Abstract
Simple nucleotide templating activities are of interest as potential primordial reactions. Here we describe the acceleration of 5′-5′ AppA synthesis by 3′-5′ poly(U) under normal solution conditions. This reaction is apparently templated via complementary U:A base-pairing, despite the involvement of two different RNA backbones, because poly(U), unlike other polymers, significantly stimulates AppA synthesis. These interactions occur in moderate (K+) and (Mg2+) and are temperature sensitive, being more efficient at 10°C than at 4°C, but absent at 20°C. The reaction is only slightly pH sensitive, despite potentially relevant substrate pKa’s. Kinetic data explicitly support production of AppA by interaction of stacked 2MeImpA and pA nucleotides paired with a single molecule of U template. At a lower rate, AppA can also be produced by a chemical reaction between 2MeImpA and pA, without participation of poly(U). Molecular modeling suggests that 5′-5′ joining between stacked or concurrently paired A's can occur without major departures from normal U-A helical coordinates. So, coenzyme-like 5′-5′ purine dinucleotides might be readily synthesized from 3′-5′ RNAs with complementary sequences.
Highlights
By many kinds of calculations, RNA and ribozymes are likely to have played early roles in life on Earth (Atkins et al 2011)
Even small known ribozymes can contain dozens of required ribonucleotides, making them statistically infrequent (Kennedy et al 2008), unstable because adjacent nucleotides can be aligned for easy hydrolysis (Soukup and Breaker 1999), burdened with replication that is poisoned by chirally related sugars (Joyce et al 1984b), and difficult to extricate from stable double-stranded replicative intermediates (Sievers and Von Kiedrowski 1994; Engelhart et al 2013)
We report here the apparent third-order reaction between poly(U), 5′ activated nucleotide 2MeImpA, and pA (5′ AMP) to yield the dinucleotide A5′pp5′A
Summary
By many kinds of calculations, RNA and ribozymes are likely to have played early roles in life on Earth (Atkins et al 2011). Even small known ribozymes can contain dozens of required ribonucleotides, making them statistically infrequent (Kennedy et al 2008), unstable because adjacent nucleotides can be aligned for easy hydrolysis (Soukup and Breaker 1999), burdened with replication that is poisoned by chirally related sugars (Joyce et al 1984b), and difficult to extricate from stable double-stranded replicative intermediates (Sievers and Von Kiedrowski 1994; Engelhart et al 2013) Many such problems are simultaneously solved if early RNAs are small, perhaps as small as dinucleotides (Yarus 2011).
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