Replacing uridine with 2-thiouridine enhances the rate and fidelity of nonenzymatic RNA primer extension.

The nonenzymatic replication of RNA oligonucleotides is thought to have played a key role in the origin of life prior to the evolution of ribozyme-catalyzed RNA replication. Although the copying of oligo-C templates by 2-methylimidazole-activated G monomers can be quite efficient, the copying of mixed sequence templates, especially those containing A and U, is particularly slow and error-prone. The greater thermodynamic stability of the 2-thio-U(s(2)U):A base pair, relative to the canonical U:A base pair, suggests that replacing U with s(2)U might enhance the rate and fidelity of the nonenzymatic copying of RNA templates. Here we report that this single atom substitution in the activated monomer improves both the kinetics and the fidelity of nonenzymatic primer extension on mixed-sequence RNA templates. In addition, the mean lengths of primer extension products obtained with s(2)U is greater than those obtained with U, augmenting the potential for nonenzymatic replication of heritable function-rich sequences. We suggest that noncanonical nucleotides such as s(2)U may have played a role during the infancy of the RNA world by facilitating the nonenzymatic replication of genomic RNA oligonucleotides.

Crystal structure studies of RNA duplexes containing s(2)U:A and s(2)U:U base pairs.

Structural studies of modified nucleobases in RNA duplexes are critical for developing a full understanding of the stability and specificity of RNA base pairing. 2-Thio-uridine (s(2)U) is a modified nucleobase found in certain tRNAs. Thermodynamic studies have evaluated the effects of s(2)U on base pairing in RNA, where it has been shown to stabilize U:A pairs and destabilize U:G wobble pairs. Surprisingly, no high-resolution crystal structures of s(2)U-containing RNA duplexes have yet been reported. We present here two high-resolution crystal structures of heptamer RNA duplexes (5'-uagcs(2)Ucc-3' paired with 3'-aucgAgg-5' and with 3'-aucgUgg-5') containing s(2)U:A and s(2)U:U pairs, respectively. For comparison, we also present the structures of their native counterparts solved under identical conditions. We found that replacing O2 with S2 stabilizes the U:A base pair without any detectable structural perturbation. In contrast, an s(2)U:U base pair is strongly stabilized in one specific U:U pairing conformation out of four observed for the native U:U base pair. This s(2)U:U stabilization appears to be due at least in part to an unexpected sulfur-mediated hydrogen bond. This work provides additional insights into the effects of 2-thio-uridine on RNA base pairing.

Two Watson-Crick-like metallo base-pairs.

Two Watson-Crick-like metallo base-pairs are described with mutually independent geometries that have similar dimensions and stabilities to their natural, hydrogen-bonded counterparts.

Nonenzymatic oligomerization of RNA by TNA templates.

Cytosine TNA promotes nonenzymatic, template-directed oligomerization of complementary activated rGMP, leading to selective and efficient formation of RNA products. This process models "genetic takeover" of a pre-RNA by RNA. [reaction: see text]