncloaking) made use of azide reduction followed by amine cyclization, requiring ∼2-4 h for the completion of cyclization. In new studies aimed at improving reversal rates and yields, we have designed novel acylating reagents that utilize quinone methide (QM) elimination for reversal. The QM de-acylation reactions were tested with two bioorthogonally cleavable motifs, azide and vinyl ether, and their acylation and reversal efficiencies were assessed with NMR and mass spectrometry on model small-molecule substrates as well as on RNAs. Successful reversal both with phosphines and strained alkenes was documented. Among the compounds tested, the azido-QM compound A-3 displayed excellent de-acylation efficiency, with t1/2 for de-acylation of less than an hour using a phosphine trigger. To test its function in RNA caging, A-3 was successfully applied to control EGFP mRNA translation in vitro and in HeLa cells. We expect that this molecular caging strategy can serve as a valuable tool for biological investigation and control of RNAs both in vitro and in cells.

Stable Hg(II)-mediated base pairs with a phenanthroline-derived nucleobase surrogate in antiparallel-stranded DNA.

Metal-mediated base pairs involving artificial nucleobases have emerged as a promising means for the site-specific functionalization of nucleic acids with metal ions. In this context, a GNA-appended (GNA: glycol nucleic acid) nucleoside analogue containing the artificial nucleobase 1H-imidazo[4,5-f][1,10]phenanthroline (P) has already been applied successfully in a variety of homo- and heteroleptic metal-mediated base pairs, mainly involving Ag(I) ions. Herein, we report a thorough investigation of the Hg(II)-binding properties of P when incorporated into antiparallel-stranded DNA duplexes. The artificial nucleobase P is able to form Hg(II)-mediated homoleptic base pairs of the type P-Hg(II)-P with a [2 + 2] coordination environment. In addition, the heteroleptic P-Hg(II)-T pair was investigated. The addition of a stoichiometric amount of Hg(II) to a duplex comprising either a P:P pair or a P:T pair stabilizes the DNA duplex by 4.3 °C and 14.5 °C, respectively. The P-Hg(II)-T base pair, hence, represents the most stabilizing non-organometallic Hg(II)-mediated base pair reported to date. The formation of the Hg(II)-mediated base pairs was investigated by means of temperature-dependent UV spectroscopy and CD spectroscopy.

Concomitant Site-Specific Incorporation of Silver(I) and Mercury(II) Ions into a DNA Duplex.

A GNA (glycol nucleic acid)-based nucleoside analogue containing 1 H-imidazo[4,5-f][1,10]phenanthroline (P) as an artificial nucleobase was used to form a stable mercury(II)-mediated P-HgII -T-H base pair within a parallel-stranded DNA duplex. The nucleobase P shows an affinity towards silver(I) and mercury(II), tuneable through the acidity of the medium when the canonical nucleobase thymine is located in its complementary position. This extraordinary behavior was exploited to enable the concomitant site-specific incorporation of silver(I) and mercury(II) into a DNA scaffold for the first time. This achievement is all the more remarkable because it was made possible by the involvement of only one type of artificial nucleobase. The simultaneous incorporation of two different soft metal ions with a precise control of their respective positions within the nucleic acid scaffold significantly reduces the complexity in the formation of a heterometallic array of metal ions in DNA and thereby facilitates new applications of metal-functionalized nucleic acids.

Stable Copper(I)-Mediated Base Pairing in DNA.

A GNA (glycol nucleic acid) functionalized nucleoside analogue containing the artificial nucleobase 1H-imidazo[4,5-f][1,10]phenanthroline (P) was used to form a copper(I)-mediated base pair within a DNA duplex. The geometrical constraints imposed by the artificial nucleobase play a pivotal role in this unprecedented stabilization of copper(I) in aqueous medium via metal-mediated base pairing. The formation of the copper(I)-mediated base pair was investigated by temperature-dependent UV spectroscopy and CD spectroscopy. The metal-mediated base pair stabilizes the DNA oligonucleotide duplex by 23 °C. A redox chemistry approach confirmed that this base pair formation was due to the incorporation of copper(I) into the duplex. This first report of a copper(I)-mediated base pair adds metal-based diversity to the field and consequently opens up the range of possible applications of metal-modified nucleic acids.

Metal-Mediated Base Pairs: From Characterization to Application.

The investigation of metal-mediated base pairs and the development of their applications represent a prominent area of research at the border of bioinorganic chemistry and supramolecular coordination chemistry. In metal-mediated base pairs, the complementary nucleobases in a nucleic acid duplex are connected by coordinate bonds to an embedded metal ion rather than by hydrogen bonds. Because metal-mediated base pairs facilitate a site-specific introduction of metal-based functionality into nucleic acids, they are ideally suited for use in DNA nanotechnology. This minireview gives an overview of the general requirements that need to be considered when devising a new metal-mediated base pair, both from a conceptual and from an experimental point of view. In addition, it presents selected recent applications of metal-modified nucleic acids to indicate the scope of metal-mediated base pairing.

Sequence-Dependent Duplex Stabilization upon Formation of a Metal-Mediated Base Pair.

An artificial nucleoside surrogate with 1H-imidazo[4,5-f][1,10]phenanthroline (P) acting as an aglycone has been introduced into DNA oligonucleotide duplexes. This nucleoside surrogate can act as a bidentate ligand, and so is useful in the context of metal-mediated base pairs. Several duplexes involving a hetero base pair with an imidazole nucleoside have been investigated. The stability of DNA duplexes incorporating the respective Ag(I) -mediated base pairs strongly depends on the sequence context. Quantum mechanical/molecular mechanical (QM/MM) calculations have been performed in order to gain insight into the factors determining this sequence dependence. The results indicated that, in addition to the stabilizing effect that results from the formation of coordinative bonds, destabilizing effects may occur when the artificial base pair does not fit optimally into the surrounding B-DNA duplex.

Conjugation of RNA via 2'-OH acylation: Mechanisms determining nucleotide reactivity.

The acylation reactivity of RNA 2'-OH groups has proven broadly useful for labeling and mapping RNA. Here we perform kinetics studies to test the mechanisms governing this reaction, and we find strong steric and inductive effects modulating reactivity. The results shed light on new strategies for improved conjugation and mapping.

Single nucleotide translation without ribosomes.

The translation of messenger RNA sequences into polypeptide sequences according to the genetic code is central to life. How this process, which relies on the ribosomal machinery, arose from much simpler precursors is unclear. Here, we demonstrate that single nucleotides charged with an amino acid couple with amino acids linked to the 5'-terminus of an RNA primer in reactions directed by the nucleotides of an RNA template in dilute aqueous solution at 0 °C. When a mixture of U-Val, A-Gly and G-Leu competed for coupling to Gly-RNA, base pairing dictated which dipeptide sequence formed preferentially. The resulting doubly anchored dipeptides can retain their link to the primer for further extension or can be fully released under mild acidic conditions. These results show that a single-nucleotide-based form of translation exists that requires no more than oligoribonucleotides and anchored amino acids.

Templates direct the sequence-specific anchoring of the C-terminus of peptido RNAs.

When amino acids and ribonucleotides react in aqueous condensation buffer, they form peptido RNA with a phosphoramidate bond between the N-terminus of the peptide and the 5'-terminal phosphate of a ribonucleotide. If peptido RNA was the product of spontaneous reactions of amino acids and nucleotides, there must have been a transition to peptidyl tRNAs, where the C-terminus of the peptide is ester-linked to the 2',3'-terminus of an oligonucleotide. Here we report how short peptido RNAs react with the 3'-terminus of oligodeoxynucleotides, templated by RNA strands. In our model system, the rate and yield of the anchoring of the C-terminus of the dipeptido dinucleotides to an amino group was found to depend on the sequence of the peptide, the 5'-terminal nucleotide of the dinucleotide and the RNA template. In all cases tested, highest yields were found for dinucleotides hybridizing next to the primer terminus. For the most reactive species, GlyPro-AA, anchoring yields ranged from 8-99%, depending on the template. When LeuLeu-AA, PhePhe-AA and GlyGly-AA were allowed to compete for anchoring on 3'-UUC-5' as templating sequence, they gave a product ratio of 1 : 2 : 6, and this selectivity was almost independent of the terminal base of the primer. Our results show the control that a simple duplex context has over the covalent anchoring of peptido RNAs at a position known from peptidyl tRNAs. Processes of this type may have bridged the gap between untemplated condensation reactions and the highly specific processes of ribosomal protein synthesis.

A stable zinc(II)-mediated base pair in a parallel-stranded DNA duplex.

A stable zinc(II)-mediated base pair was formed within a parallel-stranded DNA duplex comprising a GNA (glycol nucleic acid) functionalized nucleoside analog containing the artificial nucleobase 1H-imidazo[4,5-f][1,10]phenanthroline (P). The formation of the metal-mediated base pair was confirmed by UV and CD spectroscopic analyses. In the Zn(II)-mediated homo base pairs of the type P-Zn(II)-P, the metal ion adopts a [2 + 2] coordination environment. CD spectroscopic data suggest that the chiral metal complex is formed enantiospecifically, likely induced by the helical chirality of the surrounding DNA duplex. The Zn(II)-mediated base pair stabilizes the DNA oligonucleotide duplex by 9 °C. This stable Zn(II)-mediated base pair within a parallel-stranded duplex extends the scope of site-specific functionalization of nucleic acids by virtue of metal-mediated base pairing.

A metal-mediated base pair that discriminates between the canonical pyrimidine nucleobases.

A nucleoside analogue comprising the ligand 1H-imidazo[4,5-f][1,10]phenanthroline (P) was applied to develop a molecular beacon capable of discriminating the canonical nucleobases cytosine and thymine. The beacon is based on the formation of a stable Ag+-mediated base pair between P and cytosine, whereas the presence of Ag+ strongly destabilizes nucleic acids comprising an artificial base pair between P and thymine. Metal-mediated base pair formation was investigated by temperature-dependent UV spectroscopy and CD spectroscopy and complemented by extensive DFT calculations. The molecular beacon significantly extends the application spectrum of nucleic acids with metal-mediated base pairs. It is of potential use in the detection of single-nucleotide polymorphisms.