Poly(U) RNA-templated synthesis of AppA.

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 (Mg(2+)) 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.

Chiral histidine selection by D-ribose RNA.

The invariant choice of L-amino acids and D-ribose RNA for biological translation requires explanation. Here we study this chiral choice using mixed, equimolar D-ribose RNAs having 15, 18, 21, 27, 35, and 45 contiguous randomized nucleotides. These are used for simultaneous affinity selection of the smallest bound and eluted RNAs using equal amounts of L- and D-His immobilized on an achiral glass support, with racemic histidine elution. The experiment as a whole therefore determines whether RNA containing D-ribose binds L-histidine or D-histidine more easily (that is, by using a site that is more abundant/requires fewer nucleotides). The most prevalent/smallest RNA sites are reproducibly and repeatedly selected and there is a four- to sixfold greater abundance of L-histidine sites. RNA's chiral D-ribose therefore yields a more frequent fit to L-histidine. Accordingly, a D-ribose RNA site for L-His is smaller by the equivalent of just over one conserved nucleotide. The most prevalent L-His site also performs better than the most frequent D-His site-but rarer D-ribose RNAs can bind D-His with excellent affinity and discrimination. The prevalent L-His site is one we have selected before under very different conditions. Thus, selection is again reproducible, as is the recurrence of cognate coding triplets in these most probable L-His sites. If our selected RNA population were equilibrated with racemic His, we calculate that L-His would participate in seven of eight His:RNA complexes, or more. Thus, if D-ribose RNA were first chosen biologically, translational L-His usage could have followed.

Nucleotides that are essential but not conserved; a sufficient L-tryptophan site in RNA.

Conservation is often used to define essential sequences within RNA sites. However, conservation finds only invariant sequence elements that are necessary for function, rather than finding a set of sequence elements sufficient for function. Biochemical studies in several systems-including the hammerhead ribozyme and the purine riboswitch-find additional elements, such as loop-loop interactions, required for function yet not phylogenetically conserved. Here we define a critical test of sufficiency: We embed a minimal, apparently sufficient motif for binding the amino acid tryptophan in a random-sequence background and ask whether we obtain functional molecules. After a negative result, we use a combination of three-dimensional structural modeling, selection, designed mutations, high-throughput sequencing, and bioinformatics to explore functional insufficiency. This reveals an essential unpaired G in a diverse structural context, varied sequence, and flexible distance from the invariant internal loop binding site identified previously. Addition of the new element yields a sufficient binding site by the insertion criterion, binding tryptophan in 22 out of 23 tries. Random insertion testing for site sufficiency seems likely to be broadly revealing.

Small aminoacyl transfer centers at GU within a larger RNA.

Separate aminoacyl transfer centers related to the small …GUNNN..: NNNU ribozyme seem possible at the frequent GU sequences dispersed throughout an RNA tertiary structure. In fact, such activity is easily detected and varies more than 2 orders in rate, probabably being faster at sites with less structural constraint. Analysis of a particular constrained active site in an rRNA transcript suggests that its difficulty lies not in substrate strand association, but in binding and/or group transfer from the aminoacyl precursor. Efficient aminoacyl transfer requires accurate complementarity between large or small ribozymes and oligoribonucleotide substrates, even when only three or four base pairs link the two. Thus, multi-site active ribozymal superstructures might have coordinated an RNA metabolism, including aiding an early translation apparatus.

Catalyzed and spontaneous reactions on ribozyme ribose.

The RNA world hypothesis requires that early translation be catalyzed by RNA enzymes. Here we show that a five-nucleotide RNA enzyme, reacting with a tetranucleotide substrate and elevated PheAMP, forms aminoacyl- and peptidyl-RNAs RNA-Phe through RNA-Phe(5). A second series of products is formed from RNA-Phe diesters, after trans migration of phenylalanine from the 2'- to the 3'-hydroxyl group of the substrate RNA, followed by reaminoacylation of the 2'-OH. While the ribozyme is required for initial attachment of phenylalanine to an RNA substrate, as well as reacylation (and thus for formation of all products), further extension into RNA-peptides appears to be an uncatalyzed, but RNA-stimulated reaction. The ribozyme readily turns over at high PheAMP and GCCU concentrations. Thus, GUGGC/GCCU comprises a true RNA enzyme. We define Michaelis-Menten parameters plus and minus divalent magnesium and characterize ca. 20 molecular species of aminoacyl-, peptidyl-, dipeptidyl-, and mixed peptidyl/aminoacyl-RNAs.

Phenylalanine-binding RNAs and genetic code evolution.

We isolated RNAs by selection-amplification, selecting for affinity to Phe-Sepharose and elution with free l-phenylalanine. Constant sequences did not contain Phe condons or anticodons, to avoid any possible confounding influence on initially randomized sequences. We examined the eight most frequent Phe-binding RNAs for inclusion of coding triplets. Binding sites were defined by nucleotide conservation, protection, and interference data. Together these RNAs comprise 70% of the 105 sequenced RNAs. The KD for the strongest sites is approximately 50 microM free amino acid, with strong stereoselectivity. One site strongly distinguishes free Phe from Trp and Tyr, a specificity not observed previously. In these eight Phe-binding RNAs, Phe codons are not significantly associated with Phe binding sites. However, among 21 characterized RNAs binding Phe, Tyr, Arg, and Ile, containing 1342 total nucleotides, codons are 2.7-fold more frequent within binding sites than in surrounding sequences in the same molecules. If triplets were not specifically related to binding sites, the probability of this distribution would be 4.8 x 10(-11). Therefore, triplet concentration within amino acid binding sites taken together is highly likely. In binding sites for Arg, Tyr, and Ile cognate codons are overrepresented. Thus Arg, Tyr, and Ile may be amino acids whose codons were assigned during an era of direct RNA-amino acid affinity. In contrast, Phe codons arguably were assigned by another criterion, perhaps during later code evolution.