Non-Watson-Crick RNA synthesis suited to origin functions.

A templated RNA synthesis is characterized in which G5'pp5'G accelerates synthesis of A5'pp5'A from pA and chemically activated ImpA precursors. Similar acceleration is not observable in the presence of UppU, CppC, AppG, AppA, or pG alone. Thus, it seems likely that AppA is templated by GppG via a form or forms of G:A base-pairing. AppA also appears, more slowly, via a previously known untemplated second-order chemical route. Such AppA synthesis requires only ordinary near-neutral solutions containing monovalent and divalent salts, and rates are only slightly sensitive to variation in pH. Templated synthesis rates are first order in pA, ImpA, and template GppG; thus third order overall. Therefore, this reaction resembles cross-templating of AppA on poly(U), but is notably slower and less sensitive to temperature. Viewing AppA as a coenzyme analog, GppG templating provides a simpler molecular route, termed para-templating, to encoded chemical functions. Para-templating can also arise from a single, localized nucleobase geosynthetic event which yields purines. It requires only a single backbone-forming chemistry. Thus it may have appeared earlier and served as evolutionary precursor for more complex forms of encoded genetic expression.

Cross-backbone templating; ribodinucleotides made on poly(C).

G(5')pp(5')G synthesis from pG and chemically activated 2MeImpG is accelerated by the addition of complementary poly(C), but affected only slightly by poly(G) and not at all by poly(U) and poly(A). This suggests that 3'-5' poly(C) is a template for uncatalyzed synthesis of 5'-5' GppG, as was poly(U) for AppA synthesis, previously. The reaction occurs at 50 mM mono- and divalent ion concentrations, at moderate temperatures, and near pH 7. The reactive complex at the site of enhanced synthesis of 5'-5' GppG seems to contain a single pG, a single phosphate-activated nucleotide 2 MeImpG, and a single strand of poly(C). Most likely this structure is base-paired, as the poly(C)-enhanced reaction is completely disrupted between 30 and 37 °C, whereas slower, untemplated synthesis of GppG accelerates. More specifically, the reactive center acts as would be expected for short, isolated G nucleotide stacks expanded and ordered by added poly(C). For example, poly(C)-mediated GppG production is very nonlinear in overall nucleotide concentration. Uncatalyzed NppN synthesis is now known for two polymers and their complementary free nucleotides. These data suggest that varied, simple, primordial 3'-5' RNA sequences could express a specific chemical phenotype by encoding synthesis of complementary, reactive, coenzyme-like 5'-5' ribodinucleotides.

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.

The plausibility of RNA-templated peptides: simultaneous RNA affinity for adjacent peptide side chains.

According to the RNA world hypothesis, coded peptide synthesis (translation) must have been first catalyzed by RNAs. Here, we show that small RNA sequences can simultaneously bind the dissimilar amino acids His and Phe in peptide linkage. We used in vitro counterselection/selection to isolate a pool of RNAs that bind the dipeptide NH(2)-His-Phe-COOH with K (D) ranging from 36 to 480 µM. These sites contact both side chains, usually including the protonated imidazole of His, but bind-free L: -His and L: -Phe with much lower, sometimes undetectable, affinities. The most frequent His-Phe sites do not usually contain previously isolated sites for individual amino acids, and are only ≈35 % larger than previously known separate His and Phe sites. Nonetheless, His-Phe sites appear enriched in His anticodons, as previous L: -His sites also were. Accordingly, these data add to existing experimental evidence for a stereochemical genetic code. In these peptide sites, bound amino acids approach each other to a proximity that allows a covalent peptide linkage. Isolation of several RNAs embracing two amino acids with a linking peptide bond supports the idea that a direct-RNA-template could encode primordial peptides, though crucial experiments remain.

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.

A diminutive and specific RNA binding site for L-tryptophan.

Selection for amino acid affinity by elution of RNAs from tryptophan-Sepharose using free L-tryptophan evokes one sequence predominantly (K(D) = 12 microM), a symmetrical internal loop of 3 nt per side. Though we have also isolated larger sequences with affinity for tryptophan, successively squeezed selection in randomized tracts of 70, 60, 40, 20 and 17 nt show that this internal loop is the simplest sequence that can meet the column affinity selection. From sequence variation in approximately 50 independent isolates, only 26 bits of information are required to describe this loop (equivalent to only 13 fully conserved nucleotides). Thus, it is among the simplest amino acid binding sites known, as well as selective among hydrophobic side chains. Among site sequences defined as essential to affinity by conservation, protection and modification-interference, there is a recurring CCA sequence (a tryptophan anticodon triplet) which apparently forms one side of the binding site. Such conserved juxtaposition of tryptophan with a cognate coding triplet supports a stereochemical origin for the genetic code.

RNA affinity for molecular L-histidine; genetic code origins.

Selection for affinity for free histidine yields a single RNA aptamer, which was isolated 54 times independently. This RNA is highly specific for the side chain and binds protonated L-histidine with 10(2)-10(3)-fold stereoselectivity and a dissociation constant (K(D)) of 8-54 microM in different isolates. These histidine-binding RNAs have a common internal loop-hairpin loop structure, based on a conserved RAAGUGGGKKN(0-36) AUGUN(0-2)AGKAACAG sequence. Notably, the repetitively isolated sequence contains two histidine anticodons, both implicated by conservation and chemical data in amino acid affinity. This site is probably the simplest structure that can meet our histidine affinity selection, which strengthens experimental support for a "stereochemical" origin of the genetic code.

Selection of the simplest RNA that binds isoleucine.

We have identified the simplest RNA binding site for isoleucine using selection-amplification (SELEX), by shrinking the size of the randomized region until affinity selection is extinguished. Such a protocol can be useful because selection does not necessarily make the simplest active motif most prominent, as is often assumed. We find an isoleucine binding site that behaves exactly as predicted for the site that requires fewest nucleotides. This UAUU motif (16 highly conserved positions; 27 total), is also the most abundant site in successful selections on short random tracts. The UAUU site, now isolated independently at least 63 times, is a small asymmetric internal loop. Conserved loop sequences include isoleucine codon and anticodon triplets, whose nucleotides are required for amino acid binding. This reproducible association between isoleucine and its coding sequences supports the idea that the genetic code is, at least in part, a stereochemical residue of the most easily isolated RNA-amino acid binding structures.