NMR studies of the conformational effect of single and double 3'-S-phosphorothiolate substitutions within deoxythymidine trinucleotides

Stabilization of a Bimolecular Triplex by 3'-S-Phosphorothiolate Modifications: An NMR and UV Thermal Melting Investigation

Triplexes formed from oligonucleic acids are key to a number of biological processes. They have attracted attention as molecular biology tools and as a result of their relevance in novel therapeutic strategies. The recognition properties of single-stranded nucleic acids are also relevant in third-strand binding. Thus, there has been considerable activity in generating such moieties, referred to as triplex forming oligonucleotides (TFOs). Triplexes, composed of Watson-Crick (W-C) base-paired DNA duplexes and a Hoogsteen base-paired RNA strand, are reported to be more thermodynamically stable than those in which the third strand is DNA. Consequently, synthetic efforts have been focused on developing TFOs with RNA-like structural properties. Here, the structural and stability studies of such a TFO, composed of deoxynucleic acids, but with 3'-S-phosphorothiolate (3'-SP) linkages at two sites is described. The modification results in an increase in triplex melting temperature as determined by UV absorption measurements. (1) H NMR analysis and structure generation for the (hairpin) duplex component and the native and modified triplexes revealed that the double helix is not significantly altered by the major groove binding of either TFO. However, the triplex involving the 3'-SP modifications is more compact. The 3'-SP modification was previously shown to stabilise G-quadruplex and i-motif structures and therefore is now proposed as a generic solution to stabilising multi-stranded DNA structures.

Thermal stabilisation of RNA·RNA duplexes and G-quadruplexes by phosphorothiolate linkages

The effect of 3'-S-phosphorothiolate linkages on the stability of RNA·RNA duplexes and G-quadruplex structures has been studied. 3'-Thio-2'-deoxyuridine was incorporated into RNA duplexes and thermal melting studies revealed that the resulting 3'-S-phosphorothiolate linkages increased the stability of the duplex to thermal denaturation. Additionally, and contrary to expectation, a similar effect on duplex stability was observed when the same thionucleoside was incorporated into the RNA strand of a RNA·DNA duplex. A suitably protected derivative of 3'-thio-2'-deoxyguanosine was prepared using an oxidation-reduction strategy and this residue also increased the thermal stability the [d(TGGGGT)](4) G-quadruplex when positioned centrally. The results are discussed in terms of the influence that the sulfur atom has on the conformation of the furanose ring and imply that the previously noted high thermal stability of parallel RNA quadruplexes is not derived from H-bonding interactions of the 2'-hydroxyl group, but can be attributed to conformational effects.

Synthesis, properties, and applications of oligonucleotides containing an RNA dinucleotide phosphorothiolate linkage

RNA represents a prominent class of biomolecules. Present in all living systems, RNA plays many essential roles in gene expression, regulation, and development. Accordingly, many biological processes depend on the accurate enzymatic processing, modification, and cleavage of RNA. Understanding the catalytic mechanisms of these enzymes therefore represents an important goal in defining living systems at the molecular level. In this context, RNA molecules bearing 3'- or 5'-S-phosphorothiolate linkages comprise what are arguably among the most incisive mechanistic probes available. They have been instrumental in showing that RNA splicing systems are metalloenzymes and in mapping the ligands that reside within RNA active sites. The resulting models have in turn verified the functional relevance of crystal structures. In other cases, phosphorothiolates have offered an experimental strategy to circumvent the classic problem of kinetic ambiguity; mechanistic enzymologists have used this tool to assign precise roles to catalytic groups as general acids or bases. These insights into macromolecular function are enabled by the synthesis of nucleic acids bearing phosphorothiolate linkages and the unique chemical properties they impart. In this Account, we review the synthesis, properties, and applications of oligonucleotides and oligodeoxynucleotides containing an RNA dinucleotide phosphorothiolate linkage. Phosphorothioate linkages are structurally very similar to phosphorothiolate linkages, as reflected in the single letter of difference in nomenclature. Phosphorothioate substitutions, in which sulfur replaces one or both nonbridging oxygens within a phosphodiester linkage, are now widely available and are used routinely in numerous biochemical and medicinal applications. Indeed, synthetic phosphorothioate linkages can be introduced readily via a sulfurization step programmed into automated solid-phase oligonucleotide synthesizers. In contrast, phosphorothiolate oligonucleotides, in which sulfur replaces a specific 3'- or 5'-bridging oxygen, have presented a more difficult synthetic challenge, requiring chemical alterations to the attached sugar moiety. Here we begin by outlining the synthetic strategies used to access these phosphorothiolate RNA analogues. The Arbuzov reaction and phosphoramidite chemistry are often brought to bear in creating either 3'- or 5'-S-phosphorothiolate dinucleotides. We then summarize the responses of the phosphorothiolate derivatives to chemical and enzymatic cleavage agents, as well as mechanistic insights their use has engendered. They demonstrate particular utility as probes of metal-ion-dependent phosphotransesterification, general acid-base-catalyzed phosphotransesterification, and rate-limiting chemistry. The 3'- and 5'-S-phosphorothiolates have proven invaluable in elucidating the mechanisms of enzymatic and nonenzymatic phosphoryl transfer reactions. Considering that RNA cleavage represents a fundamental step in the maturation, degradation, and regulation of this important macromolecule, the significant synthetic challenges that remain offer rich research opportunities.